1 / 30

Human Molecular Evolution Lecture 1

Human Molecular Evolution Lecture 1. Molecular evolution – Humans as apes You can download a copy of these slides from www.stats.ox.ac.uk/~harding. We are apes! though a unique form of ape. What makes us different from other apes?. Apes are primates.

cheng
Download Presentation

Human Molecular Evolution Lecture 1

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Human Molecular Evolution Lecture 1 Molecular evolution – Humans as apes You can download a copy of these slides from www.stats.ox.ac.uk/~harding

  2. We are apes!though a unique form of ape • What makes us different from other apes?

  3. Apes are primates Great apes are shown. Gibbons also are apes, (i.e. lesser apes). Homo sapiens (human) Pan troglodytes(common chimpanzee) Pongo pygmaeus (orangutan) Gorilla gorilla (lowland gorilla)

  4. Gibbon (lesser ape) Primate classification In 1735 Linneas classified humans in the same taxonomic group with other living primates: apes, monkeys, lemurs, lorises, and tarsiers, in his Anthropomorpha, now Order: Primates. Ring tailed lemur Pygmy loris Spider monkey Tarsier

  5. The beginnings of the study of primate evolution • 1830s: first discoveries of primate fossils, providing evidence of a temporal dimension in primate diversity and biogeography, including extinct species & evidence that apes once lived in Europe. • Publication of Darwin’s Origin of Species (1859) and The Descent of Man and Selection in Relation to Sex (1871): explaining how evolution could take place. • ‘much light will be thrown on the origin of man and his history’ Charles Darwin

  6. Primates: basic design • Generalised arboreal anatomy, but many examples of specialized adaptations for locomotion, e.g. • Knuckle walking by chimpanzees and gorillas, but not by humans. • Stereoscopic vision • Most have opposability of their thumbs and/or first toes to make for a grasping hand • Many have relatively large brains for their body size • Life history traits: variation in gestation length, age of weaning, age at sexual maturity (the high end of which is not found in other primates of comparable body size), that emphasize high investment in small numbers of offspring, learned behaviour and sociality.

  7. Primatology as a basis for the study of human evolution • By the beginning of the 20th century, primate evolution had become established as an area of major interest within anthropology – providing the broad evolutionary context for studying human origins. • Classification by morphological similarity is challenged by phylogenetic methods. • What was the branching order of these species? • Chromosomes (karyotypes) • Molecules (proteins and DNA) • What was the time scale? • Fossils • Molecules

  8. Tarsier Primate Phylogeny Pygmy Loris Higher Primates (including apes and monkeys) and Tarsiers are Haplorhines Divergence between Haplorhines vs Strepsirhines (bushbabies, lorises and lemurs) Note the time scales. Supported by fossils Estimated from molecular divergence

  9. Branching order and time-scale for ape phylogeny Hla: Hylobates lar (gibbon) Ggo: Gorilla gorilla Ptr: Pan troglodytes (common chimp) Ppa: Pan paniscus (bonobo) Hsa: Homo sapiens (humans) Ppy: Pongo pygmaeus (orangutan) 1 2 3 4 5 Hacia JG (2001)

  10. What traits distinguish humans from other apes? • Body shape, S-shaped spine • Relative limb length • Efficient bipedal locomotion • Skull balanced upright on vertebral column • Cranial properties, relative brain size and brain topology • Small canine teeth • Long ontogeny (development time) and lifespan • Reduced body hair • Language • Advanced tool making

  11. How did these traits evolve? Evidence from hominin fossils • Bipedal mode of location, evident for earliest hominins – australopithecines • Large brain, disproportionately large for body size; evolved ~2 MYA, characteristic of Homo

  12. Our closest living relatives are chimps Nature 437(7055):17-19, 2005

  13. Chimpanzees: two species (and several subspecies) Pan troglodytes (common chimp) Pan paniscus (bonobo)

  14. What can we learn from studies of chimps?

  15. Chimp species (Pan troglodytes and Pan paniscus) and subspecies are geographically isolated NigerR. Western Ubangui R. Eastern Sanaga R. Central Bonobo Ranges of chimp species and subspecies appear bounded by rivers. Gagneux (2002) TIG 18:327-330

  16. Unrooted phylogenetic tree (maximum parsimony) for Y chromosome haplotypes Gorilla Bonobo P.t. schweinfurthii (Eastern) Human The tree indicates that some nucleotide differences discriminate chimp subspecies. What does this impIy for FST? P.t. verus (Western) P.t. troglodytes (Central) Figure from Stone et al. (2002)

  17. Reconstructing haplotypes from the tree Pp3 Bonobo Pp2 Pp1 Ptv1 Western Ptv2 Ptt1 Ptt2 Central Ptt4 Ptt5 The actual locations of variable sites are unknown, but we have some information about how variable sites are shared between haplotypes.

  18. Estimating FST from Y haplotypes • FST = 0 (min value) when allele / haplotype lineages frequencies are the same across subpopulations, ie variance (s2) is zero. • FST = 1 (max value) when alternative alleles / haplotype lineages are fixed (100% freq) in different subpopulations. • The Y haplotype tree indicates that chimp subpopulations have diverged and do not share haplotype lineages. FST ~ 1 • The Western and Central common chimpanzee (P. troglotydes) subpopulations have diverged nearly as much from each other as from P. paniscus (bonobo). • MtDNA likewise discriminates chimp sub-’species’.

  19. Estimating diversity from average pairwise sequence difference Bonobo Pp3 freq= 2 Pp2 freq= 2 Pp1 freq= 4 Pp1 Pp1 Pp1 Pp1 Pp2 Pp2 Pp3 Pp3 Av = 104/64 = 1.625 0 0 0 0 3 3 3 3 0 0 0 0 3 3 3 3 0 0 0 0 3 3 3 3 0 0 0 0 3 3 3 3 3 3 3 3 0 0 1 1 3 3 3 3 0 0 1 1 3 3 3 3 1 1 0 0 3 3 3 3 1 1 0 0 Pp1 Pp1 Pp1 Pp1 Pp2 Pp2 Pp3 Pp3 Divide Av by the length of sequence to give nucleotide diversity, p.

  20. Unrooted phylogenetic tree (maximum parsimony) for Y chromosome haplotypes Gorilla Bonobo P.t. schweinfurthii (Eastern) Human The tree indicates that Bonobo and Central chimps have similar levels of diversity, but that Western chimps have less diversity. P.t. verus (Western) P.t. troglodytes (Central) Figure from Stone et al. (2002)

  21. Phylogenetic tree (maximum likelihood) of chimpanzee and bonobo Xq13.3 haplotypes B: Bonobo, Pan paniscus C: Central African, P. t. t. W: Western, P. t. verus E: Eastern, P. t. schweinfurthii Haplotypes do not completely discriminate subspecies. What does this imply for FST ? Kaessmann et al. 1999 Science 286:1159-1162

  22. Implications for FST and p • The tree shows incomplete lineage sorting for Xq13.3 haplotypes. • There is a high level of population divergence but some Central chimp haplotypes are mixed in with the Western chimp haplotypes, so FST <1 • Note that the average sequence difference between pairs of haplotypes (p) taken for Western chimps will be smaller than the average sequence difference between pairs of haplotypes (p) taken for Central chimps. • Diversity for Central chimps is higher than for Western chimps.

  23. p = 7.51 x 10-4 i.e. 1 SNP per 1,331 bp NIH diversity panel (including African American, European, Chinese) p = 9.5 x 10-4 for Clint (from West Africa) p = 9.5 x 10-4 among 4 West African chimps p = 17.6 x 10-4 among 3 Central African chimps. Comparing human and chimp genomes Heterozygosity, estimated by p (av. sequence difference between two chromosomes) 15 Feb 2001 1 Sept 2005 West African chimps have similar genomic diversity to humans. Central African chimps have twice as much diversity.

  24. Ne for Chimps (P. troglodytes) ? % sequence differences ~3-7 times higher in chimps than in humans for mtDNA, NRY and Xq13.3 ~1-2 times higher in chimps than in humans for autosomal loci.

  25. Differences between loci • Why are there greater sequence differences among chimps in Y haplotypes and mtDNA compared with autosomal genomes? • Isolation between chimp subpopulations leads to genetic divergence, lineage sorting and accumulation of fixed differences. This effect has added sequence differences in addition to polymorphism in Y haplotypes and mtDNA but not to autosomal loci. • The estimates of Ne for chimps from Y haplotypes and mtDNA are incorrect because they should be based only on polymorphism, not on fixed differences.

  26. What is effective population size, Ne? • An estimate of Ne from autosomal genetic diversity: Ne = p / 4.m • In the model, Ne is inversely proportional to how genetic drift has enhanced or eroded polymorphism. • In the data, p is an estimator of Nem provided that it is based on polymorphism. • Two issues for interpreting sequence diversity: • Size (Ne) – diversity shared by larger numbers of breeding individuals in a population is less subject to erosion by genetic drift. • Structure – a number of individuals in a structured population (island model) may present more sequence differences than the same number in a randomly-mating population. ^

  27. Diversity in racial phenotypes does not mark genetic divergence. A moderate level of structure: FST ~0.15 between populations, across most classes of polymorphism, though lower than this for (microsatellites) and higher (~0.33-0.38) for Y haplotypes. Largest genetic distances are between populations within sub-Saharan Africa not between populations on different continents Diversity in phenotypes does mark genetic divergence between bonobo and common chimps but not divergence between chimp subpopulations. A high level of structure and isolation leading to divergence. Even higher for Y chromosomes than for autosomal loci. Genetic distances between subpopulations almost as large as between species. Comparing humans with chimps: population structure Humans Chimpanzees

  28. Comparing humans with chimps: differential selective pressures? • Morphological diversity is low in chimps compared with humans. Is this due to strong differential selection in humans. • Classical polymorphisms (blood groups) and enzyme polymorphisms have higher diversity in humans than in chimps. • MHC diversity, for HLA-A in particular, is lower in chimps than in humans. • Levels of polymorphism at VNTRs, dinucleotide microsatellites in particular, seem reduced in chimps compared with humans. Ascertainment bias is a partial but incomplete explanation. • How have patterns of selection differed in humans compared with chimps? Local adaptations to climate? And to pathogens?

  29. Conclusions • One feasible assumption is that hominins during the Pleistocene were a highly structured species, with species and sub-species differentiation like in chimps today. • Then from contemporary levels and patterns of genetic diversity we can suggest that modern humans descend from a single regional sub-population and reject the multiregional hypothesis. • The estimates of ~10,000 for Ne for humans and for western chimps implies that neutral diversity is being lost by genetic drift as expected in long term small populations • The estimate of 20,000 for Ne for central chimps implies a larger long term evolutionary size.

  30. References • Bramble DM and Lieberman DE (2004) Endurance running and the evolution of Homo. Nature 432: 352-345. • Hacia JG (2001) Genome of the apes. Trends in Genetics 17(11): 645-637 • Gagneux P (2002) The genus Pan: population genetics of an endangered outgroup. Trends in Genetics 18:327-330

More Related