An evolutionary landscape of sesame: chromosomal variation, allopolyploid speciation and metabolic specialization.
Tanaka, H.; Ono, E.; Segawa, T.; Murata, J.; Takagi, H.; Uegaki, Y.; Toyonaga, H.; Shiraishi, A.; Takagi, M.; Toyoda, A.; Sato, K.; Wakasugi, T.; Horikawa, M.; Kawase, M.; Itoh, T.; Yamamoto, M. P.
Show abstract
Sesame (Sesamum indicum) is one of the earliest domesticated oilseed crops and is valued for antioxidant lignans that stabilize oil quality. However, the genomic and evolutionary history of the genus Sesamum, including the origin of its allotetraploid relative S. radiatum and the diversification of lignan metabolism, remains poorly understood owing to limited chromosome-scale genomic resources. Here we present chromosome-level genome assemblies for three wild Sesamum species, two Ceratotheca species and a Japanese sesame cultivar to reconstruct genome and karyotype evolution across the Sesamum-Ceratotheca complex. Comparative analyses show that the derived x=16 lineage originated from an ancestral x=13 karyotype through chromosome fission, fusion and translocation, whereas another x=13 lineage underwent extensive restructuring associated with retrotransposon expansion. Phylogenomics places Ceratotheca within the x=16 Sesamum clade and reveals that S. radiatum originated through hybridization involving a C. sesamoides-like ancestor. The antioxidative lignan gene CYP92B14 was reintroduced via the BB progenitor, linking hybridization with restoration of oil-stabilizing metabolism during sesame evolution.
Matching journals
The top 5 journals account for 50% of the predicted probability mass.