Evolution of Homeologous Gene Expression in Polyploid Wheat.

Polyploidization has played a prominent role in the evolutionary history of plants. Two recent and sequential allopolyploidization events have resulted in the formation of wheat species with different ploidies, and which provide a model to study the effects of polyploidization on the evolution of gene expression. In this study, we identified differentially expressed genes (DEGs) between four BBAA tetraploid wheats of three different ploidy backgrounds. DEGs were found to be unevenly distributed among functional categories and duplication modes. We observed more DEGs in the extracted tetraploid wheat (ETW) than in natural tetraploid wheats (TD and TTR13) as compared to a synthetic tetraploid (AT2). Furthermore, DEGs showed higher Ka/Ks ratios than those that did not show expression changes (non-DEGs) between genotypes, indicating DEGs and non-DEGs experienced different selection pressures. For A-B homeolog pairs with DEGs, most of them had only one differentially expressed copy, however, when both copies of a homeolog pair were DEGs, the A and B copies were more likely to be regulated to the same direction. Our results suggest that both cis- and inter-subgenome trans-regulatory changes are important drivers in the evolution of homeologous gene expression in polyploid wheat, with ploidy playing a significant role in the process.

Genetic and epigenetic divergence of duplicate genes in two legume species.

Soybean (Glycine max) and common bean (Phaseolus vulgaris) share a polyploidy event ~59 MYA, followed by a Glycine-specific whole genome duplication (WGD) ~8-13 MYA. Duplicated genes were classified into five categories: singletons, dispersed, proximal, tandem, or WGD/segmental and found strong correlations between gene category and functional annotation. Photosynthesis and transcriptional regulation-related Gene Ontology terms were significantly over-represented in singletons and WGD genes, respectively, aligning with the gene balance hypothesis. We found that the divergence of gene expression and DNA methylation between WGD-derived paralogs increased with age and that WGD genes, initially retained via dosage constraints, subsequently underwent expression divergence, associated with other factors such as DNA methylation. Genes derived from different modes of duplication differed in breadth, level, and specificity of expression in both species. Orthologous genes and ungrouped genes (genes not in an ortholog group) differed in expression patterns. The protein divergence rates of WGD paralog pairs containing an ungrouped gene were higher than those for which both copies had orthologs. We propose that many ungrouped genes are derived from divergent and redundant gene copies, concordant with the neofunctionalization hypothesis. Tandemly duplicated genes were distinct from WGD-derived genes, indicating that mode of duplication contributes to the evolutionary fate of duplicated genes.