We mapped the QTLs for FAAs in edamame seeds and identified TOF11 as the causal gene. TOF11 loss-of-function accelerates flowering/maturation and increases FAAs during the edamame stage. The free amino acid (FAA) content in edamame seeds is a determinant of sweetness and umami taste; however, its genetic regulation remains unclear. Therefore, in this study, to elucidate the genetic basis of FAA accumulation, we identified major QTLs and causal genes. We developed a recombinant inbred line population derived from a cross between the Japanese cultivar Enrei (low FAA) and the Japanese landrace edamame Shirayama (high FAA). Using this population, we identified three quantitative trait loci (QTLs) associated with FAA accumulation (qAAD6, qAAD11₁, and qAAD11₂). qAAD11₁ co-localised with qDFD11, a QTL for flowering time. Whole-genome resequencing-based polymorphism analysis revealed five strong candidates within the qDFD11 interval, among which PRR3a/TOF11 was identified as the causal gene for qDFD11. Compared with the wild-type allele, loss-of-function alleles of TOF11 and its homologue TOF12, derived from a mutant and a near-isogenic line with an Enrei background, respectively, both resulted in earlier flowering and maturation, as well as higher FAA accumulation in edamame seeds. These results demonstrated that TOF11 is the causal gene of qAAD11₁. We performed QTL analysis after fixing the qAAD11₁ genotype and identified qAAD11₂, which is tightly linked to qAAD11₁. Because the Shirayama allele at TOF11 and the Enrei allele at qAAD11₂ promote FAA accumulation, breaking their linkage through marker-assisted selection is essential for high-FAA edamame breeding. This study demonstrated that TOF11 regulates not only flowering and maturation but also FAA content at the edamame stage. These findings provide important insights for high-quality edamame breeding.
Shioya et al. (Tue,) studied this question.