Integrating Au Catalysis and Engineered Amine Dehydrogenase for the Chemoenzymatic Synthesis of Chiral Aliphatic Amines

IF 8.5 Q1 CHEMISTRY, MULTIDISCIPLINARY

JACS Au Pub Date : 2024-06-10 DOI:10.1021/jacsau.4c00222

Jianqiao Liu, Jing Bai*, Yunting Liu, Liya Zhou, Ying He, Li Ma, Guanhua Liu, Jing Gao and Yanjun Jiang*,

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Abstract

Direct synthesis of aliphatic amines from alkynes is highly desirable due to its atom economy and high stereoselectivity but still challenging, especially for the long-chain members. Here, a combination of Au-catalyzed alkyne hydration and amine dehydrogenase-catalyzed (AmDH) reductive amination was constructed, enabling sequential conversion of alkynes into chiral amines in aqueous solutions, particularly for the synthesis of long-chain aliphatic amines on a large scale. The production of chiral aliphatic amines with more than 6 carbons reached 36–60 g/L. A suitable biocatalyst [PtAmDH (A113G/T134G/V294A)], obtained by data mining and active site engineering, enabled the transformation of previously inactive long-chain ketones at high concentrations. Computational analysis revealed that the broader substrate scope and tolerance with the high substrate concentrations resulted from the additive effects of mutations introduced to the three gatekeeper residues 113, 134, and 294.

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将金催化与工程胺脱氢酶结合用于手性脂肪胺的化学酶法合成

从炔烃直接合成脂肪族胺具有原子经济性和高立体选择性，因此非常理想，但仍然具有挑战性，尤其是对于长链成员。在此，我们构建了金催化炔烃水合和胺脱氢酶催化（AmDH）还原胺化的组合，实现了在水溶液中将炔烃依次转化为手性胺，尤其适用于大规模合成长链脂肪族胺。含 6 个以上碳原子的手性脂肪胺的产量达到 36-60 克/升。通过数据挖掘和活性位点工程获得了一种合适的生物催化剂[PtAmDH (A113G/T134G/V294A)]，该催化剂能够在高浓度下转化之前没有活性的长链酮。计算分析表明，113、134 和 294 这三个守门残基的突变产生了叠加效应，从而扩大了底物范围并提高了对高浓度底物的耐受性。

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