Abstract
ABSTRACTMicroorganisms play a significant role in fermented food biotechnology by converting raw materials in human edible organoleptic and nutritive components, especially in the beer brewing industry. The lager-style beer is the dominant industrial beer type, and it is fermented bySaccharomyces pastorianus(Sp) whose members encompass two groups. Typically, strains belonging to group I are deficient in maltotriose consumption. The main variables linked to this phenotype are fermentation conditions, the presence of maltotriose transporters, copy number variation of maltose and maltotriose transporters, and differential genetic regulation. This study was aimed to determine that the differences the alpha-glycoside consumption phenotypes of two Sp strains, Sp820 and Sp790, are related with different phylogenetic distribution and gene expression of the transporters ScMalx1, SeMalx1, ScAGT1, SeAGT1,MTT1 andMPHx. Biochemical analyses of the transport rate confirmed that the Sp790 strain transported more maltose and maltotriose, 28% and 32% respectively, than Sp820 strain. In addition, detection of Sp790 transcripts indicated the presence of all theMalgenes analyzed since the first day of fermentation, whereas Sp820 only presented transcripts for the ScMalx1, ScAGT1, andMPHx genes. These results indicate that a multifactorial phenomenon related with phylogenetic distribution, polymorphisms in transmembrane domains and the difference in the genetic expression of maltose and maltotriose transporters are involved in the phenotypic diversity related with maltose and maltotriose consumption in two lager yeast.IMPORTANCEBeer is the third most popular beverage around the world and has roughly 90% market share in the alcoholic beverage industry.Saccharomyces pastorianus(Sp) strains, which are widely used for lager beer production, have a phenotypic diversity involved in maltotriosa consumption. The fermentation of this sugar is fundamental for the flavor landscape produced during lager beer brewing. This phenotypic diversity encompasses lager yeast strain with remarkable ability to consume maltotriose; Sp group II, to poor capacity of consumption for some lager yeast belonging to Sp group I. Research in this field indicate that variables like conditions of fermentation, presence of maltotriose transporter specific genes, and differential gene regulation can cause this diversity. The significance of our study is to approximate and also contribute to the elucidation of mechanistic variables involved in such phenotypic variability that will allow the development of more controlled and efficient biotechnological processes around beer brewing industry.
Publisher
Cold Spring Harbor Laboratory