Phylogenomic Analyses of Alismatales Shed Light into Adaptations to Aquatic Environments

• Published in: Molecular biology and evolution Vol. 39; no. 5
• Main Authors: Chen, Ling-Yun, Lu, Bei, Morales-Briones, Diego F., Moody, Michael L., Liu, Fan, Hu, Guang-Wan, Huang, Chien-Hsun, Chen, Jin-Ming, Wang, Qing-Feng
• Format: Journal Article
• Language: English
• Published: United States Oxford University Press 03.05.2022
• Subjects: Adaptation; Adaptation, Physiological - genetics; Algae; Alismatales; Alismatales - genetics; Analysis; Angiosperms; Aquatic environment; Aquatic plants; Biological Evolution; Cao Yu; Cretaceous; Discoveries; Evolution; Flowering; Flowering plants; Fresh water; Freshwater plants; Genes; Genomes; Genomics; Interspecific hybridization; Magnoliopsida - genetics; Nicotianamine synthase; Phylogenetics; Phylogeny; Plants; Plants (botany); Sea grasses; Seagrasses; Stomata; Transcriptomes; China; adaptation; whole-genome duplication; Alismatales; marine angiosperms; phylogenetic conflict
• ISSN: 0737-4038; 1537-1719; 1537-1719
• DOI: 10.1093/molbev/msac079

Abstract Land plants first evolved from freshwater algae, and flowering plants returned to water as early as the Cretaceous and multiple times subsequently. Alismatales is the largest clade of aquatic angiosperms including all marine angiosperms, as well as terrestrial plants. We used Alismatales to explore plant adaptations to aquatic environments by analyzing a data set that included 95 samples (89 Alismatales species) covering four genomes and 91 transcriptomes (59 generated in this study). To provide a basis for investigating adaptations, we assessed phylogenetic conflict and whole-genome duplication (WGD) events in Alismatales. We recovered a relationship for the three main clades in Alismatales as (Tofieldiaceae, Araceae) + core Alismatids. We also found phylogenetic conflict among the three main clades that was best explained by incomplete lineage sorting and introgression. Overall, we identified 18 putative WGD events across Alismatales. One of them occurred at the most recent common ancestor of core Alismatids, and three occurred at seagrass lineages. We also found that lineage and life-form were both important for different evolutionary patterns for the genes related to freshwater and marine adaptation. For example, several light- or ethylene-related genes were lost in the seagrass Zosteraceae, but are present in other seagrasses and freshwater species. Stomata-related genes were lost in both submersed freshwater species and seagrasses. Nicotianamine synthase genes, which are important in iron intake, expanded in both submersed freshwater species and seagrasses. Our results advance the understanding of the adaptation to aquatic environments and WGDs using phylogenomics.