光合作用产生的电子跨膜穿梭,以模块化方式推动细胞外生物催化氧化还原反应。

Valentina Jurkaš, Florian Weissensteiner, Piera De Santis, Stephan Vrabl, Frieda A Sorgenfrei, Sarah Bierbaumer, Selin Kara, Robert Kourist, Pramod P Wangikar, Christoph K Winkler, Wolfgang Kroutil
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引用次数: 0

摘要

许多生物催化氧化还原反应都依赖于辅助因子 NAD(P)H,而 NAD(P)H 可由专门的回收系统提供。利用光和水进行 NADPH 再生(如蓝藻)在概念上非常吸引人,因为它具有高原子经济性。然而,目前对蓝藻的利用受到了限制,例如蓝藻中具有挑战性且耗时的异源酶表达,以及底物或产物通过细胞壁运输的限制。在这里,我们建立了一个由蓝藻光合作用推动的跨膜电子穿梭系统,以驱动细胞外依赖 NAD(P)H 的氧化还原反应。模块化光电子穿梭系统(MPS)克服了克隆的需要以及与酶或底物毒性和底物吸收相关的问题。该模块化光电子穿梭技术已在四类酶、19 种酶和各种底物上得到了验证,转化率高达 99%,产物的光学纯度大于 99%。
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Transmembrane Shuttling of Photosynthetically Produced Electrons to Propel Extracellular Biocatalytic Redox Reactions in a Modular Fashion.

Many biocatalytic redox reactions depend on the cofactor NAD(P)H, which may be provided by dedicated recycling systems. Exploiting light and water for NADPH-regeneration as it is performed, e.g. by cyanobacteria, is conceptually very appealing due to its high atom economy. However, the current use of cyanobacteria is limited, e.g. by challenging and time-consuming heterologous enzyme expression in cyanobacteria as well as limitations of substrate or product transport through the cell wall. Here we establish a transmembrane electron shuttling system propelled by the cyanobacterial photosynthesis to drive extracellular NAD(P)H-dependent redox reactions. The modular photo-electron shuttling (MPS) overcomes the need for cloning and problems associated with enzyme- or substrate-toxicity and substrate uptake. The MPS was demonstrated on four classes of enzymes with 19 enzymes and various types of substrates, reaching conversions of up to 99 % and giving products with >99 % optical purity.

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