| Author |
Huang Y, Zhang S, Lin H, Liu C, Li Z, Yang K, Liu Y, Jin L, Lu C, Cheng Y, Hu C, Zhao H, Zhang G, Qian Q, Fan L, Wu D.
|
| Abstract |
Genetic transfers are pervasive across both prokaryotes and eukaryotes, primarily involving canonical genomic introgression between species or genera and horizontal gene transfer (HGT) across kingdoms. However, DNA transfer between phylogenetically distant species, which differs from canonical introgression and HGT in certain aspects of its temporal scale and mechanistic features, here defined as remote introgression (RI), has received less attention in evolutionary genomics. In this study, we present RIFinder, a novel phylogeny-based method for the detection of RI events, and apply it to a comprehensive dataset of 122 grass genomes. Our analysis identifies 622 RI events originating from 543 distinct homologous genes, revealing distinct characteristics among grass subfamilies. Specifically, the subfamily Pooideae contains the largest number of introgressed genes, whereas Bambusoideae contains the fewest. Comparisons among the accepted genes, their donor copies, and native homologs demonstrate that introgressed genes undergo post-transfer localized adaptation and show significant functional enrichment in stress-response pathways. Notably, we identify a large Triticeae-derived segment in the Chloridoideae species Cleistogenes songorica, which is potentially associated with its exceptional drought tolerance. Furthermore, we provide compelling evidence that RI has contributed to the origin and diversification of biosynthetic gene clusters for gramine, a defensive alkaloid chemical, across grass species. Our study establishes a robust method for RI detection and highlights its critical role in adaptive evolution. The Python implementation of RIFinder is publicly available at https://github.com/Ne0tea/RIFinder.
|