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Table 8.3 & Alberts Fig.1.38 EVOLUTION OF GENOMES C-value paradox: - in certain cases, lack of correlation between morphological complexity and genome.

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Presentation on theme: "Table 8.3 & Alberts Fig.1.38 EVOLUTION OF GENOMES C-value paradox: - in certain cases, lack of correlation between morphological complexity and genome."— Presentation transcript:

1 Table 8.3 & Alberts Fig.1.38 EVOLUTION OF GENOMES 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

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

3 Hartwell Fig. 21.11 Genic contribution to expansion in genome size

4 Figure 8.7 Scenario showing possible events following whole genome duplication 26 genes on 2 chromosomes 36 genes on 4 chromosomes

5 Kellis Nature 428:617, 2004 Evidence for whole genome duplication in ancestor of yeast see also Fig.8.7 ~ 100 million years ago?

6 Frequency distribution of haploid chromosome numbers in dicot plants For chromosome number >12, even numbers much more common than odd numbers Griffiths 7 th ed, Fig. 26-12 Duplication of entire genome much more common in plant evolution than in animal evolutionary history

7 Fig. 6.25 Over evolutionary time expect independent mutations to accumulate Evolution of tandem arrays of eukaryotic genes … but often observe all copies identical (or nearly so) - evolve “in concert”

8 Concerted evolution - maintenance of homogeneous nt sequences among multi-gene family members (especially when in tandem arrays) - eg. eukaryotic ribosomal RNA gene copies - exchange of sequence info so members kept very similar Fig. 6.26

9 Fig. 6.27 Possible evolutionary scenarios resulting in “homogenized” tandem array 1. Beneficial mutations fixed by positive selection -but spacers with no known function show concerted evolution 2. Recent amplification 3. Mutation in one repeat “spreads” to others

10 Fig. 6.31 Unequal crossing over - homologous recombination between misaligned arrays - change in number of repeats

11 Example of unequal crossing over in human  globin array misalignment (of sister chromatids during mitosis in germ cell or homologous chromosomes during meiosis…) Page & Holmes Fig. 3.15 “Lepore”  thalassemia

12 Gene conversion - non-reciprocal recombination - no change in gene copy number - can occur in dispersed as well as tandem repeats Fig. 6.29 Watson Fig. 10-21 - example of yeast mating-type switching

13 Fig. 6.33 Exon 3 Exons 1 & 2 How do you interpret these data? Example of concerted evolution in primate  globin gene cluster... and panel 3 of Fig.6.33 ?

14 Fig. 6.33 PR pancreative ribonuclease SR seminal ribonuclease Resurrection of ribonuclease pseudogene by gene conversion What is predicted status of SR gene in giraffe? or sheep? … in some bovine species, gene conversion of  SR with PR gene, so functional again

15 Factors affecting rate of concerted evolution (p. 317-320) 1. Number, arrangement, structure of repeats 2. Functional requirement - selective advantage of high amount of same gene product vs. diversity 3. Population size - non-coding regions evolve more rapidly, and if divergent enough may “escape” homogenization - time for variant to be fixed or eliminated

16 Evolutionary implications of concerted evolution (p.320-322) 1. Spread of advantageous mutations (or removal of deleterious ones) 2. Retards paralogous gene divergence (preventing redundant copy from becoming non-functional) 3. Generates increased genetic variation at a particular locus within a population “molecular drive” Methodological implications - degree of sequence divergence of paralogous genes undergoing concerted evolution is not correlated with evolutionary time so gene duplications can appear younger than they really are…


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