Difference between revisions of "BIO Assignment 3 2011"

From "A B C"
Jump to navigation Jump to search
 
(12 intermediate revisions by the same user not shown)
Line 1: Line 1:
<!-- {{Template:Active}} -->
+
<!-- {{Template:Inactive}} -->
{{Template:Inactive}}
+
{{Template:Active}}
  
 +
&nbsp;<br>
  
&nbsp;
+
__TOC__
&nbsp;
 
  
__TOC__
+
&nbsp;<br>
&nbsp;
 
&nbsp;
 
  
 
<div style="padding: 5px; background: #A6AFD0;  border:solid 1px #AAAAAA; font-size:200%;font-weight:bold;">
 
<div style="padding: 5px; background: #A6AFD0;  border:solid 1px #AAAAAA; font-size:200%;font-weight:bold;">
Assignment 3 - Multiple Sequence Alignment
+
Assignment 3 (last: 2011) - Multiple Sequence Alignment
 
</div>
 
</div>
  
 +
&nbsp;<br>
 +
 +
{{Template:Preparation|
 +
care=Be sure you have understood all parts of the assignment and cover all questions in your answers! Sadly, we always get assignments back in which people have simply overlooked crucial questions. Sadly, we always get assignments back in which people have not described procedural details. If you did not notice that the above were two different sentences, you are still not reading carefully enough.|
 +
num=3|
 +
ord=third|
 +
due = Monday, November 21. at 12:00}}
 +
 +
;Your documentation for the procedures you follow in this assignment will be worth 1 mark.
  
 +
 +
&nbsp;<br>
  
 
<div style="padding: 2px; background: #F0F1F7;  border:solid 1px #AAAAAA; font-size:125%;color:#444444">
 
<div style="padding: 2px; background: #F0F1F7;  border:solid 1px #AAAAAA; font-size:125%;color:#444444">
 
Introduction
 
Introduction
&nbsp;
+
 
 +
&nbsp;<br>
  
 
;Take care of things, and they will take care of you.
 
;Take care of things, and they will take care of you.
Line 24: Line 34:
 
</div>
 
</div>
  
A carefully done multiple sequence alignment (MSA) is a cornerstone for the annotation of a gene or protein. MSAs combine the information from several related proteins, allowing us to study their essential, shared and conserved properties. They are useful to resolve ambiguities in the precise placement of gaps and to ensure that columns in alignments actually contain amino acids that evolve in a similar context. Therefore we need MSAs as input for  
+
Much of what we know about a protein's physiological function is based on the '''conservation''' of that function as the species evolves. We assess conservation by comparison to related proteins. Conservation - or variability - is a consequence of '''selection under constraints''': the multiple effects on a species' fitness function that are induced through changes to the structural or functional features of a protein. Conservation patterns can thus provide evidence for many different questions: structural conservation among proteins with similar 3D-structures, functional conservation among homologues with comparable roles, peaks of sequence variability that indicate domain boundaries in multi-domain proteins, or amino acid propensities as predictors for protein engineering and design tasks.
* protein homology modeling,
+
 
 +
Measuring conservation requires alignment. Therefore a carefully done multiple sequence alignment (MSA) is a cornerstone for the annotation of the essential properties a gene or protein. MSAs are also useful to resolve ambiguities in the precise placement of indels and to ensure that columns in alignments actually contain amino acids that evolve in a similar context. MSAs serve as input for  
 +
* functional annotation;
 +
* protein homology modeling;
 
* phylogenetic analyses, and
 
* phylogenetic analyses, and
 
* sensitive homology searches in databases.
 
* sensitive homology searches in databases.
  
In addition, conservation - or the lack of conservation - is a consequence of selection under the constraints imposed by the structural or functional features of a protein. Conservation patterns emphasize domain boundaries in multi-domain proteins, and amino acid propensities are powerful predictors for protein engineering and design.
 
  
Given the ubiquitous importance of multiple sequence alignment, it is remarkable that by far the most frequently used algorithm is CLUSTAL, a procedure that was first published for the microprocessors of the late 1980s, surpassed in performance many times, and shown to be significantly inferior to more modern approaches when aligning sequences with about 30% identity or less.
+
As a first step, we will explore the search and retrieval of fungal proteins that are orthologous to yeast Mbp1, and of the APSES domains they contain. Each student is being assigned one genome-sequenced fungus. Briefly, you will
  
In this assignment we will explore MSAs of fungal proteins that are orthologous to yeast Mbp1, and of the APSES domains they contain, and compare several approaches to alignment:
+
# Collect sequence identifiers for all APSES domain transcription factors in [[Species list|your assigned species]];
 +
# Retrieve the sequences;
 +
# Perform a multiple sequence alignment with these, and a number of reference domains;
 +
# Edit the alignment and annotate.
 +
 
 +
 
 +
Multiple Sequence Alignment is not a solved, computational problem and a significant number of alignment tools exist, each with different strengths and objectives. It is remarkable that by far the most frequently used MSA algorithm is CLUSTAL, a procedure that was first published for the microprocessors of the late 1980s, surpassed in performance many times, and shown to be significantly inferior to more modern approaches when aligning sequences with 30% identity or less. In this assignment we will encounter various approaches to multiple alignment:
  
 
* A model-based approach (based on the [[Glossary#PSSM| PSSM]] that PSI-BLAST generates)
 
* A model-based approach (based on the [[Glossary#PSSM| PSSM]] that PSI-BLAST generates)
* A progressive alignment - the CLUSTAL algorithm
+
* Progressive alignments - CLUSTAL and MAFFT
* A consistency based alignment - T-Coffee, MUSCLE or Probcons
+
* Consistency based alignment - T-Coffee and MUSCLE
 +
 
 +
 
 +
<div style="padding: 5px; background: #BDC3DC;  border:solid 1px #AAAAAA;">
 +
==(1) Mbp1 homologues==
 +
</div>
  
  
<div style="padding: 2px; background: #F0F1F7;  border:solid 1px #AAAAAA; font-size:125%;color:#444444">
+
<div style="padding: 5px; background: #E9EBF3;  border:solid 1px #AAAAAA;">
Preparation, submission and due date
+
===(1.1) Retrieving sequences===
 
</div>
 
</div>
  
Please read carefully. Be sure you have understood all parts of the assignment and cover all questions in your answers! Sadly, we always get assignments back in which people have simply overlooked crucial questions. Sadly, we always get assignments back in which people have not described procedural details. If you did not notice that the above were two different sentences, you are still not reading carefully enough.
 
  
Prepare a Microsoft Word document with a title page that contains:
+
In [[Assignment 2]] you retrieved the protein sequences of ''saccharomyces cerevisiae'' [http://www.ncbi.nlm.nih.gov/entrez/viewer.fcgi?db=protein&val=6320147 '''Mbp1'''] and defined its APSES (KilA-N) domain. Let us now search for an orthologue of this sequence in ''[[Species list|Your Species]]''. More precisely, you should identify proteins that fulfill the '''Reciprocal Best Match''' criterion.
*your full name
 
*your Student ID
 
*your e-mail address
 
*the organism name you have been [[Organism_list_2007|assigned]]
 
  
Follow the steps outlined below. You are encouraged to write your answers in short answer form or point form, '''like you would document an analysis in a laboratory notebook'''. However, you must
+
First, we need to '''define the sequence''' you will use to find Mbp1 homologues. Since Mbp1 contains the very widely distributed Ankyrin motifs, a BLAST search with full length sequences will pick up a large number of Ankyrin-repeat containing proteins that are otherwise unrelated to our query. We will instead search for homologues using only the APSES domain as a query. However, the Pfam definition of the APSES domain (or KilA-N family, as it is now called) does not cover the entire length of the domain that has been crystallized. Therefore, we will use the sequence of the crystallized protein instead of the Pfam alignment. One of the results of our analysis will be '''whether APSES domains in fungi all have the same length as the Mbp1 domain, or whether some are indeed much shorter, as sugested by the Pfam alignment.''' To remind you, here is the full sequence of the [http://www.pdb.org/pdb/explore/derivedData.do?structureId=1MB1 1MB1 structure] (Note that the C-terminal His<sub>6</sub> tag that has been added for purification is not part of the Mbp1 protein sequence.) ...  
*document what you have done,  
 
*note what Web sites and tools you have used,
 
*paste important data sequences, alignments, information etc.
 
  
'''If you do not document the process of your work, we will deduct marks.'''  Try to be concise, not wordy! Use your judgement: are you giving us enough information so we could exactly reproduce what you have done? If not, we will deduct marks. Avoid RTF and unnecessary formating. Do not paste screendumps or other uncompressed images. The size of your submission must remain '''below 1.5 MB'''.
 
  
Write your answers into separate paragraphs and give each its title. Save your document with a filename of:
+
>PDB:1MB1
<code>A3_family name.given name.doc</code>
+
MSNQIYSARYSGVDVYEFIHSTGSIMKRKKDDWVNATHILKAANFAKAKRTRILEKEVLKETHEKVQGGFGKYQGTWVPL
<small>(for example my submission would be named: A3_steipe.boris.doc - and don't switch the order of your given name and family name please!)</small>
+
NIAKQLAEKFSVYDQLKPLFDFTQTDGSASPPPAPKHHHASKVDHHHHHH
  
Finally e-mail the document to [mailto:boris.steipe@utoronto.ca boris.steipe@utoronto.ca] before the due date.
 
  
Your document must not contain macros. Please turn off and/or remove all macros from your Word document; we will disable macros, since they pose a security risk.
+
... and, for comparison, this is the corresponding alignment with the Pfam KilA-N model obtained from a '''[http://www.ncbi.nlm.nih.gov/Structure/cdd/wrpsb.cgi RPS-BLAST]''' search of the above sequence against the '''[http://www.ncbi.nlm.nih.gov/cdd/ CDD database]''':
  
With the number of students in the course, we have to economize on processing the assignments. '''Thus we will not accept assignments that are not prepared as described above.''' If you have technical difficulties, contact the course coordinator.
 
  
'''The due date for the assignment is Sunday, October 28. at 21:00.'''
+
<span style="color:#700777;">                          10        20        30        40        50        60        70        80</span>
 +
<span style="color:#700777;">                  ....*....|....*....|....*....|....*....|....*....|....*....|....*....|....*....|</span>
 +
<b>1MB1</b>          <span style="color:#229922;"> 19 </span><span style="color:#2233cc;">IHSTGS</span><span style="color:#ff4466;">I</span><span style="color:#2233cc;">MK</span><span style="color:#ff4466;">R</span><span style="color:#2233cc;">K</span><span style="color:#ff4466;">KD</span><span style="color:#2233cc;">DWV</span><span style="color:#ff4466;">NAT</span><span style="color:#2233cc;">HIL</span><span style="color:#ff4466;">KAA</span><span style="color:#2233cc;">NFA</span><span style="color:#ff4466;">K</span><span style="color:#888888;">a</span><span style="color:#2233cc;">KRTRI</span><span style="color:#ff4466;">L</span><span style="color:#2233cc;">EK</span><span style="color:#ff4466;">E</span><span style="color:#2233cc;">VL</span><span style="color:#ff4466;">KE</span><span style="color:#2233cc;">TH</span><span style="color:#ff4466;">E</span><span style="color:#2233cc;">KVQ</span><span style="color:#888888;">----------------</span><span style="color:#ff4466;">G</span><span style="color:#2233cc;">GF</span><span style="color:#ff4466;">G</span><span style="color:#2233cc;">KY</span><span style="color:#ff4466;">QGT</span><span style="color:#2233cc;">W</span><span style="color:#ff4466;">V</span><span style="color:#2233cc;">PLNI</span> <span style="color:#229922;">82</span>
 +
 +
Cdd:pfam04383  <span style="color:#229922;">  3 </span><span style="color:#2233cc;">YNDFEI</span><span style="color:#ff4466;">I</span><span style="color:#2233cc;">IR</span><span style="color:#ff4466;">R</span><span style="color:#2233cc;">D</span><span style="color:#ff4466;">KD</span><span style="color:#2233cc;">GYI</span><span style="color:#ff4466;">NAT</span><span style="color:#2233cc;">KLC</span><span style="color:#ff4466;">KAA</span><span style="color:#2233cc;">GAT</span><span style="color:#ff4466;">K</span><span style="color:#888888;">-</span><span style="color:#2233cc;">RFRNW</span><span style="color:#ff4466;">L</span><span style="color:#2233cc;">RL</span><span style="color:#ff4466;">E</span><span style="color:#2233cc;">ST</span><span style="color:#ff4466;">KE</span><span style="color:#2233cc;">LI</span><span style="color:#ff4466;">E</span><span style="color:#2233cc;">ELS</span><span style="color:#888888;">kennidvliievenkk</span><span style="color:#ff4466;">G</span><span style="color:#2233cc;">KN</span><span style="color:#ff4466;">G</span><span style="color:#2233cc;">RL</span><span style="color:#ff4466;">QGT</span><span style="color:#2233cc;">Y</span><span style="color:#ff4466;">V</span><span style="color:#2233cc;">HPDL</span> <span style="color:#229922;">81</span>
 +
 +
 +
<span style="color:#700777;">                          90</span>
 +
<span style="color:#700777;">                  ....*....|....*</span>
 +
<b>1MB1</b>          <span style="color:#229922;"> 83 </span><span style="color:#ff4466;">A</span><span style="color:#2233cc;">KQL</span><span style="color:#ff4466;">A</span><span style="color:#888888;">----</span><span style="color:#2233cc;">EK</span><span style="color:#ff4466;">F</span><span style="color:#2233cc;">SVY</span> <span style="color:#229922;">93</span>
 +
 +
Cdd:pfam04383  <span style="color:#229922;"> 82 </span><span style="color:#ff4466;">A</span><span style="color:#2233cc;">LAI</span><span style="color:#ff4466;">A</span><span style="color:#888888;">swis</span><span style="color:#2233cc;">PE</span><span style="color:#ff4466;">F</span><span style="color:#2233cc;">ALK</span> <span style="color:#229922;">96</span>
 +
 
 +
 
 +
As you can see, the Pfam alignment is 18 amino acids shorter at the N-terminus and 31 amino acids shorter at the C-terminus.  
  
<div style="padding: 2px; background: #F0F1F7; border:solid 1px #AAAAAA; font-size:125%;color:#444444">
+
 
Grading
+
;Find APSES domain proteins in your species:
 +
 
 +
<div style="padding: 5px; background: #EEEEEE;">
 +
#Access the [[Species list|species list]] and identify the species that has been assigned to you.
 +
#Navigate to the [http://www.ncbi.nlm.nih.gov '''NCBI's main page'''].
 +
#In the left-hand menu of links, follow the link to [http://www.ncbi.nlm.nih.gov/guide/genomes-maps/ '''Genomes &amp; Maps'''].
 +
#Under the '''Databases''' tab, follow the link to [http://www.ncbi.nlm.nih.gov/genome '''Genome'''].
 +
#In the '''Genome tools''' section of that page, follow the link to [http://www.ncbi.nlm.nih.gov/sutils/genom_table.cgi?species=euk '''Genomic groups BLAST'''].
 +
#Click on link to the '''eukaryotic''' genomes tree, then on the link for the '''text table'''. This produces a BLAST interface to a list of species for which whole-genome sequences have been sequenced, annotated and entered into the various databases.
 +
#Paste the FASTA sequence of the structurally defined Mbp1 APSES domain (e.g. from [http://www.pdb.org/pdb/explore/derivedData.do?structureId=1MB1 1MB1]) into the search field (excluding the His-tag, of course), set the parameters correctly for a '''Protein''' search against '''Protein''' sequences using '''blastp'''. Then find your [[Species list|assigned species]] in the table and check the box next to its name. Remember to record the parameters for your search. I expect you to understand which parameters would be needed in order to make this search reproducible. Run the search.
 +
#On the next screen, check the box next to '''Format for: PSI-BLAST'''. Then click on '''View report''' to show the results of the first PSI-BLAST iteration.
 +
#Run subsequent iterations of PSI-BLAST simply by clicking on '''Go''' after checking the sequences that have been included.
 +
#Iterate the PSI-BLAST search until convergence (i.e. until no more '''new''' sequences are added); make sure to include only sequences for which the E-value is small (smaller than about 10e-03 should be safe). Sequences with borderline E-values that improve significantly in an iteration are probably homologues. Sequences with borderline E-values that do not improve much, or for which the E-value increases are probably not homologues.  If this step does not work for you or the results are not what you expect, please contact your TA right away.
 +
 
 +
*Note: Please spend a little time on each page to understand its contents. <small>Ask, if the page contains resources or features you don't understand. Think about what you are doing. If you simply click on the links I provide, you will miss the opportunity to understand how the resources fit into the workflow you are working on, and to be able to execute similar processes yourself. Questions on page contents can potentially appear on quizzes and exam.</small>  
 
</div>
 
</div>
  
Don't wait until the last day to find out there are problems! Assignments that are received past the due date will have one mark deducted and an additional mark for every full twelve hour period past the due date. Assignments received more than 5 days past the due date will not be assessed.  If you need an extension, you '''must''' arrange this beforehand.
 
  
Marks are noted below in the section headings for of the tasks. A total of 10 marks will be awarded, if your assignment answers all of the questions. A total of 2 bonus marks (up to a maximum of 10 overall) can be awarded for particularily interesting findings, or insightful comments. A total of 2 marks can be subtracted for lack of form or for glaring errors. The marks you receive will
+
Familiarize yourself with the '''output form''' you obtain, this is by far the most frequently used bioinformatics result page. You may want to refer to the [http://www.ncbi.nlm.nih.gov/staff/tao/URLAPI/new_view.html NCBI explanation].  
* count directly towards your final marks at the end of term, for BCH441 (undergraduates), or
+
 
* be divided by two for BCH1441 (graduates).
+
Here is a list of things to look for, all of which I expect you to know and understand. (However you do not need to comment on these points in your submission.)
 +
 
 +
;On the alignment image:
 +
*What do the different colored bars mean?
 +
*What is the information you get when you "mouse-over" a colored bar on the alignment image.
 +
*What happens when you click on one of the bars?
 +
 
 +
;In the description list:
 +
*Where does the link next to an identifier take you?
 +
*Where does the link in the "score" column take you?
 +
*What does the icon at the end of each row mean? What other icons could appear there? <!-- cf. [http://www.ncbi.nlm.nih.gov/staff/tao/URLAPI/new_view.html] -->
 +
 
 +
;In the alignment section:
 +
*What do the alignment metrics mean:
 +
**Score?
 +
**Expect (E-value)?
 +
**Identities?
 +
**Positives?
 +
**Gaps?
 +
*What is the alignment length?
 +
*Which sequence is labeled '''Query''' and which one is labelled '''Sbjct'''?
 +
 
 +
 
 +
;Next
 +
:retrieve the sequences that have E-values low enough to make you conclude they contain APSES domain homologues.
  
&nbsp;
+
<div style="padding: 5px; background: #EEEEEE;">
&nbsp;
 
  
<div style="padding: 5px; background: #BDC3DC;  border:solid 1px #AAAAAA;">
+
#Review the sequences you have found: they should all be significantly similar to the query profile. In some of the assigned species you will find one hit for each distinct sequence in the genome, in others, you will find several versions of essentially the same gene (e.g. refseq and other accession numbers).
==(1) Retrieve==
+
#Explore the relationship between the hits by clicking on '''select all sequences''', then choosing '''Distance tree of results''' at the top or bottom of your search results to visualize a tree representation of similarity. Highly similar sequences will be collapsed into the same node in the distance tree; you can expand those nodes to list all the node's members.
 +
#Identify '''one''' representative for each distinct protein you have found. If possible, use proteins with refseq identifiers. Avoid duplicates or nearly identical variants. If there are length differences, use the longer version (shorter versions may contain only partial sequences). Click on the checkbox next to each protein you have identified.
 +
#Click on '''get selected sequences''' at the top or bottom of the page. Note and record the GIs for your sequences that are listed in the ''Search details'' box, you can use them to easily reproduce your results by pasting them into any Entrez search. Also note the URL that this has produced (in your browser's URL bar). As you see, you can retrieve a list of sequences from NCBI simply by adding a list of comma-separated GI numbers to the [http://www.ncbi.nlm.nih.gov/protein/ URL of the protein database].
 +
#Click on '''Display settings''' and choose '''FASTA (text)'''.
 +
 
 +
<small>If you want, for comparison, you can run a multiple alignment with an NCBI-developed MSA tool: '''COBALT'''. On the sequence list page, in the right-hand column, in the section '''Analyze these sequences''', click on '''Align sequences with COBALT'''. It is a convenient way to get a quick first look at an alignment of NCBI retrieved sequences.</small>
 
</div>
 
</div>
&nbsp;
 
&nbsp;
 
  
In [[Assignment 2]] you retrieved the protein sequences of ''saccharomyces cerevisiae'' [http://www.ncbi.nlm.nih.gov/entrez/viewer.fcgi?db=protein&val=6320147 '''Mbp1'''] and its orthologue in your assigned organism. In order to produce a multiple sequence alignment, we have to define which sequences we wish to use. Then we need to retrieve the sequences from the database. Finally we have to store the sequences in a format that we can use as input for the alignment programs.
+
You now have a collection of APSES domain-containing homologues in your organism. There are two more tasks we need to address before we can compute alignments and analyze them. (A) we need to rename our sequences, and (B) we need to define the boundaries of their APSES domains.  
 +
 
 +
 
  
 
<div style="padding: 5px; background: #E9EBF3;  border:solid 1px #AAAAAA;">
 
<div style="padding: 5px; background: #E9EBF3;  border:solid 1px #AAAAAA;">
===(1.1) Input data for multiple alignments (1 mark)===
+
 
 +
===(1.2) Renaming Sequences===
 
</div>
 
</div>
&nbsp;<br>
 
  
<hr>
+
A phylogenetic tree or multiple alignment is not really informative if it that displays GI numbers or other abstract identifiers as labels of rows or nodes. The relationship between species is fundamental to the variation we observe and we need to make this relationship explicit.
 +
 
 +
Imagine that the rows in an MSA were completely unlabeled, or the nodes in the tree would be just circles: we would have a very hard time relating the computed relationships back to the biology they represent. Abstract identifiers like <tt>NP_010227</tt> are not much better.
 +
 
 +
Typically, the information that programs use to label sequences is taken from the FASTA header. This provides us with an easy way to make sure they display the information we need and that we can interpret. Typically such programs will use the first few (often ten) characters they find. We will therefore design short strings strings that identify potential gene family relationships as well as species.
 +
 
 +
 
 +
;Species codes
 +
 
 +
The scientific name of a species is formed according to Linnaean [http://en.wikipedia.org/wiki/Binomial_nomenclature binomial nomenclature] and Swissprot has for a long time condensed species names into mnemonic five-character codes, taking the first three from the [http://en.wikipedia.org/wiki/Genus genus name] and the last two from the [http://en.wikipedia.org/wiki/Specific_name specific name]. For example ''Saccharomyces cerevisiae'' is abbreviated as <tt>SACCE</tt> and ''Lachancea thermotolerans'' is <tt>LACTH</tt>. For the most part, this creates unique strings that are good mnemonic labels for the species. I have added these "codes" to the [[Species list]].
 +
 
 +
 
 +
;Gene families
 +
Most yeast genes have traditional names, like mbp1 or sok2. These names are convenient family labels since ''saccharomyces cerevisiae'' is one of the best studied [http://en.wikipedia.org/wiki/Model_organism model organisms]. Therefore, once we identify a protein family that includes a yeast gene, we can easily access expert knowledge in textbooks or manuscripts. Of course, such labels are arbitrary - whether we call a gene '''Mbp1''' or '''WXYZ''' makes no difference - as long as all genes that we presume to be family members carry the same label.  For higher eukaryotes, I would probably choose human gene names as a reference point, for bacteria I would choose ''E. coli''.
 +
 
 +
To define which gene belongs into which family, we can align all newly found genes with all yeast APSES domain homologues, to find out which ones they are most similar to. This creates common family labels.  We can use these as provisional family names for the encoded proteins, even though we may want to revise them once we have mapped out explicit phylogenetic trees.
 +
 
 +
 
 +
;Identifying APSES domains (general procedure).
 +
In order to identify the APSES domain boundaries, you can simply run a multiple sequence alignment of the structurally defined APSES domain sequence (e.g. taken from PDB-ID 1MB1) against all sequences you have found. The boundaries of the aligned APSES domain then define the domain boundaries in the aligned proteins.
 +
 
  
Mbp1 is a large multidomain protein; it binds DNA through a small domain called the APSES domain and many organisms have more than one transcription factor that has a domain homologous to other APSES domains. In the assignments, we will analyse how these APSES domains have evolved, to obtain a perspective on the evolution of regulatory systems in general. Accordingly we should first define an APSES domain sequence and then use it to find all its relatives in each target organism.
+
;Identifiying family relationships (in the same run)
 +
However, for efficiency, we can also determine '''family relationships''' in the same alignment that we use to define domain boundaries, if we simply include '''all''' yeast APSES domains in the MSA. Then we can judge similarity simply from examining the guide tree of the alignment and label the families accordingly. This has the added advantage that the domain boundaries are more securely defined, since we include more sequence information into the alignment.
  
&nbsp;<br>
+
;Proceed as follows.
Use the NCBI Entrez system to search for the string "apses" in the "Conserved Domains" database and access the entry for the APSES domain. You should find a number of aligned sequences on that page, each with their own GI identifier.  
 
  
 
<div style="padding: 5px; background: #EEEEEE;">
 
<div style="padding: 5px; background: #EEEEEE;">
*Identify the two sequences that come from ''Saccharomyces cerevisiae'' (the Mbp1 and Swi4 APSES domains).
+
#Open the [http://www.ebi.ac.uk/Tools/muscle/ Muscle MSA input page] at the EBI.
 +
#Access the [[APSES domains (yeast)|Yeast APSES domain collection]] I have prepared and copy the FASTA sequences. Paste them into the sequence field of the MUSCLE program input form.
 +
#Copy the FASTA sequenced of the full length APSES domain protein sequence collection from your PSI-BLAST search (above) and paste them into the MUSCLE input form as well.
 +
#Set the following parameters:
 +
 
 +
OUTPUT FORMAT: CLUSTALW2
 +
OUTPUT TREE: from second iteration
 +
OUTPUT ORDER: aligned
 +
 
 +
#Click on Submit.  
 
</div>
 
</div>
  
&nbsp;<br>
+
 
Access the GenPept (NCBI protein) record for the ''Saccharomyces cerevisiae'' Mbp1 protein.  
+
The output should show the MSA. The overlap of the yeast APSES domains with your sequences defines the domain boundaries. Moreover, a tree has been calculated and you can view the tree to identify family relationships.
 +
 
 +
;Visualize the alignment tree and decide on names
  
 
<div style="padding: 5px; background: #EEEEEE;">
 
<div style="padding: 5px; background: #EEEEEE;">
*Obtain the FASTA sequence for the whole, full-length protein, save it and paste it into your assignment.
+
Click on the link to the Guide tree. This is the so-called Newick tree format and there are a large number of online tree viewers to visualize such trees. The MUSCLE form will display one tree for you,
 +
 
 +
<small>You could also navigate (for example) to the [http://www.proweb.org/treeviewer/ proWeb Tree viewer] and paste the tree data into the '''User-supplied Newick Tree''' input field. Choose any graphics format your browser can handle (JPEG is a pretty safe bet) and click on '''View tree'''.</small>
 +
 
 +
 
 +
#Interpret the tree to decide on the protein family names for your sequences:
 +
##If a yeast protein is grouped with exactly one of your proteins, your protein gets the same name.
 +
##If a yeast protein is grouped with more than one of your proteins, replace the number in the yeast protein with a, b, c ..., from most similar to least similar for your protein. For example: if one Aspergillus fumigatus protein is most similar to yeast Mbp1, you will give it the name MBP1_ASPFU. If two proteins are both most similar to yeast Sok2, you will name them SOKA_ASPFU and SOKB_ASPFU. Try to get it approximately right but remember that this is a process of estimation - we are not accurately measuring distances (yet).
 +
 
 +
That done, edit your FASTA headers and save your APSES domain sequence set. We will need them for the next assignment.
 +
 
 +
</div>
 +
 
 +
 
 +
 
 +
<div style="padding: 5px; background: #BDC3DC;  border:solid 1px #AAAAAA;">
 +
 
 +
==(2) Align and Annotate==
 
</div>
 
</div>
  
 
&nbsp;<br>
 
&nbsp;<br>
Working from the APSES domain alignment in CDD, define the sequence of the entire APSES domain in the Mbp1 protein.
+
 
 +
 
 +
<div style="padding: 5px; background: #E9EBF3;  border:solid 1px #AAAAAA;">
 +
===(2.1) Review of domain annotations===
 +
</div>
 +
 
 +
APSES domains are relatively easy to identify and annotate but we have had problems with the ankyrin domains in Mbp1 homologues. Both CDD as well as SMART have identified such domains, but while the domain model was based on the same Pfam profile for both, and both annotated approximately the same regions, the details of the alignments and the extent of the predicted region was different.
 +
 
 +
[http://www.yeastgenome.org/cgi-bin/locus.fpl?locus=mbp1 Mbp1] forms heterodimeric complexes with a homologue, [http://www.yeastgenome.org/cgi-bin/locus.fpl?locus=swi6 Swi6]. Swi6 does not have an APSES domain, thus it does not bind DNA. But it is similar to Mbp1 in the region spanning the ankyrin domains and in 1999 [http://www.ncbi.nlm.nih.gov/pubmed/10048928 Foord ''et al.''] published its crystal structure ([http://www.rcsb.org/pdb/cgi/explore.cgi?pdbId=1SW6 1SW6]). This structure is a good model for Ankyrin repeats in Mbp1. For details, please refer to the consolidated [[Mbp1 annotation|Mbp1 annotation page]] I have prepared.
 +
 
 +
In what follows, we will use the program JALVIEW - a Java based multiple sequence alignment editor to load and align sequences and to consider structural similarity between yeast Mbp1 and its closest homologue in your organism.
 +
 
 +
In this part of the assignment,
 +
 
 +
#You will load sequences that are most similar to Mbp1 into an MSA editor;
 +
#You will add sequences of ankyrin domain models;
 +
#You will perform a multiple sequence alignment;
 +
#You will try to improve the alignment manually;
 +
<!-- Finally you will consider if the Mbp1 APSES domains could extend beyond the section of homology with Swi6 -->
 +
 
 +
 
 +
<div style="padding: 5px; background: #E9EBF3;  border:solid 1px #AAAAAA;">
 +
 
 +
===(2.2) Jalview, loading sequences===
 +
</div>
 +
 
 +
Geoff Barton's lab in Dundee has developed an integrated MSA editor and sequence annotation workbench with a number of very useful functions. It is written in Java and should run on Mac, Linux and Windows platforms without modifications. We will use this tool for this assignment and explore its features as we go along.  
  
 
<div style="padding: 5px; background: #EEEEEE;">
 
<div style="padding: 5px; background: #EEEEEE;">
*Save the sequence of the Mbp1 APSES domain in FASTA format (i.e. give it an appropriate header) and paste it into your assignment. Comment if and how it is different from the sequence you find on the CDD page.
+
#Navigate to the [http://www.jalview.org/ Jalview homepage] click on '''Download''', install Jalview on your computer and start it. A number of windows that showcase the program's abilities will load, you can close these.
 +
#Prepare homologous Mbp1 sequences for alignment:
 +
##Find the sequence in your assigned species that fulfills the Reciprocal Best Match crierion with yeast Mbp1.
 +
##Open the [[Mbp1 RBM reference sequences]] page.
 +
##Copy the FASTA sequences of the reference proteins, return to Jalview and select File &rarr; Input Alignment &rarr; from Textbox and paste the sequences into the textbox.
 +
##Also paste a FASTA sequence of your species' Mbp1 protein into the window.
 +
##Finally copy the sequences for ankyrin domain models (below) and paste them into the Jalview textbox as well. Paste two separate copies of the CD00204 consensus sequence and one copy of 1SW6.
 +
##When all the sequences are present, click on New Window. Jalview gives you all the sequences, but of course this is not yet an alignment.
 +
 
 
</div>
 
</div>
  
&nbsp;<br>
+
;Ankyrin domain models
Navigate back to the Genome Project Database table for fungi and click on the '''"B"''' link next to your organism. This takes you to a page with a BLAST search form. Run a BLAST search with the full-length ''Saccharomyces cervisiae'' Mbp1 protein sequence against the proteins of your organism only!
+
>CD00204 ankyrin repeat consensus sequence from CDD
<!-- (In the case of Schizosaccharomyces pombe, it appears the link is not included on that page but you have to go through the main BLAST page and use the drop down selection in the "Options" field to limit your query to S. pombe). -->
+
NARDEDGRTPLHLAASNGHLEVVKLLLENGADVNAKDNDGRTPLHLAAKNGHLEIVKLLL
 +
EKGADVNARDKDGNTPLHLAARNGNLDVVKLLLKHGADVNARDKDGRTPLHLAAKNGHL
 +
 
 +
>1SW6 from PDB - unstructured loops replaced with xxxx
 +
GPIITFTHDLTSDFLSSPLKIMKALPSPVVNDNEQKMKLEAFLQRLLFxxxxSFDSLLQE
 +
VNDAFPNTQLNLNIPVDEHGNTPLHWLTSIANLELVKHLVKHGSNRLYGDNMGESCLVKA
 +
VKSVNNYDSGTFEALLDYLYPCLILEDSMNRTILHHIIITSGMTGCSAAAKYYLDILMGW
 +
IVKKQNRPIQSGxxxxDSILENLDLKWIIANMLNAQDSNGDTCLNIAARLGNISIVDALL
 +
DYGADPFIANKSGLRPVDFGAG
 +
 
 +
 
  
<div style="padding: 5px; background: #EEEEEE;">
+
<div style="padding: 5px; background: #E9EBF3;  border:solid 1px #AAAAAA;">
*Record the parameters you have used for the search and the relevant search results.
 
  
*List the accession numbers and names of all putative homologues. How many are there? How many (if any) do you expect? What do you conclude ?
+
===(2.3) Computing alignments===
 
</div>
 
</div>
  
&nbsp;<br>
+
Sequence alignments can be calculated directly from Jalview.
Run a second BLAST search using only the ''Saccharomyces cervisiae'' Mbp1 APSES domain sequence.
 
  
 
<div style="padding: 5px; background: #EEEEEE;">
 
<div style="padding: 5px; background: #EEEEEE;">
*Record the parameters you have used for the search and the relevant search results.
+
#In Jalview, select '''Web Service &rarr; Alignment &rarr; MAFFT Multiple Protein Sequence Alignment'''. The alignment is calculated in a few minutes and displayed in a new window.
 +
#Choose '''Colour &rarr; Hydrophobicity''' and '''&rarr; by Conservation'''. Then select '''Modify Conservation Threshold...'''  and adjust the slider left or right to see which columns are highly conserved. You will notice that the Swi6 sequence that was supposed to align only to the ankyrin domains was in fact aligned to other parts of the sequence as well. This is one part of the MSA that we will have to correct manually and a common problem when aligning sequences of different lengths.
 +
#Other alignment algorithms are available and you may wish to explore whether the alignments differ significantly.
 +
</div>
  
*List the accession numbers and names of all putative homologues. How many are there? Are the results different from your previous search? How? What do you conclude ?
+
 
 +
<div style="padding: 5px; background: #E9EBF3;  border:solid 1px #AAAAAA;">
 +
===(2.4) Editing ankyrin domain alignments===
 
</div>
 
</div>
  
&nbsp;
 
  
;(Please contact me immediately in case you cannnot find any significant alignments - you cannot continue with the assignment if you get stuck at this point.)
+
A '''good''' MSA comprises only columns of residues that play similar roles in the proteins' mechanism and/or that evolve in a comparable structural context. Since it is a result of biological selection and conservation, it has relatively few indels and the indels it has are usually not placed into elements of secondary structure or into functional motifs. The contiguous features annotated for Mbp1 are expected to be left intact by a good alignment.
 +
 
 +
A '''poor''' MSA has many errors in its columns; these contain residues that actually have different functions or structural roles, even though they may look similar according to a (pairwise!) scoring matrix. A poor MSA also may have introduced indels in biologically irrelevant positions, to maximize spurious sequence similarities. Some of the features annotated for Mbp1 will be disrupted in a poor alignment and residues that are conserved may be placed into different columns.
 +
 
 +
Often errors or inconsistencies are easy to spot, and manually editing an MSA is not generally frowned upon, even though this is not a strictly objective procedure. The main goal of manual editing is to make an alignment biologically more plausible. Most comonly this means to mimize the number of rare evolutionary events that the alignment suggests and/or to emphasize conservation of known functional motifs. Here are some examples for what one might aim for in manually editing an alignment:
 +
 
 +
;Reduce number of indels
 +
From a Probcons alignment:
 +
0447_DEBHA    ILKTE-K<span style="color: rgb(255, 0, 0);">-</span>T<span style="color: rgb(255, 0, 0);">---</span>K--SVVK      ILKTE----KTK---SVVK
 +
9978_GIBZE    MLGLN<span style="color: rgb(255, 0, 0);">-</span>PGLKEIT--HSIT      MLGLNPGLKEIT---HSIT
 +
1513_CANAL    ILKTE-K<span style="color: rgb(255, 0, 0);">-</span>I<span style="color: rgb(255, 0, 0);">---</span>K--NVVK      ILKTE----KIK---NVVK
 +
6132_SCHPO    ELDDI-I<span style="color: rgb(255, 0, 0);">-</span>ESGDY--ENVD      ELDDI-IESGDY---ENVD
 +
1244_ASPFU    ----N<span style="color: rgb(255, 0, 0);">-</span>PGLREIC--HSIT  -&gt;  ----NPGLREIC---HSIT
 +
0925_USTMA    LVKTC<span style="color: rgb(255, 0, 0);">-</span>PALDPHI--TKLK      LVKTCPALDPHI---TKLK
 +
2599_ASPTE    VLDAN<span style="color: rgb(255, 0, 0);">-</span>PGLREIS--HSIT      VLDANPGLREIS---HSIT
 +
9773_DEBHA    LLESTPKQYHQHI--KRIR      LLESTPKQYHQHI--KRIR
 +
0918_CANAL    LLESTPKEYQQYI--KRIR      LLESTPKEYQQYI--KRIR
 +
 
 +
<small>Gaps marked in red were moved. The sequence similarity in the alignment does not change considerably, however the total number of indels in this excerpt is reduced to 13 from the original 22</small>
 +
 
 +
 
 +
;Move indels to more plausible position
 +
From a CLUSTAL alignment:
 +
4966_CANGL    MKHEKVQ------GGYGRFQ---GTW      MKHEKV<span style="color: rgb(0, 170, 0);">Q</span>------GGYGRFQ---GTW
 +
1513_CANAL    KIKNVVK------VGSMNLK---GVW      KIKNVV<span style="color: rgb(0, 170, 0);">K</span>------VGSMNLK---GVW
 +
6132_SCHPO    VDSKHP<span style="color: rgb(255, 0, 0);">-</span>----------<span style="color: rgb(255, 0, 0);">Q</span>ID---GVW  -&gt;  VDSKHP<span style="color: rgb(0, 170, 0);">Q</span>-----------ID---GVW
 +
1244_ASPFU    EICHSIT------GGALAAQ---GYW      EICHSI<span style="color: rgb(0, 170, 0);">T</span>------GGALAAQ---GYW
 +
 
 +
<small>The two characters marked in red were swapped. This does not change the number of indels but places the "Q" into a a column in which it is more highly conserved (green). Progressive alignments are especially prone to this type of error.</small>
 +
 
 +
;Conserve motifs
 +
From a CLUSTAL alignment:
 +
6166_SCHPO      --DKR<span style="color: rgb(255, 0, 0);">V</span>A---<span style="color: rgb(255, 0, 0);">G</span>LWVPP      --DKR<span style="color: rgb(0, 255, 0);">V</span>A--<span style="color: rgb(0, 255, 0);">G</span>-LWVPP
 +
XBP1_SACCE      GGYIK<span style="color: rgb(255, 0, 0);">I</span>Q---<span style="color: rgb(255, 0, 0);">G</span>TWLPM      GGYIK<span style="color: rgb(0, 255, 0);">I</span>Q--<span style="color: rgb(0, 255, 0);">G</span>-TWLPM
 +
6355_ASPTE      --DE<span style="color: rgb(255, 0, 0);">I</span>A<span style="color: rgb(255, 0, 0);">G</span>---NVWISP  -&gt;  ---DE<span style="color: rgb(0, 255, 0);">I</span>A--<span style="color: rgb(0, 255, 0);">G</span>NVWISP
 +
5262_KLULA      GGYIK<span style="color: rgb(255, 0, 0);">I</span>Q---<span style="color: rgb(255, 0, 0);">G</span>TWLPY      GGYIK<span style="color: rgb(0, 255, 0);">I</span>Q--<span style="color: rgb(0, 255, 0);">G</span>-TWLPY
 +
 
 +
<small>The first of the two residues marked in red is a conserved, solvent exposed hydrophobic residue that may mediate domain interactions. The second residue is the conserved glycine in a beta turn that cannot be mutated without structural disruption. Changing the position of a gap and insertion in one sequence improves the conservation of both motifs.</small>
 +
 
 +
 
 +
The Ankyrin domains are quite highly diverged, the boundaries not well defined and not even CDD, SMART and SAS agree on the precise annotations. We expect there to be alignment errors in this region. Nevertheless we would hope that a good alignment would recognize homology in that region and that ideally the required <i>indels</i> would be placed between the secondary structure elements, not in their middle. But judging from the sequence alignment alone, we cannot judge where the secondary structure elements ought to be. You should therefore add the following "sequence" to the alignment; it contains exactly as many characters as the Swi6 sequence above and annotates the secondary structure elements. I have derived it from the 1SW6 structure
 +
 
 +
>SecStruc 1SW6 E: strand  t: turn  H: helix  _: irregular
 +
_EEE__tt___ttt______EE_____t___HHHHHHHHHHHHHHHH_xxxx_HHHHHHH
 +
HHHH_t_____t_____t____HHHHHHH__tHHHHHHHHH____t___tt____HHHHH
 +
HH__HHHH___HHHHHHHHHHHHHEE_t____HHHHHHHHH__t__HHHHHHHHHHHHHH
 +
HHHHHH__EEE_xxxx_HHHHHt_HHHHHHH______t____HHHHHHHH__HHHHHHHH
 +
H____t____t____HHHH___
 +
 
  
&nbsp;
+
To proceed:
 +
#You should manually align the Swi6 sequence with yeast Mbp1
 +
#You should bring the Secondary structure annotation into its correct alignment with Swi6
 +
#You should bring both CDD ankyrin profiles into the correct alignment with yeast Mbp1
  
Retrieve the entire protein sequences for those significant hits that you have found with the APSES domain search in your organism. The easiest way to do this is to click on the links on the BLAST results page. The NCBI does most of their internal cross-referencing with GI numbers, however these are less useful for crossreferencing to other databases.
+
Proceed along the following steps:
  
&nbsp;<br><div style="padding: 5px; background: #EEEEEE;">
+
<div style="padding: 5px; background: #EEEEEE;">
Find  and record
+
#Add the secondary structure annotation to the sequence alignment in Jalview. Copy, select File &rarr; Add sequences &rarr; from Textbox and paste the sequence.
* the GI number
+
#Select Help &rarr; Documentation and read about Editing Alignments, Cursor Mode and Key strokes.
*the GenPept accession number(s) ('''NCBI'''),
+
#Click on the yeast Mbp1 sequence row to select the entire row. Then use the cursor key to move that sequence directly above the 1SW6 sequence. Select the row of 1SW6 and use shift/mouse to move the sequence elements and realign them with yeast Mbp1. Refer to the alignment given in the [[Mbp1_annotation|Mbp1 annotation page]].
*the RefSeq identifier(s) if available,
+
#Align the secondary structure elements with the 1SW6 sequence: Every character of 1SW6 should be matched with either E, t, H, or _. The result should be similar to the [[Mbp1_annotation|Mbp1 annotation page]]. If you need to insert gaps into all sequences in the alignment, simply drag your mouse over all row headers - movement of sequences is constrained to selected regions, the rest is locked into place to prevent inadvertent misalignments. Remember to save your project from time to time: File → save so you can reload a previous state if anything goes wrong and can't be fixed with Edit → Undo.
*and the Uniprot accession number(s) ('''EBI''')
+
#Finally align the two CD00204 consensus sequences to their correct positions (again, refer to the [[Mbp1_annotation|Mbp1 annotation page]]).
*and as always, report what you have done to find this information.
+
#You can now consider the principles stated above and see if you can improve the alignment, for example by moving indels out of regions of secondary structure if that is possible without changing the character of the aligned columns significantly. Select blocks within which to work to leave the remaining alignment unchanged. So that this does not become tedious, you can restrict your editing to one Ankyrin repeat that is structurally defined in Swi6. You may want to open the 1SW6 structure in VMD to define the boundaries of one such repeat. You can copy and paste sections from Jalview into your assignment for documentation or export sections of the alignment to HTML (see the example below).  
 
</div>
 
</div>
  
 +
 +
<div style="padding: 5px; background: #F0F4FA;  border:solid 1px #AAAAAA;">
 +
 +
===(2.4.1) Editing ankyrin domain alignments - Sample===
 
</div>
 
</div>
  
Retrieve the FASTA sequence of the protein in your organism that you have found to be most similar to yeast Mbp1.
+
This sample was created by
 +
 
 +
# Editing the alignments as described above;
 +
# Copying a block of aligned sequence;
 +
# Pasting it To New Alignment;
 +
# Colouring the residues by Hydrophobicity and setting the colour saturation according to Conservation;
 +
# Choosing File &rarr; Export Image &rarr; HTML and pasting the resulting HTML source into this Wikipage.  
  
Use an online tool to generate an optimal full-length (global) alignment between the most-similar protein and  ''S. cerevisiae''Mbp1. (BLAST does not generate ''optimal'' alignments! Use the correct one of the EMBOSS tools instead.). You have to figure out where to find a Web service that does such alignments, which algorithm to use and to how to define reasonable parameters for the alignment.
 
  
&nbsp;<br><div style="padding: 5px; background: #EEEEEE;">
+
<table border="1"><tr><td>
*Report your procedure, parameters, alignment and results, and comment on the quality of the alignment. Is the protein a full-length homologue of Mbp1?
+
<table border="0" cellpadding="0" cellspacing="0">
</div>
 
  
 +
<tr><td colspan="6"></td>
 +
<td colspan="9">10<br>|</td><td></td>
 +
<td colspan="9">20<br>|</td><td></td>
 +
<td colspan="9">30<br>|</td><td></td>
 +
<td colspan="3"></td><td colspan="3">40<br>|</td>
  
 +
</tr>
 +
<tr><td nowrap="nowrap">MBP1_USTMA/341-368&nbsp;&nbsp;</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#f3eef9">Y</td>
 +
<td bgcolor="#f4eef7">G</td>
 +
<td bgcolor="#eeeefe">D</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#fdeeef">L</td>
  
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#f9eef3">A</td>
 +
<td bgcolor="#eeeefe">D</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
  
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#ffd8d8">I</td>
 +
<td bgcolor="#fbd8db">L</td>
 +
<td>-</td>
  
<hr>
+
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#dad8fd">N</td>
 +
<td bgcolor="#fbeef1">F</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#c5c2fb">D</td>
 +
<td bgcolor="#c5c2fb">D</td>
 +
<td bgcolor="#eeeefe">E</td>
  
 +
<td bgcolor="#cfaddc">G</td>
 +
<td bgcolor="#dad8fd">E</td>
 +
<td bgcolor="#d9c2e7">T</td>
 +
<td bgcolor="#d3c2ee">P</td>
 +
<td bgcolor="#f7adb3">L</td>
 +
<td bgcolor="#ccaddf">T</td>
 +
<td bgcolor="#ecc2d5">M</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#e4adc7">A</td>
  
 +
<td bgcolor="#adadff">R</td>
 +
<td bgcolor="#ebc2d5">A</td>
 +
<td bgcolor="#eeeeff">R</td>
 +
<td bgcolor="#f4eef8">S</td>
 +
</tr>
 +
<tr><td nowrap="nowrap">MBP1B_SCHCO/470-498&nbsp;&nbsp;</td>
 +
<td>-</td>
 +
<td bgcolor="#eeeeff">R</td>
 +
<td bgcolor="#eeeefe">E</td>
  
In your second assignments, you used BLAST to find the best matches to the yeast Mbp1 protein in your assigned organism's genome. To avoid ambiguity, I have generated a reference list of these homologues using the canonical procedure defined below. This was not entirely straightforward in all cases and several departures from the procedure are noted below the table; I consider these variations quite normal for a database query. You need to be familiar with exceptions such as the ones described below and know how to deal with them.
+
<td bgcolor="#eeeefe">D</td>
 +
<td bgcolor="#f4eef7">G</td>
 +
<td bgcolor="#eeeefe">D</td>
 +
<td bgcolor="#f3eef9">Y</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#eeeeff">K</td>
 +
<td bgcolor="#f4eef8">S</td>
  
# Retrieved the Mbp1 protein sequence by searching [http://www.ncbi.nlm.nih.gov/ Entrez] for <code>Mbp1 AND "saccharomyces cerevisiae"[organism]</code>
+
<td>-</td>
# Clicked on the ''RefSeq tab'' to find the RefSeq ID "<code>[http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=Protein&list_uids=6320147&dopt=GenPept NP_010227]</code>"
+
<td>-</td>
# Accessed the [http://www.ncbi.nlm.nih.gov/blast '''BLAST'''] form, followed the link to the list of all genomic BLAST databases and clicked on the (B) icon, next to Fungi to navigate to the [http://www.ncbi.nlm.nih.gov/sutils/genom_table.cgi?organism=fungi Fungi Genomic BLAST page.]
+
<td>-</td>
# Pasted "<code>NP_010227</code>" into the ''query field''. Chose ''Protein'' for both Query and Database, kept default parameters but set the ''Filter'' option to ''none''. Clicked on the check-box of each of the fungal species we have considered in the previous assignment. Run BLAST.
+
<td>-</td>
#On the results page, checked the checkbox next to the alignment to select ''the most significant hit from each organism'' we are studying.
+
<td>-</td>
#Clicked on the "Get selected sequences" button.
+
<td>-</td>
#Separately searched for sequences from organisms that were either not included in the list or for which no hits were reported. Verified all ambiguous cases, as explained in the notes below. 
+
<td>-</td>
#Verified that each of these sequences finds Mbp1 as the best match in the ''saccharomyces cerevisiae'' genome by clicking on each "Blink" ([http://www.ncbi.nlm.nih.gov/sutils/blink.cgi?pid=68465419 <small>click for example</small>]) in the retrieved list. Scrolled down the list to confirm that the '''top hit of a  ''saccharomyces cerevisiae'' protein''' is indeed Mbp1 (<code>NP_010227</code>).
+
<td>-</td>
#Obtained UniProt accessions for all sequences, with a single query using the UniProt [http://www.pir.uniprot.org/search/idmapping.shtml ID mapping service]. This service accepts a comma delimited list of RefSeq IDs, GI numbers or  GenPept accession numbers and returns a list of Uniprot accession numbers.
+
<td>-</td>
  
Since it was thus confirmed that each of these sequences is the protein that is most similar to yeast Mbp1 in its respective organism's genome, and that yeast Mbp1 is the most similar yeast protein to each of them, the all fulfil the criterion of a '''reciprocal best match''' with yeast Mbp1. Accordingly we can postulate that this list contains the fungal '''orthologues''' to Mbp1.
+
<td>-</td>
<!-- Clarify: relationship of RBM to orthology -->
+
<td bgcolor="#f7d8e0">F</td>
 +
<td bgcolor="#fbd8db">L</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#dad8fd">D</td>
 +
<td bgcolor="#fdeeef">L</td>
  
<br>&nbsp;
+
<td bgcolor="#eeeefe">Q</td>
<br>&nbsp;
+
<td bgcolor="#c5c2fb">D</td>
<table style="border-left:1px solid #AAAAAA; border-bottom:1px solid #AAAAAA;" cellpadding="10" cellspacing="0">
+
<td bgcolor="#c5c2fb">E</td>
 +
<td bgcolor="#efeefd">H</td>
 +
<td bgcolor="#cfaddc">G</td>
 +
<td bgcolor="#dad8fd">D</td>
 +
<td bgcolor="#d9c2e7">T</td>
 +
<td bgcolor="#ebc2d5">A</td>
 +
<td bgcolor="#f7adb3">L</td>
  
<tr style="background: #A6AFD0;">
+
<td bgcolor="#b0adfa">N</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;" colspan="6"><b>Mbp1 and its orthologues</b></td>
+
<td bgcolor="#ffc2c2">I</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#adadff">R</td>
 +
<td bgcolor="#fcc2c4">V</td>
 +
<td bgcolor="#f4eef7">G</td>
 +
<td bgcolor="#eeeefe">N</td>
 
</tr>
 
</tr>
  
<tr style="background: #BDC3DC;">
+
<tr><td nowrap="nowrap">MBP1_ASHGO/465-494&nbsp;&nbsp;</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><b><i>Organism</i></b></td>
+
<td>F</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><code>CODE</code></td>
+
<td bgcolor="#f4eef8">S</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><b>GI</b></td>
+
<td bgcolor="#f2eefa">P</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><b>NCBI</b></td>
+
<td bgcolor="#eeeefe">Q</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><b>Uniprot</b></td>
+
<td bgcolor="#f3eef9">Y</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><b>Most similar yeast gene</b></td>
+
<td bgcolor="#eeeeff">R</td>
 +
<td bgcolor="#ffeeee">I</td>
 +
<td>-</td>
 +
 
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#eeeefe">E</td>
 +
<td bgcolor="#f4eef8">T</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#fbd8db">L</td>
 +
<td bgcolor="#ffd8d8">I</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#dad8fd">N</td>
 +
<td bgcolor="#f9eef3">A</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#c5c2fb">D</td>
 +
<td bgcolor="#efc2d0">C</td>
 +
<td bgcolor="#eeeeff">K</td>
 +
<td bgcolor="#cfaddc">G</td>
 +
 
 +
<td bgcolor="#e6d8f0">S</td>
 +
<td bgcolor="#d9c2e7">T</td>
 +
<td bgcolor="#d3c2ee">P</td>
 +
<td bgcolor="#f7adb3">L</td>
 +
<td bgcolor="#b3adf7">H</td>
 +
<td bgcolor="#ffc2c2">I</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#e5adc6">M</td>
 +
 
 +
<td bgcolor="#c5c2fb">N</td>
 +
<td bgcolor="#eeeeff">R</td>
 +
<td bgcolor="#eeeefe">D</td>
 
</tr>
 
</tr>
 +
<tr><td nowrap="nowrap">MBP1_CLALU/550-586&nbsp;&nbsp;</td>
 +
<td>G</td>
 +
<td bgcolor="#eeeefe">N</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#eeeefe">N</td>
 +
 +
<td bgcolor="#f4eef7">G</td>
 +
<td bgcolor="#eeeefe">N</td>
 +
<td bgcolor="#f4eef8">S</td>
 +
<td>N</td>
 +
<td>D</td>
 +
<td>K</td>
 +
<td bgcolor="#eeeeff">K</td>
 +
<td bgcolor="#eeeefe">E</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td bgcolor="#fbd8db">L</td>
 +
<td bgcolor="#ffd8d8">I</td>
 +
<td>S</td>
 +
<td>K</td>
 +
<td>F</td>
 +
<td>L</td>
 +
<td bgcolor="#dad8fd">N</td>
 +
<td bgcolor="#efeefd">H</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
 +
<td bgcolor="#c5c2fb">D</td>
 +
<td bgcolor="#c5c2fb">N</td>
 +
<td bgcolor="#eeeefe">E</td>
 +
<td bgcolor="#cfaddc">G</td>
 +
<td bgcolor="#dad8fd">N</td>
 +
<td bgcolor="#d9c2e7">T</td>
 +
<td bgcolor="#ebc2d5">A</td>
 +
<td bgcolor="#edadbd">F</td>
 +
<td bgcolor="#b3adf7">H</td>
  
<tr style="background: #FFFFFF;">
+
<td bgcolor="#ffc2c2">I</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><i>Aspergillus fumigatus</i></td>
+
<td bgcolor="#e4adc7">A</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><code>ASPFU</code></td>
+
<td bgcolor="#e4adc7">A</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">70999021</td>
+
<td bgcolor="#c6ade5">Y</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">XP_754232</td>
+
<td bgcolor="#c5c2fb">N</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"> Q4WYQ9_ASPFU </td>
+
<td bgcolor="#f9eef3">M</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">Mbp1</td>
+
<td bgcolor="#f4eef8">S</td>
 
</tr>
 
</tr>
  
<tr style="background: #E9EBF3;">
+
<tr><td nowrap="nowrap">MBPA_COPCI/514-542&nbsp;&nbsp;</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><i>Aspergillus nidulans</i></td>
+
 
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><code>ASPNI</code></td>
+
<td>-</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">67525393</td>
+
<td bgcolor="#efeefd">H</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">XP_660758</td>
+
<td bgcolor="#eeeefe">E</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"> Q5B8H6_EMENI </td>
+
<td bgcolor="#f4eef7">G</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">Mbp1</td>
+
<td bgcolor="#f4eef7">G</td>
 +
<td bgcolor="#eeeefe">D</td>
 +
<td bgcolor="#fbeef1">F</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 
 +
<td>-</td>
 +
<td bgcolor="#eeeeff">R</td>
 +
<td bgcolor="#f4eef8">S</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#fbd8db">L</td>
 +
<td bgcolor="#fdd8da">V</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 
 +
<td>-</td>
 +
<td bgcolor="#dad8fd">D</td>
 +
<td bgcolor="#fdeeef">L</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#c5c2fb">D</td>
 +
<td bgcolor="#c5c2fb">E</td>
 +
<td bgcolor="#efeefd">H</td>
 +
<td bgcolor="#cfaddc">G</td>
 +
<td bgcolor="#dad8fd">D</td>
 +
 
 +
<td bgcolor="#d9c2e7">T</td>
 +
<td bgcolor="#ebc2d5">A</td>
 +
<td bgcolor="#ffadad">I</td>
 +
<td bgcolor="#b0adfa">N</td>
 +
<td bgcolor="#ffc2c2">I</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#adadff">R</td>
 +
<td bgcolor="#fcc2c4">V</td>
 +
 
 +
<td bgcolor="#f4eef7">G</td>
 +
<td bgcolor="#eeeefe">N</td>
 
</tr>
 
</tr>
 +
<tr><td nowrap="nowrap">MBP1_DEBHA/507-550&nbsp;&nbsp;</td>
 +
<td>I</td>
 +
<td bgcolor="#eeeeff">R</td>
 +
<td bgcolor="#eeeefe">D</td>
 +
<td bgcolor="#f4eef8">S</td>
 +
<td bgcolor="#eeeefe">Q</td>
  
<tr style="background: #FFFFFF;">
+
<td bgcolor="#eeeefe">E</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><i>Aspergillus terreus</i></td>
+
<td bgcolor="#ffeeee">I</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><code>ASPTE</code></td>
+
<td>-</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">115391425</td>
+
<td>-</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">XP_001213217</td>
+
<td>-</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"> Q0CQJ5_ASPTN </td>
+
<td bgcolor="#eeeefe">E</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">Mbp1</td>
+
<td bgcolor="#eeeefe">N</td>
 +
<td>K</td>
 +
<td>K</td>
 +
 
 +
<td>L</td>
 +
<td>S</td>
 +
<td>L</td>
 +
<td>S</td>
 +
<td>D</td>
 +
<td>K</td>
 +
<td>K</td>
 +
<td>E</td>
 +
<td bgcolor="#fbd8db">L</td>
 +
 
 +
<td bgcolor="#ffd8d8">I</td>
 +
<td>A</td>
 +
<td>K</td>
 +
<td>F</td>
 +
<td>I</td>
 +
<td bgcolor="#dad8fd">N</td>
 +
<td bgcolor="#efeefd">H</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#c5c2fb">D</td>
 +
 
 +
<td bgcolor="#ffc2c2">I</td>
 +
<td bgcolor="#eeeefe">D</td>
 +
<td bgcolor="#cfaddc">G</td>
 +
<td bgcolor="#dad8fd">N</td>
 +
<td bgcolor="#d9c2e7">T</td>
 +
<td bgcolor="#ebc2d5">A</td>
 +
<td bgcolor="#edadbd">F</td>
 +
<td bgcolor="#b3adf7">H</td>
 +
<td bgcolor="#ffc2c2">I</td>
 +
 
 +
<td bgcolor="#fbadaf">V</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#c6ade5">Y</td>
 +
<td bgcolor="#c5c2fb">N</td>
 +
<td bgcolor="#fdeeef">L</td>
 +
<td bgcolor="#eeeefe">N</td>
 
</tr>
 
</tr>
 +
<tr><td nowrap="nowrap">MBP1A_SCHCO/388-415&nbsp;&nbsp;</td>
 +
<td>-</td>
  
<tr style="background: #E9EBF3;">
+
<td>-</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><i>Candida albicans</i></td>
+
<td bgcolor="#f3eef9">Y</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><code>CANAL</code></td>
+
<td bgcolor="#f2eefa">P</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">46444933</td>
+
<td bgcolor="#eeeeff">K</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">EAL04204</td>
+
<td bgcolor="#eeeefe">E</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"> Q5ANP5_CANAL </td>
+
<td bgcolor="#fdeeef">L</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">Mbp1</td>
+
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 
 +
<td bgcolor="#f9eef3">A</td>
 +
<td bgcolor="#eeeefe">D</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#fdd8da">V</td>
 +
<td bgcolor="#fbd8db">L</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 
 +
<td bgcolor="#dad8fd">N</td>
 +
<td bgcolor="#fbeef1">F</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#c5c2fb">D</td>
 +
<td bgcolor="#c5c2fb">E</td>
 +
<td bgcolor="#eeeefe">D</td>
 +
<td bgcolor="#cfaddc">G</td>
 +
<td bgcolor="#dad8fd">E</td>
 +
<td bgcolor="#d9c2e7">T</td>
 +
 
 +
<td bgcolor="#ebc2d5">A</td>
 +
<td bgcolor="#f7adb3">L</td>
 +
<td bgcolor="#ccaddf">T</td>
 +
<td bgcolor="#ecc2d5">M</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#adadff">R</td>
 +
<td bgcolor="#efc2d0">C</td>
 +
<td bgcolor="#eeeeff">R</td>
 +
 
 +
<td bgcolor="#f4eef8">S</td>
 
</tr>
 
</tr>
 +
<tr><td nowrap="nowrap">MBP1_AJECA/374-403&nbsp;&nbsp;</td>
 +
<td>T</td>
 +
<td bgcolor="#fdeeef">L</td>
 +
<td bgcolor="#f2eefa">P</td>
 +
<td bgcolor="#f2eefa">P</td>
 +
<td bgcolor="#efeefd">H</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
 +
<td bgcolor="#ffeeee">I</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#f4eef8">S</td>
 +
<td bgcolor="#f9eef3">M</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#fbd8db">L</td>
 +
<td bgcolor="#fbd8db">L</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#e6d8f0">S</td>
 +
<td bgcolor="#f4eef8">S</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#c5c2fb">D</td>
 +
<td bgcolor="#d8c2e8">S</td>
 +
 +
<td bgcolor="#eeeefe">N</td>
 +
<td bgcolor="#cfaddc">G</td>
 +
<td bgcolor="#dad8fd">D</td>
 +
<td bgcolor="#d9c2e7">T</td>
 +
<td bgcolor="#ebc2d5">A</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#f7adb3">L</td>
 +
<td bgcolor="#ebc2d5">A</td>
 +
<td bgcolor="#e4adc7">A</td>
  
<tr style="background: #FFFFFF;">
+
<td bgcolor="#e4adc7">A</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><i>Candida glabrata</i></td>
+
<td bgcolor="#adadff">K</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><code>CANGL</code></td>
+
<td bgcolor="#c5c2fb">N</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">50286059</td>
+
<td bgcolor="#f4eef7">G</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">XP_445458</td>
+
<td bgcolor="#faeef2">C</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"> Q6FWD6_CANGA </td>
 
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">Mbp1</td>
 
 
</tr>
 
</tr>
 +
<tr><td nowrap="nowrap">MBP1_PARBR/380-409&nbsp;&nbsp;</td>
 +
<td>I</td>
 +
<td bgcolor="#fdeeef">L</td>
 +
 +
<td bgcolor="#f2eefa">P</td>
 +
<td bgcolor="#f2eefa">P</td>
 +
<td bgcolor="#efeefd">H</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#ffeeee">I</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#f4eef8">S</td>
 +
 +
<td bgcolor="#fdeeef">L</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#fbd8db">L</td>
 +
<td bgcolor="#fbd8db">L</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#e6d8f0">S</td>
 +
 +
<td bgcolor="#f4eef8">S</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#c5c2fb">D</td>
 +
<td bgcolor="#d8c2e8">S</td>
 +
<td bgcolor="#eeeefe">N</td>
 +
<td bgcolor="#cfaddc">G</td>
 +
<td bgcolor="#dad8fd">D</td>
 +
<td bgcolor="#d9c2e7">T</td>
 +
<td bgcolor="#ebc2d5">A</td>
 +
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#f7adb3">L</td>
 +
<td bgcolor="#ebc2d5">A</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#adadff">K</td>
 +
<td bgcolor="#c5c2fb">N</td>
 +
<td bgcolor="#f4eef7">G</td>
 +
<td bgcolor="#faeef2">C</td>
 +
 +
</tr>
 +
<tr><td nowrap="nowrap">MBP1_NEOFI/363-392&nbsp;&nbsp;</td>
 +
<td>T</td>
 +
<td bgcolor="#faeef2">C</td>
 +
<td bgcolor="#f4eef8">S</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#eeeefe">D</td>
 +
<td bgcolor="#eeeefe">E</td>
 +
<td bgcolor="#ffeeee">I</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#eeeefe">D</td>
 +
<td bgcolor="#fdeeef">L</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#fbd8db">L</td>
 +
<td bgcolor="#fbd8db">L</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#e6d8f0">S</td>
 +
<td bgcolor="#faeef2">C</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#c5c2fb">D</td>
 +
<td bgcolor="#d8c2e8">S</td>
 +
<td bgcolor="#eeeefe">N</td>
 +
 +
<td bgcolor="#cfaddc">G</td>
 +
<td bgcolor="#dad8fd">D</td>
 +
<td bgcolor="#d9c2e7">T</td>
 +
<td bgcolor="#ebc2d5">A</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#f7adb3">L</td>
 +
<td bgcolor="#fcc2c4">V</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
 +
<td bgcolor="#adadff">R</td>
 +
<td bgcolor="#c5c2fb">N</td>
 +
<td bgcolor="#f4eef7">G</td>
 +
<td bgcolor="#f9eef3">A</td>
 +
</tr>
 +
<tr><td nowrap="nowrap">MBP1_ASPNI/365-394&nbsp;&nbsp;</td>
 +
<td>T</td>
 +
<td bgcolor="#fbeef1">F</td>
 +
<td bgcolor="#f4eef8">S</td>
 +
 +
<td bgcolor="#f2eefa">P</td>
 +
<td bgcolor="#eeeefe">E</td>
 +
<td bgcolor="#eeeefe">E</td>
 +
<td bgcolor="#fdeeee">V</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#eeeefe">D</td>
 +
<td bgcolor="#fdeeef">L</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td bgcolor="#fbd8db">L</td>
 +
<td bgcolor="#fbd8db">L</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#e6d8f0">S</td>
 +
<td bgcolor="#faeef2">C</td>
 +
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#c5c2fb">D</td>
 +
<td bgcolor="#d8c2e8">S</td>
 +
<td bgcolor="#fdeeee">V</td>
 +
<td bgcolor="#cfaddc">G</td>
 +
<td bgcolor="#dad8fd">D</td>
 +
<td bgcolor="#d9c2e7">T</td>
 +
<td bgcolor="#ebc2d5">A</td>
 +
<td bgcolor="#fbadaf">V</td>
 +
 +
<td bgcolor="#f7adb3">L</td>
 +
<td bgcolor="#fcc2c4">V</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#adadff">R</td>
 +
<td bgcolor="#c5c2fb">N</td>
 +
<td bgcolor="#f4eef7">G</td>
 +
<td bgcolor="#fdeeee">V</td>
 +
</tr>
 +
 +
<tr><td nowrap="nowrap">MBP1_UNCRE/377-406&nbsp;&nbsp;</td>
 +
<td>M</td>
 +
<td bgcolor="#f3eef9">Y</td>
 +
<td bgcolor="#f2eefa">P</td>
 +
<td bgcolor="#efeefd">H</td>
 +
<td bgcolor="#efeefd">H</td>
 +
<td bgcolor="#eeeefe">E</td>
 +
<td bgcolor="#fdeeee">V</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#f4eef7">G</td>
 +
<td bgcolor="#fdeeef">L</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#fbd8db">L</td>
 +
<td bgcolor="#fbd8db">L</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#f2d8e5">A</td>
 +
<td bgcolor="#f4eef8">S</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#c5c2fb">D</td>
 +
<td bgcolor="#d8c2e8">S</td>
 +
<td bgcolor="#eeeefe">N</td>
 +
<td bgcolor="#cfaddc">G</td>
 +
 +
<td bgcolor="#dad8fd">D</td>
 +
<td bgcolor="#d9c2e7">T</td>
 +
<td bgcolor="#ebc2d5">A</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#f7adb3">L</td>
 +
<td bgcolor="#d9c2e7">T</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#adadff">K</td>
  
<tr style="background: #E9EBF3;">
+
<td bgcolor="#c5c2fb">N</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><i>Coprinopsis cinerea</i></td>
+
<td bgcolor="#f4eef7">G</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><code>COPCI</code></td>
+
<td bgcolor="#faeef2">C</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">116501415</td>
 
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">EAU84310</td>
 
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"> N.A. </td>
 
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">Mbp1</td>
 
 
</tr>
 
</tr>
 +
<tr><td nowrap="nowrap">MBP1_PENCH/439-468&nbsp;&nbsp;</td>
 +
<td>T</td>
 +
<td bgcolor="#faeef2">C</td>
 +
<td bgcolor="#f4eef8">S</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
 +
<td bgcolor="#eeeefe">D</td>
 +
<td bgcolor="#eeeefe">E</td>
 +
<td bgcolor="#ffeeee">I</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#f9eef3">M</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td bgcolor="#fbd8db">L</td>
 +
<td bgcolor="#fbd8db">L</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#e6d8f0">S</td>
 +
<td bgcolor="#faeef2">C</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
 +
<td bgcolor="#c5c2fb">D</td>
 +
<td bgcolor="#c5c2fb">Q</td>
 +
<td bgcolor="#eeeefe">N</td>
 +
<td bgcolor="#cfaddc">G</td>
 +
<td bgcolor="#dad8fd">D</td>
 +
<td bgcolor="#d9c2e7">T</td>
 +
<td bgcolor="#ebc2d5">A</td>
 +
<td bgcolor="#fbadaf">V</td>
 +
<td bgcolor="#f7adb3">L</td>
  
<tr style="background: #FFFFFF;">
+
<td bgcolor="#fcc2c4">V</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><i>Cryptococcus neoformans</i></td>
+
<td bgcolor="#e4adc7">A</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><code>CRYNE</code></td>
+
<td bgcolor="#e4adc7">A</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">134110416</td>
+
<td bgcolor="#adadff">R</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">XP_776035</td>
+
<td bgcolor="#c5c2fb">N</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"> Q5KHS0_CRYNE </td>
+
<td bgcolor="#f4eef7">G</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">Mbp1</td>
+
<td bgcolor="#f9eef3">A</td>
 
</tr>
 
</tr>
  
<tr style="background: #E9EBF3;">
+
<tr><td nowrap="nowrap">MBPA_TRIVE/407-436&nbsp;&nbsp;</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><i>Debaryomyces hansenii</i></td>
+
 
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><code>DEBHA</code></td>
+
<td>V</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">50420495</td>
+
<td bgcolor="#fbeef1">F</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">XP_458784</td>
+
<td bgcolor="#f2eefa">P</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"> Q6BSN6_DEBHA </td>
+
<td bgcolor="#eeeeff">R</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">Mbp1</td>
+
<td bgcolor="#efeefd">H</td>
 +
<td bgcolor="#eeeefe">E</td>
 +
<td bgcolor="#ffeeee">I</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 
 +
<td>-</td>
 +
<td bgcolor="#f4eef8">S</td>
 +
<td bgcolor="#fdeeef">L</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#fbd8db">L</td>
 +
<td bgcolor="#fbd8db">L</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 
 +
<td>-</td>
 +
<td bgcolor="#e6d8f0">S</td>
 +
<td bgcolor="#f4eef8">S</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#c5c2fb">D</td>
 +
<td bgcolor="#ebc2d5">A</td>
 +
<td bgcolor="#eeeefe">N</td>
 +
<td bgcolor="#cfaddc">G</td>
 +
<td bgcolor="#dad8fd">D</td>
 +
 
 +
<td bgcolor="#d9c2e7">T</td>
 +
<td bgcolor="#ebc2d5">A</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#f7adb3">L</td>
 +
<td bgcolor="#d9c2e7">T</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#adadff">K</td>
 +
<td bgcolor="#c5c2fb">N</td>
 +
 
 +
<td bgcolor="#f4eef7">G</td>
 +
<td bgcolor="#faeef2">C</td>
 
</tr>
 
</tr>
 +
<tr><td nowrap="nowrap">MBP1_PHANO/400-429&nbsp;&nbsp;</td>
 +
<td>T</td>
 +
<td bgcolor="#f4eef9">W</td>
 +
<td bgcolor="#ffeeee">I</td>
 +
<td bgcolor="#f2eefa">P</td>
 +
<td bgcolor="#eeeefe">E</td>
 +
 +
<td bgcolor="#eeeefe">E</td>
 +
<td bgcolor="#fdeeee">V</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#f4eef8">T</td>
 +
<td bgcolor="#eeeeff">R</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#fbd8db">L</td>
 +
 +
<td bgcolor="#fbd8db">L</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#dad8fd">N</td>
 +
<td bgcolor="#f9eef3">A</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#c5c2fb">D</td>
 +
 +
<td bgcolor="#c5c2fb">Q</td>
 +
<td bgcolor="#eeeefe">N</td>
 +
<td bgcolor="#cfaddc">G</td>
 +
<td bgcolor="#dad8fd">D</td>
 +
<td bgcolor="#d9c2e7">T</td>
 +
<td bgcolor="#ebc2d5">A</td>
 +
<td bgcolor="#ffadad">I</td>
 +
<td bgcolor="#e5adc6">M</td>
 +
<td bgcolor="#ffc2c2">I</td>
  
<tr style="background: #FFFFFF;">
+
<td bgcolor="#e4adc7">A</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><i>Eremothecium gossypii</i></td>
+
<td bgcolor="#e4adc7">A</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><code>EREGO</code></td>
+
<td bgcolor="#adadff">R</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">45199118</td>
+
<td bgcolor="#c5c2fb">N</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">NP_986147</td>
+
<td bgcolor="#f4eef7">G</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"> Q752H3_ASHGO </td>
+
<td bgcolor="#f9eef3">A</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">Mbp1</td>
 
 
</tr>
 
</tr>
 +
<tr><td nowrap="nowrap">MBPA_SCLSC/294-313&nbsp;&nbsp;</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#fbd8db">L</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td bgcolor="#dad8fd">D</td>
 +
<td bgcolor="#f9eef3">A</td>
 +
<td bgcolor="#eeeeff">R</td>
 +
<td bgcolor="#c5c2fb">D</td>
 +
<td bgcolor="#ffc2c2">I</td>
 +
<td bgcolor="#eeeefe">N</td>
 +
<td bgcolor="#cfaddc">G</td>
 +
<td bgcolor="#dad8fd">N</td>
 +
<td bgcolor="#d9c2e7">T</td>
 +
 +
<td bgcolor="#ebc2d5">A</td>
 +
<td bgcolor="#ffadad">I</td>
 +
<td bgcolor="#b3adf7">H</td>
 +
<td bgcolor="#ffc2c2">I</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#adadff">K</td>
 +
<td bgcolor="#c5c2fb">N</td>
 +
<td bgcolor="#eeeeff">K</td>
  
<tr style="background: #E9EBF3;">
+
<td bgcolor="#f9eef3">A</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><i>Gibberella zeae</i></td>
 
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><code>GIBZE</code></td>
 
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">46116756</td>
 
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">XP_384396</td>
 
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"> UPI000023DBF3 </td>
 
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">Mbp1</td>
 
 
</tr>
 
</tr>
 +
<tr><td nowrap="nowrap">MBPA_PYRIS/363-392&nbsp;&nbsp;</td>
 +
<td>T</td>
 +
<td bgcolor="#f4eef9">W</td>
 +
<td bgcolor="#ffeeee">I</td>
 +
<td bgcolor="#f2eefa">P</td>
 +
<td bgcolor="#eeeefe">E</td>
 +
<td bgcolor="#eeeefe">E</td>
 +
 +
<td bgcolor="#fdeeee">V</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#f4eef8">T</td>
 +
<td bgcolor="#eeeeff">R</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#fbd8db">L</td>
 +
<td bgcolor="#fbd8db">L</td>
  
<tr style="background: #FFFFFF;">
+
<td>-</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><i>Kluyveromyces lactis</i></td>
+
<td>-</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><code>KLULA</code></td>
+
<td>-</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">50308375</td>
+
<td>-</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">XP_454189</td>
+
<td bgcolor="#dad8fd">N</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"> MBP1_KLULA </td>
+
<td bgcolor="#f9eef3">A</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">Mbp1</td>
+
<td bgcolor="#f9eef3">A</td>
 +
<td bgcolor="#c5c2fb">D</td>
 +
<td bgcolor="#c5c2fb">Q</td>
 +
 
 +
<td bgcolor="#eeeefe">N</td>
 +
<td bgcolor="#cfaddc">G</td>
 +
<td bgcolor="#dad8fd">D</td>
 +
<td bgcolor="#d9c2e7">T</td>
 +
<td bgcolor="#ebc2d5">A</td>
 +
<td bgcolor="#ffadad">I</td>
 +
<td bgcolor="#e5adc6">M</td>
 +
<td bgcolor="#ffc2c2">I</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
 
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#adadff">R</td>
 +
<td bgcolor="#c5c2fb">N</td>
 +
<td bgcolor="#f4eef7">G</td>
 +
<td bgcolor="#f9eef3">A</td>
 
</tr>
 
</tr>
 +
<tr><td nowrap="nowrap">MBP1_/361-390&nbsp;&nbsp;</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td bgcolor="#eeeefe">N</td>
 +
<td bgcolor="#efeefd">H</td>
 +
<td bgcolor="#f4eef8">S</td>
 +
<td bgcolor="#fdeeef">L</td>
 +
<td>G</td>
 +
<td>V</td>
 +
<td>L</td>
 +
<td bgcolor="#f4eef8">S</td>
 +
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#f7d8e0">F</td>
 +
<td bgcolor="#f3d8e4">M</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#dad8fd">D</td>
 +
 +
<td bgcolor="#f4eef8">T</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#c5c2fb">N</td>
 +
<td bgcolor="#c5c2fb">N</td>
 +
<td bgcolor="#eeeefe">E</td>
 +
<td bgcolor="#cfaddc">G</td>
 +
<td bgcolor="#dad8fd">D</td>
 +
<td bgcolor="#d9c2e7">T</td>
 +
<td bgcolor="#ebc2d5">A</td>
 +
 +
<td bgcolor="#f7adb3">L</td>
 +
<td bgcolor="#b3adf7">H</td>
 +
<td bgcolor="#ffc2c2">I</td>
 +
<td bgcolor="#f7adb3">L</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#adadff">R</td>
 +
<td bgcolor="#d8c2e8">S</td>
 +
<td bgcolor="#f4eef7">G</td>
 +
<td bgcolor="#f9eef3">A</td>
  
<tr style="background: #E9EBF3;">
 
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><i>Magnaporthe grisea</i></td>
 
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><code>MAGGR</code></td>
 
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">74274844</td>
 
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">ABA02072 </td>
 
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"> Q3S405_MAGGR </td>
 
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">Mbp1*</td>
 
 
</tr>
 
</tr>
 +
<tr><td nowrap="nowrap">MBP1_ASPFL/328-364&nbsp;&nbsp;</td>
 +
<td>T</td>
 +
<td bgcolor="#eeeefe">E</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#f2eefa">P</td>
 +
<td bgcolor="#f4eef7">G</td>
 +
<td bgcolor="#eeeefe">E</td>
 +
<td bgcolor="#fdeeee">V</td>
  
<tr style="background: #FFFFFF;">
+
<td>I</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><i>Neurospora crassa</i></td>
+
<td>T</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><code>NEUCR</code></td>
+
<td>L</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">157070373</td>
+
<td bgcolor="#f4eef7">G</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">EAA33731</td>
+
<td bgcolor="#eeeeff">R</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"> ''Q7SBG9'' </td>
+
<td>-</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">Mbp1</td>
+
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#f7d8e0">F</td>
 +
<td bgcolor="#ffd8d8">I</td>
 +
<td>S</td>
 +
 
 +
<td>E</td>
 +
<td>I</td>
 +
<td>V</td>
 +
<td bgcolor="#dad8fd">N</td>
 +
<td bgcolor="#fdeeef">L</td>
 +
<td bgcolor="#eeeeff">R</td>
 +
<td bgcolor="#c5c2fb">D</td>
 +
<td bgcolor="#c5c2fb">D</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
 
 +
<td bgcolor="#cfaddc">G</td>
 +
<td bgcolor="#dad8fd">D</td>
 +
<td bgcolor="#d9c2e7">T</td>
 +
<td bgcolor="#ebc2d5">A</td>
 +
<td bgcolor="#f7adb3">L</td>
 +
<td bgcolor="#b0adfa">N</td>
 +
<td bgcolor="#f9c2c7">L</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#cfaddc">G</td>
 +
 
 +
<td bgcolor="#adadff">R</td>
 +
<td bgcolor="#ebc2d5">A</td>
 +
<td bgcolor="#eeeeff">R</td>
 +
<td bgcolor="#f4eef8">S</td>
 
</tr>
 
</tr>
 +
<tr><td nowrap="nowrap">MBPA_MAGOR/375-404&nbsp;&nbsp;</td>
 +
<td>Q</td>
 +
<td bgcolor="#efeefd">H</td>
 +
<td bgcolor="#eeeefe">D</td>
 +
 +
<td bgcolor="#f2eefa">P</td>
 +
<td bgcolor="#eeeefe">N</td>
 +
<td bgcolor="#fbeef1">F</td>
 +
<td bgcolor="#fdeeee">V</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td bgcolor="#fbd8db">L</td>
 +
<td bgcolor="#fbd8db">L</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#dad8fd">D</td>
 +
<td bgcolor="#f9eef3">A</td>
 +
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#c5c2fb">D</td>
 +
<td bgcolor="#c5c2fb">N</td>
 +
<td bgcolor="#eeeefe">D</td>
 +
<td bgcolor="#cfaddc">G</td>
 +
<td bgcolor="#dad8fd">N</td>
 +
<td bgcolor="#d9c2e7">T</td>
 +
<td bgcolor="#ebc2d5">A</td>
 +
<td bgcolor="#fbadaf">V</td>
  
<tr style="background: #E9EBF3;">
+
<td bgcolor="#b3adf7">H</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><i>Pichia stipitis</i></td>
+
<td bgcolor="#f9c2c7">L</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><code>PICST</code></td>
+
<td bgcolor="#e4adc7">A</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">149388844</td>
+
<td bgcolor="#e4adc7">A</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">EAZ62798</td>
+
<td bgcolor="#b0adfa">Q</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"> A3GHD6_PICST </td>
+
<td bgcolor="#c2c2ff">R</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">Mbp1</td>
+
<td bgcolor="#f4eef7">G</td>
 +
<td bgcolor="#f4eef8">S</td>
 
</tr>
 
</tr>
  
<tr style="background: #FFFFFF;">
+
<tr><td nowrap="nowrap">MBP1_CHAGL/361-390&nbsp;&nbsp;</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><i>Saccharomyces cerevisiae</i></td>
+
<td>S</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><code>SACCE</code></td>
+
<td bgcolor="#eeeeff">R</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">6320147 </td>
+
<td bgcolor="#f4eef8">S</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">NP_010227</td>
+
<td bgcolor="#f9eef3">A</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"> MBP1_YEAST </td>
+
<td bgcolor="#eeeefe">D</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">Mbp1</td>
+
<td bgcolor="#eeeefe">E</td>
 +
<td bgcolor="#fdeeef">L</td>
 +
<td>-</td>
 +
 
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#fbd8db">L</td>
 +
<td bgcolor="#fbd8db">L</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#dad8fd">D</td>
 +
<td bgcolor="#f4eef8">S</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#c5c2fb">D</td>
 +
<td bgcolor="#c5c2fb">N</td>
 +
<td bgcolor="#eeeefe">E</td>
 +
<td bgcolor="#cfaddc">G</td>
 +
 
 +
<td bgcolor="#dad8fd">N</td>
 +
<td bgcolor="#d9c2e7">T</td>
 +
<td bgcolor="#ebc2d5">A</td>
 +
<td bgcolor="#fbadaf">V</td>
 +
<td bgcolor="#b3adf7">H</td>
 +
<td bgcolor="#f9c2c7">L</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#e5adc6">M</td>
 +
 
 +
<td bgcolor="#c2c2ff">R</td>
 +
<td bgcolor="#eeeefe">D</td>
 +
<td bgcolor="#f9eef3">A</td>
 
</tr>
 
</tr>
 +
<tr><td nowrap="nowrap">MBP1_PODAN/372-401&nbsp;&nbsp;</td>
 +
<td>V</td>
 +
<td bgcolor="#eeeeff">R</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#f2eefa">P</td>
  
<tr style="background: #E9EBF3;">
+
<td bgcolor="#eeeefe">E</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><i>Schizosaccharomyces pombe</i></td>
+
<td bgcolor="#eeeefe">E</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><code>SCHPO</code></td>
+
<td bgcolor="#fdeeee">V</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">19113944</td>
+
<td>-</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">NP_593032</td>
+
<td>-</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"> RES2_SCHPO </td>
+
<td>-</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">Mbp1</td>
+
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#f9eef3">A</td>
 +
<td>-</td>
 +
 
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 
 +
<td bgcolor="#fbd8db">L</td>
 +
<td bgcolor="#fbd8db">L</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#dad8fd">D</td>
 +
<td bgcolor="#f9eef3">A</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
 
 +
<td bgcolor="#c5c2fb">D</td>
 +
<td bgcolor="#c5c2fb">E</td>
 +
<td bgcolor="#eeeefe">E</td>
 +
<td bgcolor="#cfaddc">G</td>
 +
<td bgcolor="#dad8fd">N</td>
 +
<td bgcolor="#d9c2e7">T</td>
 +
<td bgcolor="#ebc2d5">A</td>
 +
<td bgcolor="#f7adb3">L</td>
 +
<td bgcolor="#b3adf7">H</td>
 +
 
 +
<td bgcolor="#f9c2c7">L</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#adadff">R</td>
 +
<td bgcolor="#fcc2c4">V</td>
 +
<td bgcolor="#eeeefe">N</td>
 +
<td bgcolor="#f9eef3">A</td>
 
</tr>
 
</tr>
  
<tr style="background: #FFFFFF;">
+
<tr><td nowrap="nowrap">MBP1_LACTH/458-487&nbsp;&nbsp;</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><i>Ustilago maydis</i></td>
+
 
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><code>USTMA</code></td>
+
<td>F</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">46101867</td>
+
<td bgcolor="#f4eef8">S</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">EAK87100</td>
+
<td bgcolor="#f2eefa">P</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"> Q4P117_USTMA </td>
+
<td bgcolor="#eeeeff">R</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">Mbp1</td>
+
<td bgcolor="#f3eef9">Y</td>
 +
<td bgcolor="#eeeeff">R</td>
 +
<td bgcolor="#ffeeee">I</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 
 +
<td>-</td>
 +
<td bgcolor="#eeeefe">E</td>
 +
<td bgcolor="#eeeefe">N</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#fbd8db">L</td>
 +
<td bgcolor="#ffd8d8">I</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 
 +
<td>-</td>
 +
<td bgcolor="#dad8fd">N</td>
 +
<td bgcolor="#f9eef3">A</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#c5c2fb">D</td>
 +
<td bgcolor="#c5c2fb">Q</td>
 +
<td bgcolor="#eeeefe">N</td>
 +
<td bgcolor="#cfaddc">G</td>
 +
<td bgcolor="#dad8fd">D</td>
 +
 
 +
<td bgcolor="#d9c2e7">T</td>
 +
<td bgcolor="#ebc2d5">A</td>
 +
<td bgcolor="#fbadaf">V</td>
 +
<td bgcolor="#b3adf7">H</td>
 +
<td bgcolor="#f9c2c7">L</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#b0adfa">Q</td>
 +
<td bgcolor="#c5c2fb">N</td>
 +
 
 +
<td bgcolor="#f4eef7">G</td>
 +
<td bgcolor="#eeeefe">D</td>
 
</tr>
 
</tr>
 +
<tr><td nowrap="nowrap">MBP1_FILNE/433-460&nbsp;&nbsp;</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#f3eef9">Y</td>
 +
<td bgcolor="#f2eefa">P</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
 +
<td bgcolor="#eeeefe">E</td>
 +
<td bgcolor="#fdeeef">L</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#f9eef3">A</td>
 +
<td bgcolor="#eeeefe">D</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#fdd8da">V</td>
 +
 +
<td bgcolor="#ffd8d8">I</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#dad8fd">N</td>
 +
<td bgcolor="#fbeef1">F</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#c5c2fb">D</td>
  
<tr style="background: #E9EBF3;">
+
<td bgcolor="#c5c2fb">E</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><i>Yarrowia lipolytica</i></td>
+
<td bgcolor="#eeeefe">E</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"><code>YARLI</code></td>
+
<td bgcolor="#cfaddc">G</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">50545439</td>
+
<td bgcolor="#dad8fd">E</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">XP_500257</td>
+
<td bgcolor="#d9c2e7">T</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;"> Q6CGF5_YARLI </td>
+
<td bgcolor="#ebc2d5">A</td>
  <td style="border-right:1px solid #AAAAAA; border-top:1px solid #AAAAAA;">Mbp1</td>
+
<td bgcolor="#f7adb3">L</td>
 +
<td bgcolor="#ccaddf">T</td>
 +
<td bgcolor="#ffc2c2">I</td>
 +
 
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#adadff">R</td>
 +
<td bgcolor="#ebc2d5">A</td>
 +
<td bgcolor="#eeeeff">R</td>
 +
<td bgcolor="#f4eef8">S</td>
 
</tr>
 
</tr>
 +
<tr><td nowrap="nowrap">MBP1_KLULA/477-506&nbsp;&nbsp;</td>
 +
<td>F</td>
  
 +
<td bgcolor="#f4eef8">T</td>
 +
<td bgcolor="#f2eefa">P</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#f3eef9">Y</td>
 +
<td bgcolor="#eeeeff">R</td>
 +
<td bgcolor="#ffeeee">I</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td bgcolor="#eeeefe">D</td>
 +
<td bgcolor="#fdeeee">V</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#fbd8db">L</td>
 +
<td bgcolor="#ffd8d8">I</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td bgcolor="#dad8fd">N</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#c5c2fb">D</td>
 +
<td bgcolor="#c5c2fb">N</td>
 +
<td bgcolor="#eeeefe">D</td>
 +
<td bgcolor="#cfaddc">G</td>
 +
<td bgcolor="#dad8fd">N</td>
 +
<td bgcolor="#d8c2e8">S</td>
 +
 +
<td bgcolor="#d3c2ee">P</td>
 +
<td bgcolor="#f7adb3">L</td>
 +
<td bgcolor="#b3adf7">H</td>
 +
<td bgcolor="#d5c2ec">Y</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#ccaddf">T</td>
 +
<td bgcolor="#c5c2fb">N</td>
 +
<td bgcolor="#eeeeff">K</td>
 +
 +
<td bgcolor="#eeeefe">D</td>
 +
</tr>
 +
<tr><td nowrap="nowrap">MBP1_SCHST/468-501&nbsp;&nbsp;</td>
 +
<td>A</td>
 +
<td bgcolor="#eeeeff">K</td>
 +
<td bgcolor="#eeeefe">D</td>
 +
<td bgcolor="#f2eefa">P</td>
 +
<td bgcolor="#eeeefe">D</td>
 +
<td bgcolor="#eeeefe">N</td>
 +
 +
<td bgcolor="#eeeeff">K</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#eeeeff">K</td>
 +
<td bgcolor="#eeeefe">D</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#fbd8db">L</td>
 +
<td bgcolor="#ffd8d8">I</td>
 +
 +
<td>A</td>
 +
<td>K</td>
 +
<td>F</td>
 +
<td>I</td>
 +
<td bgcolor="#dad8fd">N</td>
 +
<td bgcolor="#efeefd">H</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#c5c2fb">D</td>
 +
<td bgcolor="#d8c2e8">S</td>
 +
 +
<td bgcolor="#eeeefe">D</td>
 +
<td bgcolor="#cfaddc">G</td>
 +
<td bgcolor="#dad8fd">N</td>
 +
<td bgcolor="#d9c2e7">T</td>
 +
<td bgcolor="#ebc2d5">A</td>
 +
<td bgcolor="#edadbd">F</td>
 +
<td bgcolor="#b3adf7">H</td>
 +
<td bgcolor="#ffc2c2">I</td>
 +
<td bgcolor="#eaadc0">C</td>
 +
 +
<td bgcolor="#caade0">S</td>
 +
<td bgcolor="#b3adf7">H</td>
 +
<td bgcolor="#c5c2fb">N</td>
 +
<td bgcolor="#fdeeef">L</td>
 +
<td bgcolor="#eeeefe">N</td>
 +
</tr>
 +
<tr><td nowrap="nowrap">MBP1_SACCE/496-525&nbsp;&nbsp;</td>
 +
<td>F</td>
 +
<td bgcolor="#f4eef8">S</td>
 +
 +
<td bgcolor="#f2eefa">P</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#f3eef9">Y</td>
 +
<td bgcolor="#eeeeff">R</td>
 +
<td bgcolor="#ffeeee">I</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#eeeefe">E</td>
 +
 +
<td bgcolor="#fdeeef">L</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#fbd8db">L</td>
 +
<td bgcolor="#fbd8db">L</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#dad8fd">N</td>
 +
 +
<td bgcolor="#f4eef8">T</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#c5c2fb">D</td>
 +
<td bgcolor="#c2c2ff">K</td>
 +
<td bgcolor="#eeeefe">N</td>
 +
<td bgcolor="#cfaddc">G</td>
 +
<td bgcolor="#dad8fd">D</td>
 +
<td bgcolor="#d9c2e7">T</td>
 +
<td bgcolor="#ebc2d5">A</td>
 +
 +
<td bgcolor="#f7adb3">L</td>
 +
<td bgcolor="#b3adf7">H</td>
 +
<td bgcolor="#ffc2c2">I</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#caade0">S</td>
 +
<td bgcolor="#adadff">K</td>
 +
<td bgcolor="#c5c2fb">N</td>
 +
<td bgcolor="#f4eef7">G</td>
 +
<td bgcolor="#eeeefe">D</td>
 +
 +
</tr>
 +
<tr><td nowrap="nowrap">CD00204/1-19&nbsp;&nbsp;</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#dad8fd">N</td>
 +
<td bgcolor="#f9eef3">A</td>
 +
<td bgcolor="#eeeeff">R</td>
 +
<td bgcolor="#c5c2fb">D</td>
 +
<td bgcolor="#c5c2fb">E</td>
 +
<td bgcolor="#eeeefe">D</td>
 +
 +
<td bgcolor="#cfaddc">G</td>
 +
<td bgcolor="#d8d8ff">R</td>
 +
<td bgcolor="#d9c2e7">T</td>
 +
<td bgcolor="#d3c2ee">P</td>
 +
<td bgcolor="#f7adb3">L</td>
 +
<td bgcolor="#b3adf7">H</td>
 +
<td bgcolor="#f9c2c7">L</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
 +
<td bgcolor="#caade0">S</td>
 +
<td bgcolor="#c5c2fb">N</td>
 +
<td bgcolor="#f4eef7">G</td>
 +
<td bgcolor="#efeefd">H</td>
 +
</tr>
 +
<tr><td nowrap="nowrap">CD00204/99-118&nbsp;&nbsp;</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#fdd8da">V</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#dad8fd">N</td>
 +
<td bgcolor="#f9eef3">A</td>
 +
 +
<td bgcolor="#eeeeff">R</td>
 +
<td bgcolor="#c5c2fb">D</td>
 +
<td bgcolor="#c2c2ff">K</td>
 +
<td bgcolor="#eeeefe">D</td>
 +
<td bgcolor="#cfaddc">G</td>
 +
<td bgcolor="#d8d8ff">R</td>
 +
<td bgcolor="#d9c2e7">T</td>
 +
<td bgcolor="#d3c2ee">P</td>
 +
<td bgcolor="#f7adb3">L</td>
 +
 +
<td bgcolor="#b3adf7">H</td>
 +
<td bgcolor="#f9c2c7">L</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#adadff">K</td>
 +
<td bgcolor="#c5c2fb">N</td>
 +
<td bgcolor="#f4eef7">G</td>
 +
<td bgcolor="#efeefd">H</td>
 +
</tr>
 +
 +
<tr><td nowrap="nowrap">1SW6/203-232&nbsp;&nbsp;</td>
 +
<td>L</td>
 +
<td bgcolor="#eeeefe">D</td>
 +
<td bgcolor="#fdeeef">L</td>
 +
<td bgcolor="#eeeeff">K</td>
 +
<td bgcolor="#f4eef9">W</td>
 +
<td bgcolor="#ffeeee">I</td>
 +
<td bgcolor="#ffeeee">I</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#f9eef3">A</td>
 +
<td bgcolor="#eeeefe">N</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#f3d8e4">M</td>
 +
<td bgcolor="#fbd8db">L</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#dad8fd">N</td>
 +
<td bgcolor="#f9eef3">A</td>
 +
<td bgcolor="#eeeefe">Q</td>
 +
<td bgcolor="#c5c2fb">D</td>
 +
<td bgcolor="#d8c2e8">S</td>
 +
<td bgcolor="#eeeefe">N</td>
 +
<td bgcolor="#cfaddc">G</td>
 +
 +
<td bgcolor="#dad8fd">D</td>
 +
<td bgcolor="#d9c2e7">T</td>
 +
<td bgcolor="#efc2d0">C</td>
 +
<td bgcolor="#f7adb3">L</td>
 +
<td bgcolor="#b0adfa">N</td>
 +
<td bgcolor="#ffc2c2">I</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#e4adc7">A</td>
 +
<td bgcolor="#adadff">R</td>
 +
 +
<td bgcolor="#f9c2c7">L</td>
 +
<td bgcolor="#f4eef7">G</td>
 +
<td bgcolor="#eeeefe">N</td>
 +
</tr>
 +
<tr><td nowrap="nowrap">SecStruc/203-232&nbsp;&nbsp;</td>
 +
<td>t</td>
 +
<td bgcolor="#f5eef6">_</td>
 +
<td bgcolor="#efeefd">H</td>
 +
<td bgcolor="#efeefd">H</td>
 +
 +
<td bgcolor="#efeefd">H</td>
 +
<td bgcolor="#efeefd">H</td>
 +
<td bgcolor="#efeefd">H</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#efeefd">H</td>
 +
<td bgcolor="#efeefd">H</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td bgcolor="#ead8ed">_</td>
 +
<td bgcolor="#ead8ed">_</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#ead8ed">_</td>
 +
<td bgcolor="#f5eef6">_</td>
 +
<td bgcolor="#f5eef6">_</td>
 +
 +
<td bgcolor="#dec2e3">_</td>
 +
<td bgcolor="#d9c2e7">t</td>
 +
<td bgcolor="#f5eef6">_</td>
 +
<td bgcolor="#d2add8">_</td>
 +
<td bgcolor="#ead8ed">_</td>
 +
<td bgcolor="#dec2e3">_</td>
 +
<td bgcolor="#c7c2f9">H</td>
 +
<td bgcolor="#b3adf7">H</td>
 +
<td bgcolor="#b3adf7">H</td>
 +
 +
<td bgcolor="#c7c2f9">H</td>
 +
<td bgcolor="#b3adf7">H</td>
 +
<td bgcolor="#b3adf7">H</td>
 +
<td bgcolor="#b3adf7">H</td>
 +
<td bgcolor="#c7c2f9">H</td>
 +
<td bgcolor="#f5eef6">_</td>
 +
<td bgcolor="#f5eef6">_</td>
 +
</tr>
 
</table>
 
</table>
 +
</td></tr>
 +
 +
</table>
 +
;Aligned sequences before editing. The algorithm has placed gaps into the Swi6 helix <code>LKWIIAN</code> and the four-residue gaps before the block of well aligned sequence on the right are poorly supported.
 +
 +
 +
<table border="1"><tr><td>
 +
<table border="0" cellpadding="0" cellspacing="0">
 +
 +
<tr><td colspan="6"></td>
 +
<td colspan="9">10<br>|</td><td></td>
 +
<td colspan="9">20<br>|</td><td></td>
 +
 +
<td colspan="9">30<br>|</td><td></td>
 +
<td colspan="3"></td><td colspan="3">40<br>|</td>
 +
</tr>
 +
<tr><td nowrap="nowrap">MBP1_USTMA/341-368&nbsp;&nbsp;</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#dfd2f0">Y</td>
 +
<td bgcolor="#e4d2ec">G</td>
 +
 +
<td bgcolor="#d4d2fc">D</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td bgcolor="#fbd2d5">L</td>
 +
<td bgcolor="#f0d2e0">A</td>
 +
<td bgcolor="#d4d2fc">D</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td bgcolor="#ffbfbf">I</td>
 +
<td bgcolor="#f9bfc4">L</td>
 +
<td bgcolor="#c2bffc">N</td>
 +
<td bgcolor="#f5d2db">F</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td bgcolor="#afabfa">D</td>
 +
<td bgcolor="#afabfa">D</td>
 +
<td bgcolor="#d4d2fc">E</td>
 +
 +
<td bgcolor="#c399d4">G</td>
 +
<td bgcolor="#c2bffc">E</td>
 +
<td bgcolor="#cbabdf">T</td>
 +
<td bgcolor="#c2abe8">P</td>
 +
<td bgcolor="#f699a1">L</td>
 +
<td bgcolor="#bf99d7">T</td>
 +
<td bgcolor="#e5abc5">M</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
 +
<td bgcolor="#9999ff">R</td>
 +
<td bgcolor="#e3abc6">A</td>
 +
<td bgcolor="#d2d2ff">R</td>
 +
<td bgcolor="#e2d2ee">S</td>
 +
</tr>
 +
<tr><td nowrap="nowrap">MBP1B_SCHCO/470-498&nbsp;&nbsp;</td>
 +
<td>-</td>
 +
<td bgcolor="#d2d2ff">R</td>
 +
<td bgcolor="#d4d2fc">E</td>
 +
 +
<td bgcolor="#d4d2fc">D</td>
 +
<td bgcolor="#e4d2ec">G</td>
 +
<td bgcolor="#d4d2fc">D</td>
 +
<td bgcolor="#dfd2f0">Y</td>
 +
<td bgcolor="#d2d2ff">K</td>
 +
<td bgcolor="#e2d2ee">S</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#f2bfcc">F</td>
 +
<td bgcolor="#f9bfc4">L</td>
 +
<td bgcolor="#c2bffc">D</td>
 +
<td bgcolor="#fbd2d5">L</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td bgcolor="#afabfa">D</td>
 +
<td bgcolor="#afabfa">E</td>
 +
 +
<td bgcolor="#d5d2fb">H</td>
 +
<td bgcolor="#c399d4">G</td>
 +
<td bgcolor="#c2bffc">D</td>
 +
<td bgcolor="#cbabdf">T</td>
 +
<td bgcolor="#e3abc6">A</td>
 +
<td bgcolor="#f699a1">L</td>
 +
<td bgcolor="#9d99f9">N</td>
 +
<td bgcolor="#ffabab">I</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#9999ff">R</td>
 +
<td bgcolor="#fcabae">V</td>
 +
<td bgcolor="#e4d2ec">G</td>
 +
<td bgcolor="#d4d2fc">N</td>
 +
</tr>
 +
<tr><td nowrap="nowrap">MBP1_ASHGO/465-494&nbsp;&nbsp;</td>
 +
<td>F</td>
 +
<td bgcolor="#e2d2ee">S</td>
 +
 +
<td bgcolor="#ded2f2">P</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td bgcolor="#dfd2f0">Y</td>
 +
<td bgcolor="#d2d2ff">R</td>
 +
<td bgcolor="#ffd2d2">I</td>
 +
<td bgcolor="#d4d2fc">E</td>
 +
<td bgcolor="#e2d2ed">T</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#f9bfc4">L</td>
 +
<td bgcolor="#ffbfbf">I</td>
 +
<td bgcolor="#c2bffc">N</td>
 +
<td bgcolor="#f0d2e0">A</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td bgcolor="#afabfa">D</td>
 +
 +
<td bgcolor="#eaabbf">C</td>
 +
<td bgcolor="#d2d2ff">K</td>
 +
<td bgcolor="#c399d4">G</td>
 +
<td bgcolor="#d6bfe7">S</td>
 +
<td bgcolor="#cbabdf">T</td>
 +
<td bgcolor="#c2abe8">P</td>
 +
<td bgcolor="#f699a1">L</td>
 +
<td bgcolor="#a199f6">H</td>
 +
<td bgcolor="#ffabab">I</td>
 +
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#df99b8">M</td>
 +
<td bgcolor="#afabfa">N</td>
 +
<td bgcolor="#d2d2ff">R</td>
 +
<td bgcolor="#d4d2fc">D</td>
 +
</tr>
 +
<tr><td nowrap="nowrap">MBP1_CLALU/550-586&nbsp;&nbsp;</td>
 +
<td>G</td>
 +
 +
<td bgcolor="#d4d2fc">N</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td bgcolor="#d4d2fc">N</td>
 +
<td bgcolor="#e4d2ec">G</td>
 +
<td bgcolor="#d4d2fc">N</td>
 +
<td bgcolor="#e2d2ee">S</td>
 +
<td bgcolor="#d4d2fc">N</td>
 +
<td bgcolor="#d4d2fc">D</td>
 +
<td>K</td>
 +
 +
<td>K</td>
 +
<td>E</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td>L</td>
 +
<td>I</td>
 +
<td>S</td>
 +
<td>K</td>
 +
<td bgcolor="#f2bfcc">F</td>
 +
<td bgcolor="#f9bfc4">L</td>
 +
<td bgcolor="#c2bffc">N</td>
 +
<td bgcolor="#d5d2fb">H</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
 +
<td bgcolor="#afabfa">D</td>
 +
<td bgcolor="#afabfa">N</td>
 +
<td bgcolor="#d4d2fc">E</td>
 +
<td bgcolor="#c399d4">G</td>
 +
<td bgcolor="#c2bffc">N</td>
 +
<td bgcolor="#cbabdf">T</td>
 +
<td bgcolor="#e3abc6">A</td>
 +
<td bgcolor="#e999ad">F</td>
 +
<td bgcolor="#a199f6">H</td>
 +
 +
<td bgcolor="#ffabab">I</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#b899df">Y</td>
 +
<td bgcolor="#afabfa">N</td>
 +
<td bgcolor="#f0d2df">M</td>
 +
<td bgcolor="#e2d2ee">S</td>
 +
</tr>
 +
<tr><td nowrap="nowrap">MBPA_COPCI/514-542&nbsp;&nbsp;</td>
 +
 +
<td>-</td>
 +
<td bgcolor="#d5d2fb">H</td>
 +
<td bgcolor="#d4d2fc">E</td>
 +
<td bgcolor="#e4d2ec">G</td>
 +
<td bgcolor="#e4d2ec">G</td>
 +
<td bgcolor="#d4d2fc">D</td>
 +
<td bgcolor="#f5d2db">F</td>
 +
<td bgcolor="#d2d2ff">R</td>
 +
<td bgcolor="#e2d2ee">S</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#f9bfc4">L</td>
 +
<td bgcolor="#fcbfc1">V</td>
 +
<td bgcolor="#c2bffc">D</td>
 +
<td bgcolor="#fbd2d5">L</td>
 +
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td bgcolor="#afabfa">D</td>
 +
<td bgcolor="#afabfa">E</td>
 +
<td bgcolor="#d5d2fb">H</td>
 +
<td bgcolor="#c399d4">G</td>
 +
<td bgcolor="#c2bffc">D</td>
 +
<td bgcolor="#cbabdf">T</td>
 +
<td bgcolor="#e3abc6">A</td>
 +
<td bgcolor="#ff9999">I</td>
 +
 +
<td bgcolor="#9d99f9">N</td>
 +
<td bgcolor="#ffabab">I</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#9999ff">R</td>
 +
<td bgcolor="#fcabae">V</td>
 +
<td bgcolor="#e4d2ec">G</td>
 +
<td bgcolor="#d4d2fc">N</td>
 +
</tr>
 +
 +
<tr><td nowrap="nowrap">MBP1_DEBHA/507-550&nbsp;&nbsp;</td>
 +
<td>I</td>
 +
<td bgcolor="#d2d2ff">R</td>
 +
<td bgcolor="#d4d2fc">D</td>
 +
<td bgcolor="#e2d2ee">S</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td bgcolor="#d4d2fc">E</td>
 +
<td bgcolor="#ffd2d2">I</td>
 +
<td bgcolor="#d4d2fc">E</td>
 +
 +
<td bgcolor="#d4d2fc">N</td>
 +
<td>K</td>
 +
<td>K</td>
 +
<td>L</td>
 +
<td>S</td>
 +
<td>L</td>
 +
<td>S</td>
 +
<td>D</td>
 +
<td>K</td>
  
<small>Table of yeast Mbp1 orthologues in genome-sequenced fungi. Columns from left to right: Systematic name, organism code (simply a string that lets us identify the organism in alignments), GI number, RefSeq ID (if existing) or GenPept accession, Uniprot accession, most similar yeast protein.
+
<td>K</td>
 +
<td>E</td>
 +
<td>L</td>
 +
<td>I</td>
 +
<td>A</td>
 +
<td>K</td>
 +
<td bgcolor="#f2bfcc">F</td>
 +
<td bgcolor="#ffbfbf">I</td>
 +
<td bgcolor="#c2bffc">N</td>
  
Note: for ''Aspergillus fumigatus'' and ''Aspergillus nidulans'', the top BLAST hit is not the best match. The reason is that the best matching protein has a deletion just C-terminal to the APSES domain. This causes BLAST to split the HSP into two parts,and even though the APSES domain alone has a higher % identity, its E-value turns out to be lower because it is a shorter sequence. Global alignment of each sequence with yeast Mbp1, as well as alignment of only the APSES domains were consistent in showing that for both ''Aspergillus'' species the second highest BLAST score is indeed the most similar protein. The take-home message is that the '''comparison of BLAST scores can be misleading if we apply them to sequences of different length'''. For the record: ''Aspergillus fumigatus'' highest BLAST score is with XP_748947, second highest BLAST score is with XP_754232; the latter has higher global identity (25.7% vs. 22.6%) and higher identity in the APSES domain (55% vs. 45%). ''Aspergillus nidulans'' highest BLAST score is with XP_664319, second highest BLAST score is with XP_660758; the latter has higher global identity (26.7% vs. 22.8%) and higher identity in the APSES domain (59.5% vs. 50.6%). Interestingly, the ''Aspergillus terreus'' orthologue has the same deletion, but it provided the highest BLAST score to begin with.
+
<td bgcolor="#d5d2fb">H</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td bgcolor="#afabfa">D</td>
 +
<td bgcolor="#ffabab">I</td>
 +
<td bgcolor="#d4d2fc">D</td>
 +
<td bgcolor="#c399d4">G</td>
 +
<td bgcolor="#c2bffc">N</td>
 +
<td bgcolor="#cbabdf">T</td>
 +
<td bgcolor="#e3abc6">A</td>
  
Note: ''Coprinopsis cinerea'' accession numbers are not yet in UniProt.
+
<td bgcolor="#e999ad">F</td>
 +
<td bgcolor="#a199f6">H</td>
 +
<td bgcolor="#ffabab">I</td>
 +
<td bgcolor="#fb999c">V</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#b899df">Y</td>
 +
<td bgcolor="#afabfa">N</td>
 +
<td bgcolor="#fbd2d5">L</td>
 +
<td bgcolor="#d4d2fc">N</td>
  
Note: For ''Giberella zeae'' and ''Magnaporthe grisea'', the protein BLAST search had to go through the entire '''nr''' database, by entering an organism restriction,  since genomic BLAST was not enabled.
+
</tr>
 +
<tr><td nowrap="nowrap">MBP1A_SCHCO/388-415&nbsp;&nbsp;</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#dfd2f0">Y</td>
 +
<td bgcolor="#ded2f2">P</td>
 +
<td bgcolor="#d2d2ff">K</td>
 +
<td bgcolor="#d4d2fc">E</td>
 +
<td bgcolor="#fbd2d5">L</td>
  
Note: For ''Giberella zeae'' XP_384396  no UniProt ID was returned as cross-reference. EBI-BLAST retrieved  FG04220 which is largely identical, except for short stretches that are absent in GenPept: apparently UniProt has a different gene-model for this protein.
+
<td bgcolor="#f0d2e0">A</td>
 +
<td bgcolor="#d4d2fc">D</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
  
Note: The ''Neurospora crassa'' protein EAA33731 has no direct cross-reference in UniProt. The closest match is Q7SBG9 which is largely identical, except for short stretches that are absent in GenPept: apparently UniProt has a different gene-model for this protein.
+
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#fcbfc1">V</td>
 +
<td bgcolor="#f9bfc4">L</td>
  
Note: The ''Magnaporthe grisea'' protein ABA02072 has greater local C-terminal similarity to the yeast protein Swi6 than to Mbp1, whereas the N-terminal APSES domain is most similar to yeast Mbp1. However a '''global''' Needleman-Wunsch alignment (BLOSUM 30, gaps: 8.0/1.0) shows greater '''overall''' similarity to yeast Mbp1 than to Swi6. Accordingly I consider this an orthologue to Mbp1 even though its database annotation calls ABA02072  the ''M. grisea'' Swi6 homologue.
+
<td bgcolor="#c2bffc">N</td>
 +
<td bgcolor="#f5d2db">F</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td bgcolor="#afabfa">D</td>
 +
<td bgcolor="#afabfa">E</td>
 +
<td bgcolor="#d4d2fc">D</td>
 +
<td bgcolor="#c399d4">G</td>
 +
<td bgcolor="#c2bffc">E</td>
 +
<td bgcolor="#cbabdf">T</td>
  
Note: For ''Pichia stipitis'', BLAST finds two very similar sequences in GenPept as candidate Mbp1 orthologues; the RefSeq sequence XP_001386821.1 is translated according to the standard code, the entry EAZ62798.2 is translated according to the alternative nuclear code [http://www.ncbi.nlm.nih.gov/Taxonomy/Utils/wprintgc.cgi?mode=c#SG12 '''12''']. The question had to be considered which translation appears to be correct. This required looking at the conservation of the residues in question in the BLAST alignment; better conservation indeed supports the alternative code translation.
+
<td bgcolor="#e3abc6">A</td>
 +
<td bgcolor="#f699a1">L</td>
 +
<td bgcolor="#bf99d7">T</td>
 +
<td bgcolor="#e5abc5">M</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#9999ff">R</td>
 +
<td bgcolor="#eaabbf">C</td>
 +
<td bgcolor="#d2d2ff">R</td>
  
Note: The ''Ustilago maydis'' protein EAK87100 (XP_762343, the protein with the sytematic name UM06196) is only the second-best hit in the original BLAST list as performed on the genomic BLAST page for the organism, however local optimal alignment (EMBOSS water) shows a much higher percentage of identity to yeast Mbp1 in the APSES domain than the top BLAST hit EAK86587 (XP_761485, systematic name UM05338) and global alignment  (after trimming the N- and C- terminal extensions, respectively) also shows a slightly higher degree of similarity for EAK87100 than EAK86587. Accordingly, EAK87100 is considered the Mbp1 orthologue, even though it is the second highest hit according to BLAST. The situation is similar as with the ''Aspergillus'' species, one protein was reported as a single HSP and one protein was broken into two HSPs. This emphasizes the fact that optimal sequence alignments are not entirely equivalent to BLAST alignments. Further, performing the same search against the "'''nr'''" database and applying an '''Organism''' filter for ''Ustilago maydis''  resulted in '''both''' proteins being split and the correct orthologue having the highest BLAST score in the list. This emphasizes the fact that searches in organism databases are not entirely equivalent to searches in the global database, even if the results are filtered.
+
<td bgcolor="#e2d2ee">S</td>
 +
</tr>
  
</small>
+
<tr><td nowrap="nowrap">MBP1_AJECA/374-403&nbsp;&nbsp;</td>
 +
<td>T</td>
 +
<td bgcolor="#fbd2d5">L</td>
 +
<td bgcolor="#ded2f2">P</td>
 +
<td bgcolor="#ded2f2">P</td>
 +
<td bgcolor="#d5d2fb">H</td>
 +
<td bgcolor="#d4d2fc">Q</td>
  
&nbsp;<br>
+
<td bgcolor="#ffd2d2">I</td>
Our second task is to obtain all FASTA sequences based on a list of identifiers and to save them in a format in which we can use them as input for other programs or services. This is easy: we simply paste all GI numbers as a comma separated list into the Entrez search form and select Display FASTA, send to Text on the results page, then save the contents as a Text file.
+
<td bgcolor="#e2d2ee">S</td>
&nbsp;<br>
+
<td bgcolor="#f0d2df">M</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#f9bfc4">L</td>
 +
 
 +
<td bgcolor="#f9bfc4">L</td>
 +
<td bgcolor="#d6bfe7">S</td>
 +
<td bgcolor="#e2d2ee">S</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td bgcolor="#afabfa">D</td>
 +
<td bgcolor="#caabe0">S</td>
 +
<td bgcolor="#d4d2fc">N</td>
 +
<td bgcolor="#c399d4">G</td>
 +
<td bgcolor="#c2bffc">D</td>
 +
 
 +
<td bgcolor="#cbabdf">T</td>
 +
<td bgcolor="#e3abc6">A</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#f699a1">L</td>
 +
<td bgcolor="#e3abc6">A</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#9999ff">K</td>
 +
<td bgcolor="#afabfa">N</td>
 +
 
 +
<td bgcolor="#e4d2ec">G</td>
 +
<td bgcolor="#f4d2dc">C</td>
 +
</tr>
 +
<tr><td nowrap="nowrap">MBP1_PARBR/380-409&nbsp;&nbsp;</td>
 +
<td>I</td>
 +
<td bgcolor="#fbd2d5">L</td>
 +
<td bgcolor="#ded2f2">P</td>
 +
<td bgcolor="#ded2f2">P</td>
 +
<td bgcolor="#d5d2fb">H</td>
 +
 
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td bgcolor="#ffd2d2">I</td>
 +
<td bgcolor="#e2d2ee">S</td>
 +
<td bgcolor="#fbd2d5">L</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 
 +
<td bgcolor="#f9bfc4">L</td>
 +
<td bgcolor="#f9bfc4">L</td>
 +
<td bgcolor="#d6bfe7">S</td>
 +
<td bgcolor="#e2d2ee">S</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td bgcolor="#afabfa">D</td>
 +
<td bgcolor="#caabe0">S</td>
 +
<td bgcolor="#d4d2fc">N</td>
 +
<td bgcolor="#c399d4">G</td>
 +
 
 +
<td bgcolor="#c2bffc">D</td>
 +
<td bgcolor="#cbabdf">T</td>
 +
<td bgcolor="#e3abc6">A</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#f699a1">L</td>
 +
<td bgcolor="#e3abc6">A</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#9999ff">K</td>
 +
 
 +
<td bgcolor="#afabfa">N</td>
 +
<td bgcolor="#e4d2ec">G</td>
 +
<td bgcolor="#f4d2dc">C</td>
 +
</tr>
 +
<tr><td nowrap="nowrap">MBP1_NEOFI/363-392&nbsp;&nbsp;</td>
 +
<td>T</td>
 +
<td bgcolor="#f4d2dc">C</td>
 +
<td bgcolor="#e2d2ee">S</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
 
 +
<td bgcolor="#d4d2fc">D</td>
 +
<td bgcolor="#d4d2fc">E</td>
 +
<td bgcolor="#ffd2d2">I</td>
 +
<td bgcolor="#d4d2fc">D</td>
 +
<td bgcolor="#fbd2d5">L</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 
 +
<td>-</td>
 +
<td bgcolor="#f9bfc4">L</td>
 +
<td bgcolor="#f9bfc4">L</td>
 +
<td bgcolor="#d6bfe7">S</td>
 +
<td bgcolor="#f4d2dc">C</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td bgcolor="#afabfa">D</td>
 +
<td bgcolor="#caabe0">S</td>
 +
<td bgcolor="#d4d2fc">N</td>
 +
 
 +
<td bgcolor="#c399d4">G</td>
 +
<td bgcolor="#c2bffc">D</td>
 +
<td bgcolor="#cbabdf">T</td>
 +
<td bgcolor="#e3abc6">A</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#f699a1">L</td>
 +
<td bgcolor="#fcabae">V</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
 
 +
<td bgcolor="#9999ff">R</td>
 +
<td bgcolor="#afabfa">N</td>
 +
<td bgcolor="#e4d2ec">G</td>
 +
<td bgcolor="#f0d2e0">A</td>
 +
</tr>
 +
<tr><td nowrap="nowrap">MBP1_ASPNI/365-394&nbsp;&nbsp;</td>
 +
<td>T</td>
 +
<td bgcolor="#f5d2db">F</td>
 +
<td bgcolor="#e2d2ee">S</td>
 +
 
 +
<td bgcolor="#ded2f2">P</td>
 +
<td bgcolor="#d4d2fc">E</td>
 +
<td bgcolor="#d4d2fc">E</td>
 +
<td bgcolor="#fcd2d3">V</td>
 +
<td bgcolor="#d4d2fc">D</td>
 +
<td bgcolor="#fbd2d5">L</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#f9bfc4">L</td>
 +
<td bgcolor="#f9bfc4">L</td>
 +
<td bgcolor="#d6bfe7">S</td>
 +
<td bgcolor="#f4d2dc">C</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td bgcolor="#afabfa">D</td>
 +
<td bgcolor="#caabe0">S</td>
 +
 
 +
<td bgcolor="#fcd2d3">V</td>
 +
<td bgcolor="#c399d4">G</td>
 +
<td bgcolor="#c2bffc">D</td>
 +
<td bgcolor="#cbabdf">T</td>
 +
<td bgcolor="#e3abc6">A</td>
 +
<td bgcolor="#fb999c">V</td>
 +
<td bgcolor="#f699a1">L</td>
 +
<td bgcolor="#fcabae">V</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
 
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#9999ff">R</td>
 +
<td bgcolor="#afabfa">N</td>
 +
<td bgcolor="#e4d2ec">G</td>
 +
<td bgcolor="#fcd2d3">V</td>
 +
</tr>
 +
<tr><td nowrap="nowrap">MBP1_UNCRE/377-406&nbsp;&nbsp;</td>
 +
<td>M</td>
 +
<td bgcolor="#dfd2f0">Y</td>
 +
 
 +
<td bgcolor="#ded2f2">P</td>
 +
<td bgcolor="#d5d2fb">H</td>
 +
<td bgcolor="#d5d2fb">H</td>
 +
<td bgcolor="#d4d2fc">E</td>
 +
<td bgcolor="#fcd2d3">V</td>
 +
<td bgcolor="#e4d2ec">G</td>
 +
<td bgcolor="#fbd2d5">L</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#f9bfc4">L</td>
 +
<td bgcolor="#f9bfc4">L</td>
 +
<td bgcolor="#eabfd3">A</td>
 +
<td bgcolor="#e2d2ee">S</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td bgcolor="#afabfa">D</td>
 +
 
 +
<td bgcolor="#caabe0">S</td>
 +
<td bgcolor="#d4d2fc">N</td>
 +
<td bgcolor="#c399d4">G</td>
 +
<td bgcolor="#c2bffc">D</td>
 +
<td bgcolor="#cbabdf">T</td>
 +
<td bgcolor="#e3abc6">A</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#f699a1">L</td>
 +
<td bgcolor="#cbabdf">T</td>
 +
 
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#9999ff">K</td>
 +
<td bgcolor="#afabfa">N</td>
 +
<td bgcolor="#e4d2ec">G</td>
 +
<td bgcolor="#f4d2dc">C</td>
 +
</tr>
 +
<tr><td nowrap="nowrap">MBP1_PENCH/439-468&nbsp;&nbsp;</td>
 +
<td>T</td>
 +
 
 +
<td bgcolor="#f4d2dc">C</td>
 +
<td bgcolor="#e2d2ee">S</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td bgcolor="#d4d2fc">D</td>
 +
<td bgcolor="#d4d2fc">E</td>
 +
<td bgcolor="#ffd2d2">I</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td bgcolor="#f0d2df">M</td>
 +
<td>-</td>
 +
 
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#f9bfc4">L</td>
 +
<td bgcolor="#f9bfc4">L</td>
 +
<td bgcolor="#d6bfe7">S</td>
 +
<td bgcolor="#f4d2dc">C</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
 
 +
<td bgcolor="#afabfa">D</td>
 +
<td bgcolor="#afabfa">Q</td>
 +
<td bgcolor="#d4d2fc">N</td>
 +
<td bgcolor="#c399d4">G</td>
 +
<td bgcolor="#c2bffc">D</td>
 +
<td bgcolor="#cbabdf">T</td>
 +
<td bgcolor="#e3abc6">A</td>
 +
<td bgcolor="#fb999c">V</td>
 +
<td bgcolor="#f699a1">L</td>
 +
 
 +
<td bgcolor="#fcabae">V</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#9999ff">R</td>
 +
<td bgcolor="#afabfa">N</td>
 +
<td bgcolor="#e4d2ec">G</td>
 +
<td bgcolor="#f0d2e0">A</td>
 +
</tr>
 +
<tr><td nowrap="nowrap">MBPA_TRIVE/407-436&nbsp;&nbsp;</td>
 +
 
 +
<td>V</td>
 +
<td bgcolor="#f5d2db">F</td>
 +
<td bgcolor="#ded2f2">P</td>
 +
<td bgcolor="#d2d2ff">R</td>
 +
<td bgcolor="#d5d2fb">H</td>
 +
<td bgcolor="#d4d2fc">E</td>
 +
<td bgcolor="#ffd2d2">I</td>
 +
<td bgcolor="#e2d2ee">S</td>
 +
<td bgcolor="#fbd2d5">L</td>
 +
 
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
 
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#f9bfc4">L</td>
 +
<td bgcolor="#f9bfc4">L</td>
 +
<td bgcolor="#d6bfe7">S</td>
 +
<td bgcolor="#e2d2ee">S</td>
 +
 
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td bgcolor="#afabfa">D</td>
 +
<td bgcolor="#e3abc6">A</td>
 +
<td bgcolor="#d4d2fc">N</td>
 +
<td bgcolor="#c399d4">G</td>
 +
<td bgcolor="#c2bffc">D</td>
 +
<td bgcolor="#cbabdf">T</td>
 +
<td bgcolor="#e3abc6">A</td>
 +
<td bgcolor="#dd99b9">A</td>
  
 +
<td bgcolor="#f699a1">L</td>
 +
<td bgcolor="#cbabdf">T</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#9999ff">K</td>
 +
<td bgcolor="#afabfa">N</td>
 +
<td bgcolor="#e4d2ec">G</td>
 +
<td bgcolor="#f4d2dc">C</td>
 +
</tr>
  
&nbsp;<br><div style="padding: 5px; background: #EEEEEE;">
+
<tr><td nowrap="nowrap">MBP1_PHANO/400-429&nbsp;&nbsp;</td>
*We have applied the "reciprocal best match criterion" to assert that these sequences are '''orthologues to yeast Mbp1''' and this is how orthologues are commonly defined computationally. Briefly explain why this criterium will distinguish between orthologues and paralogues (when no genes have been lost). Consider at least the following three cases (''i'') a gene duplication has occurred before a speciation event, (''ii'') a gene duplication in the query organism has occurred after a speciation event. (''iii'') a gene duplication in the target organism has occurred after a speciation event. Use sketches to illustrate the cases. (1 mark)
+
<td>T</td>
 +
<td bgcolor="#e2d2ef">W</td>
 +
<td bgcolor="#ffd2d2">I</td>
 +
<td bgcolor="#ded2f2">P</td>
 +
<td bgcolor="#d4d2fc">E</td>
 +
<td bgcolor="#d4d2fc">E</td>
 +
<td bgcolor="#fcd2d3">V</td>
 +
<td bgcolor="#e2d2ed">T</td>
  
*<!-- Clarify: no need to submit anything here -->Review the resulting multi-FASTA file for the  [[All_Mbp1_proteins|'''Mbp1 proteins (linked here)''']] and make sure you understand the procedure that led to it. Depending on your personal learning style you may either carefully review the described procedure, reproduce key steps of the procedure, reproduce the entire procedure paying special attention to the problem cases discussed in the notes, or develop your own procedure. Whatever you do, you must be confident in the end that you could have produced the same input file.<br>
+
<td bgcolor="#d2d2ff">R</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
  
</div>
+
<td>-</td>
&nbsp;<br>
+
<td>-</td>
Mbp1 orthologues are not the only proteins that contain APSES domains. In order to find all the rest, a PSI-BLAST search was performed using the yeast Mbp1 APSES domain as query. From the list of hits, the APSES domains were extracted and summarized in a file.
+
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#f9bfc4">L</td>
 +
<td bgcolor="#f9bfc4">L</td>
 +
<td bgcolor="#c2bffc">N</td>
  
&nbsp;<br><div style="padding: 5px; background: #EEEEEE;">
+
<td bgcolor="#f0d2e0">A</td>
*Review the resulting file for the  [[All_APSES_domains|'''APSES domains (linked here)''']] and make sure you understand the procedure that was used in its construction, as above.
+
<td bgcolor="#d4d2fc">Q</td>
</div>
+
<td bgcolor="#afabfa">D</td>
&nbsp;<br>
+
<td bgcolor="#afabfa">Q</td>
 +
<td bgcolor="#d4d2fc">N</td>
 +
<td bgcolor="#c399d4">G</td>
 +
<td bgcolor="#c2bffc">D</td>
 +
<td bgcolor="#cbabdf">T</td>
 +
<td bgcolor="#e3abc6">A</td>
  
<div style="padding: 5px; background: #E9EBF3;  border:solid 1px #AAAAAA;">
+
<td bgcolor="#ff9999">I</td>
 +
<td bgcolor="#df99b8">M</td>
 +
<td bgcolor="#ffabab">I</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#9999ff">R</td>
 +
<td bgcolor="#afabfa">N</td>
 +
<td bgcolor="#e4d2ec">G</td>
 +
<td bgcolor="#f0d2e0">A</td>
  
===(1.2)  Orthologues (1 mark)===
+
</tr>
</div>
+
<tr><td nowrap="nowrap">MBPA_SCLSC/294-313&nbsp;&nbsp;</td>
&nbsp;<br>
+
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
  
For '''one''' of the the APSES domains from your assigned organism, determine whether it is orthologous to a yeast APSES domain, according to the reciprocal-best-match criterion:
+
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
  
# Choose at random one sequence from the list of [[All_APSES_domains|'''APSES domains''']] from your organism (but not one from an Mbp1 orthologue) and copy it's [[All_APSES_domains|sequence]] into the input window of a genomic [http://www.ncbi.nlm.nih.gov/blast/ BLAST] search against ''saccharomyces cerevisiae'' proteins.
+
<td>-</td>
# Run the search and determine the gene name of the best hit. (This is the best match.)
+
<td>-</td>
# The BLAST-retrieved sequence may be truncated on the results page and not cover the entire APSES domain: find the sequence of your best match in yeast in the [[All_APSES_domains| sequence file]]. (Since the file contains all yeast APSES domains, your best match should be in this file, labeled with <code>????_SACCE</code> - except if the match is to Xbp1, which matches only to a part of the canonical APSES domain.)
+
<td>-</td>
# Copy the APSES domain sequence sequence from the Wiki page and perform the same kind of BLAST search with this yeast sequence, against the proteins in your organism's genome. (This finds the reciprocal match.) In case that you have found Xbp1 as the best match, use only the matching segment from your BLAST report for the search.
+
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#f9bfc4">L</td>
  
&nbsp;<br><div style="padding: 5px; background: #EEEEEE;">
+
<td bgcolor="#c2bffc">D</td>
* Document the process and report briefly what you have found on the forward and on the reverse search. Does the gene you have chosen have an APSES domain that fulfils the ''reciprocal best match'' criterion for orthology with a yeast gene? (1 mark)
+
<td bgcolor="#f0d2e0">A</td>
</div>
+
<td bgcolor="#d2d2ff">R</td>
&nbsp;<br>
+
<td bgcolor="#afabfa">D</td>
 +
<td bgcolor="#ffabab">I</td>
 +
<td bgcolor="#d4d2fc">N</td>
 +
<td bgcolor="#c399d4">G</td>
 +
<td bgcolor="#c2bffc">N</td>
 +
<td bgcolor="#cbabdf">T</td>
  
<div style="padding: 5px; background: #E9EBF3;  border:solid 1px #AAAAAA;">
+
<td bgcolor="#e3abc6">A</td>
 +
<td bgcolor="#ff9999">I</td>
 +
<td bgcolor="#a199f6">H</td>
 +
<td bgcolor="#ffabab">I</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#9999ff">K</td>
 +
<td bgcolor="#afabfa">N</td>
 +
<td bgcolor="#d2d2ff">K</td>
  
==(2) Align==
+
<td bgcolor="#f0d2e0">A</td>
</div>
+
</tr>
&nbsp;
 
&nbsp;
 
  
Actually performing multiple sequence alignements used to involve downloading and installing software on your own computer. While most tools were available on the Web in principle, many groups have restricted the total number of sequences or the total number of characters to be aligned. The EBI however offers three of the most commonly used tools with few limitations and it was possible to run MSAs for all Mbp1 orthologues jointly.
+
<tr><td nowrap="nowrap">MBPA_PYRIS/363-392&nbsp;&nbsp;</td>
&nbsp;
+
<td>T</td>
&nbsp;
+
<td bgcolor="#e2d2ef">W</td>
 +
<td bgcolor="#ffd2d2">I</td>
 +
<td bgcolor="#ded2f2">P</td>
 +
<td bgcolor="#d4d2fc">E</td>
 +
<td bgcolor="#d4d2fc">E</td>
  
<div style="padding: 5px; background: #E9EBF3;  border:solid 1px #AAAAAA;">
+
<td bgcolor="#fcd2d3">V</td>
===(2.1) Aligning the Mbp1 orthologues (1 mark)===
+
<td bgcolor="#e2d2ed">T</td>
</div>
+
<td bgcolor="#d2d2ff">R</td>
&nbsp;<br>
+
<td>-</td>
+
<td>-</td>
I used the following three servers:
+
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
  
* [http://www.ebi.ac.uk/clustalw/ '''CLUSTAL-W''']  is a progressive alignment program, it is the most popular, most widely referenced MSA algorithm, it is reasonably fast and easy to use. But alignment errors that are made early in the process can't get corrected and thus CLUSTAL is prone to misalign sets of sequences that have poor (<30% ID) local similarity. It is no longer considered state-of-the-art for carefully done alignments.
+
<td>-</td>
* [http://www.ebi.ac.uk/muscle/ '''MUSCLE'''] essentially starts out from a CLUSTAL like alignment as a draft, then identifies similar groups of sequences from which it calculates profiles, it then re-aligns the group to the profile. This procedure is iterated.
+
<td>-</td>
* [http://www.ebi.ac.uk/t-coffee/ '''T-Coffee'''] is one of my favourites - the tradeoffs appear to be especially well balanced. It too starts from a set of pairwise global alignments, like CLUSTAL, then additionally calculates sets of best local alignments. Global and local alignments are then combined to a similarity matrix and based on this matrix a guide-tree is constructed. This determines the order of steps in which sequences are added to the multiple alignment. A nice feature of T-Coffee is color coded output that allows you to quickly judge the local reliability of the alignment.
+
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#f9bfc4">L</td>
  
We shall perform multiple sequence alignments for all 18 Mbp1 orthologues and compare the results. Since the results will all look the same for the same input file, I have simply prepared them. Of course you are welcome to do run an alignment on your own for your own learning experience, but it is not required. The first alignment was run with CLUSTAL.
+
<td bgcolor="#f9bfc4">L</td>
 +
<td bgcolor="#c2bffc">N</td>
 +
<td bgcolor="#f0d2e0">A</td>
 +
<td bgcolor="#f0d2e0">A</td>
 +
<td bgcolor="#afabfa">D</td>
 +
<td bgcolor="#afabfa">Q</td>
 +
<td bgcolor="#d4d2fc">N</td>
 +
<td bgcolor="#c399d4">G</td>
 +
<td bgcolor="#c2bffc">D</td>
  
[[Image:A03_01.jpg|frame|none|Assignment 3, Figure 01<br>
+
<td bgcolor="#cbabdf">T</td>
The guide tree computed by CLUSTAL-W. The algorithm uses this tree to determine the best order for its progressive alignment for the 18 Mbp1 orthologue sequences. This tree is based on a matrix of pairwise distances.]]
+
<td bgcolor="#e3abc6">A</td>
 +
<td bgcolor="#ff9999">I</td>
 +
<td bgcolor="#df99b8">M</td>
 +
<td bgcolor="#ffabab">I</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#9999ff">R</td>
 +
<td bgcolor="#afabfa">N</td>
  
Subseqently, sequence alignments were performed with T-Coffee and MUSCLE. However, the input files were re-ordered to correspond to the order of the CLUSTAL output, and the option to order the alignments according to the ''input sequences'' was chosen on the form. This makes it much easier to compare alignments, since all MSAs are displayed in the same relative order.
+
<td bgcolor="#e4d2ec">G</td>
 +
<td bgcolor="#f0d2e0">A</td>
 +
</tr>
 +
<tr><td nowrap="nowrap">MBP1_/361-390&nbsp;&nbsp;</td>
 +
<td>N</td>
 +
<td bgcolor="#d5d2fb">H</td>
 +
<td bgcolor="#e2d2ee">S</td>
 +
<td bgcolor="#fbd2d5">L</td>
 +
<td bgcolor="#e4d2ec">G</td>
  
 +
<td bgcolor="#fcd2d3">V</td>
 +
<td bgcolor="#fbd2d5">L</td>
 +
<td bgcolor="#e2d2ee">S</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
  
The result files are linked here:
+
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
  
* [[All_Mbp1_CLUSTAL|Mbp1 proteins '''CLUSTAL''' aligned]]
+
<td bgcolor="#f2bfcc">F</td>
* [[All_Mbp1_MUSCLE|Mbp1 proteins '''MUSCLE''' aligned]]
+
<td bgcolor="#ebbfd3">M</td>
* [[All_Mbp1_T-COFFEE|Mbp1 proteins '''T-Coffee''' aligned (text version)]] and [http://biochemistry.utoronto.ca/undergraduates/courses/BCH441H/resources/T-coffee_scores.html (coloured according to scores)]
+
<td bgcolor="#c2bffc">D</td>
 +
<td bgcolor="#e2d2ed">T</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td bgcolor="#afabfa">N</td>
 +
<td bgcolor="#afabfa">N</td>
 +
<td bgcolor="#d4d2fc">E</td>
 +
<td bgcolor="#c399d4">G</td>
  
Globally speaking, the alignments are quite similar. Let's first look at the common themes, before we discuss details of the results. The  [http://biochemistry.utoronto.ca/undergraduates/courses/BCH441H/resources/T-coffee_scores.html (score-colored T-COFFEE alignment)] is well suited to look at general relationships between the sequences, since outliers can be easily identified.  For example, if one of the sequences would have a low-scoring domain that aligns poorly to the others of the group, it may be possible that that domain has been acquired in a separate evolutionary event and is not homologous to all others. We would notice an isolated stretch of poorly alignable sequence, i.e. it should be a segment coloured with a low score in a set of otherwise high-scoring segments. Also a gene may have acquired significant lengths of N- or C-terminal extensions which may not be homologous (unless they are the result of an internal duplication).
+
<td bgcolor="#c2bffc">D</td>
 +
<td bgcolor="#cbabdf">T</td>
 +
<td bgcolor="#e3abc6">A</td>
 +
<td bgcolor="#f699a1">L</td>
 +
<td bgcolor="#a199f6">H</td>
 +
<td bgcolor="#ffabab">I</td>
 +
<td bgcolor="#f699a1">L</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#9999ff">R</td>
  
&nbsp;<br><div style="padding: 5px; background: #EEEEEE;">
+
<td bgcolor="#caabe0">S</td>
*Review the  [http://biochemistry.utoronto.ca/undergraduates/courses/BCH441H/resources/T-coffee_scores.html (score-colored T-COFFEE alignment)]. Based on this alignment, how do you feel about our initial assertion that these 18 proteins should be considered orthologous<!-- over their entire length-->? (Answer briefly, but with reference to specific evidence in the alignment. Note that this question does not ask about the general level of conservation, but about whether significant segments (of about the lenght of a domain) do not appear related/alignable at all in regions where the rest of the group are reasonably well conserved.) (1 mark)
+
<td bgcolor="#e4d2ec">G</td>
</div>
+
<td bgcolor="#f0d2e0">A</td>
 +
</tr>
 +
<tr><td nowrap="nowrap">MBP1_ASPFL/328-364&nbsp;&nbsp;</td>
 +
<td>T</td>
 +
<td bgcolor="#d4d2fc">E</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td bgcolor="#ded2f2">P</td>
  
&nbsp;
+
<td bgcolor="#e4d2ec">G</td>
&nbsp;
+
<td bgcolor="#d4d2fc">E</td>
 +
<td bgcolor="#fcd2d3">V</td>
 +
<td bgcolor="#ffd2d2">I</td>
 +
<td bgcolor="#e2d2ed">T</td>
 +
<td>L</td>
 +
<td>G</td>
 +
<td>R</td>
 +
<td>F</td>
  
<div style="padding: 5px; background: #BDC3DC;  border:solid 1px #AAAAAA;">
+
<td>I</td>
 +
<td>S</td>
 +
<td>E</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
  
==(3) Mbp1 orthologues: analysis of full length MSAs==
+
<td>-</td>
</div>
+
<td bgcolor="#ffbfbf">I</td>
&nbsp;
+
<td bgcolor="#fcbfc1">V</td>
&nbsp;
+
<td bgcolor="#c2bffc">N</td>
 +
<td bgcolor="#fbd2d5">L</td>
 +
<td bgcolor="#d2d2ff">R</td>
 +
<td bgcolor="#afabfa">D</td>
 +
<td bgcolor="#afabfa">D</td>
 +
<td bgcolor="#d4d2fc">Q</td>
  
What do we mean by a ''good'' versus a ''poor'' multiple sequence alignment?
+
<td bgcolor="#c399d4">G</td>
 +
<td bgcolor="#c2bffc">D</td>
 +
<td bgcolor="#cbabdf">T</td>
 +
<td bgcolor="#e3abc6">A</td>
 +
<td bgcolor="#f699a1">L</td>
 +
<td bgcolor="#9d99f9">N</td>
 +
<td bgcolor="#f7abb2">L</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#c399d4">G</td>
  
Let us first consider some of the features of the yeast Mbp1 protein that we have defined in the second assignment (and some structural features I have compiled from various sources). Below is the yeast Mbp1 sequence with a number of annotations, compiled according to the following procedure.
+
<td bgcolor="#9999ff">R</td>
 +
<td bgcolor="#e3abc6">A</td>
 +
<td bgcolor="#d2d2ff">R</td>
 +
<td bgcolor="#e2d2ee">S</td>
 +
</tr>
 +
<tr><td nowrap="nowrap">MBPA_MAGOR/375-404&nbsp;&nbsp;</td>
 +
<td>Q</td>
 +
<td bgcolor="#d5d2fb">H</td>
 +
<td bgcolor="#d4d2fc">D</td>
  
# Performed [http://www.ncbi.nlm.nih.gov/Structure/cdd/wrpsb.cgi '''CDD'''] search with yeast Mbp1 protein sequence. This retrieves alignments of Mbp1 with the APSES and the ANKYRIN domains. These are profile based alignments and thus they are more reliable than pairwise alignments.
+
<td bgcolor="#ded2f2">P</td>
# Performed  [http://smart.embl-heidelberg.de/ '''SMART'''] search with yeast Mbp1 protein sequence. This retrieved the APSES domain, annotated a number of low-complexity regions and a stretch of coiled coil.
+
<td bgcolor="#d4d2fc">N</td>
# Performed a [http://www.ebi.ac.uk/thornton-srv/databases/sas/ '''SAS'''] search with yeast Mbp1 protein sequence. This retrieved pairwise alignments with the structures 1MB1 (APSES) and chain D of 1IKN (ankyrin domains of I<sub>kappa</sub>b), together with their respective secondary structure annotations.
+
<td bgcolor="#f5d2db">F</td>
# Copied GenPept sequence into Word-processor.
+
<td bgcolor="#fcd2d3">V</td>
# Transferred annotations of low complexity and coiled-coil regions from SMART.
+
<td bgcolor="#d4d2fc">Q</td>
# Transferred annotations of APSES secondary structure from SAS (this is a ''direct'' annotation, since the experimentally determined structure 1MB1 is a fagment of of the Mbp1 protein). The central helix that was proposed to be part of the DNA binding region is slightly distorted and SAS annotates a break in the helix, this break was bridged with lowercase "h" in the annotation.
+
<td bgcolor="#d4d2fc">Q</td>
# Ankyrin domain annotation was not as straightforward. While CDD, SMART and SAS all annotate the same general regions, they disagree in details of the domain boundaries and on the precise alignment. Used the profile-based CDD alignment of 1IKN. Transferred annotations of secondary structure from SAS output for 1IKN to sequence (this is a ''transferred'' annotation, the original annotation was for 1IKN and we assume that it applies to Mbp1 as well).
+
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
  
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
  
MBP1_SACCE
+
<td>-</td>
Annotations based on
+
<td>-</td>
- CDD domain analysis,
+
<td bgcolor="#f9bfc4">L</td>
- SAS structure annotation and
+
<td bgcolor="#f9bfc4">L</td>
- literature data on binding region
+
<td bgcolor="#c2bffc">D</td>
+
<td bgcolor="#f0d2e0">A</td>
Keys:
+
<td bgcolor="#d4d2fc">Q</td>
+
<td bgcolor="#afabfa">D</td>
C  Coiled coil regions predicted by Coils2 program
+
<td bgcolor="#afabfa">N</td>
x  Low complexity region
 
*  Proposed binding region
 
+  positively charged residues, oriented for possible DNA binding interactions
 
-  negatively charged residues, oriented for possible DNA binding interactions
 
 
E  beta strand
 
H  alpha helix
 
t  beta turn
 
 
 
                  10        20        30        40        50        60
 
          MSNQIYSARY SGVDVYEFIH STGSIMKRKK DDWVNATHIL KAANFAKAKR TRILEKEVLK
 
1MB1      ----EEEEEt t-EEEEEEEE t-EEEEEEtt ---EEHHHHH HH----HHHH HHHHhhhHHH
 
                                                                * *+**-+****
 
 
                  70        80        90        100        110        120
 
          ETHEKVQGGF GKYQGTWVPL NIAKQLAEKF SVYDQLKPLF DFTQTDGSAS PPPAPKHHHA
 
1MB1      ---EEE---- tt--EEEE-H HHHHHHHHH- --HHHHtt-        xxx xxxxxxxxxx
 
          **+*+***** ****
 
 
                  130        140        150        160        170        180
 
          SKVDRKKAIR SASTSAIMET KRNNKKAEEN QFQSSKILGN PTAAPRKRGR PVGSTRGSRR
 
          x                                                                         
 
 
 
                  190        200        210        220        230        240
 
          KLGVNLQRSQ SDMGFPRPAI PNSSISTTQL PSIRSTMGPQ SPTLGILEEE RHDSRQQQPQ
 
                                                                      xxxxx
 
 
 
                  250        260        270        280        290        300
 
          QNNSAQFKEI DLEDGLSSDV EPSQQLQQVF NQNTGFVPQQ QSSLIQTQQT ESMATSVSSS
 
          x                                        xx xxxxxxxxxx xxxxxxxxxx
 
 
 
                  310        320        330        340        350        360
 
          PSLPTSPGDF ADSNPFEERF PGGGTSPIIS MIPRYPVTSR PQTSDINDKV NKYLSKLVDY
 
          xxxxxxx
 
 
                  370        380        390        400        410        420
 
          FISNEMKSNK SLPQVLLHPP PHSAPYIDAP IDPELHTAFH WACSMGNLPI AEALYEAGTS
 
ANKYRIN                                -- t----HHHHH HH---HHHHH t-t--t-t--
 
 
 
                  430        440        450        460        470        480
 
          IRSTNSQGQT PLMRSSLFHN SYTRRTFPRI FQLLHETVFD IDSQSQTVIH HIVKRKSTTP
 
ANKYRIN  t----t---- HHHHHHHH-- -------HHH HHHHHH-ttH HH-----HHH HHHH--tH--
 
 
 
                  490        500        510        520        530        540
 
          SAVYYLDVVL SKIKDFSPQY RIELLLNTQD KNGDTALHIA SKNGDVVFFN TLVKMGALTT
 
ANKYRIN  HHHHHHHHH- ---------- -----t---- tt---HHHHH HH---HHHHH HHH--t-tt-
 
 
 
                  550        560        570        580        590        600
 
          ISNKEGLTAN EIMNQQYEQM MIQNGTNQHV NSSNTDLNIH VNTNNIETKN DVNSMVIMSP
 
ANKYRIN  ---t----HH HHHHHH--HH HHH-t--HHH -t----HHHH HHH--tHHHH HHHHHH---t
 
 
 
                  610        620        630        640        650        660
 
          VSPSDYITYP SQIATNISRN IPNVVNSMKQ MASIYNDLHE QHDNEIKSLQ KTLKSISKTK
 
ANKYRIN  ---tt----H HHHHHH---H HHHHHHH      CCCCCCCC CCCCCCCCCC CCCCC
 
 
 
                  670        680        690        700        710        720
 
          IQVSLKTLEV LKESSKDENG EAQTNDDFEI LSRLQEQNTK KLRKRLIRYK RLIKQKLEYR
 
                                                    x xxxxxxxxxx xxxxxxx
 
 
                  730        740        750        760        770        780
 
          QTVLLNKLIE DETQATTNNT VEKDNNTLER LELAQELTML QLQRKNKLSS LVKKFEDNAK
 
 
 
                  790        800        810        820        830
 
          IHKYRRIIRE GTEMNIEEVD SSLDVILQTL IANNNKNKGA EQIITISNAN SHA
 
 
 
A '''good''' MSA comprises only columns of residues that play similar roles in the proteins' mechanism and/or that evolve in a comparable structural context. Since it is a result of biological selection and conservation, it has relatively few indels and the indels it has are usually not placed into elements of secondary structure or into functional motifs.
 
  
A '''poor''' MSA has many errors in its columns, they contain residues that actuallly have diffferent functions or structural roles, even though they may look similar to a scoring matrix. It also may have introduced indels in biologically irrelevant positions, to maximize spurious sequence similarities.
+
<td bgcolor="#d4d2fc">D</td>
 +
<td bgcolor="#c399d4">G</td>
 +
<td bgcolor="#c2bffc">N</td>
 +
<td bgcolor="#cbabdf">T</td>
 +
<td bgcolor="#e3abc6">A</td>
 +
<td bgcolor="#fb999c">V</td>
 +
<td bgcolor="#a199f6">H</td>
 +
<td bgcolor="#f7abb2">L</td>
 +
<td bgcolor="#dd99b9">A</td>
  
In order to evaluate the MSAs for our proteins, we will analyze alignments relative to the features we have annotated above.
+
<td bgcolor="#dd99b9">A</td>
&nbsp;
+
<td bgcolor="#9d99f9">Q</td>
 +
<td bgcolor="#ababff">R</td>
 +
<td bgcolor="#e4d2ec">G</td>
 +
<td bgcolor="#e2d2ee">S</td>
 +
</tr>
 +
<tr><td nowrap="nowrap">MBP1_CHAGL/361-390&nbsp;&nbsp;</td>
 +
<td>S</td>
 +
<td bgcolor="#d2d2ff">R</td>
  
 +
<td bgcolor="#e2d2ee">S</td>
 +
<td bgcolor="#f0d2e0">A</td>
 +
<td bgcolor="#d4d2fc">D</td>
 +
<td bgcolor="#d4d2fc">E</td>
 +
<td bgcolor="#fbd2d5">L</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td>-</td>
 +
<td>-</td>
  
<div style="padding: 5px; background: #E9EBF3;  border:solid 1px #AAAAAA;">
+
<td>-</td>
===(3.1)  APSES domains (1 mark)===
+
<td>-</td>
</div>
+
<td>-</td>
&nbsp;<br>
+
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
  
The APSES domains in all of our Mbp1 orthologues are highly conserved and any program must be able to align such obviously similar regions.
+
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#f9bfc4">L</td>
 +
<td bgcolor="#f9bfc4">L</td>
 +
<td bgcolor="#c2bffc">D</td>
 +
<td bgcolor="#e2d2ee">S</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td bgcolor="#afabfa">D</td>
  
&nbsp;<br><div style="padding: 5px; background: #EEEEEE;">
+
<td bgcolor="#afabfa">N</td>
*Consider the CLUSTAL, Muscle and T-Coffee alignments of the Mbp1 orthologues.  Orient yourselves as to where the APSES domains are located. Briefly note whether the three alignments agree and, for one of the alignments, whether the charged residues in the proposed binding region are wholly or partially conserved across all 18 proteins. (Refer to the specific residues labelled (+) or (-) in the Mbp1 annotation above). (1 mark) <!-- Sequence variation may indicate variations in binding site -->
+
<td bgcolor="#d4d2fc">E</td>
</div>
+
<td bgcolor="#c399d4">G</td>
&nbsp;<br>
+
<td bgcolor="#c2bffc">N</td>
 +
<td bgcolor="#cbabdf">T</td>
 +
<td bgcolor="#e3abc6">A</td>
 +
<td bgcolor="#fb999c">V</td>
 +
<td bgcolor="#a199f6">H</td>
 +
<td bgcolor="#f7abb2">L</td>
  
&nbsp;
+
<td bgcolor="#dd99b9">A</td>
&nbsp;
+
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#df99b8">M</td>
 +
<td bgcolor="#ababff">R</td>
 +
<td bgcolor="#d4d2fc">D</td>
 +
<td bgcolor="#f0d2e0">A</td>
 +
</tr>
 +
<tr><td nowrap="nowrap">MBP1_PODAN/372-401&nbsp;&nbsp;</td>
 +
<td>V</td>
  
<div style="padding: 5px; background: #E9EBF3;  border:solid 1px #AAAAAA;">
+
<td bgcolor="#d2d2ff">R</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td bgcolor="#ded2f2">P</td>
 +
<td bgcolor="#d4d2fc">E</td>
 +
<td bgcolor="#d4d2fc">E</td>
 +
<td bgcolor="#fcd2d3">V</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td bgcolor="#f0d2e0">A</td>
 +
<td>-</td>
  
===(3.2)  Ankyrin domains (1 mark)===
+
<td>-</td>
</div>
+
<td>-</td>
&nbsp;<br>
+
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
  
The Ankyrin domains are more highly diverged, the boundaries are less well defined and not even CDD, SMART and SAS agree on the precise annotations. Nevertheless we would hope that a good alignment would recognize homology in that region and that ideally the required indels would be placed between the secondary structure elements, not in their middle.
+
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#f9bfc4">L</td>
 +
<td bgcolor="#f9bfc4">L</td>
 +
<td bgcolor="#c2bffc">D</td>
 +
<td bgcolor="#f0d2e0">A</td>
 +
<td bgcolor="#d4d2fc">Q</td>
  
&nbsp;<br><div style="padding: 5px; background: #EEEEEE;">
+
<td bgcolor="#afabfa">D</td>
*For one of the alignments of your choice (CLUSTAL, T-coffee or MUSCLE), identify the helices in the Ankyrin repeat region of Mbp1, based on the annotations given above. (This is probably easiest done by pasting that part of the alignment into a word-processor and highlighting the residues you are discussing). Briefly state whether the indels in this region are concentrated in segments that connect the helices, or if they are more or less evenly distributed along the entire region of similarity. Conclude whether the assertion that ''indels should not be placed in elements of secondary structure'' has merit in this case; in particular if you notice indels that violate this rule-of-thumb, consider whether the location of the indel has strong support from aligned sequence motifs, or whether it could apparently be placed  into a different location whithout much loss in alignment quality. Support your conclusions with specific reference to particular elements of the alignment. (1 mark)
+
<td bgcolor="#afabfa">E</td>
</div>
+
<td bgcolor="#d4d2fc">E</td>
&nbsp;<br>
+
<td bgcolor="#c399d4">G</td>
 +
<td bgcolor="#c2bffc">N</td>
 +
<td bgcolor="#cbabdf">T</td>
 +
<td bgcolor="#e3abc6">A</td>
 +
<td bgcolor="#f699a1">L</td>
 +
<td bgcolor="#a199f6">H</td>
  
&nbsp;
+
<td bgcolor="#f7abb2">L</td>
&nbsp;
+
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#9999ff">R</td>
 +
<td bgcolor="#fcabae">V</td>
 +
<td bgcolor="#d4d2fc">N</td>
 +
<td bgcolor="#f0d2e0">A</td>
 +
</tr>
 +
<tr><td nowrap="nowrap">MBP1_LACTH/458-487&nbsp;&nbsp;</td>
  
<div style="padding: 5px; background: #E9EBF3;  border:solid 1px #AAAAAA;">
+
<td>F</td>
 +
<td bgcolor="#e2d2ee">S</td>
 +
<td bgcolor="#ded2f2">P</td>
 +
<td bgcolor="#d2d2ff">R</td>
 +
<td bgcolor="#dfd2f0">Y</td>
 +
<td bgcolor="#d2d2ff">R</td>
 +
<td bgcolor="#ffd2d2">I</td>
 +
<td bgcolor="#d4d2fc">E</td>
 +
<td bgcolor="#d4d2fc">N</td>
  
===(3.3)  Other features (1 mark)===
+
<td>-</td>
</div>
+
<td>-</td>
&nbsp;<br>
+
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
  
Aligning functional features like ''coiled coil domains'' or ''intrinsically disorderd regions'' is even more difficult, since this is to a large degree a property of the amino acid composition, not as much the precise sequence. Thus we would expect it to be difficult to detect the correspondence between sequences in such regions.  I have annotated four low complexity regions of the yeast Mbp1 sequence.
+
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#f9bfc4">L</td>
 +
<td bgcolor="#ffbfbf">I</td>
 +
<td bgcolor="#c2bffc">N</td>
 +
<td bgcolor="#f0d2e0">A</td>
  
&nbsp;<br><div style="padding: 5px; background: #EEEEEE;">
+
<td bgcolor="#d4d2fc">Q</td>
*Copy the Mbp1 sequence from your organism from the multi-FASTA files and run a [http://smart.embl-heidelberg.de/ SMART] sequence analysis: paste your FASTA formatted sequence (or its Uniprot accession number), check only the checkbox for detecting '''intrinsic protein disorder''' and click "Sequence SMART". Locate the segments of '''low complexity''' for your sequence (they are in the lower part of the results page since they overlap with disordered segments). Now comment on '''one''' of the multiple sequence alignments: does your protein '''have''' similar low complexity regions as <code>Mbp1_SACCE</code>, and have these regions been '''aligned''' by the MSA algorithm? Briefly describe the situation: state whether these segments are found in the same general region, in the same detailed location, or perhaps even conserved in sequence, when you compare them to the ''saccharomyces cerevisiae'' protein.  Backup your conclusions with specific reference to particular elements of the alignment.
+
<td bgcolor="#afabfa">D</td>
 +
<td bgcolor="#afabfa">Q</td>
 +
<td bgcolor="#d4d2fc">N</td>
 +
<td bgcolor="#c399d4">G</td>
 +
<td bgcolor="#c2bffc">D</td>
 +
<td bgcolor="#cbabdf">T</td>
 +
<td bgcolor="#e3abc6">A</td>
 +
<td bgcolor="#fb999c">V</td>
  
* Briefly discuss whether this observation should lead you to conclude that disorder in these proteins appears to be a conserved feature, i.e. a feature that is selected for in evolution. (1 mark)
+
<td bgcolor="#a199f6">H</td>
</div>
+
<td bgcolor="#f7abb2">L</td>
&nbsp;<br>
+
<td bgcolor="#dd99b9">A</td>
&nbsp;
+
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#9d99f9">Q</td>
 +
<td bgcolor="#afabfa">N</td>
 +
<td bgcolor="#e4d2ec">G</td>
 +
<td bgcolor="#d4d2fc">D</td>
 +
</tr>
  
<!-- add at a later time similar analysis of coils via 2ZIP server - conserved feature? [http://2zip.molgen.mpg.de/index.html 2Zip server], also add VMD alignment on ankyrin prototype.
+
<tr><td nowrap="nowrap">MBP1_FILNE/433-460&nbsp;&nbsp;</td>
&nbsp;<br><div style="padding: 5px; background: #EEEEEE;">
+
<td>-</td>
*Task
+
<td>-</td>
</div>
+
<td bgcolor="#dfd2f0">Y</td>
&nbsp;<br>
+
<td bgcolor="#ded2f2">P</td>
&nbsp;
+
<td bgcolor="#d4d2fc">Q</td>
-->
+
<td bgcolor="#d4d2fc">E</td>
 +
<td bgcolor="#fbd2d5">L</td>
 +
<td bgcolor="#f0d2e0">A</td>
  
 +
<td bgcolor="#d4d2fc">D</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
  
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#fcbfc1">V</td>
 +
<td bgcolor="#ffbfbf">I</td>
 +
<td bgcolor="#c2bffc">N</td>
  
<div style="padding: 5px; background: #BDC3DC;  border:solid 1px #AAAAAA;">
+
<td bgcolor="#f5d2db">F</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td bgcolor="#afabfa">D</td>
 +
<td bgcolor="#afabfa">E</td>
 +
<td bgcolor="#d4d2fc">E</td>
 +
<td bgcolor="#c399d4">G</td>
 +
<td bgcolor="#c2bffc">E</td>
 +
<td bgcolor="#cbabdf">T</td>
 +
<td bgcolor="#e3abc6">A</td>
  
==(4) APSES domain homologues: analysis of domain MSAs==
+
<td bgcolor="#f699a1">L</td>
</div>
+
<td bgcolor="#bf99d7">T</td>
&nbsp;<br>
+
<td bgcolor="#ffabab">I</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#9999ff">R</td>
 +
<td bgcolor="#e3abc6">A</td>
 +
<td bgcolor="#d2d2ff">R</td>
 +
<td bgcolor="#e2d2ee">S</td>
  
You have read how to generate a source sequence file based on the results of a PSI-BLAST search for all APSES domains in fungi. Of course, since PSI-BLAST has detected these sequences due to their high-similarity to a sequence profile, this similarity implies an alignment; this is a model based MSA because the sequences are aligned to a protoypic model and not to each other. To align these domains the MUSCLE server is the tool of choice for such highly diverged sequences. For comparison, a CLUSTAL alignment has been computed as well.
+
</tr>
 +
<tr><td nowrap="nowrap">MBP1_KLULA/477-506&nbsp;&nbsp;</td>
 +
<td>F</td>
 +
<td bgcolor="#e2d2ed">T</td>
 +
<td bgcolor="#ded2f2">P</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td bgcolor="#dfd2f0">Y</td>
 +
<td bgcolor="#d2d2ff">R</td>
 +
<td bgcolor="#ffd2d2">I</td>
  
* The [[APSES_domains_PSI-BLAST| resulting alignment derived from the '''PSI-BLAST''' profile]] as an example of a model-based alignment. <small>Note that PSI-BLAST has not been optimized to work as an alignment program, thus the conclusion that model-based alignments are inferior because this example is a poor alignment is not justified.</small>
+
<td bgcolor="#d4d2fc">D</td>
* The [[APSES_domains_CLUSTAL| '''CLUSTAL-W''' alignment]] as an example of a progressive alignment.
+
<td bgcolor="#fcd2d3">V</td>
* The [[APSES_domains_MUSCLE| '''MUSCLE''' alignment]] as an example of a consistency-based alignment.
+
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
  
If we compare the alignments, we notice immediately that they disagree over siginficant portions of the sequences.
+
<td>-</td>
&nbsp;
+
<td>-</td>
&nbsp;
+
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#f9bfc4">L</td>
 +
<td bgcolor="#ffbfbf">I</td>
  
===(4.1)  Manual improvement  (1 mark)===
+
<td bgcolor="#c2bffc">N</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td bgcolor="#afabfa">D</td>
 +
<td bgcolor="#afabfa">N</td>
 +
<td bgcolor="#d4d2fc">D</td>
 +
<td bgcolor="#c399d4">G</td>
 +
<td bgcolor="#c2bffc">N</td>
 +
<td bgcolor="#caabe0">S</td>
  
Often errors or inconsistencies are easy to spot, and manually editing an MSA is not generally frowned upon, even though this is not a strictly objective procedure. The main goal of manual editing is to make an alignment biologically more plausible. Most comonly this means to mimize the number of rare evolutionary events that the alignment suggestsand/or to emphasize conservation of known functional motifs. Here are some examples for what one might aim for in manually editing an alignment:
+
<td bgcolor="#c2abe8">P</td>
 +
<td bgcolor="#f699a1">L</td>
 +
<td bgcolor="#a199f6">H</td>
 +
<td bgcolor="#c5abe5">Y</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#bf99d7">T</td>
 +
<td bgcolor="#afabfa">N</td>
 +
<td bgcolor="#d2d2ff">K</td>
  
* Reduce number of indels
+
<td bgcolor="#d4d2fc">D</td>
 +
</tr>
  
From a Probcons alignment:
+
<tr><td nowrap="nowrap">MBP1_SCHST/468-501&nbsp;&nbsp;</td>
0447_DEBHA    ILKTE-K<span style="color:#FF0000;">-</span>T<span style="color:#FF0000;">---</span>K--SVVK      ILKTE----KTK---SVVK
+
<td>A</td>
9978_GIBZE    MLGLN<span style="color:#FF0000;">-</span>PGLKEIT--HSIT      MLGLNPGLKEIT---HSIT
+
<td bgcolor="#d2d2ff">K</td>
1513_CANAL    ILKTE-K<span style="color:#FF0000;">-</span>I<span style="color:#FF0000;">---</span>K--NVVK      ILKTE----KIK---NVVK
+
<td bgcolor="#d4d2fc">D</td>
6132_SCHPO    ELDDI-I<span style="color:#FF0000;">-</span>ESGDY--ENVD      ELDDI-IESGDY---ENVD
+
<td bgcolor="#ded2f2">P</td>
1244_ASPFU    ----N<span style="color:#FF0000;">-</span>PGLREIC--HSIT  ->  ----NPGLREIC---HSIT
+
<td bgcolor="#d4d2fc">D</td>
0925_USTMA    LVKTC<span style="color:#FF0000;">-</span>PALDPHI--TKLK      LVKTCPALDPHI---TKLK
+
<td bgcolor="#d4d2fc">N</td>
2599_ASPTE    VLDAN<span style="color:#FF0000;">-</span>PGLREIS--HSIT      VLDANPGLREIS---HSIT
 
9773_DEBHA    LLESTPKQYHQHI--KRIR      LLESTPKQYHQHI--KRIR
 
0918_CANAL    LLESTPKEYQQYI--KRIR      LLESTPKEYQQYI--KRIR
 
  
<small>Gaps marked in red were moved. The sequence similarity in the alignment does not change considerably, however the total number of indels in this excerpt is reduced to 13 from the original 22</small>
+
<td bgcolor="#d2d2ff">K</td>
 +
<td bgcolor="#d2d2ff">K</td>
 +
<td bgcolor="#d4d2fc">D</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
  
* Move indels to more plausible position
+
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>L</td>
 +
<td>I</td>
 +
<td>A</td>
 +
<td>K</td>
 +
<td bgcolor="#f2bfcc">F</td>
  
From a CLUSTAL alignment:
+
<td bgcolor="#ffbfbf">I</td>
4966_CANGL    MKHEKVQ------GGYGRFQ---GTW      MKHEKV<span style="color:#00AA00;">Q</span>------GGYGRFQ---GTW
+
<td bgcolor="#c2bffc">N</td>
1513_CANAL    KIKNVVK------VGSMNLK---GVW      KIKNVV<span style="color:#00AA00;">K</span>------VGSMNLK---GVW
+
<td bgcolor="#d5d2fb">H</td>
6132_SCHPO    VDSKHP<span style="color:#FF0000;">-</span>----------<span style="color:#FF0000;">Q</span>ID---GVW  ->  VDSKHP<span style="color:#00AA00;">Q</span>-----------ID---GVW
+
<td bgcolor="#d4d2fc">Q</td>
1244_ASPFU    EICHSIT------GGALAAQ---GYW      EICHSI<span style="color:#00AA00;">T</span>------GGALAAQ---GYW
+
<td bgcolor="#afabfa">D</td>
 +
<td bgcolor="#caabe0">S</td>
 +
<td bgcolor="#d4d2fc">D</td>
 +
<td bgcolor="#c399d4">G</td>
 +
<td bgcolor="#c2bffc">N</td>
  
<small>The two characters marked in red were swapped. This does not change the number of indels but places the "Q" into a a column in which it is more highly conserved (green). Progressive alignments are especially prone to this type of error.</small>
+
<td bgcolor="#cbabdf">T</td>
 +
<td bgcolor="#e3abc6">A</td>
 +
<td bgcolor="#e999ad">F</td>
 +
<td bgcolor="#a199f6">H</td>
 +
<td bgcolor="#ffabab">I</td>
 +
<td bgcolor="#e699b1">C</td>
 +
<td bgcolor="#be99d9">S</td>
 +
<td bgcolor="#a199f6">H</td>
 +
<td bgcolor="#afabfa">N</td>
  
* Conserve motifs
+
<td bgcolor="#fbd2d5">L</td>
 +
<td bgcolor="#d4d2fc">N</td>
 +
</tr>
 +
<tr><td nowrap="nowrap">MBP1_SACCE/496-525&nbsp;&nbsp;</td>
 +
<td>F</td>
 +
<td bgcolor="#e2d2ee">S</td>
 +
<td bgcolor="#ded2f2">P</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td bgcolor="#dfd2f0">Y</td>
  
From a CLUSTAL alignment:
+
<td bgcolor="#d2d2ff">R</td>
6166_SCHPO      --DKR<span style="color:#FF0000;">V</span>A---<span style="color:#FF0000;">G</span>LWVPP      --DKR<span style="color:#FF0000;">V</span>A--<span style="color:#FF0000;">G</span>-LWVPP
+
<td bgcolor="#ffd2d2">I</td>
XBP1_SACCE      GGYIK<span style="color:#FF0000;">I</span>Q---<span style="color:#FF0000;">G</span>TWLPM      GGYIK<span style="color:#FF0000;">I</span>Q--<span style="color:#FF0000;">G</span>-TWLPM
+
<td bgcolor="#d4d2fc">E</td>
6355_ASPTE      --DE<span style="color:#FF0000;">I</span>A<span style="color:#FF0000;">G</span>---NVWISP  ->  ---DE<span style="color:#FF0000;">I</span>A--<span style="color:#FF0000;">G</span>NVWISP
+
<td bgcolor="#fbd2d5">L</td>
5262_KLULA      GGYIK<span style="color:#FF0000;">I</span>Q---<span style="color:#FF0000;">G</span>TWLPY      GGYIK<span style="color:#FF0000;">I</span>Q--<span style="color:#FF0000;">G</span>-TWLPY
+
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
  
<small>The first of the two residues marked in red is a conserved, solvent exposed hydrophobic residue that may mediate domain interactions. The second residue is the conserved glycine in a beta turn that cannot be mutated without structural disruption. Changing the position of a gap and insertion in one sequence improves the conservation of both motifs.</small>
+
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
  
 +
<td bgcolor="#f9bfc4">L</td>
 +
<td bgcolor="#f9bfc4">L</td>
 +
<td bgcolor="#c2bffc">N</td>
 +
<td bgcolor="#e2d2ed">T</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td bgcolor="#afabfa">D</td>
 +
<td bgcolor="#ababff">K</td>
 +
<td bgcolor="#d4d2fc">N</td>
 +
<td bgcolor="#c399d4">G</td>
  
&nbsp;
+
<td bgcolor="#c2bffc">D</td>
&nbsp;
+
<td bgcolor="#cbabdf">T</td>
 +
<td bgcolor="#e3abc6">A</td>
 +
<td bgcolor="#f699a1">L</td>
 +
<td bgcolor="#a199f6">H</td>
 +
<td bgcolor="#ffabab">I</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#be99d9">S</td>
 +
<td bgcolor="#9999ff">K</td>
  
Please consider the following excerpt from the PSI-BLAST alignment:
+
<td bgcolor="#afabfa">N</td>
 +
<td bgcolor="#e4d2ec">G</td>
 +
<td bgcolor="#d4d2fc">D</td>
 +
</tr>
 +
<tr><td nowrap="nowrap">CD00204/1-19&nbsp;&nbsp;</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
  
'''Mbp1_SACCE  RILEKEV-LKET-HE--KVQG-GF-GK-----------Y-----------QGTW'''
+
<td>-</td>
MbpA_ASPTE  KTLEKEI-AAGE-HE--KVQG-GY-GK-----------Y-----------QGTW
+
<td>-</td>
MbpC_CANAL  NYFDNEI-LSNLKYF--GSSS-NT-PQ-----------YLDLRKHQNIYLQGIW
+
<td>-</td>
MbpB_CANAL  KLLESTP-KEYQ-QYIKRIRG-GF-LK-----------I-----------QGTW
+
<td>-</td>
MbpA_CANAL  KILEKGV-QQGL-HE--KVQG-GF-GR-----------F-----------QGTW
+
<td>-</td>
Swi4_CANGL  KILEKES-TNMK-HE--KVQG-GY-GR-----------F-----------QGTW
+
<td>-</td>
MbpA_COPCI  KMIDSQPDLAPL-IR--RVRG-GY-LK-----------I-----------QGTW
+
<td>-</td>
MbpA_CRYNE  RVLEREV-QKGE-HE--KVQG-GY-GK-----------Y-----------QGTW
+
<td>-</td>
MbpB_DEBHA  KLLESTP-KQYH-QHIKRIRG-GF-LK-----------I-----------QGTW
+
<td>-</td>
MbpA_DEBHA  KILEKGV-QQGL-HE--KIQG-GY-GR-----------F-----------QGTW
 
Swi4_DEBHA  NFLNNEI-LTNT-QY--LSSG-GSNPQFNDLRNHEVRDL-----------RGLW
 
Swi4_KLULA  KILEKEA-NEIK-HE--KIQG-GY-GR-----------F-----------QGTW
 
Swi4_SACCE  KILEKES-NDMQ-HE--KVQG-GY-GR-----------F-----------QGTW
 
Swi4_USTMA  KILEKSI-LTGE-HE--KIQG-GY-GK-----------F-----------QGTW
 
  
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
  
&nbsp;<br><div style="padding: 5px; background: #EEEEEE;">
+
<td>-</td>
*Find at least one example where this alignment could be manually improved. Show the original version, the improved version, highlight the changes in red and explain your rationale for the change. (1 mark)
+
<td>-</td>
</div>
+
<td>-</td>
 +
<td bgcolor="#c2bffc">N</td>
 +
<td bgcolor="#f0d2e0">A</td>
 +
<td bgcolor="#d2d2ff">R</td>
 +
<td bgcolor="#afabfa">D</td>
 +
<td bgcolor="#afabfa">E</td>
 +
<td bgcolor="#d4d2fc">D</td>
  
&nbsp;
+
<td bgcolor="#c399d4">G</td>
&nbsp;
+
<td bgcolor="#bfbfff">R</td>
 +
<td bgcolor="#cbabdf">T</td>
 +
<td bgcolor="#c2abe8">P</td>
 +
<td bgcolor="#f699a1">L</td>
 +
<td bgcolor="#a199f6">H</td>
 +
<td bgcolor="#f7abb2">L</td>
 +
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#dd99b9">A</td>
  
<div style="padding: 5px; background: #E9EBF3; border:solid 1px #AAAAAA;">
+
<td bgcolor="#be99d9">S</td>
 +
<td bgcolor="#afabfa">N</td>
 +
<td bgcolor="#e4d2ec">G</td>
 +
<td bgcolor="#d5d2fb">H</td>
 +
</tr>
 +
<tr><td nowrap="nowrap">CD00204/99-118&nbsp;&nbsp;</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
  
===(4.2)  Patterns of residue conservation  (1 mark)===
+
<td>-</td>
</div>
+
<td>-</td>
&nbsp;<br>
+
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
  
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
  
With any computational tool, we have to consider whether the program's objective function corresponds to our requirements. For example, the lack of conservation in a particular column does not necessarily mean that a residue has changed in evolution - sometimes this is simply a consequence of an alignment that has matched residues with a higher score at the expense of conserving columns we believe to be biologically important. MSAs can only take sequence information into account, while we may have complementary information available on structural and functional conservation patterns. This may include secondary structure (gaps should be moved out of regions of secondary structure, where possible), structurally required residues (these are expected to be conserved accross all structurally similar sequences), and functionally conserved residues (these are expected to have a high likelyhood of being conserved within groups of orthologues, but varying between paralogues).
+
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#fcbfc1">V</td>
 +
<td bgcolor="#c2bffc">N</td>
 +
<td bgcolor="#f0d2e0">A</td>
 +
<td bgcolor="#d2d2ff">R</td>
 +
<td bgcolor="#afabfa">D</td>
 +
<td bgcolor="#ababff">K</td>
  
In terms of structural conservation, we expect motif or consistency based alignments to be more accurate since they align to the "big picture". In terms of functional variation we expect progressive alignments to be more accurate, since they align to local similarities.
+
<td bgcolor="#d4d2fc">D</td>
 +
<td bgcolor="#c399d4">G</td>
 +
<td bgcolor="#bfbfff">R</td>
 +
<td bgcolor="#cbabdf">T</td>
 +
<td bgcolor="#c2abe8">P</td>
 +
<td bgcolor="#f699a1">L</td>
 +
<td bgcolor="#a199f6">H</td>
 +
<td bgcolor="#f7abb2">L</td>
 +
<td bgcolor="#dd99b9">A</td>
  
Let us consider the alignments in terms of their biological relevance. I have annotated the ligand-binding residues for the yeast Mbp1 APSES domain in the multiple sequence alignments by color coding the charged residues that putatively could bind DNA <span style="color:#FF0000;">'''red'''</span> (-) and <span style="color:#0066FF;">'''blue'''</span> (+).  Thus these residues label columns of the alignment in which we expect ''functional'' conservation. I have also highlighted two residues that are associated with important structural features of the APSES domain in <span style="color:#00AA33;">'''green'''</span>. These two residues are G75, a mandatory glycine in the third position of a particular type of beta-turn, and W77, a key component of the domain's hydrophobic core. Thus these two residues label columns in which we expect ''structural'' conservation. Let's assume (''i'') that all the APSES domains fold into similar structures and (''ii'') that they all bind DNA, but (''iii'') they do not necessarily bind the same cognate sequence, as a consequence of the functional diversification of paralogues. This should allow you to discuss the following questions:
+
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#9999ff">K</td>
 +
<td bgcolor="#afabfa">N</td>
 +
<td bgcolor="#e4d2ec">G</td>
 +
<td bgcolor="#d5d2fb">H</td>
 +
</tr>
 +
<tr><td nowrap="nowrap">1SW6/203-232&nbsp;&nbsp;</td>
 +
<td>L</td>
 +
<td bgcolor="#d4d2fc">D</td>
  
 +
<td bgcolor="#fbd2d5">L</td>
 +
<td bgcolor="#d2d2ff">K</td>
 +
<td bgcolor="#e2d2ef">W</td>
 +
<td bgcolor="#ffd2d2">I</td>
 +
<td bgcolor="#ffd2d2">I</td>
 +
<td bgcolor="#f0d2e0">A</td>
 +
<td bgcolor="#d4d2fc">N</td>
 +
<td>-</td>
 +
<td>-</td>
  
&nbsp;<br><div style="padding: 5px; background: #EEEEEE;">
+
<td>-</td>
Consider any '''one''' of the three APSES domain alignments. 
+
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
  
*Are the patterns of sequence variation for ''functionally conserved'' residues compatible with the notion that orthologues have conserved binding specificities and paralogues have acquired new functions by binding to different sequences?
+
<td>-</td>
*Are the patterns of sequence variation for ''structurally conserved'' residues compatible with the notion that all APSES domains have a common fold? (1 mark)
+
<td>-</td>
 +
<td>-</td>
 +
<td bgcolor="#ebbfd3">M</td>
 +
<td bgcolor="#f9bfc4">L</td>
 +
<td bgcolor="#c2bffc">N</td>
 +
<td bgcolor="#f0d2e0">A</td>
 +
<td bgcolor="#d4d2fc">Q</td>
 +
<td bgcolor="#afabfa">D</td>
  
For both cases, state briefly (but with reference to specific sequences and residues) what you would expect (hypothesis) and whether the alignment supports or contradicts your expectations (observation). We have determined that the sequences labelled as Mbp1 are orthologues, and the other labels were constructed to identify the yeast gene that each sequence is most similar to (although a reciprocal search was not done). This means you may group Mbp1 sequences as orthologues, Swi4, Sok2, and Phd1 sequences are presumably orthologous, and all sequences originating from the same organism are of course groups of paralogues. However, labels such as MbpA, MbpB etc. are arbitrary: these sequences as a group are paralogous to e.g. Mbp1 but not necessarily orthologous to each other. Your discussion ''may'' be easier if you sort the sequences differently than they are presented, this is easy to do in a text editor. Re-sorting does not change the alignment.
+
<td bgcolor="#caabe0">S</td>
</div>
+
<td bgcolor="#d4d2fc">N</td>
 +
<td bgcolor="#c399d4">G</td>
 +
<td bgcolor="#c2bffc">D</td>
 +
<td bgcolor="#cbabdf">T</td>
 +
<td bgcolor="#eaabbf">C</td>
 +
<td bgcolor="#f699a1">L</td>
 +
<td bgcolor="#9d99f9">N</td>
 +
<td bgcolor="#ffabab">I</td>
  
&nbsp;
+
<td bgcolor="#dd99b9">A</td>
&nbsp;
+
<td bgcolor="#dd99b9">A</td>
 +
<td bgcolor="#9999ff">R</td>
 +
<td bgcolor="#f7abb2">L</td>
 +
<td bgcolor="#e4d2ec">G</td>
 +
<td bgcolor="#d4d2fc">N</td>
 +
</tr>
 +
<tr><td nowrap="nowrap">SecStruc/203-232&nbsp;&nbsp;</td>
 +
<td>t</td>
  
<div style="padding: 5px; background: #E9EBF3;  border:solid 1px #AAAAAA;">
+
<td bgcolor="#e6d2e9">_</td>
===(4.3)  Visualization and analysis of alignment with VMD  (2 marks)===
+
<td bgcolor="#d5d2fb">H</td>
</div>
+
<td bgcolor="#d5d2fb">H</td>
&nbsp;<br>
+
<td bgcolor="#d5d2fb">H</td>
 +
<td bgcolor="#d5d2fb">H</td>
 +
<td bgcolor="#d5d2fb">H</td>
 +
<td bgcolor="#d5d2fb">H</td>
 +
<td bgcolor="#d5d2fb">H</td>
 +
<td>-</td>
  
VMD offers a very well constructed set of tools for the analyis of sequence and structural conservation: the '''MultiSeq''' extension. In this part of the assignment you will use VMD to analyse and visualize conservation patterns and comment on the alignments the servers have produced. I highly recommend to familiarize yourself with MultiSeq and the developers have produced an [http://www.ks.uiuc.edu/Training/Tutorials/#evolution excellent tutorial on the evolution of tRNA synthetases] to showcase the program's capabilities. However I am not ''requiring'' this for the course and we will be using only a subset of the available Multiseq functions. The tool is intuitive enough, beginning to use it should require no more than following the steps below.
+
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
 +
<td>-</td>
  
Proceed through the following steps:
+
<td>-</td>
:(1) Save an alignment of the APSES domains on your computer.
+
<td>-</td>
::(A) Choose either the CLUSTAL or MUSCLE alignment of all APSES domains, copy it from the Wiki page and save it on your computer, as a '''text file''' with some convenient filename and the extension .aln . This is a CLUSTAL formatted input file.
+
<td>-</td>
::(B) Edit the file to remove any header lines and lines containing the conservation symbols <code> .:*</code>. Leave the gene-names and aligned sequences as they are. Make sure you are not saving the file in MS-Word binary format (.doc) and that the extension is not changed (depending on how your computer is configured, it may silently append a <code>.txt</code> extension that will cause trouble later on).
+
<td>-</td>
 +
<td bgcolor="#dcbfe1">_</td>
 +
<td bgcolor="#dcbfe1">_</td>
 +
<td bgcolor="#dcbfe1">_</td>
 +
<td bgcolor="#e6d2e9">_</td>
 +
<td bgcolor="#e6d2e9">_</td>
  
:(2) Open the Multiseq extension in VMD.
+
<td bgcolor="#d2abd8">_</td>
::(A) start VMD and load one of the APSES domain structures (1BM8 or 1MB1).
+
<td bgcolor="#cbabdf">t</td>
::(B) choose a stereo representation that will show you the fold of the domain and the sidechains of key residues. For example you could use a Tube representation for the protein backbone and a Licorice representation for the selection <code>((sidechain or type CA) and not element H) and resid 30 to 90</code>.  (And switch the axes display off! The axes carry no information you need).
+
<td bgcolor="#e6d2e9">_</td>
::(C) On the VMD Main form navigate to Extensions &rarr; Analysis &rarr; MultiSeq
+
<td bgcolor="#c799cf">_</td>
::(D) When you run MultiSeq for the first time, you will be asked for a directory in which to store metadata. You can use the default or a directory of your choice; you may subsequently skip all steps that ask you to install "required" databases locally since we will not need them for this task.
+
<td bgcolor="#dcbfe1">_</td>
::(E) A window will appear - the ''MultiSeq'' window -it contains the sequence of the APSES domain you are visualizing. MultiSeq will also generate an additional cartoon representation of the structure.
+
<td bgcolor="#d2abd8">_</td>
 +
<td bgcolor="#b2abf7">H</td>
 +
<td bgcolor="#a199f6">H</td>
 +
<td bgcolor="#a199f6">H</td>
  
:(3) Load the APSES alignment.
+
<td bgcolor="#b2abf7">H</td>
::(A) In the MultiSeq Window, navigate to File &rarr; Import Data...; Choose "From Files" and Browse to the location of the alignment you have saved. The File navigation window gives you options which files to enable: choose to Enable ALN files (these are CLUSTAL formatted multiple sequence alignments).
+
<td bgcolor="#a199f6">H</td>
::(B) Open the alignment file, click on Ok to Import Data, it will take a short while to load. If the data can't be loaded, the file may have the wrong extension: <code>.aln</code> is required.
+
<td bgcolor="#a199f6">H</td>
::(C) find the Mbp1_SACCE sequence in the list, click on it and move it to the top of the '''Sequences''' list with your mouse (the list is not static, you can re-order the sequences in any way you like).
+
<td bgcolor="#a199f6">H</td>
 +
<td bgcolor="#b2abf7">H</td>
 +
<td bgcolor="#e6d2e9">_</td>
 +
<td bgcolor="#e6d2e9">_</td>
 +
</tr>
 +
</table>
 +
</td></tr>
  
You will see that the stucture's sequence and the APSES domain sequence do not match; at the beginning the structure has extra sequence extending its N-terminus and in the middle the APSES sequences have gaps inserted.
+
</table>
 +
;Aligned sequence after editing. A significant cleanup of the frayed region is possible. Now there is only one insertion event, and it is placed into the loop that connects two helices of the 1SW6 structure.
  
:(4) Bring the structure's sequence in register with the APSES alignment.
 
::(A) MultiSeq supports typical text-editor selection mechanisms. Clicking on a residue selects it, clicking on a row selects the whole sequence. Dragging with the mouse selects several residues, shift-clicking selects ranges, and option-clicking toggles the selection on or off for individual residues. Using the mouse and/or the shift key as required, select the '''entire first column''' of the sequence group.
 
::(B) Select Edit &rarr; Enable Editing... &rarr; Gaps only to allow changing indels.
 
::(C) Pressing the spacebar once should insert a gap character before the selected column in all sequences. Insert as many gaps as you need to align the beginning of sequences with the corresponding residues of the structure <code>S&nbsp;I&nbsp;M&nbsp;...</code>.
 
::(D) Now insert as many gaps as you need into the '''structure''' sequence, to align it completely with the Mbp1_SACCE APSES domain sequence. (Simply select residues in the sequence and use the space bar to insert gaps. <small>(Note: I have noticed a bug that sometimes prevents slider or keuyboard input to the MultiSeq window; it fails to ''regain focus'' after operations in a different window. I don't know whether this is a Mac related problem or a more general bug in MultiSeq. When this happens I quit VMD and restore the session from a saved state. It is a bit annoying but not mission-critical.)</small>
 
::(E) When you are done, it may be prudent to save the state of your alignment. Use File &rarr; Save Session...
 
  
:(5) Color by similarity
+
<div style="padding: 5px; background: #E9EBF3; border:solid 1px #AAAAAA;">
::(A) Use the View &rarr; Coloring &rarr; Sequence similarity &rarr; BLOSUM30 option to color the residues in the alignment and structure. This clearly shows you where conserved and variable residues are located and allows to analyze their structural context.
 
::(B) You can adjust the color scale in the usual way by navigating to VMD main &rarr; Graphics &rarr; Colors..., choosing the Color Scale tab and adjusting the scale midpoint (0.75 works well for me).
 
::(C) Navigate to the Representations window and apply the color scheme to your tube-and-sidechain representation: double-click on the NewCartoon representation to hide it and use '''User''' coloring of your Tube and Licorice representations to apply the sequence similarity color gradient that MultiSeq has calculated. The example below shows in principle what you could expect to see (without sidechains).
 
  
[[Image:A03_02.jpg|frame|none|Assignment 3, Figure 02<br>
+
===(2.5) Final analysis===
Stereo view of a tube representation of an APSES domain structure, colored according to residue similarity of all fungal APSES domains as defined in this assignment. A BLOSUM30 similarity matrix was applied and a gradient midpoint of 0.75. The domain is oriented with the putative recognition helix towards the front, left and the "wing" on the right.]]
+
</div>
  
::(D) Now delete all non-Mbp1 sequences from the alignment and recalculate the similarity coloring using only the Mbp1 orthologues. You may want to shift the gradient midpoint to 0.9 or so since overall conservation is much higher. Again study the conservation patterns.
 
  
[[Image:A03_03.jpg|frame|none|Assignment 3, Figure 03<br>
+
<div style="padding: 5px; background: #EEEEEE;">
Stereo view of a tube representation of an APSES domain structure, colored according to residue similarity of all Mbp1 orthologue APSES domains, as defined in this assignment. A BLOSUM50 similarity matrix was applied and a gradient midpoint of 0.90. The domain is oriented with the putative recognition helix towards the front, left and the "wing" on the right.]]
+
* Compare the distribution of indels in the ankyrin repeat regions of your alignments. '''Review''' whether the indels in this region are concentrated in segments that connect the helices, or if they are more or less evenly distributed along the entire region of similarity. Think about whether the assertion that ''indels should not be placed in elements of secondary structure'' has merit in your alignment. Recognize that an indel in an element of secondary structure could be interpreted in a number of different ways:
 +
** The alignment is correct, the annotation is correct too: the indel is tolerated in that particular case, for example by extending the length of an &alpha;-helix or &beta;-strand;
 +
** The alignment algorithm has made an error, the structural annotation is correct: the indel should be moved a few residues;
 +
** The alignment is correct, the structural annotation is wrong, this is not a secondary structure element after all;
 +
** Both the algorithm and the annotation are probably wrong, but we have no data to improve the situation.  
  
 +
(<small>NB: remember that the structural annotations have been made for the yeast protein and might have turned out differently for the other proteins...</small>)
  
&nbsp;<br><div style="padding: 5px; background: #EEEEEE;">
+
You should be able to analyse discrepancies between annotation and expectation in a structured and systematic way. In particular if you notice indels that have been placed into structurally annotated regions of secondary structure, you should be able to comment on whether the location of the indel has strong support from aligned sequence motifs, or whether the indel could possibly be moved into a different location without much loss in alignment quality.
+
</div>
*Generate two  parallel stereo views that shows the APSES domain backbone and selected sidechains as described above. One should be colored by sequence similarity among all APSES domains, the other by similarity among only the Mbp1 orthologues. Scale and rotate the structure so that the putative DNA binding domain is easily visible. Paste both views into your assignment in a compressed format, as was explained for Assignment 2.
 
  
*Briefly discuss what you see (with reference to specific residues and sidechains) and what you conclude about residue conservation in the alignment of all APSES domains. Are the patterns of sequence variation for ''structurally conserved'' residues compatible with the notion that all APSES domains have a common fold?
 
  
*Briefly discuss how the situation changes when you compare only Mbp1 orthologues with each other. Never mind that overall conservation is higher: does the '''distribution''' of conserved residues in the context of the domain change, and if so, how? Are the patterns of sequence variation for ''functionally conserved'' residues compatible with the notion that all Mbp1 orthologues have a similar function?
+
<div style="padding: 5px; background: #FFCC99;">
 +
;Analysis (2 marks)
  
*The structure makes it easy to confirm where gaps in the alignment have been placed. Discuss briefly (but with reference to specific instances) whether the indel placements of CLUSTAL or MUSCLE appear more plausible. To do this, define where you would expect to find indels and where they have been placed by the MSA program. (2 marks total)
+
*Considering the whole alignment and your experience with editing, please note in your assignment your assessment of whether the position of indels relative to structural features of the ankyrin domains in your organism's Mbp1 protein is reliable.  
  
 +
*CDD extends the ankyrin domain annotation beyond the 1SW6 domain boundaries. Given your assessment of conservation in that region, do you think that this is reasonable in your organisms' protein? Is there evidence for this in the alignment of the CD00204 consensus with well aligned blocks of sequence beyond the positions that match Swi6?
 
</div>
 
</div>
  
&nbsp;
 
&nbsp;
 
  
 
<div style="padding: 5px; background: #BDC3DC;  border:solid 1px #AAAAAA;">
 
<div style="padding: 5px; background: #BDC3DC;  border:solid 1px #AAAAAA;">
  
==(5) Summary of Resources==
+
==(3) Summary of Resources==
 
</div>
 
</div>
 
&nbsp;<br>
 
&nbsp;<br>
  
 
;Links
 
;Links
:* [[Organism_list_2007|Assigned Organisms]]
 
 
:* [http://www.ncbi.nlm.nih.gov/blast '''BLAST''']
 
:* [http://www.ncbi.nlm.nih.gov/blast '''BLAST''']
:* [http://www.pir.uniprot.org/search/idmapping.shtml '''Uniprot ID mapping''' service]
+
:* [http://www.pir.uniprot.org/?tab=mapping '''Uniprot ID mapping''' service]
 
:* [http://www.ncbi.nlm.nih.gov/sutils/blink.cgi?pid=68465419  A '''BLink''' example]
 
:* [http://www.ncbi.nlm.nih.gov/sutils/blink.cgi?pid=68465419  A '''BLink''' example]
 
:* [http://www.ebi.ac.uk/clustalw/ EBI '''CLUSTAL-W''' server]
 
:* [http://www.ebi.ac.uk/clustalw/ EBI '''CLUSTAL-W''' server]
Line 834: Line 3,741:
 
:* [http://www.ebi.ac.uk/thornton-srv/databases/sas/ '''SAS''']
 
:* [http://www.ebi.ac.uk/thornton-srv/databases/sas/ '''SAS''']
  
;Sequences
+
;Lists
:* [[All_Mbp1_proteins|'''All Mbp1 proteins''']]
+
:* [[Species list]]
:* [[All_APSES_domains|'''All APSES domains''']]
+
:* [[Mbp1_RBM_reference_sequences|'''A page of reference sequence of Mbp1 proteins''']]
 +
:* [[Mbp1_annotation|'''A page of text-based annotations for the yeast Mbp1 protein''']]
  
;Alignments
 
:'''Mbp1 proteins:'''
 
:* [[All_Mbp1_CLUSTAL|Mbp1 proteins '''CLUSTAL''' aligned]]
 
:* [[All_Mbp1_MUSCLE|Mbp1 proteins '''MUSCLE''' aligned]]
 
:* [[All_Mbp1_T-COFFEE|Mbp1 proteins '''T-Coffee''' aligned (text version)]]
 
:* [http://biochemistry.utoronto.ca/undergraduates/courses/BCH441H/resources/T-coffee_scores.html Mbp1 proteins '''T-Coffee''' aligned (coloured according to scores)]
 
  
:'''APSES domains:'''
+
:'''Further reading'''
:* [[APSES_domains_PSI-BLAST|All APSES domains - alignment based on '''PSI-BLAST''' results]]
+
:* [http://bioinformatics.oxfordjournals.org/content/24/3/319.full Moreno-Hagelsieb &amp; Latimer compare Reciprocal Best Match vs. a related concept: Reciprocal Smallest Distance]
:* [[APSES_domains_CLUSTAL|All APSES domains - '''CLUSTAL-W''' alignment]]
 
:* [[APSES_domains_MUSCLE|All APSES domains -  '''MUSCLE''' alignment]]
 
  
 
+
&nbsp;<br>
&nbsp;
 
&nbsp;
 
  
 
<div style="padding: 5px; background: #D3D8E8;  border:solid 1px #AAAAAA;">
 
<div style="padding: 5px; background: #D3D8E8;  border:solid 1px #AAAAAA;">
Line 858: Line 3,756:
 
</div>
 
</div>
  
If you have any questions at all, don't hesitate to mail me at [mailto:boris.steipe@utoronto.ca boris.steipe@utoronto.ca] or post your question to the [mailto:bch441_2006@googlegroups.com Course Mailing List]
+
&nbsp;<br>
 +
 
 +
If you have any questions at all, don't hesitate to mail me at [mailto:boris.steipe@utoronto.ca boris.steipe@utoronto.ca] or post your question to the [mailto:bch441_2011@googlegroups.com Course Mailing List]

Latest revision as of 23:32, 21 September 2012

Note! This assignment is currently active. All significant changes will be announced on the mailing list.

 
 

 

 

Assignment 3 (last: 2011) - Multiple Sequence Alignment

 

Preparation, submission and due date

Read carefully.
Be sure you have understood all parts of the assignment and cover all questions in your answers! Sadly, we always get assignments back in which people have simply overlooked crucial questions. Sadly, we always get assignments back in which people have not described procedural details. If you did not notice that the above were two different sentences, you are still not reading carefully enough.

Review the guidelines for preparation and submission of BCH441 assignments.

The due date for the assignment is Monday, November 21. at 12:00.

   

Your documentation for the procedures you follow in this assignment will be worth 1 mark.


 

Introduction

 

Take care of things, and they will take care of you.
Shunryu Suzuki

Much of what we know about a protein's physiological function is based on the conservation of that function as the species evolves. We assess conservation by comparison to related proteins. Conservation - or variability - is a consequence of selection under constraints: the multiple effects on a species' fitness function that are induced through changes to the structural or functional features of a protein. Conservation patterns can thus provide evidence for many different questions: structural conservation among proteins with similar 3D-structures, functional conservation among homologues with comparable roles, peaks of sequence variability that indicate domain boundaries in multi-domain proteins, or amino acid propensities as predictors for protein engineering and design tasks.

Measuring conservation requires alignment. Therefore a carefully done multiple sequence alignment (MSA) is a cornerstone for the annotation of the essential properties a gene or protein. MSAs are also useful to resolve ambiguities in the precise placement of indels and to ensure that columns in alignments actually contain amino acids that evolve in a similar context. MSAs serve as input for

  • functional annotation;
  • protein homology modeling;
  • phylogenetic analyses, and
  • sensitive homology searches in databases.


As a first step, we will explore the search and retrieval of fungal proteins that are orthologous to yeast Mbp1, and of the APSES domains they contain. Each student is being assigned one genome-sequenced fungus. Briefly, you will

  1. Collect sequence identifiers for all APSES domain transcription factors in your assigned species;
  2. Retrieve the sequences;
  3. Perform a multiple sequence alignment with these, and a number of reference domains;
  4. Edit the alignment and annotate.


Multiple Sequence Alignment is not a solved, computational problem and a significant number of alignment tools exist, each with different strengths and objectives. It is remarkable that by far the most frequently used MSA algorithm is CLUSTAL, a procedure that was first published for the microprocessors of the late 1980s, surpassed in performance many times, and shown to be significantly inferior to more modern approaches when aligning sequences with 30% identity or less. In this assignment we will encounter various approaches to multiple alignment:

  • A model-based approach (based on the PSSM that PSI-BLAST generates)
  • Progressive alignments - CLUSTAL and MAFFT
  • Consistency based alignment - T-Coffee and MUSCLE


(1) Mbp1 homologues


(1.1) Retrieving sequences


In Assignment 2 you retrieved the protein sequences of saccharomyces cerevisiae Mbp1 and defined its APSES (KilA-N) domain. Let us now search for an orthologue of this sequence in Your Species. More precisely, you should identify proteins that fulfill the Reciprocal Best Match criterion.

First, we need to define the sequence you will use to find Mbp1 homologues. Since Mbp1 contains the very widely distributed Ankyrin motifs, a BLAST search with full length sequences will pick up a large number of Ankyrin-repeat containing proteins that are otherwise unrelated to our query. We will instead search for homologues using only the APSES domain as a query. However, the Pfam definition of the APSES domain (or KilA-N family, as it is now called) does not cover the entire length of the domain that has been crystallized. Therefore, we will use the sequence of the crystallized protein instead of the Pfam alignment. One of the results of our analysis will be whether APSES domains in fungi all have the same length as the Mbp1 domain, or whether some are indeed much shorter, as sugested by the Pfam alignment. To remind you, here is the full sequence of the 1MB1 structure (Note that the C-terminal His6 tag that has been added for purification is not part of the Mbp1 protein sequence.) ... 


>PDB:1MB1
MSNQIYSARYSGVDVYEFIHSTGSIMKRKKDDWVNATHILKAANFAKAKRTRILEKEVLKETHEKVQGGFGKYQGTWVPL
NIAKQLAEKFSVYDQLKPLFDFTQTDGSASPPPAPKHHHASKVDHHHHHH


... and, for comparison, this is the corresponding alignment with the Pfam KilA-N model obtained from a RPS-BLAST search of the above sequence against the CDD database: 


                           10        20        30        40        50        60        70        80
                   ....*....|....*....|....*....|....*....|....*....|....*....|....*....|....*....|
1MB1            19 IHSTGSIMKRKKDDWVNATHILKAANFAKaKRTRILEKEVLKETHEKVQ----------------GGFGKYQGTWVPLNI 82

Cdd:pfam04383    3 YNDFEIIIRRDKDGYINATKLCKAAGATK-RFRNWLRLESTKELIEELSkennidvliievenkkGKNGRLQGTYVHPDL 81


                           90
                   ....*....|....*
1MB1            83 AKQLA----EKFSVY 93

Cdd:pfam04383   82 ALAIAswisPEFALK 96


As you can see, the Pfam alignment is 18 amino acids shorter at the N-terminus and 31 amino acids shorter at the C-terminus.


Find APSES domain proteins in your species
  1. Access the species list and identify the species that has been assigned to you.
  2. Navigate to the NCBI's main page.
  3. In the left-hand menu of links, follow the link to Genomes & Maps.
  4. Under the Databases tab, follow the link to Genome.
  5. In the Genome tools section of that page, follow the link to Genomic groups BLAST.
  6. Click on link to the eukaryotic genomes tree, then on the link for the text table. This produces a BLAST interface to a list of species for which whole-genome sequences have been sequenced, annotated and entered into the various databases.
  7. Paste the FASTA sequence of the structurally defined Mbp1 APSES domain (e.g. from 1MB1) into the search field (excluding the His-tag, of course), set the parameters correctly for a Protein search against Protein sequences using blastp. Then find your assigned species in the table and check the box next to its name. Remember to record the parameters for your search. I expect you to understand which parameters would be needed in order to make this search reproducible. Run the search.
  8. On the next screen, check the box next to Format for: PSI-BLAST. Then click on View report to show the results of the first PSI-BLAST iteration.
  9. Run subsequent iterations of PSI-BLAST simply by clicking on Go after checking the sequences that have been included.
  10. Iterate the PSI-BLAST search until convergence (i.e. until no more new sequences are added); make sure to include only sequences for which the E-value is small (smaller than about 10e-03 should be safe). Sequences with borderline E-values that improve significantly in an iteration are probably homologues. Sequences with borderline E-values that do not improve much, or for which the E-value increases are probably not homologues. If this step does not work for you or the results are not what you expect, please contact your TA right away.
  • Note: Please spend a little time on each page to understand its contents. Ask, if the page contains resources or features you don't understand. Think about what you are doing. If you simply click on the links I provide, you will miss the opportunity to understand how the resources fit into the workflow you are working on, and to be able to execute similar processes yourself. Questions on page contents can potentially appear on quizzes and exam.


Familiarize yourself with the output form you obtain, this is by far the most frequently used bioinformatics result page. You may want to refer to the NCBI explanation.

Here is a list of things to look for, all of which I expect you to know and understand. (However you do not need to comment on these points in your submission.)

On the alignment image
  • What do the different colored bars mean?
  • What is the information you get when you "mouse-over" a colored bar on the alignment image.
  • What happens when you click on one of the bars?
In the description list
  • Where does the link next to an identifier take you?
  • Where does the link in the "score" column take you?
  • What does the icon at the end of each row mean? What other icons could appear there?
In the alignment section
  • What do the alignment metrics mean:
    • Score?
    • Expect (E-value)?
    • Identities?
    • Positives?
    • Gaps?
  • What is the alignment length?
  • Which sequence is labeled Query and which one is labelled Sbjct?


Next
retrieve the sequences that have E-values low enough to make you conclude they contain APSES domain homologues.
  1. Review the sequences you have found: they should all be significantly similar to the query profile. In some of the assigned species you will find one hit for each distinct sequence in the genome, in others, you will find several versions of essentially the same gene (e.g. refseq and other accession numbers).
  2. Explore the relationship between the hits by clicking on select all sequences, then choosing Distance tree of results at the top or bottom of your search results to visualize a tree representation of similarity. Highly similar sequences will be collapsed into the same node in the distance tree; you can expand those nodes to list all the node's members.
  3. Identify one representative for each distinct protein you have found. If possible, use proteins with refseq identifiers. Avoid duplicates or nearly identical variants. If there are length differences, use the longer version (shorter versions may contain only partial sequences). Click on the checkbox next to each protein you have identified.
  4. Click on get selected sequences at the top or bottom of the page. Note and record the GIs for your sequences that are listed in the Search details box, you can use them to easily reproduce your results by pasting them into any Entrez search. Also note the URL that this has produced (in your browser's URL bar). As you see, you can retrieve a list of sequences from NCBI simply by adding a list of comma-separated GI numbers to the URL of the protein database.
  5. Click on Display settings and choose FASTA (text).

If you want, for comparison, you can run a multiple alignment with an NCBI-developed MSA tool: COBALT. On the sequence list page, in the right-hand column, in the section Analyze these sequences, click on Align sequences with COBALT. It is a convenient way to get a quick first look at an alignment of NCBI retrieved sequences.

You now have a collection of APSES domain-containing homologues in your organism. There are two more tasks we need to address before we can compute alignments and analyze them. (A) we need to rename our sequences, and (B) we need to define the boundaries of their APSES domains.


(1.2) Renaming Sequences

A phylogenetic tree or multiple alignment is not really informative if it that displays GI numbers or other abstract identifiers as labels of rows or nodes. The relationship between species is fundamental to the variation we observe and we need to make this relationship explicit.

Imagine that the rows in an MSA were completely unlabeled, or the nodes in the tree would be just circles: we would have a very hard time relating the computed relationships back to the biology they represent. Abstract identifiers like NP_010227 are not much better.

Typically, the information that programs use to label sequences is taken from the FASTA header. This provides us with an easy way to make sure they display the information we need and that we can interpret. Typically such programs will use the first few (often ten) characters they find. We will therefore design short strings strings that identify potential gene family relationships as well as species.


Species codes

The scientific name of a species is formed according to Linnaean binomial nomenclature and Swissprot has for a long time condensed species names into mnemonic five-character codes, taking the first three from the genus name and the last two from the specific name. For example Saccharomyces cerevisiae is abbreviated as SACCE and Lachancea thermotolerans is LACTH. For the most part, this creates unique strings that are good mnemonic labels for the species. I have added these "codes" to the Species list.


Gene families

Most yeast genes have traditional names, like mbp1 or sok2. These names are convenient family labels since saccharomyces cerevisiae is one of the best studied model organisms. Therefore, once we identify a protein family that includes a yeast gene, we can easily access expert knowledge in textbooks or manuscripts. Of course, such labels are arbitrary - whether we call a gene Mbp1 or WXYZ makes no difference - as long as all genes that we presume to be family members carry the same label. For higher eukaryotes, I would probably choose human gene names as a reference point, for bacteria I would choose E. coli.

To define which gene belongs into which family, we can align all newly found genes with all yeast APSES domain homologues, to find out which ones they are most similar to. This creates common family labels. We can use these as provisional family names for the encoded proteins, even though we may want to revise them once we have mapped out explicit phylogenetic trees.


Identifying APSES domains (general procedure).

In order to identify the APSES domain boundaries, you can simply run a multiple sequence alignment of the structurally defined APSES domain sequence (e.g. taken from PDB-ID 1MB1) against all sequences you have found. The boundaries of the aligned APSES domain then define the domain boundaries in the aligned proteins.


Identifiying family relationships (in the same run)

However, for efficiency, we can also determine family relationships in the same alignment that we use to define domain boundaries, if we simply include all yeast APSES domains in the MSA. Then we can judge similarity simply from examining the guide tree of the alignment and label the families accordingly. This has the added advantage that the domain boundaries are more securely defined, since we include more sequence information into the alignment.

Proceed as follows.
  1. Open the Muscle MSA input page at the EBI.
  2. Access the Yeast APSES domain collection I have prepared and copy the FASTA sequences. Paste them into the sequence field of the MUSCLE program input form.
  3. Copy the FASTA sequenced of the full length APSES domain protein sequence collection from your PSI-BLAST search (above) and paste them into the MUSCLE input form as well.
  4. Set the following parameters:
OUTPUT FORMAT: CLUSTALW2
OUTPUT TREE: from second iteration
OUTPUT ORDER: aligned
  1. Click on Submit.


The output should show the MSA. The overlap of the yeast APSES domains with your sequences defines the domain boundaries. Moreover, a tree has been calculated and you can view the tree to identify family relationships.

Visualize the alignment tree and decide on names

Click on the link to the Guide tree. This is the so-called Newick tree format and there are a large number of online tree viewers to visualize such trees. The MUSCLE form will display one tree for you,

You could also navigate (for example) to the proWeb Tree viewer and paste the tree data into the User-supplied Newick Tree input field. Choose any graphics format your browser can handle (JPEG is a pretty safe bet) and click on View tree.


  1. Interpret the tree to decide on the protein family names for your sequences:
    1. If a yeast protein is grouped with exactly one of your proteins, your protein gets the same name.
    2. If a yeast protein is grouped with more than one of your proteins, replace the number in the yeast protein with a, b, c ..., from most similar to least similar for your protein. For example: if one Aspergillus fumigatus protein is most similar to yeast Mbp1, you will give it the name MBP1_ASPFU. If two proteins are both most similar to yeast Sok2, you will name them SOKA_ASPFU and SOKB_ASPFU. Try to get it approximately right but remember that this is a process of estimation - we are not accurately measuring distances (yet).

That done, edit your FASTA headers and save your APSES domain sequence set. We will need them for the next assignment.


(2) Align and Annotate

 


(2.1) Review of domain annotations

APSES domains are relatively easy to identify and annotate but we have had problems with the ankyrin domains in Mbp1 homologues. Both CDD as well as SMART have identified such domains, but while the domain model was based on the same Pfam profile for both, and both annotated approximately the same regions, the details of the alignments and the extent of the predicted region was different.

Mbp1 forms heterodimeric complexes with a homologue, Swi6. Swi6 does not have an APSES domain, thus it does not bind DNA. But it is similar to Mbp1 in the region spanning the ankyrin domains and in 1999 Foord et al. published its crystal structure (1SW6). This structure is a good model for Ankyrin repeats in Mbp1. For details, please refer to the consolidated Mbp1 annotation page I have prepared.

In what follows, we will use the program JALVIEW - a Java based multiple sequence alignment editor to load and align sequences and to consider structural similarity between yeast Mbp1 and its closest homologue in your organism.

In this part of the assignment,

  1. You will load sequences that are most similar to Mbp1 into an MSA editor;
  2. You will add sequences of ankyrin domain models;
  3. You will perform a multiple sequence alignment;
  4. You will try to improve the alignment manually;


(2.2) Jalview, loading sequences

Geoff Barton's lab in Dundee has developed an integrated MSA editor and sequence annotation workbench with a number of very useful functions. It is written in Java and should run on Mac, Linux and Windows platforms without modifications. We will use this tool for this assignment and explore its features as we go along.

  1. Navigate to the Jalview homepage click on Download, install Jalview on your computer and start it. A number of windows that showcase the program's abilities will load, you can close these.
  2. Prepare homologous Mbp1 sequences for alignment:
    1. Find the sequence in your assigned species that fulfills the Reciprocal Best Match crierion with yeast Mbp1.
    2. Open the Mbp1 RBM reference sequences page.
    3. Copy the FASTA sequences of the reference proteins, return to Jalview and select File → Input Alignment → from Textbox and paste the sequences into the textbox.
    4. Also paste a FASTA sequence of your species' Mbp1 protein into the window.
    5. Finally copy the sequences for ankyrin domain models (below) and paste them into the Jalview textbox as well. Paste two separate copies of the CD00204 consensus sequence and one copy of 1SW6.
    6. When all the sequences are present, click on New Window. Jalview gives you all the sequences, but of course this is not yet an alignment.
Ankyrin domain models
>CD00204 ankyrin repeat consensus sequence from CDD
NARDEDGRTPLHLAASNGHLEVVKLLLENGADVNAKDNDGRTPLHLAAKNGHLEIVKLLL
EKGADVNARDKDGNTPLHLAARNGNLDVVKLLLKHGADVNARDKDGRTPLHLAAKNGHL

>1SW6 from PDB - unstructured loops replaced with xxxx
GPIITFTHDLTSDFLSSPLKIMKALPSPVVNDNEQKMKLEAFLQRLLFxxxxSFDSLLQE
VNDAFPNTQLNLNIPVDEHGNTPLHWLTSIANLELVKHLVKHGSNRLYGDNMGESCLVKA
VKSVNNYDSGTFEALLDYLYPCLILEDSMNRTILHHIIITSGMTGCSAAAKYYLDILMGW
IVKKQNRPIQSGxxxxDSILENLDLKWIIANMLNAQDSNGDTCLNIAARLGNISIVDALL
DYGADPFIANKSGLRPVDFGAG


(2.3) Computing alignments

Sequence alignments can be calculated directly from Jalview.

  1. In Jalview, select Web Service → Alignment → MAFFT Multiple Protein Sequence Alignment. The alignment is calculated in a few minutes and displayed in a new window.
  2. Choose Colour → Hydrophobicity and → by Conservation. Then select Modify Conservation Threshold... and adjust the slider left or right to see which columns are highly conserved. You will notice that the Swi6 sequence that was supposed to align only to the ankyrin domains was in fact aligned to other parts of the sequence as well. This is one part of the MSA that we will have to correct manually and a common problem when aligning sequences of different lengths.
  3. Other alignment algorithms are available and you may wish to explore whether the alignments differ significantly.


(2.4) Editing ankyrin domain alignments


A good MSA comprises only columns of residues that play similar roles in the proteins' mechanism and/or that evolve in a comparable structural context. Since it is a result of biological selection and conservation, it has relatively few indels and the indels it has are usually not placed into elements of secondary structure or into functional motifs. The contiguous features annotated for Mbp1 are expected to be left intact by a good alignment.

A poor MSA has many errors in its columns; these contain residues that actually have different functions or structural roles, even though they may look similar according to a (pairwise!) scoring matrix. A poor MSA also may have introduced indels in biologically irrelevant positions, to maximize spurious sequence similarities. Some of the features annotated for Mbp1 will be disrupted in a poor alignment and residues that are conserved may be placed into different columns.

Often errors or inconsistencies are easy to spot, and manually editing an MSA is not generally frowned upon, even though this is not a strictly objective procedure. The main goal of manual editing is to make an alignment biologically more plausible. Most comonly this means to mimize the number of rare evolutionary events that the alignment suggests and/or to emphasize conservation of known functional motifs. Here are some examples for what one might aim for in manually editing an alignment:

Reduce number of indels
From a Probcons alignment:
0447_DEBHA    ILKTE-K-T---K--SVVK      ILKTE----KTK---SVVK
9978_GIBZE    MLGLN-PGLKEIT--HSIT      MLGLNPGLKEIT---HSIT
1513_CANAL    ILKTE-K-I---K--NVVK      ILKTE----KIK---NVVK
6132_SCHPO    ELDDI-I-ESGDY--ENVD      ELDDI-IESGDY---ENVD
1244_ASPFU    ----N-PGLREIC--HSIT  ->  ----NPGLREIC---HSIT
0925_USTMA    LVKTC-PALDPHI--TKLK      LVKTCPALDPHI---TKLK
2599_ASPTE    VLDAN-PGLREIS--HSIT      VLDANPGLREIS---HSIT
9773_DEBHA    LLESTPKQYHQHI--KRIR      LLESTPKQYHQHI--KRIR
0918_CANAL    LLESTPKEYQQYI--KRIR      LLESTPKEYQQYI--KRIR

Gaps marked in red were moved. The sequence similarity in the alignment does not change considerably, however the total number of indels in this excerpt is reduced to 13 from the original 22


Move indels to more plausible position
From a CLUSTAL alignment:
4966_CANGL     MKHEKVQ------GGYGRFQ---GTW      MKHEKVQ------GGYGRFQ---GTW
1513_CANAL     KIKNVVK------VGSMNLK---GVW      KIKNVVK------VGSMNLK---GVW
6132_SCHPO     VDSKHP-----------QID---GVW  ->  VDSKHPQ-----------ID---GVW
1244_ASPFU     EICHSIT------GGALAAQ---GYW      EICHSIT------GGALAAQ---GYW

The two characters marked in red were swapped. This does not change the number of indels but places the "Q" into a a column in which it is more highly conserved (green). Progressive alignments are especially prone to this type of error.

Conserve motifs
From a CLUSTAL alignment:
6166_SCHPO      --DKRVA---GLWVPP      --DKRVA--G-LWVPP
XBP1_SACCE      GGYIKIQ---GTWLPM      GGYIKIQ--G-TWLPM
6355_ASPTE      --DEIAG---NVWISP  ->  ---DEIA--GNVWISP
5262_KLULA      GGYIKIQ---GTWLPY      GGYIKIQ--G-TWLPY

The first of the two residues marked in red is a conserved, solvent exposed hydrophobic residue that may mediate domain interactions. The second residue is the conserved glycine in a beta turn that cannot be mutated without structural disruption. Changing the position of a gap and insertion in one sequence improves the conservation of both motifs.


The Ankyrin domains are quite highly diverged, the boundaries not well defined and not even CDD, SMART and SAS agree on the precise annotations. We expect there to be alignment errors in this region. Nevertheless we would hope that a good alignment would recognize homology in that region and that ideally the required indels would be placed between the secondary structure elements, not in their middle. But judging from the sequence alignment alone, we cannot judge where the secondary structure elements ought to be. You should therefore add the following "sequence" to the alignment; it contains exactly as many characters as the Swi6 sequence above and annotates the secondary structure elements. I have derived it from the 1SW6 structure 

>SecStruc 1SW6 E: strand   t: turn   H: helix   _: irregular
_EEE__tt___ttt______EE_____t___HHHHHHHHHHHHHHHH_xxxx_HHHHHHH
HHHH_t_____t_____t____HHHHHHH__tHHHHHHHHH____t___tt____HHHHH
HH__HHHH___HHHHHHHHHHHHHEE_t____HHHHHHHHH__t__HHHHHHHHHHHHHH
HHHHHH__EEE_xxxx_HHHHHt_HHHHHHH______t____HHHHHHHH__HHHHHHHH
H____t____t____HHHH___


To proceed:

  1. You should manually align the Swi6 sequence with yeast Mbp1
  2. You should bring the Secondary structure annotation into its correct alignment with Swi6
  3. You should bring both CDD ankyrin profiles into the correct alignment with yeast Mbp1

Proceed along the following steps:

  1. Add the secondary structure annotation to the sequence alignment in Jalview. Copy, select File → Add sequences → from Textbox and paste the sequence.
  2. Select Help → Documentation and read about Editing Alignments, Cursor Mode and Key strokes.
  3. Click on the yeast Mbp1 sequence row to select the entire row. Then use the cursor key to move that sequence directly above the 1SW6 sequence. Select the row of 1SW6 and use shift/mouse to move the sequence elements and realign them with yeast Mbp1. Refer to the alignment given in the Mbp1 annotation page.
  4. Align the secondary structure elements with the 1SW6 sequence: Every character of 1SW6 should be matched with either E, t, H, or _. The result should be similar to the Mbp1 annotation page. If you need to insert gaps into all sequences in the alignment, simply drag your mouse over all row headers - movement of sequences is constrained to selected regions, the rest is locked into place to prevent inadvertent misalignments. Remember to save your project from time to time: File → save so you can reload a previous state if anything goes wrong and can't be fixed with Edit → Undo.
  5. Finally align the two CD00204 consensus sequences to their correct positions (again, refer to the Mbp1 annotation page).
  6. You can now consider the principles stated above and see if you can improve the alignment, for example by moving indels out of regions of secondary structure if that is possible without changing the character of the aligned columns significantly. Select blocks within which to work to leave the remaining alignment unchanged. So that this does not become tedious, you can restrict your editing to one Ankyrin repeat that is structurally defined in Swi6. You may want to open the 1SW6 structure in VMD to define the boundaries of one such repeat. You can copy and paste sections from Jalview into your assignment for documentation or export sections of the alignment to HTML (see the example below).


(2.4.1) Editing ankyrin domain alignments - Sample

This sample was created by

  1. Editing the alignments as described above;
  2. Copying a block of aligned sequence;
  3. Pasting it To New Alignment;
  4. Colouring the residues by Hydrophobicity and setting the colour saturation according to Conservation;
  5. Choosing File → Export Image → HTML and pasting the resulting HTML source into this Wikipage.


10
|		 20
|		 30
|		 40
|
MBP1_USTMA/341-368   - - Y G D Q L - - - A D - - - - - - - - - - I L - - - - N F Q D D E G E T P L T M A A R A R S
MBP1B_SCHCO/470-498   - R E D G D Y - - - K S - - - - - - - - - - F L - - - - D L Q D E H G D T A L N I A A R V G N
MBP1_ASHGO/465-494   F S P Q Y R I - - - E T - - - - - - - - - - L I - - - - N A Q D C K G S T P L H I A A M N R D
MBP1_CLALU/550-586   G N Q N G N S N D K K E - - - - - - - - - - L I S K F L N H Q D N E G N T A F H I A A Y N M S
MBPA_COPCI/514-542   - H E G G D F - - - R S - - - - - - - - - - L V - - - - D L Q D E H G D T A I N I A A R V G N
MBP1_DEBHA/507-550   I R D S Q E I - - - E N K K L S L S D K K E L I A K F I N H Q D I D G N T A F H I V A Y N L N
MBP1A_SCHCO/388-415   - - Y P K E L - - - A D - - - - - - - - - - V L - - - - N F Q D E D G E T A L T M A A R C R S
MBP1_AJECA/374-403   T L P P H Q I - - - S M - - - - - - - - - - L L - - - - S S Q D S N G D T A A L A A A K N G C
MBP1_PARBR/380-409   I L P P H Q I - - - S L - - - - - - - - - - L L - - - - S S Q D S N G D T A A L A A A K N G C
MBP1_NEOFI/363-392   T C S Q D E I - - - D L - - - - - - - - - - L L - - - - S C Q D S N G D T A A L V A A R N G A
MBP1_ASPNI/365-394   T F S P E E V - - - D L - - - - - - - - - - L L - - - - S C Q D S V G D T A V L V A A R N G V
MBP1_UNCRE/377-406   M Y P H H E V - - - G L - - - - - - - - - - L L - - - - A S Q D S N G D T A A L T A A K N G C
MBP1_PENCH/439-468   T C S Q D E I - - - Q M - - - - - - - - - - L L - - - - S C Q D Q N G D T A V L V A A R N G A
MBPA_TRIVE/407-436   V F P R H E I - - - S L - - - - - - - - - - L L - - - - S S Q D A N G D T A A L T A A K N G C
MBP1_PHANO/400-429   T W I P E E V - - - T R - - - - - - - - - - L L - - - - N A Q D Q N G D T A I M I A A R N G A
MBPA_SCLSC/294-313   - - - - - - - - - - - - - - - - - - - - - - - L - - - - D A R D I N G N T A I H I A A K N K A
MBPA_PYRIS/363-392   T W I P E E V - - - T R - - - - - - - - - - L L - - - - N A A D Q N G D T A I M I A A R N G A
MBP1_/361-390   - - - N H S L G V L S Q - - - - - - - - - - F M - - - - D T Q N N E G D T A L H I L A R S G A
MBP1_ASPFL/328-364   T E Q P G E V I T L G R - - - - - - - - - - F I S E I V N L R D D Q G D T A L N L A G R A R S
MBPA_MAGOR/375-404   Q H D P N F V - - - Q Q - - - - - - - - - - L L - - - - D A Q D N D G N T A V H L A A Q R G S
MBP1_CHAGL/361-390   S R S A D E L - - - Q Q - - - - - - - - - - L L - - - - D S Q D N E G N T A V H L A A M R D A
MBP1_PODAN/372-401   V R Q P E E V - - - Q A - - - - - - - - - - L L - - - - D A Q D E E G N T A L H L A A R V N A
MBP1_LACTH/458-487   F S P R Y R I - - - E N - - - - - - - - - - L I - - - - N A Q D Q N G D T A V H L A A Q N G D
MBP1_FILNE/433-460   - - Y P Q E L - - - A D - - - - - - - - - - V I - - - - N F Q D E E G E T A L T I A A R A R S
MBP1_KLULA/477-506   F T P Q Y R I - - - D V - - - - - - - - - - L I - - - - N Q Q D N D G N S P L H Y A A T N K D
MBP1_SCHST/468-501   A K D P D N K - - - K D - - - - - - - - - - L I A K F I N H Q D S D G N T A F H I C S H N L N
MBP1_SACCE/496-525   F S P Q Y R I - - - E L - - - - - - - - - - L L - - - - N T Q D K N G D T A L H I A S K N G D
CD00204/1-19   - - - - - - - - - - - - - - - - - - - - - - - - - - - - N A R D E D G R T P L H L A A S N G H
CD00204/99-118   - - - - - - - - - - - - - - - - - - - - - - - V - - - - N A R D K D G R T P L H L A A K N G H
1SW6/203-232   L D L K W I I - - - A N - - - - - - - - - - M L - - - - N A Q D S N G D T C L N I A A R L G N
SecStruc/203-232   t _ H H H H H - - - H H - - - - - - - - - - _ _ - - - - _ _ _ _ t _ _ _ _ H H H H H H H H _ _
Aligned sequences before editing. The algorithm has placed gaps into the Swi6 helix LKWIIAN and the four-residue gaps before the block of well aligned sequence on the right are poorly supported.


10
|		 20
|		 30
|		 40
|
MBP1_USTMA/341-368   - - Y G D Q L A D - - - - - - - - - - - - - - I L N F Q D D E G E T P L T M A A R A R S
MBP1B_SCHCO/470-498   - R E D G D Y K S - - - - - - - - - - - - - - F L D L Q D E H G D T A L N I A A R V G N
MBP1_ASHGO/465-494   F S P Q Y R I E T - - - - - - - - - - - - - - L I N A Q D C K G S T P L H I A A M N R D
MBP1_CLALU/550-586   G N Q N G N S N D K K E - - - - - - - L I S K F L N H Q D N E G N T A F H I A A Y N M S
MBPA_COPCI/514-542   - H E G G D F R S - - - - - - - - - - - - - - L V D L Q D E H G D T A I N I A A R V G N
MBP1_DEBHA/507-550   I R D S Q E I E N K K L S L S D K K E L I A K F I N H Q D I D G N T A F H I V A Y N L N
MBP1A_SCHCO/388-415   - - Y P K E L A D - - - - - - - - - - - - - - V L N F Q D E D G E T A L T M A A R C R S
MBP1_AJECA/374-403   T L P P H Q I S M - - - - - - - - - - - - - - L L S S Q D S N G D T A A L A A A K N G C
MBP1_PARBR/380-409   I L P P H Q I S L - - - - - - - - - - - - - - L L S S Q D S N G D T A A L A A A K N G C
MBP1_NEOFI/363-392   T C S Q D E I D L - - - - - - - - - - - - - - L L S C Q D S N G D T A A L V A A R N G A
MBP1_ASPNI/365-394   T F S P E E V D L - - - - - - - - - - - - - - L L S C Q D S V G D T A V L V A A R N G V
MBP1_UNCRE/377-406   M Y P H H E V G L - - - - - - - - - - - - - - L L A S Q D S N G D T A A L T A A K N G C
MBP1_PENCH/439-468   T C S Q D E I Q M - - - - - - - - - - - - - - L L S C Q D Q N G D T A V L V A A R N G A
MBPA_TRIVE/407-436   V F P R H E I S L - - - - - - - - - - - - - - L L S S Q D A N G D T A A L T A A K N G C
MBP1_PHANO/400-429   T W I P E E V T R - - - - - - - - - - - - - - L L N A Q D Q N G D T A I M I A A R N G A
MBPA_SCLSC/294-313   - - - - - - - - - - - - - - - - - - - - - - - - L D A R D I N G N T A I H I A A K N K A
MBPA_PYRIS/363-392   T W I P E E V T R - - - - - - - - - - - - - - L L N A A D Q N G D T A I M I A A R N G A
MBP1_/361-390   N H S L G V L S Q - - - - - - - - - - - - - - F M D T Q N N E G D T A L H I L A R S G A
MBP1_ASPFL/328-364   T E Q P G E V I T L G R F I S E - - - - - - - I V N L R D D Q G D T A L N L A G R A R S
MBPA_MAGOR/375-404   Q H D P N F V Q Q - - - - - - - - - - - - - - L L D A Q D N D G N T A V H L A A Q R G S
MBP1_CHAGL/361-390   S R S A D E L Q Q - - - - - - - - - - - - - - L L D S Q D N E G N T A V H L A A M R D A
MBP1_PODAN/372-401   V R Q P E E V Q A - - - - - - - - - - - - - - L L D A Q D E E G N T A L H L A A R V N A
MBP1_LACTH/458-487   F S P R Y R I E N - - - - - - - - - - - - - - L I N A Q D Q N G D T A V H L A A Q N G D
MBP1_FILNE/433-460   - - Y P Q E L A D - - - - - - - - - - - - - - V I N F Q D E E G E T A L T I A A R A R S
MBP1_KLULA/477-506   F T P Q Y R I D V - - - - - - - - - - - - - - L I N Q Q D N D G N S P L H Y A A T N K D
MBP1_SCHST/468-501   A K D P D N K K D - - - - - - - - - - L I A K F I N H Q D S D G N T A F H I C S H N L N
MBP1_SACCE/496-525   F S P Q Y R I E L - - - - - - - - - - - - - - L L N T Q D K N G D T A L H I A S K N G D
CD00204/1-19   - - - - - - - - - - - - - - - - - - - - - - - - - N A R D E D G R T P L H L A A S N G H
CD00204/99-118   - - - - - - - - - - - - - - - - - - - - - - - - V N A R D K D G R T P L H L A A K N G H
1SW6/203-232   L D L K W I I A N - - - - - - - - - - - - - - M L N A Q D S N G D T C L N I A A R L G N
SecStruc/203-232   t _ H H H H H H H - - - - - - - - - - - - - - _ _ _ _ _ _ t _ _ _ _ H H H H H H H H _ _
Aligned sequence after editing. A significant cleanup of the frayed region is possible. Now there is only one insertion event, and it is placed into the loop that connects two helices of the 1SW6 structure.


(2.5) Final analysis


  • Compare the distribution of indels in the ankyrin repeat regions of your alignments. Review whether the indels in this region are concentrated in segments that connect the helices, or if they are more or less evenly distributed along the entire region of similarity. Think about whether the assertion that indels should not be placed in elements of secondary structure has merit in your alignment. Recognize that an indel in an element of secondary structure could be interpreted in a number of different ways:
    • The alignment is correct, the annotation is correct too: the indel is tolerated in that particular case, for example by extending the length of an α-helix or β-strand;
    • The alignment algorithm has made an error, the structural annotation is correct: the indel should be moved a few residues;
    • The alignment is correct, the structural annotation is wrong, this is not a secondary structure element after all;
    • Both the algorithm and the annotation are probably wrong, but we have no data to improve the situation.

(NB: remember that the structural annotations have been made for the yeast protein and might have turned out differently for the other proteins...)

You should be able to analyse discrepancies between annotation and expectation in a structured and systematic way. In particular if you notice indels that have been placed into structurally annotated regions of secondary structure, you should be able to comment on whether the location of the indel has strong support from aligned sequence motifs, or whether the indel could possibly be moved into a different location without much loss in alignment quality.


Analysis (2 marks)
  • Considering the whole alignment and your experience with editing, please note in your assignment your assessment of whether the position of indels relative to structural features of the ankyrin domains in your organism's Mbp1 protein is reliable.
  • CDD extends the ankyrin domain annotation beyond the 1SW6 domain boundaries. Given your assessment of conservation in that region, do you think that this is reasonable in your organisms' protein? Is there evidence for this in the alignment of the CD00204 consensus with well aligned blocks of sequence beyond the positions that match Swi6?


(3) Summary of Resources

 

Links
Lists


Further reading

 

[End of assignment]

 

If you have any questions at all, don't hesitate to mail me at boris.steipe@utoronto.ca or post your question to the Course Mailing List

Retrieved from "http://steipe.biochemistry.utoronto.ca/abc/index.php?title=BIO_Assignment_3_2011&oldid=5690"