1 / 17

Genome Evolution

Genome Evolution. Xuhua Xia xxia@uottawa.ca http://dambe.bio.uottawa.ca. Causes of genomic evolution. Variation in genome size Variation in genomic GC% Variation in gene content Variation between strands Variation in DNA methylation and gene regulation. Variation in genome size.

engelbert-nathanial
Download Presentation

Genome Evolution

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. Genome Evolution Xuhua Xia xxia@uottawa.ca http://dambe.bio.uottawa.ca

  2. Causes of genomic evolution • Variation in genome size • Variation in genomic GC% • Variation in gene content • Variation between strands • Variation in DNA methylation and gene regulation

  3. Variation in genome size C-value paradox: - in certain cases, lack of correlation between morphological complexity and genome size “[For] some commonly cited extreme values for amoebae... considerable uncertainty about the accuracy of these measurements and the ploidy level of the species...” Gregory Nature Rev. Genet. 6:699, 2005 Table 8.3 & Alberts Fig.1.38

  4. Gene fraction vs. genome size Function of non-genic DNA in eukaryotes? Composition of human genome Gregory Nature Rev. Genet. 6:699, 2005 Fig. 8.15

  5. Variation in prokaryotic gene content Fig. 8.1

  6. New genes and new gene interactions Hartwell Fig. 21.11

  7. chr I chr II chr III chr IV chr V Duplicated sequences in yeast genome whole genome duplication ~ 100 Mya? Text Fig. 8.7 In Arabidopsis, ~ 60-70% genome present in duplicate copy Many multi-gene families ( ~ 65% genes are duplicated, and ~ 40% of these families have > 5 members) Nature 408:796, 2000

  8. Lateral gene transfer “Bacterial speciation is likely to be driven by a high rate of horizontal transfer, which introduces novel genes, confers beneficial phenotypic capabilities, and permits the rapid exploitation of competitive environments”. Ochman Nature 405: 299, 2000

  9. Molecular archaeology of the E.coli genome Transposition events (IS elements) Horizontal gene transfer Lawrence & Ochman PNAS 95:9413, 1998

  10. Genome reduction in obligate parasites Rickettsia prowazekii causative agent of typhus intracellular parasite a-proteobacteria – respiratory chain very similar to mitochondrial one Andersson Nature 396: 133, 1998

  11. Bacterial genomic GC and codon usage Fig.8.26 Fig. 8.29 consequences for codon usage patterns?

  12. GC% in bacteriophage and their hosts Natural selection Natural selection AT-biased mutation

  13. Empirical Data dsDNA Phage Non-dsDNA phage

  14. Variation between strands in bacteria Bacterial genomes have bias for G on leading strand of bidirectional replication fork - replication error differences between leading and lagging DNA strands Marin, A. and Xia, X. 2008. GC skew in protein-coding genes between the leading and lagging strands in bacterial genomes: new substitution models incorporating strand-bias. Journal of Theoretical Biology 253(3):508-513 Fig. 8.27

  15. “Experimental evolution” in vivo Comparison of positions of orthologous genes in Mycoplasma & Haemophilus Fig.8.22 Papdopoulos, PNAS 96:3807, 1999

  16. Search for a “minimal” genome E. coli Search for “minimal” bacterial genome Haemophilus influenzae Mycoplasma genitalium Fig. 8.1 Search for “signature proteins” distinctive for 3 “domains of life” eg. archaeal-specific (no detectable homologues in other lineages) = 350 Woese PNAS 97:3302, 2000 eg. eukaryotic-specific = 915 (or315if include Giardia - parasite with reduced gene set) Hartman PNAS 99:1420, 2002

More Related