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Evolution of Duplicated Genomes. Talline Martins 4.24.07. Null hypothesis. Interlocus gene conversion. Loss of homoeologue. Possible Consequences of Polyploidization. Wendel, 2000. Genomic changes. Many genome-level changes may occur as a result of genomic ‘shock’ - PowerPoint PPT Presentation
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Evolution of Duplicated Genomes
Talline Martins4.24.07
Possible Consequences of Polyploidization
Null hypothesis Interlocus gene conversion
Loss of homoeologue
Wendel, 2000
Genomic changes
• Many genome-level changes may occur as a result of genomic ‘shock’– Increased transposable element activity– Elevated levels of DNA methylation
• Homoeologous recombination• Inter-genomic concerted evolution• Non- and reciprocal translocations
Processes involved in diploidization
What happens to the duplicate genes that remain???
Persistence of Duplicate Genes
• Classical model:– The most common fate of duplicated genes is to become
null through deleterious mutations. The only mechanism for preservation of duplicate genes is through fixation of beneficial mutations (neofunctionalization).
• Problems with the classical model:– Fraction of genes preserved is higher than predicted– Evidence for purifying selection can be found in both loci– Relative lack of null alleles segregating in extant
populations
The Duplication-Degeneration-Complementation (DDC) Model
• Degenerative mutations facilitate rather than hinder the preservation of duplicate functional genes.– Duplicate genes lose different regulatory
subfunctions– They must complement each other to retain all
ancestral functions
Possible Fates of Duplicate Genes
Probability of Subfunctionalization
• The probability of maintenance of duplicate genes increases with number of number of regulatory elements
zPS = Σ PS,i
i=2
Complex Regulatory Regions
Why are some duplicates expressed in some tissues together but not in others?
Embedded and overlapping regulatory regions may reduce the number of subfunctions
Relaxed Selection Among Duplicate Regulatory Genes in Lamiales
LFY/FLO & AP3/DEF
Why are the duplicates still around?
• Role of selection
– Non-synonymous/synonymous substitution Dn/ds ()
– If < 1; purifying selection = 1; no selection (neutral) > 1; positive selection
Codon Substitution Models
• Branch and fixed-sites models• Sites and branch-site models
Branch and Fixed-Sites Models
• Branch models: Models R1-R4
• Fixed-sites model: compare ’s between paralogs– Model C (single )– Model E (allows
separate ’s for paralogs)
Results
LFY/FLO = paralogs diverging more quickly relative to single-copy lineages (R2) , and significantly different from each other (model E).AP3/DEF = paralogs diverging more quickly relative to single-copy lineages (R2), but not significantly different from each other (models C and E).
Sites and Branch-Sites Models(more powerful way to test for positive selection)
• Sites models: “hold constant among all branches while allowing to take on multiple values among site classes”– Models: M1a, M2a, M7, M8
• Branch-sites models: 1 set as foreground branches, allowing for different ’s over different branches and sites.– Reflects initial positive selection on duplicates
followed by purifying selection on ancestral lineages
– Model A and Model Anull. (2 is fixed at 1)
Results
Is different among functional domains of LFY/FLO & AP3/DEF?
• DEF: MADS (DNA-binding site), I, K, and C-terminus
• FLO: N- and C-terminus (putative DNA-binding site)
• How: used sites, fixed-sites, and branch models in addition to Bayes
Results 1. DNA-binding domain in FLO and MADS domain in DEF are under stronger purifying selection than other domains.
3. DEF’s increase in is due to I, K, and C-terminus domains
2. FLOB has higher than FLOA in both domains
FLO
DEF
Conclusions….• Continuous purifying selection on both
paralogs for both genes, although relaxed in comparison to single-copy taxa (supports the DDC model).
• Relaxed constraint in some domains may be an indication of subfunctionalization.– Subfunctionalization rather than adaptive
evolution contributes to preservation of duplicate genes
Alternative explanations
• Gene Dosage– Unlikely, because duplicates have diverged
and because of partial functional redundancy
• Transcriptional regulatory interactions– FLO and DEF paralogs may have co-
evolved (concerted divergence)– Still needs to be tested
References• Chen, ZF and Z Ni. 2006. Mechanisms of genomic
rearrangements and gene expression changes in plant polyploids. BioEssays 28:240-252.
• Adams, KL and JF Wendel. 2005. Polyploidy and genome evolution in plants. Curr. Op. Plant Bio. 8:135-141
• Wendel JF. 2000. Genome evolution in polyploids. Plant Mol. Bio. 42:225-249.
• Force et al. 1999. Preservation of duplicate genes by complementary, degenerative mutations. Genetics 151:1531-1545.
• Aagard JE, Willis JH, and PC Phillips. 2006. Relaxed selection among duplicate floral regulatory genes in Lamiales. J Mol. Evol. 63:493-503.
Time to Subfunctionalization
Fates of duplicated genes are determined shortly after polyploidization
Ratio of mutation rate in regulatory and coding regions is a weak factor in expected degree of resolution
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