Multiple Paleopolyploidizations during the Evolution of the Compositae Reveal Parallel Patterns of Duplicate Gene Retention after Millions of Years

Barker, Michael S.; Kane, Nolan C.; Matvienko, Marta; Kozik, Alexander; Michelmore, Richard W.; Knapp, Steven J.; Rieseberg, Loren H.

doi:10.1093/molbev/msn187

Cited by 317 publications

(422 citation statements)

References 58 publications

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“…However, studies on the Compositae (Asteraceae) lineage showed that duplicated genes generated by WGD were significantly enriched for genes associated with structural components or cellular organization, and regulatory and developmental genes such as transcription factors were significantly underrepresented. This pattern was almost consistent in all Compositae species investigated (Barker et al, 2008). Together, these observations suggest that some underlying mechanisms might have contributed to the evolutionary fates of duplicated genes derived from WGD events across divergent taxa, although selection forces might be varied substantially among higher taxonomic categories.…”

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confidence: 65%

Prevalent Role of Gene Features in Determining Evolutionary Fates of Whole-Genome Duplication Duplicated Genes in Flowering Plants

et al. 2013

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The evolution of genes and genomes after polyploidization has been the subject of extensive studies in evolutionary biology and plant sciences. While a significant number of duplicated genes are rapidly removed during a process called fractionation, which operates after the whole-genome duplication (WGD), another considerable number of genes are retained preferentially, leading to the phenomenon of biased gene retention. However, the evolutionary mechanisms underlying gene retention after WGD remain largely unknown. Through genome-wide analyses of sequence and functional data, we comprehensively investigated the relationships between gene features and the retention probability of duplicated genes after WGDs in six plant genomes, Arabidopsis (Arabidopsis thaliana), poplar (Populus trichocarpa), soybean (Glycine max), rice (Oryza sativa), sorghum (Sorghum bicolor), and maize (Zea mays). The results showed that multiple gene features were correlated with the probability of gene retention. Using a logistic regression model based on principal component analysis, we resolved evolutionary rate, structural complexity, and GC3 content as the three major contributors to gene retention. Cluster analysis of these features further classified retained genes into three distinct groups in terms of gene features and evolutionary behaviors. Type I genes are more prone to be selected by dosage balance; type II genes are possibly subject to subfunctionalization; and type III genes may serve as potential targets for neofunctionalization. This study highlights that gene features are able to act jointly as primary forces when determining the retention and evolution of WGD-derived duplicated genes in flowering plants. These findings thus may help to provide a resolution to the debate on different evolutionary models of gene fates after WGDs.

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confidence: 65%

Prevalent Role of Gene Features in Determining Evolutionary Fates of Whole-Genome Duplication Duplicated Genes in Flowering Plants

et al. 2013

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“…Recent gene family expansion has also been described for the FT/TFL1 family (Blackman et al 2010). Some of these expansions likely result from persistence of duplications that arose during polyploidy events at the base of the Compositae or, more recently, within the Heliantheae (Barker et al 2008). For example, values of K s , the synonymous substitution rate between two sequences, for sunflower duplicate pairs of ZTL and FKF1 were 0.71 and 0.66, respectively, consistent with the former event; K s was 0.45 for one of the duplication events in the sunflower FT clade, consistent with the latter event.…”

Section: Flowering Time Gene Homologs In Sunflowermentioning

confidence: 93%

Contributions of Flowering Time Genes to Sunflower Domestication and Improvement

et al. 2011

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Determining the identity and distribution of molecular changes leading to the evolution of modern crop species provides major insights into the timing and nature of historical forces involved in rapid phenotypic evolution. In this study, we employed an integrated candidate gene strategy to identify loci involved in the evolution of flowering time during early domestication and modern improvement of the sunflower (Helianthus annuus). Sunflower homologs of many genes with known functions in flowering time were isolated and cataloged. Then, colocalization with previously mapped quantitative trait loci (QTLs), expression, or protein sequence differences between wild and domesticated sunflower, and molecular evolutionary signatures of selective sweeps were applied as step-wise criteria for narrowing down an original pool of 30 candidates. This process led to the discovery that five paralogs in the FLOWERING LOCUS T/TERMINAL FLOWER 1 gene family experienced selective sweeps during the evolution of cultivated sunflower and may be the causal loci underlying flowering time QTLs. Our findings suggest that gene duplication fosters evolutionary innovation and that natural variation in both coding and regulatory sequences of these paralogs responded to a complex history of artificial selection on flowering time during the evolution of cultivated sunflower.

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“…Several lineagespecific WGD events thus far documented across the angiosperms (Tang et al, 2008;Jaillon et al, 2009;Soltis et al, 2009) represent only the tip of the iceberg, as potential other WGD events remain uncovered. We envisage that more mesopolyploid WGDs will be revealed in Brassicaceae and other families, such as Asteraceae, where differently aged polyploidization events (Barker et al, 2008) and descending dysploidy have a prominent role in the genome evolution.…”

Section: Mesopolyploid Wgdmentioning

confidence: 99%

“…Multiple and often lineage-specific WGD events uncovered in Asteraceae (Barker et al, 2008), Cleomaceae Barker et al, 2009), Solanaceae (Schlueter et al, 2004), and other taxa (Soltis et al, 2009) imply a key role of WGDs in the evolution of land plants. The steadily improving knowledge of crucifer genome evolution suggests that the duplication-diploidization process is ongoing and occurred several times across the family.…”

Section: Introductionmentioning

confidence: 99%

Fast Diploidization in Close Mesopolyploid Relatives ofArabidopsis

et al. 2010

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Mesopolyploid whole-genome duplication (WGD) was revealed in the ancestry of Australian Brassicaceae species with diploid-like chromosome numbers (n = 4 to 6). Multicolor comparative chromosome painting was used to reconstruct complete cytogenetic maps of the cryptic ancient polyploids. Cytogenetic analysis showed that the karyotype of the Australian Camelineae species descended from the eight ancestral chromosomes (n = 8) through allopolyploid WGD followed by the extensive reduction of chromosome number. Nuclear and maternal gene phylogenies corroborated the hybrid origin of the mesotetraploid ancestor and suggest that the hybridization event occurred ;6 to 9 million years ago.The four, five, and six fusion chromosome pairs of the analyzed close relatives of Arabidopsis thaliana represent complex mosaics of duplicated ancestral genomic blocks reshuffled by numerous chromosome rearrangements. Unequal reciprocal translocations with or without preceeding pericentric inversions and purported end-to-end chromosome fusions accompanied by inactivation and/or loss of centromeres are hypothesized to be the main pathways for the observed chromosome number reduction. Our results underline the significance of multiple rounds of WGD in the angiosperm genome evolution and demonstrate that chromosome number per se is not a reliable indicator of ploidy level.

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Multiple Paleopolyploidizations during the Evolution of the Compositae Reveal Parallel Patterns of Duplicate Gene Retention after Millions of Years

Cited by 317 publications

References 58 publications

Prevalent Role of Gene Features in Determining Evolutionary Fates of Whole-Genome Duplication Duplicated Genes in Flowering Plants

Prevalent Role of Gene Features in Determining Evolutionary Fates of Whole-Genome Duplication Duplicated Genes in Flowering Plants

Contributions of Flowering Time Genes to Sunflower Domestication and Improvement

Fast Diploidization in Close Mesopolyploid Relatives ofArabidopsis

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