Chromosome-scale genome assembly of diploid halophyte <i>Thinopyrum bessarabicum</i> excludes J genome from polyploid <i>Thinopyrum ancestry</i>

Abstract

Wild relatives of wheat harbour genetic diversity essential for improving resilience to climate-driven stresses, yet their deployment is hampered by unresolved evolutionary relationships and the absence of reference genomes. Here we present a chromosome-scale reference genome for Thinopyrum bessarabicum , a diploid halophyte and high-priority donor for wheat salt tolerance breeding. A key unresolved question is whether the diploid J genome contributed directly to the subgenome composition of extant polyploid Thinopyrum species, and which genomic features underpin its exceptional salt tolerance. Using this resource, we show that the diploid J genome of Th. bessarabicum is not represented among the subgenomes of polyploid Thinopyrum species, resolving a long-standing ambiguity in Triticeae genomics. Gene-level resolution of the reciprocal 4/5 chromosomal translocation across six related Triticeae species identifies conserved breakpoint gene pairs, supporting a single ancestral rearrangement. Genome-wide gene content analysis shows that halophytic capacity is underpinned by quantitative expansion of conserved stress-response gene families. Salt tolerance phenotyping validates chromosome 5J as a tolerance locus in both Th. bessarabicum and wheat introgression lines. A physically anchored marker framework and dual-reference skim-sequencing pipeline enable precise megabase-resolution characterisation of Th. bessarabicum introgressions in wheat, providing a genomic foundation for deploying J-genome diversity in crop improvement.