进一步挖掘克雷伯氏菌 CD33 的儿茶酚生物降解代谢潜力。

IF 8.1 2区 环境科学与生态学 Q1 ENVIRONMENTAL SCIENCES
Xinger Xie , Qibai Tian , Jiahui Liu , Xuan Zhang , Xinyu Ye , Xian Zhang
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引用次数: 0

摘要

微生物介导的酚类污染物(如邻苯二酚)降解一直是污水处理的关键问题,而开发菌种资源、充分表征功能微生物对有毒难降解邻苯二酚的代谢潜力是关键和值得研究的问题。本研究对最初从苯酚污染环境中分离出的多达 32 株菌株进行了系统发育,将其归属于克雷伯氏菌属,并鉴定出其具有降解邻苯二酚的能力,其中 CD33 菌株是最优秀的菌株。单因素实验表明,在温度为 35 ℃、初始 pH 值为 7.0、接种量为 30.0% (v/v) 的条件下,CD33 菌株能高效降解邻苯二酚。为了初步验证儿茶酚生物降解的可能途径,检测到了初始酶(即儿茶酚 1,2 二氧合酶)和相应代谢中间产物(即顺式、顺式粘多酸)的浓度变化,这表明菌株 CD33 可以通过正交裂解途径降解儿茶酚。此外,本研究还采用了全基因组鉴定、同源建模和基因表达分析相结合的方法,阐明了儿茶酚降解的完整途径,特别是其中由 CMBL 基因介导的新分支负责将(+)-木瓜内酯直接转化为 3-oxoadipic 酸。总之,这项研究扩展了我们对克雷伯氏菌属降解邻苯二酚的认识,为污染物修复的实际应用提供了另一种有前景的途径。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Further exploitation of metabolic potential for catechol biodegradation of Klebsiella sp. CD33

Further exploitation of metabolic potential for catechol biodegradation of Klebsiella sp. CD33
Microbial-mediated degradation of phenolic pollutants (e.g., catechol) has been a critical concern for sewage treatment, while exploiting the strain resources and fully characterizing the metabolic potential of functional microbes for toxic refractory catechol are the key and study-worthy issues. In this study, up to 32 strains originally isolated from phenol-contaminated environments were phylogenetically affiliated with the genus Klebsiella and identified to have the ability of catechol degradation, with strain CD33 as the excellent one. Single-factor experiments determined that strain CD33 exhibited a highly efficient catechol degradation under the conditions of temperature 35 °C, initial pH value of 7.0, and inoculum volume of 30.0% (v/v). To preliminarily validate the possible pathway of catechol biodegradation, concentration variation of the initial enzyme (i.e., catechol 1,2 dioxygenase) and the corresponding metabolic intermediate (i.e., cis,cis-muconic acid) were detected, suggesting that strain CD33 can degrade the catechol uniquely via the ortho-cleavage pathway. Furthermore, a combination of genome-wide identification, homologous modeling, and gene expression analysis was employed to elucidate the complete pathway of catechol degradation, especially in which a novel branch mediated by CMBL gene was responsible for the direct conversion of (+)-muconolactone into 3-oxoadipic acid. Collectively, this study extends our understanding of catechol degradation of Klebsiella spp., which may provide an alternative promising avenue for the practical application of pollutant remediation.
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来源期刊
Chemosphere
Chemosphere 环境科学-环境科学
CiteScore
15.80
自引率
8.00%
发文量
4975
审稿时长
3.4 months
期刊介绍: Chemosphere, being an international multidisciplinary journal, is dedicated to publishing original communications and review articles on chemicals in the environment. The scope covers a wide range of topics, including the identification, quantification, behavior, fate, toxicology, treatment, and remediation of chemicals in the bio-, hydro-, litho-, and atmosphere, ensuring the broad dissemination of research in this field.
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