The T2T genome assembly of watershield ( Brasenia schreberi ) unveils genomic insights into aquatic adaptation

Watershield (Brasenia schreberi), belonging to Cabombaceae within the order Nymphaeales, represents one of the early-diverged angiosperm lineages. This perennial floating leaf freshwater aquatic plant features submerged juvenile leaves enveloped in a thick layer of transparent gelatinous mucilage, aiding in its resistance to aquatic stress. However, the evolutionary history of the mechanisms underlying its specific phenotype remains unclear. In this study, we present the telomere-to-telomere level genome of B. schreberi, unveiling that it underwent two rounds of whole-genome duplications (WGDs) and a recent whole-genome triplication, with the most ancient WGD being shared by Nymphaeaceae. WGD and dispersed duplication significantly contributed to the expansion of gene families, which are primarily associated with environmental adaptation. Additionally, we discovered that mature leaves primarily conduct photosynthesis and may transport nutrients to underwater juvenile leaves for polysaccharide synthesis. We also identified an ancestral broad expression pattern of ABC genes, and the similar expression of anthocyanin biosynthesis genes across all flower organs resulted in entirely purple flowers. Our findings deepen the understanding of the evolution of this specific aquatic plant phenotypes.