1. Ch. 26 Phylogeny and the Tree of Life

2. Opening Discussion: Is this basic “tree of life” a fact? If so, why? If not, what is it?

4. Appreciate the enormous diversity and complexity of life on Earth. There are 1.8 million named species.... … a fraction of the 10 – 100 million extant species.

5. Write down the hierarchical classification system: What is the binomial nomenclature? Phylogeny = the evolutionary history of a species or group of species Taxon = named taxonomic unit at any level of the hierarchy

6. What goes into phylogeny? Systematics data Homologies: similarities due to shared ancestry Linnaeus, 1707- 1778

7. Clade = a group of species that includes an ancestral species and all of its descendants ◦ Monophyletic Group Phylogenetic trees

8. Monophyletic vs Polyphyletic & Paraphyletic

9. Node Sister taxa Phylogenetic trees Shared ancestral trait Shared derived trait

10. What are the: Shared Ancestral Traits? Shared Derived Traits? AB C D

11. Parsimony = logical principle that the most likely explanation is the one that implies the least amount of change (Simplest answer is most likely true) How to tell how to make the tree?

12. Biotechnology revolution of late 20 th century has given us new type of homology Universal code: All lifeforms share certain molecular traits e.g., similarities in hemoglobin molecule Genetic & Molecular homologies

13. Actual sequence of nucleotides for the "leptin" gene for Mouse, Chimpanzee and Human: First 60 nucleotides: M gaggga tcc ctgctccagc agctgcaagg taaggcccggggcgcgctact ttctcctcca C gtaggaatcg cagcgccagc ggttgcaagg taaggccccg gcgcgctcct tcctccttct H gtaggaatcg cagcgccagc ggttgcaagg taaggccccg gcgcgctcct tcctccttct Nucelotides 121-180: C: agtcaggagg gaggcagggc ggatggctta gttctggact atgatagctt tgtaccgagt H: agtcaggagg gatgcagggc ggatggctta gttctggact atgatagctt tgtaccgagt (National Center for Biotechnology Information)

14. Evidence from Molecular Biology When confirm previous conclusions -- COHERENCE Can use molecular homologies when other approaches not possible e.g., similarities in cytochrome c protein

15. Which tree(s) is/are parsimonious and likely? ◦ Maximum Parsimony ◦ Maximum Likelihood How to tell how to make the tree?

16. Convergent evolution: Adaptation by members of different lineages to similar environment Homoplasy = similar analogous structures that arose independently, without shared ancestry Homology vs Homoplasy

17. Homoplasy Ocotillo (NA) Allaudia (Madagascar) Ichthyosaur & dolphin

18. Evolutionary History of Genome Change Homologous Genes: Orthologous genes Paralogous genes

19. Method for estimating the time of evolutionary change, based on genes that evolve at constant rates # nucleotide substitutions is proportional to elapsed time since species diverged from common ancestor Compare number of genetic differences with known evolutionary dates from fossil record to calibrate Average rate of genetic change can estimate date of divergence events unknown from fossils Molecular Clock

20. 1 bp changes per 25 million years = 100 million years of evolution occurring between the 2 species (4*25) = 50 million years each 50 my since the common ancestor #bps/rate/2 = time since divergence Molecular Clock Diagram: evolution.berkeley.edu 4 base pairs different

21. The figure shows an analysis of the evolution of the hemoglobin protein in vertebrates from sharks to humans. The straight line indicates that the evolution has occurred at a constant rate. According to the graph, on average, approximately18% of amino acids change in hemoglobin per 100 million years. What percentage change per1 million years?

22. According to the fossil record, orangutans and African apes diverged 13 million years ago. Based on the average rate shown, calculate the expected percent difference in hemoglobin between orangutans and African apes.

23. Bonobos and common chimpanzees are the closest extant relative to humans. Given that they only have a 0.468% difference in hemoglobin amino acid sequence, use the average rate of amino acid changes (from above) to calculate the time since divergence.

24. Taxon (pl. – taxa) ◦ Sister taxa Nodes Polytomy Homology ◦ Vestigial structures Homoplasy Analogy Convergent evolution Monophyletic group Paraphyletic/Polyphyletic group Shared ancestral character Shared derived character Outgroup Maximum parsimony/ Maximum likelihood Orthologous vs Paralogous Genes Molecular Clock