Coulter C, Hamilton J T, McRoberts W C, Kulakov L, Larkin M J, Harper D B
Microbial Biochemistry Section, School of Agriculture and Food Science, Belfast, United Kingdom.
Appl Environ Microbiol. 1999 Oct;65(10):4301-12. doi: 10.1128/AEM.65.10.4301-4312.1999.
A novel dehalogenating/transhalogenating enzyme, halomethane:bisulfide/halide ion methyltransferase, has been isolated from the facultatively methylotrophic bacterium strain CC495, which uses chloromethane (CH(3)Cl) as the sole carbon source. Purification of the enzyme to homogeneity was achieved in high yield by anion-exchange chromatography and gel filtration. The methyltransferase was composed of a 67-kDa protein with a corrinoid-bound cobalt atom. The purified enzyme was inactive but was activated by preincubation with 5 mM dithiothreitol and 0.5 mM CH(3)Cl; then it catalyzed methyl transfer from CH(3)Cl, CH(3)Br, or CH(3)I to the following acceptor ions (in order of decreasing efficacy): I(-), HS(-), Cl(-), Br(-), NO(2)(-), CN(-), and SCN(-). Spectral analysis indicated that cobalt in the native enzyme existed as cob(II)alamin, which upon activation was reduced to the cob(I)alamin state and then was oxidized to methyl cob(III)alamin. During catalysis, the enzyme shuttles between the methyl cob(III)alamin and cob(I)alamin states, being alternately demethylated by the acceptor ion and remethylated by halomethane. Mechanistically the methyltransferase shows features in common with cobalamin-dependent methionine synthase from Escherichia coli. However, the failure of specific inhibitors of methionine synthase such as propyl iodide, N(2)O, and Hg(2+) to affect the methyltransferase suggests significant differences. During CH(3)Cl degradation by strain CC495, the physiological acceptor ion for the enzyme is probably HS(-), a hypothesis supported by the detection in cell extracts of methanethiol oxidase and formaldehyde dehydrogenase activities which provide a metabolic route to formate. 16S rRNA sequence analysis indicated that strain CC495 clusters with Rhizobium spp. in the alpha subdivision of the Proteobacteria and is closely related to strain IMB-1, a recently isolated CH(3)Br-degrading bacterium (T. L. Connell Hancock, A. M. Costello, M. E. Lidstrom, and R. S. Oremland, Appl. Environ. Microbiol. 64:2899-2905, 1998). The presence of this methyltransferase in bacterial populations in soil and sediments, if widespread, has important environmental implications.
一种新型的脱卤/转卤酶,即卤代甲烷:二硫化物/卤离子甲基转移酶,已从兼性甲基营养细菌菌株CC495中分离出来,该菌株以氯甲烷(CH₃Cl)作为唯一碳源。通过阴离子交换色谱法和凝胶过滤,以高产率将该酶纯化至同质。甲基转移酶由一个67 kDa的蛋白质组成,该蛋白质含有一个与类咕啉结合的钴原子。纯化后的酶无活性,但与5 mM二硫苏糖醇和0.5 mM CH₃Cl预孵育后可被激活;然后它催化甲基从CH₃Cl、CH₃Br或CH₃I转移至以下受体离子(按效力递减顺序):I⁻、HS⁻、Cl⁻、Br⁻、NO₂⁻、CN⁻和SCN⁻。光谱分析表明,天然酶中的钴以钴胺素(II)的形式存在,激活后还原为钴胺素(I)状态,然后氧化为甲基钴胺素(III)。在催化过程中,该酶在甲基钴胺素(III)和钴胺素(I)状态之间穿梭,交替地被受体离子去甲基化并被卤代甲烷重新甲基化。从机制上讲,甲基转移酶表现出与大肠杆菌中钴胺素依赖性甲硫氨酸合酶的共同特征。然而,甲硫氨酸合酶的特异性抑制剂如碘化丙基、N₂O和Hg²⁺未能影响甲基转移酶,这表明存在显著差异。在菌株CC495降解CH₃Cl的过程中,该酶的生理受体离子可能是HS⁻,甲硫醇氧化酶和甲醛脱氢酶活性在细胞提取物中的检测结果支持了这一假设,这些活性提供了一条通向甲酸的代谢途径。16S rRNA序列分析表明,菌株CC495与变形菌门α亚群中的根瘤菌属聚类,并且与菌株IMB - 1密切相关,IMB - 1是最近分离出的一种可降解CH₃Br的细菌(T. L. Connell Hancock、A. M. Costello、M. E. Lidstrom和R. S. Oremland,《应用与环境微生物学》64:2899 - 2905,1998)。如果土壤和沉积物中的细菌群体中广泛存在这种甲基转移酶,将具有重要的环境意义。
