BIO Assignment Week 8

Task:

1. Open 1BM8 in Chimera, hide the ribbons and show all atoms as a stick model.
2. Color the protein white.
3. Open the sequence window and select A 42. Color it red. Choose Actions → Set pivot. Then study how nicely the alanine sidechain fits into the cavity formed by its surrounding residues.
4. To emphasize this better, hide the solvent molecules and select only the protein atoms. Display them as a sphere model to better appreciate the packing, i.e. the Van der Waals contacts we discussed in class. Use the Favorites → Side view panel to move the clipping plane and see a section through the protein. Study the packing, in particular, note that the additional methyl groups of a valine or isoleucine would not have enough space in the structure. Then restore the clipping planes so you can see the whole molecule.
5. Lets simplify the view: choose Actions → Atoms/Bonds → backbone only → chain trace. Then select A 42 again in the sequence window and choose Actions → Atoms/Bonds → show.
6. Add the surrounding residues: choose Select → Zone.... In the window, see that the box is checked that selects all atoms at a distance of less then 5Å to the current selection, and check the lower box to select the whole residue of any atom that matches the distance cutoff criterion. Click OK and choose Actions → Atoms/Bonds → show.
7. Select A 42 again: left-click (control click) on any atom of the alanine to select the atom, then up-arrow to select the entire residue. Now let's mutate this residue to isoleucine.
8. Choose Tools → Structure Editing → Rotamers and select ILE as the rotamer type. Click OK, a window will pop up that shows you the possible rotamers for isoleucine together with their database-derived probabilities; you can select them in the window and cycle through them with your arrow keys. But note that the probabilities are very different - and thus show you high-energy and low-energy rotamers to choose from. Therefore, unless you have compelling reasons to do otherwise, try to find the highest-probability rotamer that may fit. This is where your stereo viewing practice becomes important, if not essential. It is really, really hard to do this reasonably in a 2D image! It becomes quite obvious in 3D. Btw: I find such "quantitative" work - where the real distances are important - easier in orthographic than in perspective view (cf. the Camera panel).
9. I find that the first rotamer is actually not such a bad fit. The CD atom comes close to the sidechains of I 25 and L 96. But we can assume that these are somewhat mobile and can accommodate a denser packing, because - as you can easily verify in your Jalview alignment - it is NOT the case that sequences that have I 42, have a smaller residue in position 25 and/or 96. So let's accept the most frequent ILE rotamer by selecting it in the rotamer window and clicking OK (while existing side chain(s): replace is selected).
10. Done.

Task:

1. Retrieve your aligned YFO's Mbp1 RBM APSES domain sequence from the APSES.mfa selection you have prepared for the phylogeny assignment. This YFO sequence is your target sequence.
2. Navigate to the PDB.
3. Click on Advanced to enter the advanced search interface.
4. Open the menu to Choose a Query Type:
5. Find the Sequence features section and choose Sequence (BLAST...)
6. Paste your target sequence into the Sequence field, select not to mask low-complexity regions and Submit Query. Since the E-value is set rather high by default, you will get a number of low-confidence hits as well as the actual homologs, these have very low E-values.

All hits that are homologs are potentially suitable templates, but some are more suitable than others. Consider how the coordinate sets differ and which features would make each more or less suitable for creating a homology model: you should consider ...

• sequence similarity to your target
• size of expected model (= length of alignment)
• presence or absence of ligands
• experimental method and quality of the data set

Sequence similarity is the most important, but we can have the PDB tabulate the other features concisely for this task.

1. There is a menu to create Reports: - select customizable table.
2. Select (at least) the following information items:

Structure Summary

• Experimental Method

Sequence

• Chain Length

Ligands

• Ligand Name

Biological details

• Macromolecule Name

refinement Details

• Resolution
• R Work
• R free

1. click: Create report.

Unfortunately you don't get the E-values into the report, and those should strongly influence your final decision. However in our case the sequences and therefore the E-values of the top three hits are all the same. And there is a new structure from January 2015, with a lower resolution. Some of the sequences have a longer chain-length ... but those are only disordered residues (otherwise these would be better suited templates; regrettably, you'd need to check that in the real world, there is no automatic tool to evaluate disorder and its effects on template choice). In my opinion that leaves pretty much only one unambiguous choice for our template: 1BM8.

Finally

Click on the 1BM8 ID to navigate to the structure page for the template and save the FASTA sequence to your computer. This is the template sequence.

Task:
Choose one of the following options to align your target and template sequence. Make sure your template sequence is included, i.e. the FASTA sequence of 1BM8.

In Jalview...

• Load your APSES domain sequences plus the 1BM8 sequence in Jalview. Include the sequence of your template protein and align using Muscle.
• Delete all sequence you no longer need, i.e. keep only the APSES domains of the target (from your species) and the template (from the PDB) and choose Edit → Remove empty columns. This is your input alignment.
• Choose File→Output to textbox→FASTA to obtain the aligned sequences. They should both have exactly the same length, i.e. N- or C- termini have to be padded by hyphens if the original sequences had different length. Save the sequences in a text-file.

Using a different MSA program

• Copy the FASTA formatted sequences of the Mbp1 proteins in the reference species from the Reference APSES domain page.
• Access the MSA tools page at the EBI.
• Paste the Mbp1 sequence set, your target sequence and the template sequence into the input form.
• Run an alignment (I like T-coffee) and save the output.

Using the R bioconductor MSA package that you used previously.

Refer back to the page if you are lacking notes how to go about this.

Task:

• Paste the aligned sequences of the YFO target and the 1BM8 template into the form field. SwissModel will analyse the sequences and ask you to identify target and template. The YFO sequence is your target. The 1BM8 sequence is the template.

• Click Validate Target Template Alignment and check that the returned alignment is correct. All non-identical residues are shown in light-grey.

• Click Build Model to start the modeling process. This will take about a minute or so.

• The resulting page returns information about the resulting model and its quality. You can rotate the model in the window on the right with the mouse. Regions that have a reddish hue have lower quality scores, i.e. they were harder to model or could not be modelled well with good geometry. Hovering the mouse over parts of the structure highlights the respective region of the sequence alignment.

• Mouse over the Model 01 dropdown menu (under the icon of the template structure), and choose the PDB file. Note that the B-factor column of the coordinate section contains the QMEAN scores (between 0 and 1) that the server has calculated. Higher is better. Save the PDB file on your computer.

• Open the SwissModel documentation in a new tab. Read about the modelling process. there are a number of important technical details that help to understand what the computed coordinates of your model mean, you should pay special attention to the GQME and QMEAN quality scores.

• Also save:

• • The output page as pdf (for reference)
  • The modeling report (as pdf)

Task:
Open your model coordinates in a text-editor (make sure you view the PDB file in a fixed-width font (like "courier") so all the columns line up correctly) and consider the following questions:

• What is the residue number of the first residue in the model? What should it be, based on the alignment? If the putative DNA binding region was reported to be residues 50-74 in the Mbp1 protein, which residues of your model correspond to that region?

That's not easy to tell. But it should be.

Task:

1. Navigate to the bio3D home page to . bio3d has recently been made available via CRAN - previously it had to be compiled from source.

1. Explore and execute the following R script. I am assuming that your model is in your PROJECTDIR folder, change paths and filenames as required.

setwd(PROJECTDIR)
PDB_INFILE      <- "YFOmodel.pdb"
PDB_OUTFILE     <- "YFOmodelRenumbered.pdb"


# The bio3d package provides functions for working with 
# protein structures in R 
if (!require(bio3d, quietly=TRUE)) { 
	install.packages("bio3d")
	library(bio3d)
}

# == Read the YFO pdb file

iFirst <- 4  # residue number for the first residue
 
YFOmodel <- read.pdb(PDB_INFILE) # read the PDB file into a list

YFOmodel           # examine the information
YFOmodel$atom[1,]  # get information for the first atom

# Explore ?read.pdb and study the examples.

# == Modify residue numbers for each atom
resNum <- as.numeric(YFOmodel $atom[,"resno"])
resNum  
resNum <- resNum - resNum[1] + iFirst  # add offset
YFOmodel $atom[ , "resno"] <- resNum   # replace old numbers with new

# check result
YFOmodel $atom[ , "resno"]
YFOmodel $atom[1, ]

# == Write output to file
write.pdb(pdb = YFOmodel, file=PDBout)

# Done. Open the PDB file you have written in a text editor
# and confirm that this has worked.

Task:

1. Start Chimera and load the model coordinates that you have just renumbered.
2. From the PDB, also load the template structure. (Use File → Fetch by ID ...)
3. In the Favourites → Model Panel window you can switch between the two molecules.
4. Hide the ribbon and choose backbone only → full. You will note that the backbone of the two structures is virtually identical.
5. Next, choose Actions → Atoms/Bonds → show to display display the two molecules in a stick style and note how the sidechains have been modeled. Note especially how sidechain coordinates have been guessed, where the template had shorter sidechains than the target. It may be more clear if you hide H-atoms: Select → Chemistry → Element → H and Actions → Atoms/Bonds → hide
6. Display only residue 50 to 74 to focus on the putative helix-turn-helix domain. You can drag your mouse in the Favourites → Sequence, window to select the range then Select → Invert (selected model) and Actions → Atoms/Bonds → hide. Or you can use Chimera's commandline: ~display to undisplay everything, show #:50-74 to show this residue range for all models.
7. Study the result: a model of the HTH subdomain of YFO's RBM to Mbp1.

Task:

1. Back in Chimera, use the model panel to close the 1BM8 structure. Select all and show Atoms, bonds to view the entire model structure.
2. Choose Tools → Depiction → Render by attribute and select attributes of atoms, Attribute: bfactor, check color atoms and click OK.
3. Study the result: It seems that residues in the core of the protein have better energies (higher values) than residues at the surface. Why could that be the case?

Task:

The PCG2 / DNA complex

• Open Chimera and load the 4UX5 structure. Spend some time exploring it. There are two domains of identical sequence bound to one DNA molecule. The first question I would have is whether the two molecules bind to the same DNA motif - the CGCG core of the "MCB-box", and whether the observed protein:DNA interfaces are actually with the cognate sequence, or whether one (or both) proteins are non-specific complexes. The conditions under which proteins crystallize can be harsh, and physiological function under these conditions is not guaranteed.^[3] Indeed, Liu et al. (2015) report that at low concentrations a 1:1 complex is formed and the 2:1 Protein:DNA complex only forms at high concentrations. Figure 3. of their paper shows that the detailed contacts between protein and DNA are in fact not identical.

• Without taking this question too far, let's get a quick view of the comparison by duplicating one domain of the structure and superimposing it on the other. The authors feel that chain A represents the tighter, more specific mode of interaction; so we will duplicate chain B and superpose the copy on A.

• In Chimera, open the Favorites → Model Panel and use the copy/combine button to create a copy of the 4UX5 model. Call it test.
• Select chain B of the test model, then use Select → Invert (selected models) to apply the selection to everything in the test model except chain B.
• Use Actions → Atoms/Bonds → delete to remove everything but Chain B.
• Select and colour the chain red.
• Back on the Model Panel, select both models and use the match... dialogue to open a MatchMaker dialogue window. Choose the radio button two match two specific chains and select 4UX5 chain A as the Reference chain, test chain B as the Chain to match. Click Apply.

You will see that the superimposed structures are very similar, that the main difference is in the orientation of the disordered C-terminus, but also that there is a structural difference between the two structures around Gly 84 which inserts into the minor groove of the double helix.

• Select one of the residues of that loop in chain A by <control>-clicking on it and use Action → Set pivot to set the centre of rotation to that residue: this makes it easier to visualize the binding situation when you make the molecules larger.

• Select residues 81 to 87 and the corresponding (sequence VQGGYGKY) and in both chains turn their ribbon display off and display this range as "sticks".
• Select nucleic acid in the structure submenu and turn ribbons and nucleotide objects off to display the DNA as sticks as well. Colour the DNA by element.
• Study the situation. Focus on Gly 84.A, especially the interaction of its carbonyl oxygen, which hydrogen bonds to the N2 atom of G8.D chain. Gln 89.A hydrogen bonds to the N2 atom of G8.C chain. Gly 84 and Gln 82 thus recognize a G:C C:G pair. In the B chain, Gly 84.B does not contact the DNA well, since it contacts residues of chain A, especially Gln 82.A. The carbonyl atom of Gly 84.B hydrogen bonds to Gln 89.B. and therefore Gln89.B is not available to contact nucleotide bases. What do you think^[4]? It seems to me that a crucial interaction for the cognate sequence is contributed by Guanine 8,
• Finally, use the Model Panel to select test and close it.

Task:

• Start by loading your model and the 1BM8 structure into your chimera session. Select all, turn all ribbons off, and set all atoms to stick representation. Then select H atoms by element and hide them.

• We need to visualize and evaluate differences in binding between different proteins and for me it works well to colour everything by element, and give the carbon atoms some identifying, distinct colour. This is best achieved through the Chimera command line that you can turn on with the little "computer" icon on the left-hand side of the graphics window. Have a look at the Chimera Users guide, and choose select to learn how Chimera's selection syntax works.
• Open the Model Panel to check which protein has which Chimera-internal model number. Then you can use the following selection syntax. Instead of the model numbers, I will type <YFO>, <4ux5>, and <1BM8> - you will certainly know by now that these are placeholder labels and you need to replace them with the numbers 0, 1, and 2 instead.

• To colour the DNA carbon atoms white, type:
  

color white #<4ux5>:.C,.D & C

• To colour the 4ux5 A chain carbon atoms grey, type:
  

color #878795 #<4ux5>:.A & C Note: the color values after the first hash are rgb triplets in the hexadecimal numbering systems - exactly like in R.

• To undisplay the 4ux5 B chain, type:
  

~display #<4ux5>:.B Note: this is the tilde character, not a hyphen or minus sign.

• To colour the YFO model carbon atoms a pale reddish color, type:
  

color #b06268 #<YFO> & C

• To colour the 1BM8 structure carbon atoms a pale greenish color, type:
  

color #92b098 #<1BM8> & C

• Ready? Let's superimpose the chains.
  • Select all models in the Model Panel and click on match.
  • Set 4ux5 Chain A as the Reference chain.
  • Select YFO as a Chain to match, select the button for specific reference and specific match, and click Apply.
  • Repeat this with 1BM8 as the match chain.

• Easy. Now enlarge the binding site. Remember that 4ux5 and 1bm8 are independently determined crystal structures, wheres YFO was modelled on 1bm8 and is expected to be very similar to it. To give you some guidance what you should focus on, select 4ux5 residue 84 CA atom and display it as Ball & Stick. You can also repeat the Action "Set Pivot in case the pivot has shifted.

• Study the scene. This is where stereo- vision will help a lot.

• What do you think? Is this what you expected? Can you explain what you see? Was the modelling process succesful?

• Now turn the display of 4ux5 chain B back on and turn chain A off instead. Then superimpose the 1BM8 template and your model on Chain B.

• Again, focus on the binding region. What do you think of that? What would you have expected? Do you see a difference? What does this all mean?