22115 - Computational Molecular Evolution: Difference between revisions
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:* [ | :* [https://teaching.healthtech.dtu.dk/material/22115/Consensus.pdf Handout exercise: Consensus Trees] | ||
:* [ | :* [https://teaching.healthtech.dtu.dk/material/22115/Distance_handout.pdf Handout exercise: Distance Matrix Methods] | ||
:* [ | :* [https://teaching.healthtech.dtu.dk/material/22115/Slides_week3.pdf Slides, week 3] | ||
:; Computer exercises | :; Computer exercises | ||
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===Week 4+5 (February 21 + 28): Mini project 1=== | ===Week 4+5 (February 21 + 28): Mini project 1=== | ||
< | <-- | ||
Project description: [ | Project description: [https://teaching.healthtech.dtu.dk/material/22115/Miniproject1_whales.pdf Building a tree from scratch: What are the closest relatives of whales?] | ||
The mini project should be submitted and assessed via a peer assessment module that will become available on the course DTU Learn page. | The mini project should be submitted and assessed via a peer assessment module that will become available on the course DTU Learn page. | ||
Take this tree quiz to test yourself on your ability to accurately interpret evolutionary trees: | Take this tree quiz to test yourself on your ability to accurately interpret evolutionary trees: | ||
* [ | * [https://teaching.healthtech.dtu.dk/material/22115/Treequiz1.pdf Tree quiz] | ||
Check your replies here: | Check your replies here: | ||
* [ | * [https://teaching.healthtech.dtu.dk/material/22115/Treequiz1_answers.pdf Tree quiz with answers] | ||
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:; Course material | :; Course material | ||
:* [ | :* [https://teaching.healthtech.dtu.dk/material/22115/Handout_real_exp_change.pdf|Handout exercise: Real, Observed, and Expected Change] | ||
:* [ | :* [https://teaching.healthtech.dtu.dk/material/22115/Handout_likelihood.pdf Handout exercise: Computation of Likelihood] | ||
:* [ | :* [https://teaching.healthtech.dtu.dk/material/22115/Slides_week4.pdf Slides, week 6] | ||
:* [https://teaching.healthtech.dtu.dk/material/22115/substitutionmodels.pdf Lecture notes: Substitution models] | :* [https://teaching.healthtech.dtu.dk/material/22115/substitutionmodels.pdf Lecture notes: Substitution models] | ||
:* [https://teaching.healthtech.dtu.dk/material/22115/main.pdf Optional lecture notes: Matrix exponentials for Markov chains] | :* [https://teaching.healthtech.dtu.dk/material/22115/main.pdf Optional lecture notes: Matrix exponentials for Markov chains] | ||
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:; Course material | :; Course material | ||
:* [ | :* [https://teaching.healthtech.dtu.dk/material/22115/Handout.class08.pdf Handout exercise: Bayesian estimation of model parameter value] | ||
:* [ | :* [https://teaching.healthtech.dtu.dk/material/22115/Slides_week5.pdf Slides, week 7] | ||
:* [ | :* [https://teaching.healthtech.dtu.dk/material/22115/MTN122.pdf| An Introduction to Bayesian Statistics Without Using Equations] | ||
:* [http://www.nature.com/nbt/journal/v22/n9/pdf/nbt0904-1177.pdf Background reading: "What is Bayesian statistics?"] | :* [http://www.nature.com/nbt/journal/v22/n9/pdf/nbt0904-1177.pdf Background reading: "What is Bayesian statistics?"] | ||
:* [http://rsta.royalsocietypublishing.org/content/roypta/361/1813/2681.full.pdf Background reading: "Bayesian computation: a statistical revolution"] | :* [http://rsta.royalsocietypublishing.org/content/roypta/361/1813/2681.full.pdf Background reading: "Bayesian computation: a statistical revolution"] | ||
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:; Course material | :; Course material | ||
:* [ | :* [https://teaching.healthtech.dtu.dk/material/22115/Slides_week6.pdf Slides, week 10] | ||
:* [https://github.com/ddarriba/jmodeltest2/files/157130/manual.pdf jmodeltest manual] | :* [https://github.com/ddarriba/jmodeltest2/files/157130/manual.pdf jmodeltest manual] | ||
Revision as of 15:00, 19 March 2024
- Overview
- This page contains links to video lectures, computer exercises, and other material for the course 22115 - Computational Molecular Evolution, which is part of the MSc in Bioinformatics and Systems Biology at the Technical University of Denmark. The course is taught by Professor Anders Gorm Pedersen, Section for Bioinformatics, Department of Health Technology.
- The main goal of this course is to give an introduction to theory and algorithms in the field of computational molecular evolution. We will cover basic evolutionary theory (common descent, natural selection, genetic drift, models of growth and selection), and the main types of algorithms used for constructing and analyzing phylogenetic trees (parsimony, distance based methods, maximum likelihood methods, and Bayesian inference). We will also discuss the role of statistical modeling in science more generally
- The course will consist of lectures, computer exercises, and mini-projects. The student will acquire practical experience in the use of a range of computational methods by analyzing sequences from the scientific literature.
Computer setup
Linux
Windows
MacOS
Lecture Schedule
Week 1 (January 31): Introduction to evolutionary theory and population genetics. Models of growth, selection and mutation
- Online lectures
- Computer exercise
Week 2 (February 7): Neutral mutations and genetic drift. Tree reconstruction by parsimony
- Online lectures
- Course material
- Computer exercise
Week 3 (February 14): Consensus trees. Distance matrix methods
- Online lectures
- Course material
- Computer exercises
Week 4+5 (February 21 + 28): Mini project 1
<--
Project description: Building a tree from scratch: What are the closest relatives of whales?
The mini project should be submitted and assessed via a peer assessment module that will become available on the course DTU Learn page.
Take this tree quiz to test yourself on your ability to accurately interpret evolutionary trees:
Check your replies here:
-->
Week 6 (March 6): Models of sequence evolution. Likelihood methods
- Online lectures
- Course material
- exercise: Real, Observed, and Expected Change
- Handout exercise: Computation of Likelihood
- Slides, week 6
- Lecture notes: Substitution models
- Optional lecture notes: Matrix exponentials for Markov chains
- Computer exercises
Week 7 (March 13): Bayesian inference of phylogeny
- Online lectures
- Course material
- Computer exercise
Week 8+9 (March 20 + April 3): Mini project 2
Week 10 (April 10): Model Selection
- Online lectures
- Course material
- Computer exercise
Week 11 (April 17): Bayesian Phylogenetics, Part 2
- Course material
Week 12 + 13 (April 24 + May 1): Mini project 3: Final exam
Details will follow