热毛毛菌甲酸脱氢酶在还原碳酸氢(HCO3−)生成甲酸中具有高活性

Aşkın Sevinç Aslan, J. Valjakka, Jouni Ruupunen, D. Yıldırım, N. Turner, O. Turunen, Barış Binay
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引用次数: 29

摘要

甲酸脱氢酶(FDHs)在化学酶合成中用于辅助因子回收,FDH减少CO2的能力也可以用于通过甲酸(HCOO−)将CO2转化为有用的产物。在这项研究中,我们研究了在nadh依赖的反应中,来自甲基念珠菌(CmFDH)和嗜热毛毛菌(CtFDH)的fdh将碳酸氢形式的CO2 (HCO3−)还原为甲酸。以HCO3−为底物,通过测定动力学速率和产率来评价其催化性能。CtFDH将HCO3−转化为甲酸的效率高于CmFDH,而CmFDH对甲酸的氧化效果更好。还原的最佳pH值为pH 7 ~ 8。然而,高浓度的HCO3−降低了反应速率。CtFDH在HCO3−存在下建模,表明它适合活性位点。模拟了CO2还原过程中氢化物转移的活性位点设置。NADH提供的氢化物会与碳原子HCO3−形成有利的接触,导致分子内的电子过剩。这将导致碳酸氢和氢化物形成的络合物分解成甲酸盐和氢氧根离子。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Chaetomium thermophilum formate dehydrogenase has high activity in the reduction of hydrogen carbonate (HCO3 −) to formate
While formate dehydrogenases (FDHs) have been used for cofactor recycling in chemoenzymatic synthesis, the ability of FDH to reduce CO2 could also be utilized in the conversion of CO2 to useful products via formate (HCOO−). In this study, we investigated the reduction of CO2 in the form of hydrogen carbonate (HCO3 −) to formate by FDHs from Candida methylica (CmFDH) and Chaetomium thermophilum (CtFDH) in a NADH-dependent reaction. The catalytic performance with HCO3 − as a substrate was evaluated by measuring the kinetic rates and conducting productivity assays. CtFDH showed a higher efficiency in converting HCO3 − to formate than CmFDH, whereas CmFDH was better in the oxidation of formate. The pH optimum of the reduction was at pH 7–8. However, the high concentrations of HCO3 − reduced the reaction rate. CtFDH was modeled in the presence of HCO3 − showing that it fits to the active site. The active site setting for hydride transfer in CO2 reduction was modeled. The hydride donated by NADH would form a favorable contact to the carbon atom of HCO3 −, resulting in a surplus of electrons within the molecule. This would cause the complex formed by hydrogen carbonate and the hydride to break into formate and hydroxide ions.
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