Functional diversity and plasticity in the sugar preferences of Saccharomyces MALT transporters in domesticated yeasts.

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2022-12-07 DOI:10.1093/femsyr/foac055
Haruyo Hatanaka, Hiromi Toyonaga, Yukiko Ishida, Eiichi Mizohata, Eiichiro Ono
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Abstract

Maltose and maltotriose, together with glucose, are the major carbohydrates found in malts. Thus, brewing yeasts grown in malt-based brewing processes with serial re-pitching have likely increased their ability to uptake these sugars during domestication by modulating the expression and copy number of maltose transporter genes (MALT, also known as Malx1). However, the molecular basis for and structural insights into the sugar preferences of MALT proteins remain to be elucidated. Here we report the functional evaluation of two novel Saccharomyces cerevisiae MALT proteins, ScMalt#2p and ScMalt#5p, from industrial brewing yeasts, focusing on their maltose and maltotriose preferences. Structural models of the MALT proteins generated by AlphaFold2 and functional analyses of substitution mutants revealed that a very small number of amino acid residues in two spatially adjacent transmembrane helixes, TMH7 and TMH11, appear to be crucial for sugar preference. Thus, subtle conformational alterations conferred by a small number of amino acid polymorphisms within MALTs would contribute to the adaptation of domesticated brewing yeasts to the constrained carbohydrate environment of industrial wort during beer brewing.

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驯化酵母中酵母菌MALT转运体对糖偏好的功能多样性和可塑性。
麦芽糖、麦芽糖和葡萄糖是麦芽中主要的碳水化合物。因此,在以麦芽为基础的酿造过程中生长的酿造酵母在驯化过程中通过调节麦芽糖转运基因(MALT,也称为Malx1)的表达和拷贝数,可能增加了它们摄取这些糖的能力。然而,MALT蛋白的糖偏好的分子基础和结构见解仍有待阐明。本文报道了从工业酿造酵母中提取的两种新型酿酒酵母MALT蛋白ScMalt#2p和ScMalt#5p的功能评价,重点研究了它们对麦芽糖和麦芽糖的偏好。由AlphaFold2生成的MALT蛋白的结构模型和对替代突变体的功能分析表明,在两个空间相邻的跨膜螺旋TMH7和TMH11中,极少量的氨基酸残基似乎对糖偏好至关重要。因此,在啤酒酿造过程中,由少量氨基酸多态性引起的细微构象改变将有助于驯化酿酒酵母适应工业麦芽汁的有限碳水化合物环境。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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