BIO Assignment 2 2011

 
 

   

   

   

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 important aspects have simply been overlooked and marks are unnecessarily lost. Sadly, we always get assignments back in which important aspects have simply been overlooked and marks are unnecessarily lost. If you did not notice that the above sentence was repeated, you are not reading carefully enough.

Review the guidelines for preparation and submission of BCH441 assignments.

   

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

   

Baker's yeast, Saccharomyces cerevisiae, is perhaps the most important model organism. It is a eukaryote that has been studied genetically and biochemically in great detail for many decades, and it is easily manipulated with high-throughput experimental methods. We will use information from this model organism to study the conservation of function and sequence in other fungi whose genomes have been completely sequenced; the assignments are an exercise in model-organism reasoning: the transfer of knowledge from one, well-studied organism to others.

This and the following assignments will revolve around a transcription factor that plays an important role in the regulation of the cell cycle: Mbp1 is a key component of the MBF complex (Mbp1/Swi6). This complex regulates gene expression at the crucial G1/S-phase transition of the mitotic cell cycle and has been shown to bind to the regulatory regions of more than a hundred target genes.

One would speculate that such central control machinery would be conserved in other fungi and it will be your task in these assignments to collect evidence whether related molecular machinery is present in some of the newly sequenced fungal genomes. Throughout the assignments we will use freely available tools to conduct bioinformatics investigations of questions such as:

• What functional features can we detect in Mbp1?
• Do homologous proteins exist in other organisms?
• Do we believe these homologues may bind to similar sequence motifs?
• Do we believe they may function in a similar way?
• Do other organisms appear to have related cell-cycle control systems?

 

(If you would like to brush up on the concepts mentioned above, you could study the corresponding chapter in Lodish's Molecular Cell Biology and./or read Nobel laureate Paul Nurse's review (pdf) of the key concepts of the eukaryotic cycle. It is not strictly necessary to understand the details of the yeast cell-cycle to complete the assignments, but recommended, since it's obviously more fun to work with concepts that actually make some sense.)

In this particular assignment you will go on a search and retrieve mission for information on yeast Mbp1, using common public databases and Web resources.

Much useful information on yeast Mbp1 is compiled at the SGD information page on Mbp1. However we don't always have the luxury of such precompiled information. Let's look at the protein and it's features "the traditional way".

There are several sources for functional domain annotations of proteins. The NCBI has the Conserved Domain Database, in Europe, the SMART database provides such annotations. In terms of domains, both resources are very comparable. But SMART also analyses more general features such as low-complexity sequences and coiled coils. In order to use SMART however, we need the Uniprot accession number that corresponds to the refseq identifier. In a rational world, one would wish that such important crossreferences would simply be provided by the NCBI ... well, we have been wishing this for many years now. Fortunately ID-mapping services exist.

Now navigate to Uniprot, enter the ID you have found into the search field and select [Sequence Clusters(UniRef)] as the database to search in. There should be two sequences in the [UniRef100 ... (100% identical)] cluster. Compare them. One of them is a highly annotated Swiss-Prot record, the other is practically unannotated data that has been imported from a "third party" to UniProt. Unfortunately, that one is the sequence that the ID mapping service had found. No cross-references to the NCBI are included with Swiss-Prot records, nor do NCBI RefSeq records cross-reference NCBI holding. I consider this a sorry state of affairs. Therefore most of us actually run BLAST searches to find equivalent sequences in other databases and this is the most wasteful way imaginable to address the problem.

   

Now we can analyse Mbp1's domain in SMART, and use this information to annotate the sequence in detail.

As you see from the annotations, Mbp1 is a large protein comprising several domains; it binds DNA through a small domain called the APSES domain (this is reported as the KilA-N domain superfamily). Many organisms have transcription factors that have a domains homologous to other APSES domains. Since we are interested in related proteins, and all functional relatives would be expected to share such a DNA binding domain, we should define this domain in more detail in order to be able to use it later to search for homologous proteins in diverse organisms.  

Use the NCBI Entrez system to search for the string "apses" in the "Conserved Domains" database and access the entry for the KilA-N domain superfamily. You should find 10 aligned sequences on that page, each with their own GI identifier. To find the actual boundaries of the domain annotation, do the following:

We can expect that the structures of all homologous APSES domains should be similar, i.e. if the structure of one is known, we should be able to conclude the approximate three-dimensional structure of any APSES domain. Indeed, structural information is available for APSES domains!

There are several possible approaches you could pursue to identify candidate files:

• there may be cross references to structures/PDB on any of the pages you have visited;
• you could search the PDB itself for the keyword Mbp1;
• you could use the domain sequence you have defined and ;
  • BLAST it against the database of PDB sequences (select it as an option on the BLAST form);
  • perform an "advanced serach" for similar sequences on the PDB Website.

In any case, you should find more than one coordinate files that contain MBP1-like structures. Therefore you need to make a choice which one is the "best" for further analysis. Your choice of the "best" file for study could be based on:

• experimental method (X-ray or NMR);
• quality of the structure (resolution, refinement);
• size (coverage) of the structure (number of amino acids for which structure coordinates have been determined).

 

 

The Mbp1 APSES domain has been shown to bind to DNA and the residues involved in DNA binding have been characterized. (Taylor et al. (2000) Biochemistry 39: 3943-3954 and Deleeuw et al. (2008) Biochemistry. 47:6378-6385) . In particular the residues between 50-74 have been proposed to comprise the DNA recognition domain.

DNA binding interfaces are expected to comprise a number of positively charged amino acids, that might form salt-bridges with the phosphate backbone.

Be specific in your analysis: write exactly which residue does what. For example don't write

there are many lysines...

but write something like

K33, R35 and K76 form a patch of positively charged residues close to the C-terminus of the putative recognition helix.

This is the interpretation of results and therefore the most important step of your entire analysis.

Time for a break:

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