BIOL200 2013: Difference between revisions

1. Examine Table I, select representative species from Bergey’s Manual. Select 2 prokaryotic species from each group, giving 14 prokaryotic species total. Also select the Eukaryotic representative, Saccharomyces cerevisiae.
2. Access the NCBI website: http://www.ncbi.nlm.nih.gov/
3. Under the “Search” category, select “Nucleotide”
4. Under the “for” category, type the accession number for your first organism, and hit the “Go” button. This takes you to the access for the 16S rRNA for your organism.
5. Download the 16S rRNA sequence for your first organisms by choosing “FASTA” under the “Display” category.
6. Copy and paste the entire output into a Microsoft Word file.
7. Edit the sequence id to match the format of “Genus_Species_Genbank#” (eg. > Escherichia_coli_174375).
8. Repeat process for all of your organisms, pasting the sequences into the same Microsoft Word file. (note: be sure to place a blank line between each sequence entry)
9. Access the EMBL CLUSTALW alignment website: http://www.ebi.ac.uk/Tools/clustalw/, and copy and paste your entire Microsoft Word file into the area which asks you to “Enter or paste a set of sequences in any supported format”. Click “Run”. This program will make an alignment of all of your sequences.
10. Click “Show as Phylogram Tree” to create a tree showing the relatedness of your organisms based on their 16S rRNA sequences.
11. To print your phylogram tree..
    • a. hit the “Print Screen” button on your keyboard
    • b. open the Paint program from your “accessories” menu on your computer
    • c. hit paste to paste your screen
    • d. “select” your phylogram tree
    • e. copy and paste it into a new paint file
    • f. print your tree and email it to yourself

The branches define the order of descent and the ancestry of the nodes. The branch length represents the number of changes that have occurred along that branch. Thus, the more recently two organisms share a common ancestor, the more closely related they are. Trees can be either “unrooted” or “rooted”. Unrooted trees show the relationships among the microorganisms under study, but not the evolutionary path leading from an ancestor to a strain.

1. Answer the following questions based on a Tree of Life shown in Figure 1.
   • a. What do internal and terminal nodes represent?
   • b. What do branch lengths represent? What’s the unit and meaning of the scale bar?
   • c. Identify the positions of Humans (Homo), corn (Zea), E.coli, and Bacillus on the tree. Use the scale bar to estimate which pair is evolutionarily more distant: human/corn or E.coli/Bacillus?
2. In Figure 2, which two species are more closely related: 1 and 2, 2 and 3, or 1 and 4? Which are more distantly related? How did you determine this?
3. In Figure 2, is 1 more, less, or equally related to 4 and 5? Explain your rationale.
4. List and describe the key steps of constructing a phylogenetic tree.
5. Why do we use 18S rRNA information for yeast and 16S for prokaryotes? Could we use other molecules as phylogenetic markers? What constitutes a “good” phylogenetic marker for building a tree of life?
6. Bonus Question
   • Define 16S “phylo-species” and “metagenomics”. Describe how PCR amplification and sequencing of 16S rRNA molecules from environmental microbial samples (e.g., sea water, soil, human gut, hot springs) can be used to define species composition of an environment.

1. Jungck, J. R.; Fass, M.F.; Stanley, E. D. (ed.). 2003 (2006 Revision). Microbes Count! Problem Posing, Problem Solving, and Peer Persuasion in Microbiology. BioQUEST Curriculum Consortium. (Chapter 6, pg 191)
2. Holt. J. G. Editor-in-Chief (1984). Bergey’s Manual of Systematic Bacteriology, Volume 1-4. Williams & Wilkins: Baltimore. http://www.cme.msu.edu/bergeys/pubinfo.html