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引用次数: 0
摘要
甲酸脱氢酶(FDH)广泛应用于氧化还原辅因子的再生。人们一直致力于对 FDH 进行改造,以提高其催化活性和对辅助因子的偏好。在假单胞菌 101 的 FDH(pseFDH)晶体结构中,有 9 个氨基酸残基的 C 端无法解析。然而,我们早期的工作表明,C末端的突变导致pseFDH变体偏爱非天然辅助因子烟酰胺胞嘧啶二核苷酸(NCD)。在这里,我们通过截断 pseFDH 变体相应的 C 端残基,研究了 C 端残基对辅助因子偏好的作用。序列比较分析表明,C端残基在不同的 FDHs 之间几乎没有保守性。我们构建了 pseFDH 及其 C 端被截短的突变体,所得到的变体对 NCD 的偏好有所改善,主要是因为 NAD 依赖性活性大幅下降。进一步的结构分析表明,这些 pseFDH 变体的辅助因子结合域经过重建,有利于与 NCD 进行分子相互作用。我们的工作表明,pseFDH 的 C 端残基会影响酶的活性和对辅因子的偏好,这为改善氧化还原酶的性能提供了一种新方法。
Truncating the C terminus of formate dehydrogenase leads to improved preference to nicotinamide cytosine dinucleotide.
Formate dehydrogenase (FDH) is widely applied in regeneration of redox cofactors. There are continuing interests to engineer FDH for improved catalytic activity and cofactor preference. In the crystal structure of FDH from Pseudomonas sp. 101 (pseFDH), the C terminus with 9 amino acid residues cannot be resolved. However, our earlier work showed mutations at C terminus led pseFDH variants to favor a non-natural cofactor nicotinamide cytosine dinucleotide (NCD). Here, we investigated the role of C-terminal residues on cofactor preference by truncating their corresponding C terminus of pseFDH variants. Sequence comparison analysis showed that C-terminal residues were barely conservative among different FDHs. pseFDH and mutants with their C termini truncated were constructed, and the resulted variants showed improved preference to NCD mainly because NAD-dependent activity dropped more substantially. Further structure analysis showed that these pseFDH variants had their cofactor binding domains reconstructed to favor molecular interactions with NCD. Our work indicated that C-terminal residues of pseFDH affected enzyme activity and cofactor preference, which provides a new approach for ameliorating the performance of redox enzymes.
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