Comprehensive analyses of the BES1 gene family in Brassica napus and examination of their evolutionary pattern in representative species

Xiaoming Song, Xiao Ma, Chunjin Li, Jingjing Hu, Qihang Yang, Tong Wang, Li Wang, Jinpeng Wang, Di Guo, Weina Ge, Zhenyi Wang, Miaomiao Li, Qiumei Wang, Tianzeng Ren, Shuyan Feng, Lixia Wang, Weimeng Zhang, Xiyin Wang

The BES1 gene family, an important class of plant-specific transcription factors, play key roles in the BR signal pathway in plants, regulating various development processes. Until now, there has been no comprehensive analysis of the BES1 gene family in Brassica napus, and a cross-genome exploration of their origin, copy number changes, and functional innovation in plants was also not available. We identified 28 BES1 genes in B. napus from its two subgenomes (AA and CC). We found that 71.43% of them were duplicated in the tetraploidization, and their gene expression showed a prominent subgenome bias in the roots. Additionally, we identified 104 BES1 genes in another 18 representative angiosperms and performed a comparative analysis with B. napus, including evolutionary trajectory, gene duplication, positive selection, and expression pattern. Exploiting the available genome datasets, we performed a large-scale analysis across plants and algae suggested that the BES1 gene family could have originated from group F, expanding to form other groups (A to E) by duplicating or alternatively deleting some domains. We detected an additional domain containing M4 to M8 in exclusively groups F1 and F2. We found evidence that whole-genome duplication (WGD) contributed the most to the expansion of this gene family among examined dicots, while dispersed duplication contributed the most to expansion in certain monocots. Moreover, we inferred that positive selection might have occurred on major phylogenetic nodes during the evolution of plants. Grossly, a cross-genome comparative analysis of the BES1 genes in B. napus and other species sheds light on understanding its copy number expansion, natural selection, and functional innovation.