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BIOE 109 Summer 2009 Lecture 4- Part II Phylogenetic Inference

BIOE 109 Summer 2009 Lecture 4- Part II Phylogenetic Inference. What is phylogeny?. What is phylogeny?. A. B. None Both are phylogenetic trees Only A is phylogenetic tree Only B is phylogenetic tree. What is phylogeny?. Phylogeny: evolutionary history of a group of species

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BIOE 109 Summer 2009 Lecture 4- Part II Phylogenetic Inference

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  1. BIOE 109 Summer 2009 Lecture 4- Part II Phylogenetic Inference

  2. What is phylogeny?

  3. What is phylogeny? A B • None • Both are phylogenetic trees • Only A is phylogenetic tree • Only B is phylogenetic tree

  4. What is phylogeny? Phylogeny:evolutionary history of a group of species or a gene.

  5. What is phylogeny? Phylogeny:evolutionary history of a group of species or a gene Phylogenetic tree: graphical summary of the evolutionary history

  6. Phylogeny describes:- • Pattern and/or timing of events that occurred as species • diversified. • 2. Sequence in which lineages appeared • 3. Which organisms are more closely or distantly related.

  7. Phylogenetic Inference Two points to keep in mind:

  8. Phylogenetic Inference • Two points to keep in mind: • Phylogenetic trees are hypotheses • -how reliable?

  9. Phylogenetic Inference Two points to keep in mind: 1. Phylogenetic trees are hypotheses 2. Gene trees are not the same as species trees

  10. Phylogenetic Inference Two points to keep in mind: 1. Phylogenetic trees are hypotheses 2. Gene trees are not the same as species trees • aspecies tree depicts the evolutionary history of a group of species.

  11. Phylogenetic Inference Two points to keep in mind: 1. Phylogenetic trees are hypotheses 2. Gene trees are not the same as species trees • aspecies tree depicts the evolutionary history of a group of species. • a gene tree depicts the evolutionary history of a specific locus.

  12. Conflict between gene trees and species trees

  13. Conflict between gene trees and species trees

  14. Phylogenetic Inference • phylogenetic trees are built from “characters”.

  15. Phylogenetic Inference • phylogenetic trees are built from “characters”. • characters can be morphological, behavioral, physiological, or molecular.

  16. Phylogenetic Inference • phylogenetic trees are built from “characters”. • characters can be morphological, behavioral, physiological, or molecular. • there are two important assumptions about the characters used to build trees:

  17. Phylogenetic Inference • phylogenetic trees are built from “characters”. • characters can be morphological, behavioral, physiological, or molecular. • there are two important assumptions about the characters used to build trees: 1. they are independent.

  18. Phylogenetic Inference • phylogenetic trees are built from “characters”. • characters can be morphological, behavioral, physiological, or molecular. • there are two important assumptions about characters used to build trees: 1. they are independent. 2. they are homologous.

  19. What is a homologous character?

  20. What is a homologous character? • a homologous character is shared by two species because it was inherited from a common ancestor.

  21. What is a homologous character? • • a homologous character is shared by two species because it was inherited from a common ancestor. • • a character possessed by two species but was not present in their recent ancestors, it is said to exhibit “homoplasy”.

  22. Types of homoplasy:

  23. Types of homoplasy: 1. Convergent evolution Example: evolution of eyes, flight.

  24. Examples of convergent evolution

  25. Types of homoplasy: 1. Convergent evolution Example: evolution of eyes, flight. 2. Parallel evolution Example: drug resistance in HIV.

  26. What is the difference between convergent and parallel evolution?

  27. What is the difference between convergent and parallel evolution? Convergent Parallel

  28. What is the difference between convergent and parallel evolution? Convergent Parallel Species compared: distantly closely related related

  29. What is the difference between convergent and parallel evolution? Convergent Parallel Species compared: distantly closely related related Trait produced by: different genes/ same genes/ developmental developmental pathways pathways

  30. Types of homoplasy: 1. Convergent evolution Example: evolution of eyes, flight. 2. Parallel evolution Example: lactose tolerance in human adults 3. Evolutionary reversals Example: back mutations at the DNA sequence level (C  A  C).

  31. Evolutionary reversals are common in DNA sequences   

  32. Our objective is to identify monophyletic groups

  33. Our objective is to identify monophyletic groups A monophyletic group is derived from a single ancestral species and includes all descendants (e.g., mammals).

  34. Three monophyletic groups:

  35. Two mistakes are possible: 1. A paraphyletic group is derived from a single ancestral species but does not include all descendants.

  36. Reptiles are paraphyletic

  37. Two mistakes are possible: 1. A paraphyletic group is derived from a single ancestral species but does not include all descendants (e.g., reptiles). 2. A polyphyletic group fails to include the most recent common ancestor.

  38. “Warm blooded animals” is a polyphyletic group

  39. Contending schools of systematics 1. Phenetics (Distance methods)

  40. Contending schools of systematics 1. Phenetics (Distance methods) Objectives: 1. Tree should reflect overall degree of similarity.

  41. Contending schools of systematics 1. Phenetics (Distance methods) Objectives: 1. Tree should reflect overall degree of similarity. 2. Tree should be based on as many characters as possible.

  42. Contending schools of systematics 1. Phenetics (Distance methods) Objectives: 1. Tree should reflect overall degree of similarity. 2. Tree should be based on as many characters as possible. 3. Tree should minimize the distance among taxa.

  43. Examples of distance trees-HIV strains Discrete character data is converted into a distance value

  44. Distance tree—HIV strains • Captures overall degree of similarity • Branch lengths are important • Drawbacks: • (a) loss of information about which traits have • changed. • (b) have to correct for multiple substitutions at • the same site. • (c) the tree may not reflect “true” phylogenetic • relationship

  45. Contending schools of systematics 2. Cladistics

  46. Contending schools of systematics 2. Cladistics Objectives: 1. Tree should reflect the true phylogeny.

  47. Contending schools of systematics 2. Cladistics Objectives: 1. Tree should reflect the true phylogeny. 2. Tree should use characters that are shared (among two or more taxa) and derived (from some inferred or known ancestral state).

  48. Contending schools of systematics 2. Cladistics Objectives: 1. Tree should reflect the true phylogeny. 2. Tree should use characters that are shared (among two or more taxa) and derived (from some inferred or known ancestral state). • shared and derived characters are called synapomorphies.

  49. Contending schools of systematics 2. Cladistics Objectives: 1. Tree should reflect the true phylogeny. 2. Tree should use characters that are shared (among two or more taxa) and derived (from some inferred or known ancestral state). • shared and derived characters are called synapomorphies. 3. Ancestral state of characters inferred from an outgroup that roots the tree.

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