Wen Kai, Wang Sirui, Sun Yixin, Wang Mengsong, Zhang Yingjiu, Zhu Jingxuan, Li Quanshun
Key Laboratory for Molecular Enzymology and Engineering of Ministry of Education, School of Life Sciences, Jilin University, Changchun, 130012, China.
Center for Supramolecular Chemical Biology, Jilin University, Changchun, 130012, China.
Bioresour Bioprocess. 2024 Jul 10;11(1):67. doi: 10.1186/s40643-024-00782-4.
Formate oxidase (FOx), which contains 8-formyl flavin adenine dinucleotide (FAD), exhibits a distinct advantage in utilizing ambient oxygen molecules for the oxidation of formic acid compared to other glucose-methanol-choline (GMC) oxidoreductase enzymes that contain only the standard FAD cofactor. The FOx-mediated conversion of FAD to 8-formyl FAD results in an approximate 10-fold increase in formate oxidase activity. However, the mechanistic details underlying the autocatalytic formation of 8-formyl FAD are still not well understood, which impedes further utilization of FOx. In this study, we employ molecular dynamics simulation, QM/MM umbrella sampling simulation, enzyme activity assay, site-directed mutagenesis, and spectroscopic analysis to elucidate the oxidation mechanism of FAD to 8-formyl FAD. Our results reveal that a catalytic water molecule, rather than any catalytic amino acids, serves as a general base to deprotonate the C8 methyl group on FAD, thus facilitating the formation of a quinone-methide tautomer intermediate. An oxygen molecule subsequently oxidizes this intermediate, resulting in a C8 methyl hydroperoxide anion that is protonated and dissociated to form OHC-RP and OH. During the oxidation of FAD to 8-formyl FAD, the energy barrier for the rate-limiting step is calculated to be 22.8 kcal/mol, which corresponds to the required 14-hour transformation time observed experimentally. Further, the elucidated oxidation mechanism reveals that the autocatalytic formation of 8-formyl FAD depends on the proximal arginine and serine residues, R87 and S94, respectively. Enzymatic activity assay validates that the mutation of R87 to lysine reduces the k value to 75% of the wild-type, while the mutation to histidine results in a complete loss of activity. Similarly, the mutant S94I also leads to the deactivation of enzyme. This dependency arises because the nucleophilic OH group and the quinone-methide tautomer intermediate are stabilized through the noncovalent interaction provided by R87 and S94. These findings not only explain the mechanistic details of each reaction step but also clarify the functional role of R87 and S94 during the oxidative maturation of 8-formyl FAD, thereby providing crucial theoretical support for the development of novel flavoenzymes with enhanced redox properties.
甲酸氧化酶(FOx)含有8-甲酰基黄素腺嘌呤二核苷酸(FAD),与其他仅含有标准FAD辅因子的葡萄糖-甲醇-胆碱(GMC)氧化还原酶相比,在利用环境氧分子氧化甲酸方面具有明显优势。FOx介导的FAD向8-甲酰基FAD的转化导致甲酸氧化酶活性增加约10倍。然而,8-甲酰基FAD自催化形成的机制细节仍未得到很好的理解,这阻碍了FOx的进一步应用。在本研究中,我们采用分子动力学模拟、QM/MM伞形采样模拟、酶活性测定、定点诱变和光谱分析来阐明FAD氧化为8-甲酰基FAD的机制。我们的结果表明,一个催化水分子,而不是任何催化氨基酸,作为一个通用碱使FAD上的C8甲基去质子化,从而促进醌甲基互变异构体中间体的形成。随后,一个氧分子氧化这个中间体,产生一个C8甲基过氧化氢阴离子,该阴离子被质子化并解离形成OHC-RP和OH。在FAD氧化为8-甲酰基FAD的过程中,限速步骤的能垒计算为22.8千卡/摩尔,这与实验观察到的所需14小时转化时间相对应。此外,阐明的氧化机制表明,8-甲酰基FAD的自催化形成分别依赖于近端的精氨酸和丝氨酸残基R87和S94。酶活性测定证实,R87突变为赖氨酸会使k值降低到野生型的75%,而突变为组氨酸则会导致活性完全丧失。同样,突变体S94I也会导致酶失活。这种依赖性的产生是因为亲核OH基团和醌甲基互变异构体中间体通过R87和S94提供的非共价相互作用而得以稳定。这些发现不仅解释了每个反应步骤的机制细节,还阐明了R87和S94在8-甲酰基FAD氧化成熟过程中的功能作用,从而为开发具有增强氧化还原特性的新型黄素酶提供了关键的理论支持。
