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1 Genome Evolution Chapter 24
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2 Introduction Genomes contain the raw material for evolution; Comparing whole genomes enhances – Our ability to understand evolution; –To improve crops; –To identify genetic basis of disease.
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3 Comparative Genomics Making the connection between a specific change in a gene and a modification in a morphological character is difficult; Genomes carry information on the history of life; Evolutionary differences accumulate over long periods.
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4 Genomes of viruses and bacteria evolve in a matter of days; Complex eukaryotic species evolve over millions of years; Example: tiger pufferfish (Fugu rubripes), mouse (Mus musculus), and human genomes. Comparative Genomics
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7 Comparison between human and pufferfish genomes: –Last shared common ancestor 450 MYA; –25% human genes no counterparts in Fugu; –Extensive genome rearrangements since mammal lineage and teleost fish diverged; –Human genome is 97% repetitive DNA; –Repetitive DNA less than 1/6 th Fugu genome sequence.
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8 Human and mouse genomes: –Human: 400 million more nucleotides than the mouse; –25,000 genes and they share 99%; –Diverged about 75 MYA; –300 genes unique to either organism (1%); –Rearrangements of chromosomal regions large and small. Comparative Genomics
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9 Human and chimpanzee genomes: –Diverged 35 MYA; –1.06% of the two genomes have fixed differences in single nucleotides; –1.5% difference in insertions and deletions; –53 of human-specific indels lead to loss-of-function changes; –Smaller ratio in nonsynonymous to synonymous changes; –Purifying selection: removal of nonsynonymous genes.
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10 Genomes evolve at different rates; Mouse DNA has mutated twice as fast as human; Fruit fly and mosquito evolve more rapidly than vertebrates; Difference in generation time accounts for different rates of genome evolution. Comparative Genomics
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11 Comparison of plants with animals and fungi: –1/3 rd genes in Arabidopsis and rice “plant” genes: distinguish plant kingdom from animal kingdom; –Remaining genes similar to genes found in animal and fungal genomes: Basic intermediary metabolism Genome replication and repair RNA transcription & protein synthesis Comparative Genomics
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12 Evolution of Whole Genomes Polyploidy can result from: –Genome duplication in one species –Hybridization of two different species Autopolyploids: genome of one species is duplicated through a meiotic error –Four copies of each chromosome Allopolyploids: result from hybridization and duplication of the genomes of two different species (tobacco)
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13 Evolution of Whole Genomes
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14 Plant polyploidy is ubiquitous, with multiple common origins; Comparison of soybean, forage legume, and garden pea shows a huge difference in genome size; Some genomes increased, some decreased in size; Polyploidy induces elimination of duplicated genes. Evolution of Whole Genomes
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15 Polyploidy may be followed by the unequal loss of duplicate genes from the combined genomes. Evolution of Whole Genomes
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16 Aneuploidy: duplication or loss of an individual chromosome; Plants are able to tolerate aneuploidy better than animals; Duplication of segments of DNA is one of the greatest sources of novel traits. Evolution Within Genomes duplicationloss
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17 Fates of duplicate gene: –Losing function through mutation; –Gaining a novel function through mutation; –Having total function partitioned into the two duplicates. Evolution Within Genomes
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18 Gene duplication in humans is most likely to occur in three most gene-rich chromosomes: Growth and development genes; Immune system genes; Cell-surface receptor genes; 5% of human genome consists of segmental duplications; Duplicated genes have different patterns of gene expression; Rates of duplication vary for different groups of organisms. Evolution Within Genomes
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19 Drosophila –31 new duplicates per genome per million years (0.0023 duplications per gene per million years); –C. elegans 10 times fast rate. Paralogues: two genes within an organism that have arisen from duplication of a single gene in an ancestor. Orthologues: conservation of a single gene from a common ancestor. Evolution Within Genomes
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20 Genome reorganization Humans have 1 fewer chromosome than chimpanzees, gorillas, and orangutans; Fusion of two genes into one gene; chromosome 2 in humans; Chromosomal rearrangements in mouse ancestors have occurred at twice the rate seen in humans. Evolution Within Genomes
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21 Chromosomal rearrangement Evolution Within Genomes
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22 Variation in genomes: Conservation of synteny: the preservation over evolutionary time of arrangements of DNA segments in related species: –Long segments of chromosomes in mice and humans are the same; –Allows researchers to locate a gene in a different species using information about synteny. Evolution Within Genomes
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23 Gene inactivation results in pseudogenes: Loss of gene function: way for genomes to evolve –Olfactory receptor (OR) genes: inactivation best explanation for our reduced sense of smell –Primate genomes: > 1000 copies of OR genes; Pseudogenes: sequences of DNA that are similar to functional genes but do not function –70% of human OR genes are inactive pseudogenes –>50% gorilla & chimpanzee OR genes function –>95% New World monkey OR genes work well Evolution Within Genomes
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24 Inferred by comparing genes in different species; Why a mouse develops into a mouse and not a human: –Genes are expressed at different times; –In different tissues; –In different amounts; –In different combinations; –Example: cystic fibrosis gene. Gene Function and Expression Patterns
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25 Gene Pattern and Expression Diverse life forms emerge from similar toolkits of genes; To understand functional difference: –Look at time and place of expression; Small changes in a protein can affect gene function.
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26 Genome Size and Gene Number Genome size has varied over evolutionary time; Increases or decreases in size do not correlate with number of genes; Polyploidy in plants does not by itself explain differences in genome size; A greater amount of DNA is explained by the presence of introns and nonprotein-coding sequences than gene duplicates.
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