Abstract
Brewer's yeasts sometimes produce inadequate or excessive amounts of sulfite, an antioxidant and flavour stabilizer, so means of controlling the sulfite production are desired. Understanding the physiology and regulation of the sulfur assimilation pathway of Saccharomyces yeasts is the key to change sulfite production. The MET2 gene of Saccharomyces yeasts encodes homoserine O-acetyl transferase, which catalyzes the conversion of homoserine to O-acetyl homoserine which in turn combines with hydrogen sulfide to form homocysteine, the immediate precursor of methionine. We expected that inactivation of MET2 would lead to accumulation of sulfide and derepression of the entire sulfur assimilation pathway and, therefore, possibly also to sulfite accumulation. Brewer's yeasts were constructed in which several of the four MET2 gene copies were inactivated. Sulfite production was increased in strains with one remaining MET2 gene and even more so when no active MET2 was present. In both cases, hydrogen sulfide production was also increased. To the extent that excess sulfide can be removed, this strategy may be applied to control sulfite accumulation by brewer's yeast in beer production.
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