Multiple α-Glucoside Transporter Genes in Brewer’s Yeast

Maltose and maltotriose are the two most abundant fermentable sugars in brewer’s wort, and the rate of uptake of these sugars by brewer’s yeast can have a major impact on fermentation performance. In spite of this, no information is currently available on the genetics of maltose and maltotriose uptake in brewing strains of yeast. In this work, we studied 30 brewing strains of yeast (5 ale strains and 25 lager strains) with the aim of examining the alleles of maltose and maltotriose transporter genes contained by them. To do this, we hybridized gene probes to chromosome blots. Studies performed with laboratory strains have shown that maltose utilization is conferred by any one of five unlinked but highly homologous MAL loci (MAL1 to MAL4 and MAL6). Gene 1 at each locus encodes a maltose transporter. All of the strains of brewer’s yeast examined except two were found to contain MAL11 and MAL31 sequences, and only one of these strains lacked MAL41. MAL21 was not present in the five ale strains and 12 of the lager strains. MAL61 was not found in any of the yeast strains. In three of the lager strains, there was evidence that MAL transporter gene sequences occurred on chromosomes other than those known to carry MAL loci. Sequences corresponding to the AGT1 gene, which encodes a transporter of several α-glucosides, including maltose and maltotriose, were detected in all but one of the yeast strains. Homologues of AGT1 were identified in three of the lager strains, and two of these homologues were mapped, one to chromosome II and the other to chromosome XI. AGT1 appears to be a member of a family of closely related genes, which may have arisen in brewer’s yeast in response to selective pressure

Lys80p of Saccharomyces cerevisiae, previously proposed as a specific repressor of LYS genes, is a pleiotropic regulatory factor identical to Mks1p.

In Saccharomyces cerevisiae, an intermediate of the lysine pathway, alpha-aminoadipate semialdehyde (alpha AASA), acts as a coinducer for the transcriptional activation of LYS genes by Lys14p. The limitation of the production of this intermediate through feedback inhibition of the first step of the pathway results in apparent repression by lysine. Previously, the lys80 mutations, reducing the lysine repression and increasing the production of lysine, were interpreted as impairing a repressor of LYS genes expression. In order to understand the role of Lys80p in the control of the lysine pathway, we have analysed the effects of mutations epistatic to lys80 mutations. The effects of lys80 mutations on LYS genes expression were dependent on the integrity of the activation system (Lys14p and alpha AASA). The increased production of lysine in lys80 mutants appeared to result from an improvement of the metabolic flux through the pathway and was correlated to an increase of the alpha-ketoglutarate pool and of the level of several enzymes of the tricarboxylic acid cycle. The LYS80 genes has been cloned and sequenced; it turned out to be identical to gene MKS1 cloned as a gene encoding a negative regulator of the RAS-cAMP pathway. We conclude that Lys80p is a pleiotropic regulatory factor rather than a specific repressor of LYS genes.Journal ArticleResearch Support, Non-U.S. Gov'tSCOPUS: ar.jFLWINinfo:eu-repo/semantics/publishe