Phylogenetic reconstruction

Slides:



Advertisements
Similar presentations
LG 4 Outline Evolutionary Relationships and Classification
Advertisements

Phylogenetic Tree A Phylogeny (Phylogenetic tree) or Evolutionary tree represents the evolutionary relationships among a set of organisms or groups of.
Bioinformatics Phylogenetic analysis and sequence alignment The concept of evolutionary tree Types of phylogenetic trees Measurements of genetic distances.
. Class 9: Phylogenetic Trees. The Tree of Life Evolution u Many theories of evolution u Basic idea: l speciation events lead to creation of different.
Slide 1 of Modern Evolutionary Classification.
GENE TREES Abhita Chugh. Phylogenetic tree Evolutionary tree showing the relationship among various entities that are believed to have a common ancestor.
Phylogenetic Trees Systematics, the scientific study of the diversity of organisms, reveals the evolutionary relationships between organisms. Taxonomy,
Phylogenetic Trees Understand the history and diversity of life. Systematics. –Study of biological diversity in evolutionary context. –Phylogeny is evolutionary.
Classification of Living Things. 2 Taxonomy: Distinguishing Species Distinguishing species on the basis of structure can be difficult  Members of the.
Plant Molecular Systematics (Phylogenetics). Systematics classifies species based on similarity of traits and possible mechanisms of evolution, a change.
Summer Bioinformatics Workshop 2008 Comparative Genomics and Phylogenetics Chi-Cheng Lin, Ph.D., Professor Department of Computer Science Winona State.
18-2 Modern Evolutionary Classification
Phylogenetic trees Sushmita Roy BMI/CS 576 Sep 23 rd, 2014.
Molecular Evolution Revised 29/12/06
BIOE 109 Summer 2009 Lecture 4- Part II Phylogenetic Inference.
Review of cladistic technique Shared derived (apomorphic) traits are useful in understanding evolutionary relationships Shared primitive (plesiomorphic)
. Class 9: Phylogenetic Trees. The Tree of Life D’après Ernst Haeckel, 1891.
Chapter 2 Opener How do we classify organisms?. Figure 2.1 Tracing the path of evolution to Homo sapiens from the universal ancestor of all life.
Phylogenetic Analysis. 2 Phylogenetic Analysis Overview Insight into evolutionary relationships Inferring or estimating these evolutionary relationships.
Classification and Phylogenies Taxonomic categories and taxa Inferring phylogenies –The similarity vs. shared derived character states –Homoplasy –Maximum.
Phylogenetic trees Sushmita Roy BMI/CS 576
What Is Phylogeny? The evolutionary history of a group.
Phylogenetic analyses Kirsi Kostamo. The aim: To construct a visual representation (a tree) to describe the assumed evolution occurring between and among.
Terminology of phylogenetic trees
Molecular phylogenetics
P HYLOGENETIC T REE. OVERVIEW Phylogenetic Tree Phylogeny Applications Types of phylogenetic tree Terminology Data used to build a tree Building phylogenetic.
SB3C. Examine the evolutionary basis of modern classification systems.
Chapter 26: Phylogeny and the Tree of Life Objectives 1.Identify how phylogenies show evolutionary relationships. 2.Phylogenies are inferred based homologies.
BINF6201/8201 Molecular phylogenetic methods
Bioinformatics 2011 Molecular Evolution Revised 29/12/06.
OUTLINE Phylogeny UPGMA Neighbor Joining Method Phylogeny Understanding life through time, over long periods of past time, the connections between all.
Introduction to Phylogenetics
Calculating branch lengths from distances. ABC A B C----- a b c.
Chapter 10 Phylogenetic Basics. Similarities and divergence between biological sequences are often represented by phylogenetic trees Phylogenetics is.
Phylogeny Ch. 7 & 8.
Phylogenetic trees Sushmita Roy BMI/CS 576 Sep 23 rd, 2014.
PHYLOGENY AND THE TREE OF LIFE CH 26. I. Phylogenies show evolutionary relationships A. Binomial nomenclature: – Genus + species name Homo sapiens.
Ayesha M.Khan Spring Phylogenetic Basics 2 One central field in biology is to infer the relation between species. Do they possess a common ancestor?
Phylogeny.
Warm-Up In a population of 500 rabbits, 320 are homozygous dominant for brown coat color (BB), 160 are heterozygous (Bb), and 20 are homozygous white.
5.4 Cladistics The images above are both cladograms. They show the statistical similarities between species based on their DNA/RNA. The cladogram on the.
Chapter 26 Phylogeny and the Tree of Life
Molecular Evolution. Study of how genes and proteins evolve and how are organisms related based on their DNA sequence Molecular evolution therefore is.
Section 2: Modern Systematics
Phylogeny and the Tree of Life
Evolutionary genomics can now be applied beyond ‘model’ organisms
Phylogeny and the Tree of Life
17.2 Classification based on evolutionary relationships
Section 2: Modern Systematics
5.4 Cladistics.
Multiple Alignment and Phylogenetic Trees
Modern Evolutionary Classification 18-2
Warm-Up Contrast adaptive radiation vs. convergent evolution? Give an example of each. What is the correct sequence from the most comprehensive to least.
Phylogenetic Trees.
Molecular Evolution.
Warm-Up Contrast adaptive radiation vs. convergent evolution? Give an example of each. What is the correct sequence from the most comprehensive to least.
Chapter 20 Phylogenetic Trees. Chapter 20 Phylogenetic Trees.
Chapter 19 Molecular Phylogenetics
Warm-Up Contrast adaptive radiation vs. convergent evolution? Give an example of each. What is the correct sequence from the most comprehensive to least.
Phylogeny and Systematics (Part 6)
Warm-Up Contrast adaptive radiation vs. convergent evolution? Give an example of each. What is the correct sequence from the most comprehensive to least.
Warm-Up Contrast adaptive radiation vs. convergent evolution? Give an example of each. What is the correct sequence from the most comprehensive to least.
Copyright Pearson Prentice Hall
Chapter 26 Phylogeny and the Tree of Life
Chapter 20 Phylogeny and the Tree of Life
18-2 Modern Evolutionary Classification
Phylogeny and the Tree of Life
Copyright Pearson Prentice Hall
1 2 Biology Warm Up Day 6 Turn phones in the baskets
Evolution Biology Mrs. Johnson.
Presentation transcript:

Phylogenetic reconstruction

Phylogeny The evolutionary relationships among organisms; the patterns of lineage branching produced by the true evolutionary history of the organisms being considered

What is Molecular Phylogeny? is the inference of lines of ancestry for organisms based on DNA, RNA, or protein sequences for those organisms obtained in the laboratory We can infer relation between Organism to Organism Genes of different organisms Or genes within one organism

Gene function prediction Speciation Origin of genes & gene transfer

The tree of life A phylogenetic tree, also known as a tree of life or simply a phylogeny, describes branching relationships among species, showing which species shares its most recent common ancestor with which other species.

Rooted trees Unrooted trees infers the existence of an actual common ancestor and defines the evolutionary paths leading to the development of each organism. It provides an indication of the direction of the evolutionary process, defining ancestral and derived characters or species Unrooted trees shows only the evolutionary relationships between the organisms in the tree, and does not actually infer the placement of a common ancestor in the structure or the evolutionary path used to obtain the current relationships

16s rRNA sequences are used for species comparison

Molecular Clocks concept based on the assumption that mutations occur at some regular, more or less predictable rate.

Evolutionary Tree Construction Methods Maximum Parsimony Maximum Likelihood Distances / transformed distances

Maximum Parsimony Attempt to create an evolutionary tree for the organisms in question by using the minimum number of evolutionary steps

Phylogenetic inference using parsimony proceeds in two stages: Infer the unrooted tree for a set of species. An unrooted tree shows the branching relations between the species but does not show the position of the deepest common ancestor. It is a phylogenetic tree with the time dimension removed. 2. Locate the root. This means calculating character polarity for a group: finding the shared derived homologies which reveal whether A evolved from B or the other way round.

How can we infer the unrooted tree? Imagine there are four species: human, chimpanzee, magnolia tree and amoeba. Write out all the possible unrooted trees for the species; that is (a), (b) and (c)

count the minimum number of evolutionary events (that is, changes in character states) implied by each The best estimate of the true unrooted tree is the one requiring the least evolutionary change. Suppose we know that 1000 characters are shared in all four species, that each species has 10 characters unique to itself and that 100 characters are shared between humans and chimps, but are absent in amoebas and magnolias

the 1000 common characters could have evolved once each in the common ancestor of all four species and been retained throughout the phylogeny; that would require a total of 1000 evolutionary events. Each species' 10 unique characters can have evolved in the lineage leading to that species, making 40 evolutionary events. The smallest number of events to produce the distribution of characters between humans and chimps is 200: they could have evolved separately in the human lineage and in the chimp lineage (100 events in each, making 200). 1000 + 40 + 200 = 1240 evolutionary events.

In (c), however, the 100 characters shared by humans and chimps only need to have evolved once, in the common ancestor of humans and chimps, and would not have to be lost again; (c) therefore only requires 1140 events. (c) is therefore the most parsimonious unrooted tree, and (according to the principle of parsimony) the best estimate of the real unrooted tree.

Distance Methods

Distance is a principle of phylogeny referring to the quantitatively measured difference between two groups of organisms, such as two species. Distance can be measured in two ways: The difference between the phenetic appearance of two groups (phenetic distance). The difference in their gene frequencies (genetic difference). Distance is simply a more precise method of the 'look more similar' approach which classifies human and chimpanzees (opposite) as having a more recent common ancestor than humans and rabbits because they share more phenetic characters.

The distances method creates a matrix of all distances (difference scores) between all organisms for which the tree is to be constructed. Having calculated the matrix, the pair of organisms which have the smallest distance score are connected, with a root in between them The average of the distances from each member of the pair to a third node is use for the next iteration of the distances matrix. The process is repeated, until all organisms have been placed in the tree. There is an extremely critical assumption when creating a tree like this, and that is that there is a "molecular clock" and that all organisms are mutating at the same rate.

Maximum Likelihood Maximum likelihood methods create all possible trees containing the set of organisms in question, and then uses statistics to evaluate which tree is most likely.

Steps in Phylogeny construction BLAST Convert to FASTA CLUSTALX Treeview