Biol375 2015: Difference between revisions

1. What are the two hypotheses explaining the origin of different ecomorphs of lizards on Caribbean Islands?
2. What is the expected phylogeny under each hypothesis?
3. Which hypothesis is supported by the phylogeny of actual DNA sequences?

1. Install R & R-studio (see "Links for phylogenetic tools" above)
2. Open R-studio and install the "ape" package using the "Packages"->"Install" menu, located within the lower right window
3. Type in the console window (lower left) the following commands (one at a time, wait for the prompt ">" to appear before proceed to the next command; quit & restart R-studio if stuck):
   1. library(ape)
   2. tr = read.tree(text = "(monkey:0.09672,((tarsier:0.18996,lemur:0.14790)0.999:0.09005,(macaque:0.18524,(gibbon:0.10388,(orang-utan:0.09481,(human:0.03391,(gorilla:0.06135,chimpanzee:0.05141):0.01580)0.316:0.05381)1.000:0.03019)0.978:0.05616)0.997:0.05042)0.965:0.09672);")
   3. plot(tr)
4. Export the tree graph using the "Export->Save as PDF or Save as Image" menu in the lower right window
5. Exit R studio by typing the command "q()" and type "y" to answer the question for saving the R session
6. Copy & paste the tree image into your document to be handed in

1. Download this file & save it in a file folder you could find (e.g., /Users/john/Documents/ for Apple, and C:/Users/john/Documents/ for Windows):
   File:Mt primate.txt
   . This is an alignment of mitochondrial DNA sequences from primate species, Do not attempt to open or modify it, which may render it un-readable by R. If this happens, delete & re-download.
2. Open R-studio and install the "phangorn" package (see Assignment 2 for how to install packages)
3. Run the following commands:
   1. getwd() (this is to show your working directory, from which R-studio could read file)
   2. setwd("/Users/john/Documents") (to set the working directory to where you saved your mt_primate.txt file)
   3. library(ape) (this is to load the ape library)
   4. mt = read.FASTA("mt_primate.txt") (to read the alignment and save it in an object called "mt")
   5. mt (to show result, copy & paste into your report)
   6. dist.mt = dist.dna(mt) (to obtain a pair-wise distance matrix)
   7. dist.raw = dist.dna(mt, model = "raw") (to obtain raw, un-corrected pair-wise sequence differences, in fractions)
   8. dist.raw * 888 (888 is the length of aligned DNA bases, to show raw counts of base differences; copy & paste into your report)
   9. tr.mt = bionj(dist.mt) ( to create a tree based on the pairwise distance matrix)
   10. plot(tr.mt) (to show tree; Export and save tree image)
   11. library(phangorn)
   12. tr.mid = midpoint(tr.mt) (this creates a midpoint-rooted tree)
   13. plot(tr.mid) (Export and save tree image)
   14. q() (to quit and save your R session, to your working directory)
4. Answer the questions:
   1. Summarize, with your own complete sentences, the key steps you have taken to obtain a tree from sequences.
   2. Define "monophyly"
   3. Illustrating with your tree (by labeling ancestral nodes and groups of species), explain why "ape" excluding "human" does not constitute a monophyletic group.

1. Show the "rectangular phylogram" format (2nd tree option). Show species names (aligned, use the button "align/unalign leaf node labels"), scale bar and bootstrap values.
2. Mouse over the branch "Leiocephalus_barahonensis" and click "reroot here"
3. Make a printout of the tree & then hand-draw a tree without un-supported (support value < 0.8) branches (i.e., making polytomies).

1. Match the character matrix from Assignment 3 and tree from Assignment 4 (you may use the tree on the right). Hand-draw a diagram with tree on the left and matrix on the right (use 1-letter code for character states & include a legend of your codes).
2. Reconstruct ancestral locations and habitat of Caribbean lizards. Pick an arbitrary ancestral states if the ancestral state cannot be resolved.
3. Based on your reconstructed trait evolution, count the number of character-state changes and calculate consistency index for each trait.
4. Use the difference between the two consistency indices to explain why the molecular phylogeny supports convergent evolution in habitat.
5. Bonus (+5): Use the EvolView ColorStrip feature to automatically generate the combined diagram with tree and character-state matrix. Notes: (1) you can't have species names with spaces. e.g. "Anolis sagrei" needs to be written has "Anolis_sagrei"; (2) you don't need to remove unsupported branches; (3) the outgroup species ("Leiocephalus barahonensis") has unknown character states. Assign "gray" colors to both characters.

• What is the molecular function of CYCS?
• Describe its chromosomal location and gene structure (number of introns and exons, length of protein)
• Click the link "HomoloGene" and then in the section "Pairwise alignments generated using BLAST", run BLAST between Human and Mouse protein sequences. Show BLAST report.
• Pick another species and generate a BLAST alignment between the Human and this species. Show BLAST report.

1. Go to the the phylogeny.fr website and select "Phylogenetic Analysis" and then "One Click" analysis
2. Copy and paste these VP30 sequences into the text box and click on "Submit"
3. When analysis is finished, you should see a phylogenetic tree. Re-root the tree using three strains isolated on 1976 or 1977 as outgroup. Save and print the tree. Answer the following questions with explanation.
   1. Name the alignment program and the phylogenetic methods (Distance, parsimony, likelihood, or other method?) used to produce your tree
   2. Are isolates collected from different years all monophylogenetic, all paraphyletic, or some monophyletic and some paraphyletic?
   3. Are outbreaks in different years independent from each other, or one outbreak leads to another?
   4. What would you conclude based on your tree regarding the reservoir source of the ebolavirus: Are Ebolaviruses more likely to have a human or non-human reservoir?

1. Calculate Jukes-Cantor distance between the two sequences (specify unit)
2. Identify the number of transitions and transversions
3. Identify the number of synonymous and nonysynonymous substitutions
4. Assuming that the total number of synonymous sites S=174 and the total number of nonsynonymous sites N=690, calculate d_s and d_n (with Jukes-Cantor correction)

The left figure shows a codon alignment of 38 strains of a bacterium, with an outgroup sequence (which starts with a string of SNPs: "....g...c..ca..", etc), answer the following questions (with the outgroup sequence excluded.) Do not print the figure directly. Hand-copy the sequences to a graph sheet, include only sequences at the two variable codon positions:

1. There are two SNP sites. For each SNP, determine whether it is a synonymous or nonsynonymous change (could be both if more than 2 states). You may simply list the codons and their corresponding amino acids, at each aligned codon site.
2. Calculate allele frequencies at each SNP site (for 3 SNP states, calculate frequencies of all three separately)
3. List all haplotypes using the 2 SNP sites
4. Calculate frequencies of all haplotypes
5. Using the outgroup sequence, determine the ancestral and derived SNP, codon, and amino-acid states at each codon site. Without the outgroup sequence, could derived and ancestral states be determined (e.g., by majority)? Explain with a tree including the outgroup sequence.
6. (Bonus: +2) For sites that are fixed differences between the outgroup sequences and others (e.g., the 5th nucleotide site), could one determine which is the ancestral and which is the derived state? Explain with a tree.