Abstract
Whole-genome duplication events (polyploidy events) and gene loss events have played important roles in the evolution of legumes. Here we show that the vast majority of Hsf gene duplications resulted from whole genome duplication events rather than tandem duplication, and significant differences in gene retention exist between species. By searching for intraspecies gene colinearity (microsynteny) and dating the age distributions of duplicated genes, we found that genome duplications accounted for 42 of 46 Hsf-containing segments in Glycine max, while paired segments were rarely identified in Lotus japonicas, Medicago truncatula and Cajanus cajan. However, by comparing interspecies microsynteny, we determined that the great majority of Hsf-containing segments in Lotus japonicas, Medicago truncatula and Cajanus cajan show extensive conservation with the duplicated regions of Glycine max. These segments formed 17 groups of orthologous segments. These results suggest that these regions shared ancient genome duplication with Hsf genes in Glycine max, but more than half of the copies of these genes were lost. On the other hand, the Glycine max Hsf gene family retained approximately 75% and 84% of duplicated genes produced from the ancient genome duplication and recent Glycine-specific genome duplication, respectively. Continuous purifying selection has played a key role in the maintenance of Hsf genes in Glycine max. Expression analysis of the Hsf genes in Lotus japonicus revealed their putative involvement in multiple tissue-/developmental stages and responses to various abiotic stimuli. This study traces the evolution of Hsf genes in legume species and demonstrates that the rates of gene gain and loss are far from equilibrium in different species.
Highlights
Whole-genome duplication, or polyploidy, is a common phenomenon in the evolution of plants and is widespread in angiosperms [1,2]
Only one region of L. japonicus, M. truncatula and C. cajan was comparable to homoeologous regions of G. max, suggesting that one member of the heat shock transcription factor (Hsf) gene pair produced from ancient genome duplication was lost in their ancestral lineages
The results showed that G. max Hsf genes were highly conserved and the majority of sites were dominated by purifying selection
Summary
Whole-genome duplication, or polyploidy, is a common phenomenon in the evolution of plants and is widespread in angiosperms [1,2]. We analyzed the Hsf gene families from six papilionoid legume species for which substantial information about genomes or transcriptomes was available, namely Lotus japonicus (birdsfoot trefoil), Medicago truncatula (barrel medic), Cicer arietinum (chickpea), Glycine max (soybean), Cajanus cajan (pigeonpea) and Phaseolus vulgaris (common bean). The aim of this investigation was to determine which genes were derived from genome duplication, subsequently giving rise to paralogs, which genes descended from speciation events, giving rise to orthologs and which genes have undergone gene loss. Our results may help facilitate the extrapolation of Hsf gene function from one lineage to another
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