Eco-friendly biotransformation of penicillin G by free and immobilized marine halophilic Bacillus pseudomycoides AH1

IF 3 4区生物学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY

Annals of Microbiology Pub Date : 2024-08-20 DOI:10.1186/s13213-024-01774-7

Aida M. Farag, Hasnaa E-B. Ghonam, Aliaa M. El-Borai

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引用次数: 0

Abstract

Several antibiotics are partially metabolized by patients after administration and end up in municipal sewage systems. The fate of biodegradation in aquatic environments and the role of biodegradation in the development of bacterial resistance are poorly understood. Thus, as a crucial step in an environmental risk assessment, the biodegradability of many therapeutically significant antibiotics was investigated. A marine halophilic bacteria that degrades penicillin G (PEN-G) was isolated and identified based on morphology, physio-biochemical characteristics, and 16S rDNA sequences as Bacillus pseudomycoides AH1 (accession no. MF037698). The effects of various concentrations of PEN-G and carbon and nitrogen sources on the biotransformation ability at 30°C and pH 7.0 were evaluated. Cells grown in medium supplemented with glucose as an additional carbon source and yeast extract as a nitrogen source exhibited maximal PEN-G biotransformation efficiency and rate (71.678% ±1.28 and 2.99 mg/h, respectively). The culture conditions for B. pseudomycoides AH1 cells were optimized using a Plackett–Burman design (PBD). Six key determinants (p < 0.05) significantly affected the process outcome, as deduced by regression analysis of the PBD data, and modified MSM broth achieved PEN-G biotransformation efficiency (100%) under aerobic shaking conditions at 35°C, irrespective of HPLC analysis. Additionally, the present investigation could strongly support the application of immobilization approaches for the removal of PEN-G-contaminated environmental sites. To the best of the authors’ knowledge, this is the first detailed study on the efficient biotransformation of PEN-G by an alginate-bacteria system as a simple, green, and inexpensive process, as well as a promising method.

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游离和固定海洋嗜卤杆菌 AH1 对青霉素 G 的生态友好型生物转化

有几种抗生素在用药后会被患者部分代谢，最终进入城市污水系统。人们对生物降解在水生环境中的命运以及生物降解在细菌耐药性产生过程中的作用知之甚少。因此，作为环境风险评估的关键步骤，我们对许多具有重要治疗作用的抗生素的生物降解性进行了调查。根据形态学、物理生化特征和 16S rDNA 序列，分离并鉴定出一种可降解青霉素 G（PEN-G）的海洋嗜卤细菌--假丝酵母菌 AH1（登录号：MF037698）。在 30°C、pH 值为 7.0 的条件下，评估了不同浓度的 PEN-G、碳源和氮源对生物转化能力的影响。在添加葡萄糖作为额外碳源和酵母提取物作为氮源的培养基中生长的细胞表现出最高的 PEN-G 生物转化效率和速率（分别为 71.678% ±1.28 和 2.99 mg/h）。采用普拉克特-伯曼设计（PBD）对假丝酵母 AH1 细胞的培养条件进行了优化。通过对 PBD 数据进行回归分析，推断出六个关键决定因素（p < 0.05）对工艺结果有显著影响，改良的 MSM 肉汤在 35°C 好氧振荡条件下实现了 PEN-G 生物转化效率（100%），与 HPLC 分析结果无关。此外，本研究还为应用固定化方法清除受 PEN-G 污染的环境场地提供了有力支持。据作者所知，这是首次详细研究海藻酸盐-细菌系统对 PEN-G 的高效生物转化，这是一种简单、绿色、廉价的工艺，也是一种很有前景的方法。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Annals of Microbiology 生物-生物工程与应用微生物

CiteScore

6.40

自引率

0.00%

发文量

审稿时长

3.2 months

期刊介绍： Annals of Microbiology covers these fields of fundamental and applied microbiology: general, environmental, food, agricultural, industrial, ecology, soil, water, air and biodeterioration. The journal’s scope does not include medical microbiology or phytopathological microbiology. Papers reporting work on bacteria, fungi, microalgae, and bacteriophages are welcome. Annals of Microbiology publishes Review Articles, Original Articles, Short Communications, and Editorials. Originally founded as Annali Di Microbiologia Ed Enzimologia in 1940, Annals of Microbiology is an official journal of the University of Milan.