来自荚膜甲基球菌（巴斯德菌株）的可溶性甲烷单加氧酶的停流动力学研究。

A stopped-flow kinetic study of soluble methane mono-oxygenase from Methylococcus capsulatus (Bath).

作者信息

Green J, Dalton H

机构信息

Department of Biological Sciences, University of Warwick, Coventry, U.K.

出版信息

Biochem J. 1989 Apr 1;259(1):167-72. doi: 10.1042/bj2590167.

DOI:10.1042/bj2590167

PMID:2497729

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1138487/

Abstract

The roles of the three protein components of soluble methane mono-oxygenase were investigated by the use of rapid-reaction techniques. The transfer of electrons through the enzyme complex from NADH to methane/O2 was also investigated. 2. Electron transfer from protein C, the reductase component, to protein A, the hydroxylase component, was demonstrated. Protein C was shown to undergo a three-electron--one-electron catalytic cycle. The interaction of protein C with NADH was investigated. Reduction of protein C was shown to be rapid, and a charge-transfer interaction between reduced FAD and NAD+ was observed; this intermediate was also found in static titration experiments. Thus the binding of NADH, the reduction of protein C and the intramolecular transfer of electrons through protein C were shown to be much more rapid than the turnover rate of methane mono-oxygenase. 3. The rate of transfer of electrons from protein C to protein A was shown to be lower than the reduction of protein C but higher than the turnover rate of methane mono-oxygenase. Association of the proteins was not rate-limiting. The amount of protein A present in the system had a small effect on the rate of reduction of protein C, indicating some co-operativity between the two proteins. 4. Protein B was shown to prevent electron transfer between protein C and protein A in the absence of methane. On addition of saturating concentrations of methane electron transfer was restored. With saturating concentrations of methane and O2 the observed rate constant for the conversion of methane into methanol was 0.26 s-1 at 18 degrees C. 5. By the use of [2H4]methane it was demonstrated that C-H-bond breakage is likely to be the rate-limiting step in the conversion of methane into methanol.

摘要

利用快速反应技术研究了可溶性甲烷单加氧酶三种蛋白质组分的作用。还研究了电子通过酶复合物从NADH转移至甲烷/氧气的过程。2. 证实了电子从还原酶组分蛋白质C转移至羟化酶组分蛋白质A。蛋白质C显示经历三电子-单电子催化循环。研究了蛋白质C与NADH的相互作用。结果表明蛋白质C的还原很快，并且观察到还原型黄素腺嘌呤二核苷酸（FAD）与NAD⁺之间存在电荷转移相互作用；在静态滴定实验中也发现了这种中间体。因此，NADH的结合、蛋白质C的还原以及电子通过蛋白质C的分子内转移都比甲烷单加氧酶的周转速率快得多。3. 结果表明，电子从蛋白质C转移至蛋白质A的速率低于蛋白质C的还原速率，但高于甲烷单加氧酶的周转速率。蛋白质的缔合不是限速步骤。系统中存在的蛋白质A的量对蛋白质C的还原速率有微小影响，表明这两种蛋白质之间存在某种协同作用。4. 结果表明，在没有甲烷的情况下，蛋白质B可阻止蛋白质C与蛋白质A之间的电子转移。加入饱和浓度的甲烷后，电子转移得以恢复。在甲烷和氧气饱和浓度下，18℃时甲烷转化为甲醇的观测速率常数为0.26 s⁻¹。5. 通过使用[2H₄]甲烷证明，C-H键断裂可能是甲烷转化为甲醇的限速步骤。