细菌对酚醚的攻击:一种酶系统脱甲基香草酸。
Bacterial attack on phenolic ethers: An enzyme system demethylating vanillic acid.
机构信息
Department of Virology and Bacteriology, University of Birmingham.
出版信息
Biochem J. 1967 Mar;102(3):826-41. doi: 10.1042/bj1020826.
Abstract
- A cell-free system from Pseudomonas fluorescens catalysed the oxidative demethylation and subsequent ring-cleavage of vanillate, with uptake of 2.5 moles of oxygen/mole of substrate. 2. Demethylation involved absorption of 0.5 mole of oxygen/mole, and required reduced glutathione (GSH) and nucleotide (probably NADPH) as cofactors, with further possible requirements, the natures of which are discussed. 3. Incomplete evidence suggested that the aromatic ring was opened via protocatechuate and the appropriate oxygenase, with absorption of 1 mole of oxygen/mole of substrate, eventually yielding beta-oxoadipate. 4. The methyl group was removed sequentially as formaldehyde, formate and carbon dioxide, the steps catalysed respectively by formaldehyde dehydrogenase, which required GSH and NAD(+), and formate dehydrogenase. Each enzyme was cytochrome-linked and accounted for absorption of 0.5mole of oxygen/mole of substrate. 5. All enzymes except formate dehydrogenase, which was a cell-wall enzyme, resided in the soluble fraction of the extract. The demethylase could not be resolved because of unknown cofactor requirements.
摘要
荧光假单胞菌的无细胞体系催化香草酸盐的氧化脱甲基和随后的环裂解,每摩尔底物吸收 2.5 摩尔氧气。
脱甲基涉及吸收 0.5 摩尔氧气/摩尔,需要还原型谷胱甘肽 (GSH) 和核苷酸(可能是 NADPH)作为辅助因子,可能还有其他需求,其性质正在讨论中。
不完整的证据表明,芳环通过原儿茶酸和适当的加氧酶打开,每摩尔底物吸收 1 摩尔氧气,最终生成β-氧代己二酸。
甲基依次被甲醛、甲酸盐和二氧化碳去除,这些步骤分别由需要 GSH 和 NAD(+)的甲醛脱氢酶和甲酸盐脱氢酶催化。每个酶都与细胞色素相连,占底物吸收 0.5mole 的氧气/摩尔。
除了作为细胞壁酶的甲酸盐脱氢酶外,所有酶都存在于提取物的可溶性部分中。由于未知的辅助因子需求,脱甲基酶无法解析。
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