Class16 --2016

Assignment for Friday:

Read through sequence alignment section below
If interested, read through the details of the Needleman Wunsch alignment here.
If you want to work on this at home or from another computer, install the latest version of seaview. Send email in case you encounter problems. Clustalx is available here (download x not w), SEAVIEW is available here
Takehome exam 5 will be due next Monday (last chance to ask questions)

Assignments for Monday

Read through the wikipedia entries fro UPGMA and Neighbor Joining

Read Walter Fitch's article on types of homology (available on HuskyCT or here)

Assignment for today: Read excerpts of Chapters 5 and 6 from Li's "Molecular Evolution"

See here for the splice site consensus in Arabidopsis

Discuss non-sense mediated decay pathway (wikipedia, review article)

Discussion - two debate teams on the function of introns in evolution:
Team A) Introns Early versus Team B) Introns Late

1) discuss arguments within group (5 minutes)
2) present arguments in favor of your thesis (each site, one person one argument)
3) discuss counter arguments within group (3 minutes)
4) present arguments against opposing teams evidence

Goals class 16:

Understand the term "tree topology", and know that brancklengths provide important information.
Be able to recognize indentical trees and trees with the same topology.

The following 2 are moved to class 17

Know about distance matrix, parsimony, maximum likelihood and Bayesian approaches to phylogenetic reconstruction.
Know what bootstrapping is and what it is used for.

PRO INTRONS EARLY:

Self splicing RNA are an example for catalytic RNA that could have been present in RNA world.
There is little reason to assume that the RNA world was not plagued by self-splicing parasites
Neighboring Introns are more frequently in same phase than expected by chance
Spliceosomal introns are present in deep branching eukaryotes
Introns frequently are found in linker regions
Exon shuffling can create a large number of different catalytic sites (see the maturation of the immune system)

PRO INTRONS LATE :

Mapping individual introns onto organismal evolutionary history shows that many introns inserted into the sites where they are found presently more recently.
Exon shuffling in the maturation of the adaptive immune system is a modern trait of vertebrates.
Even if introns are ancient, this does not prove that they played a role in assembling the now existing protein families.
Intron preference for linker region could be the result of selection (they do less harm here than in tightly packed domains).

Discuss trees:

Leaves, branch, split, OTUs, root, clades. Under which operations does the tree remain the "same" tree? (see here)

From:<http://dml.cmnh.org/2002Jul/msg00351.html>

----- Original Message -----
From: <Dinogeorge@aol.com>
Sent: Thursday, July 11, 2002 6:47 PM
Subject: Re: New finds

> > --+--+-----------A
> >   | `--+--+-----B
> >   |     | `--+--C
> >   |     |     `--D
> >   |     `--------E
> >    `--------------F
>
> This is >not< a Hennigian comb. Only the entire ABCDE clade and the F
lineage
> make a (two-toothed) Hennigian comb in this cladogram. In a Hennigian comb
> the side branches are left unbranched, like the teeth of a comb. Hence the
> name.

This _is_ a Hennigian comb, because in a cladogram, _only_ topology counts.
A cladogram is a mobile. Look at the following -- it's exactly the same
cladogram as above:

--+--F
  `--+--A
     `--+--E
        `--+--B
           `--+--D
              `--C

... what a side branch is lies completely in the hand of the presentator.
All I did was I rotated a few stems around their long axes.

Intro to phylogenetic reconstruction

Phylogenetic analysis is an inference of evolutionary relationships between organisms.
Those relationships are usually represented by tree-like diagrams.
Note: the assumption of exclusively tree-likeliness of evolution is not justified.

Steps of the phylogenetic analysis:

Compilation of sequence dataset

Alignment

Determination of substitution model

Tree building

Tree evaluation

Why phylogenetic reconstruction of molecular evolution?

A) Systematic classification of organisms

e.g.: Who were the first angiosperms? (i.e. where are the first angiosperms located relative
to present day angiosperms?)

Where in the tree of life is the last common ancestor located?

B) Evolution of molecules

e.g.: domain shuffling, reassignment of function, gene duplications, horizontal gene transfer, drug targets, detection of genes that drive evolution of a species/population (e.g. influenca virus, see here for more examples)

C) Identification of organisms

e.g., phylotyping in microbiom samples),
origin of genes and viruses (e.g. recent ebola out break)

How:

1) Obtain sequences

Sequencing

Databank Searches -> ncbi a) entrez, b) BLAST, c) blast of pre-release data

Friends

2) Determine homology (see notes for earlier classes for practical implementation)

Reminder on Definitions:
Homology: Two sequences are homologous, if there existed an ancestral molecule in the past that is ancestral to both of the sequences

3) Align sequences

(most algorithms used for phylogenetic reconstruction require a global alignment. An exception is statalign
from Thorne JL, and Kishino H, 1992, Freeing phylogenies from artifacts of alignment. Mol Bio Evol 9:1148-1162)

Some evolutionary biologists recommend to select only the part of the alignment that is reliable. (Discuss!) Modify alignment, if necessary.

4) Reconstruct evolutionary history

A) Distance analyses

calculate pairwise distances
(different distance measures, correction for multiple hits, correction for codon bias)
make distance matrix (table of pairwise corrected distances)
calculate tree from distance matrix

i) using optimality criterion
(e.g.: smallest error between distance matrix
and distances in tree), or use
ii) algorithmic approaches (UPGMA or neighbor joining)

B) Parsimony analyses

find that tree that explains sequence data with minimum number of substitutions

(tree includes hypothesis of sequence at each of the nodes)

C) Maximum Likelihood analyses

given a model for sequence evolution, find the tree that has the highest probability under this model.

This approach can also be used to successively refine the model.

Bayesian statistics use ML analyses to calculate posterior probabilities for trees, clades and evolutionary parameters. Especially MCMC approaches have become very popular in the last year, because they allow to estimate evolutionary parameters (e.g., which site in a virus protein is under positive selection), without assuming that one actually knows the "true" phylogeny.

D - ...) Else:
spectral analyses, evolutionary parsimony, i.e., look only at patterns of substitutions, supertrees from many gene trees.

Another way to categorize methods of phylogenetic reconstruction is to ask if they are using

an optimality criterion (e.g.: smallest error between distance matrix and distances in tree, least number of steps), or

algorithmic approaches (UPGMA or neighbor joining)

5) Interpret the result.

It is especially important to consider artifacts that might originate in phylogenetic reconstruction, and to asses the reliability of your results.

6) Discussion: How can a tree be rooted?

Slides