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来自EDTA降解菌BNC1的EDTA单加氧酶的纯化与特性分析

Purification and characterization of EDTA monooxygenase from the EDTA-degrading bacterium BNC1.

作者信息

Payne J W, Bolton H, Campbell J A, Xun L

机构信息

Department of Microbiology, Washington State University, Pullman, Washington 99164-4233, USA.

出版信息

J Bacteriol. 1998 Aug;180(15):3823-7. doi: 10.1128/JB.180.15.3823-3827.1998.

DOI:10.1128/JB.180.15.3823-3827.1998
PMID:9683478
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC107365/
Abstract

The synthetic chelating agent EDTA can mobilize radionuclides and heavy metals in the environment. Biodegradation of EDTA should reduce this mobilization. Although several bacteria have been reported to mineralize EDTA, little is known about the biochemistry of EDTA degradation. Understanding the biochemistry will facilitate the removal of EDTA from the environment. EDTA-degrading activities were detected in cell extracts of bacterium BNC1 when flavin mononucleotide (FMN), NADH, and O2 were present. The degradative enzyme system was separated into two different enzymes, EDTA monooxygenase and an FMN reductase. EDTA monooxygenase oxidized EDTA to glyoxylate and ethylenediaminetriacetate (ED3A), with the coconsumption of FMNH2 and O2. The FMN reductase provided EDTA monooxygenase with FMNH2 by reducing FMN with NADH. The FMN reductase was successfully substituted in the assay mixture by other FMN reductases. EDTA monooxygenase was purified to greater than 95% homogeneity and had a single polypeptide with a molecular weight of 45,000. The enzyme oxidized both EDTA complexed with various metal ions and uncomplexed EDTA. The optimal conditions for activity were pH 7.8 and 35 degreesC. Kms were 34.1 microM for uncomplexed EDTA and 8.5 microM for MgEDTA2-; this difference in Km indicates that the enzyme has greater affinity for MgEDTA2-. The enzyme also catalyzed the release of glyoxylate from nitrilotriacetate and diethylenetriaminepentaacetate. EDTA monooxygenase belongs to a small group of FMNH2-utilizing monooxygenases that attack carbon-nitrogen, carbon-sulfur, and carbon-carbon double bonds.

摘要

合成螯合剂乙二胺四乙酸(EDTA)能够使环境中的放射性核素和重金属发生迁移。EDTA的生物降解作用应可减少这种迁移现象。尽管已有报道称几种细菌可使EDTA矿化,但对于EDTA降解的生物化学过程却知之甚少。了解其生物化学过程将有助于从环境中去除EDTA。当存在黄素单核苷酸(FMN)、烟酰胺腺嘌呤二核苷酸(NADH)和氧气时,在细菌BNC1的细胞提取物中检测到了EDTA降解活性。降解酶系统可分为两种不同的酶,即EDTA单加氧酶和FMN还原酶。EDTA单加氧酶将EDTA氧化为乙醛酸和乙二胺三乙酸(ED_{3}A),同时消耗FMNH_{2}和氧气。FMN还原酶通过利用NADH还原FMN为EDTA单加氧酶提供FMNH_{2}。在测定混合物中,FMN还原酶成功地被其他FMN还原酶所替代。EDTA单加氧酶被纯化至纯度大于95%,且具有一条分子量为45,000的单一多肽链。该酶既能氧化与各种金属离子络合的EDTA,也能氧化未络合的EDTA。其活性的最佳条件为pH 7.8和35℃。未络合的EDTA的米氏常数(K_{m})为34.1 μM,MgEDTA^{2-}的K_{m}为8.5 μM;K_{m}的这种差异表明该酶对MgEDTA^{2-}具有更高的亲和力。该酶还催化从次氮基三乙酸和二乙烯三胺五乙酸中释放出乙醛酸。EDTA单加氧酶属于一小类利用FMNH_{2}的单加氧酶,这类酶可攻击碳 - 氮键、碳 - 硫键和碳 - 碳双键。

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