Abstract
BackgroundGlucose repression is a global regulatory system in baker’s yeast. Maltose metabolism in baker’s yeast strains is negatively influenced by glucose, thereby affecting metabolite productivity (leavening ability in lean dough). Even if the general repression system constituted by MIG1, TUP1 and SSN6 factors has already been reported, the functions of these three genes in maltose metabolism remain unclear. In this work, we explored the effects of MIG1 and/or TUP1 and/or SSN6 deletion on the alleviation of glucose-repression to promote maltose metabolism and leavening ability of baker’s yeast.ResultsResults strongly suggest that the deletion of MIG1 and/or TUP1 and/or SSN6 can exert various effects on glucose repression for maltose metabolism. The deletion of TUP1 was negative for glucose derepression to facilitate the maltose metabolism. By contrast, the deletion of MIG1 and/or SSN6, rather than other double-gene or triple-gene mutations could partly relieve glucose repression, thereby promoting maltose metabolism and the leavening ability of baker’s yeast in lean dough.ConclusionsThe mutants of industrial baker’s yeast with enhanced maltose metabolism and leavening ability in lean dough were developed by genetic engineering. These baker’s yeast strains had excellent potential industrial applications.
Highlights
Glucose repression is a global regulatory system in baker’s yeast
The results explicitly suggest that the deletion of the MIG1 and/or TUP1 and/or SSN6 genes lead to different results in the tested conditions
Sugar consumption of single-gene deletion strains in low sugar model liquid dough (LSMLD) medium The impact of single-gene mutation of MIG1, TUP1 and SSN6 on sugar consumption was assayed in three LSMLD media
Summary
Glucose repression is a global regulatory system in baker’s yeast. Maltose metabolism in baker’s yeast strains is negatively influenced by glucose, thereby affecting metabolite productivity (leavening ability in lean dough). Even if the general repression system constituted by MIG1, TUP1 and SSN6 factors has already been reported, the functions of these three genes in maltose metabolism remain unclear. A Cys2His zinc-finger protein, binds to the promoters of several genes and represses their transcription when glucose is added to the medium [8,9,10]. As with other co-repressors, the specificity of repression is determined by sequence-specific DNA binding repressors, which recruit Ssn6-Tup to the target gene promoters; these repressors include Mig1 [13,14,15,16]. Maltose metabolism of baker’s yeast through combination mutations of MIG1, TUP1 and SSN6, which breaking the regulatory pathway of glucose repression, remains unclear
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