Involvement of methionine salvage pathway genes of Saccharomyces cerevisiae in the production of precursor compounds of dimethyl trisulflde (DMTS)

摘要

Dimethyl trisulflde (DMTS) is one of the components responsible for the unpalatable aroma of stale Japanese sake, called "hineka". Recently, a precursor compound of DMTS, l,2-dihydroxy-5-(methylsulfinyl)pentan-3-one (DMTS-P1), was identified. It was speculated that the yeast methionine salvage pathway (MTA cycle) might participate in the formation of DMTS-P1, because the chemical structure of DMTS-P1 was similar to one of the intermediate compounds of that pathway. Here, we carried out sake brewing tests using laboratory yeast strains with disrupted MTA cycle genes and found that DMTS-P1 was hardly produced by Ameul, Amril, and Amdel strains. Furthermore, the DMTS producing potential (production of DMTS during storage of sake) decreased in sake made with Amril and Amdel. We constructed sake yeast strains with a disrupted MRI1 or MDE1 gene and confirmed a decline in the DMTS-P1 content and DMTS producing potential of sake made with these disruptants. The results of sake brewing tests using MTA cycle disruptants suggested that SPE2 is responsible for the production of DMTS precursors other than DMTS-P1: although the DMTS-P1 content was higher in Aspe2 sake than in Amril or Amdel sake, the DMTS producing potential of Aspe2 sake was as low as that of Amril or Amdel sake. Sake brewing tests using BY4743 Aspe2 Amril double disruptants revealed that the DMTS producing potential was further decreased as compared with the Aspe2 or Amril single disruptant. These results suggest that MRI1, MDE1, and SPE2 are promising targets for breeding yeast to suppress the formation of DMTS during storage of sake.