<p>(2<i>S</i>,3<i>S</i>)-Butanediol (BDO) is a valuable chiral diol with growing applications in pharmaceuticals and agriculture, but microbial production is hindered by inefficient (<i>S</i>)-acetoin production. Here, we engineered <i>Saccharomyces cerevisiae</i> to synthesize (2<i>S</i>,3<i>S</i>)-BDO directly from glucose by using an efficient (<i>S</i>)-acetoin-producing strain, which was generated by introducing <i>Bacillus subtilis</i> genes encoding α-acetolactate synthase (<i>Bs</i>.AlsS) and a mutant α-acetolactate decarboxylase (<i>Bs.</i>AlsD<sup>WP</sup>) with reversed stereospecificity toward (<i>S</i>)-acetoin formation, alongside targeted deletions of genes involved in racemic acetoin production and competing pathways. (2<i>S</i>,3<i>S</i>)-BDO production in this strain was enabled by introducing <i>Cg</i>.<i>butA</i> from <i>Corynebacterium glutamicum</i>, encoding an L-butanediol dehydrogenase that reduced (<i>S</i>)-acetoin to (2<i>S</i>,3<i>S</i>)-BDO with high efficiency and stereospecificity. The engineered genome-integrated strains co-expressing <i>Bs.alsS</i>, <i>Bs.alsD</i><sup><i>WP</i></sup>, and <i>Cg.butA</i> produced 27.9&#xa0;g/L (2<i>S</i>,3<i>S</i>)-BDO in fed-batch fermentation with high optical purity, an overall yield of 0.20&#xa0;g/g glucose, and an average volumetric productivity of 0.17&#xa0;g/L·h. This represents the first demonstration of high-purity (2<i>S</i>,3<i>S</i>)-BDO biosynthesis directly from glucose without relying on spontaneous diacetyl-formation pathway, positioning <i>S. cerevisiae</i> as a versatile platform for stereoselective diol production.</p>

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Efficient production of optically pure (2S,3S)-butanediol in Saccharomyces cerevisiae

  • Seokjun Moon,
  • Seungwoo Cha,
  • Minyoung Kim,
  • Changmin Sung,
  • Ji-Sook Hahn

摘要

(2S,3S)-Butanediol (BDO) is a valuable chiral diol with growing applications in pharmaceuticals and agriculture, but microbial production is hindered by inefficient (S)-acetoin production. Here, we engineered Saccharomyces cerevisiae to synthesize (2S,3S)-BDO directly from glucose by using an efficient (S)-acetoin-producing strain, which was generated by introducing Bacillus subtilis genes encoding α-acetolactate synthase (Bs.AlsS) and a mutant α-acetolactate decarboxylase (Bs.AlsDWP) with reversed stereospecificity toward (S)-acetoin formation, alongside targeted deletions of genes involved in racemic acetoin production and competing pathways. (2S,3S)-BDO production in this strain was enabled by introducing Cg.butA from Corynebacterium glutamicum, encoding an L-butanediol dehydrogenase that reduced (S)-acetoin to (2S,3S)-BDO with high efficiency and stereospecificity. The engineered genome-integrated strains co-expressing Bs.alsS, Bs.alsDWP, and Cg.butA produced 27.9 g/L (2S,3S)-BDO in fed-batch fermentation with high optical purity, an overall yield of 0.20 g/g glucose, and an average volumetric productivity of 0.17 g/L·h. This represents the first demonstration of high-purity (2S,3S)-BDO biosynthesis directly from glucose without relying on spontaneous diacetyl-formation pathway, positioning S. cerevisiae as a versatile platform for stereoselective diol production.