Selenocysteine methyltransferase SMT catalyzed the synthesis of Se-methylselenocysteine to regulate the accumulation of glucosinolates and sulforaphane in broccoli

Selenocysteine methyltransferase (SMT) is a key enzyme involved in the Se metabolism pathway, and it is responsible for the catalysis of Se-methylselenocysteine (SeMSC) compound formation. Previous studies showed that selenium treatment activated SMT expression and promoted the accumulation of glucosinolates (GSLs) and sulforaphane, but the roles and functional mechanisms of SMT in mediating GSLs and sulforaphane synthesis remain unclear. In this study, we identified the BoSMT gene in broccoli and uncovered its roles in mediating GSLs biosynthesis. Transgenic assays revealed that BoSMT is involved in SeMSC biosynthesis in broccoli. More importantly, the contents of GSLs and sulforaphane were significantly increased in the BoSMT-overexpressing broccoli lines but decreased in the knockdown lines, suggesting that BoSMT played a positive role in regulating GSLs and sulforaphane synthesis. Further evidence indicated that BoSMT-mediated overaccumulation of GSLs and sulforaphane might be due to the increase in the endogenous SeMSC content. Compared with the mock (water) treatment, selenite-induced significantly increases of the SeMSC content in the BoSMT-knockdown plants partially compensated the phenotype of GSLs and sulforaphane loss. Compared with the mock treatment, exogenous SeMSC treatment significantly increased the contents of GSL and sulforaphane and activated GSL synthesis-related gene expression, suggesting that SeMSC acted as a positive regulator for GSL and sulforaphane production. Our findings provided novel insights into selenium-mediated GSLs and sulforaphane accumulation. The genetic manipulation of BoSMT might be a useful strategy for improving the dietary nutritional values of broccoli.