Biodegradation of Phenol by Bacillus simplex: Characterization and Kinetics Study

Q2 Agricultural and Biological Sciences

Applied Environmental Biotechnology Pub Date : 2021-01-01 DOI:10.26789/aeb.2021.02.001

Mousa K. Magharbeh, Khaled M Khleifat, Mohammad A. Al-kafaween, Razan Saraireh, Moath Alqaraleh, H. Qaralleh, Amjad Al-Tarawneh, Muhamad O. Al-limoun, T. El-Hasan, T. Hujran, Salah H. Ajbour, N. Jarrah, Malik Amonov, Hamid Ali Nagi Al-Jamal

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引用次数: 3

Abstract

Phenol is one of the main pollutants that have a serious impact on the environment and can even be very critical to human health. The biodegradation of phenol can be considered an increasingly important pollution control process. In this study, the degradation of phenol by Bacillus simplex was investigated for the first time under different growth conditions. Six different initial concentrations of phenol were used as the primary substrate. Culture conditions had an important effect on these cells' ability to biodegrade phenol. The best growth of this organism and its highest biodegradation level of phenol were noticed at pH 7, temperature 28 °C, and periods of 36 and 96 h, respectively. The GC-MS analysis of the bacterial culture sample revealed that further degradation of the catechol by 1,2-dioxygenase produce a cis, cis-mucconic acid via ortho-pathway and/or by 2,3-dioxygenase into 2-hydroxymucconic semialdehyde via meta-pathway. The highest biodegradation rate was perceived at 700 mg/L initial phenol concentration. Approximately 90% of the phenol (700 mg / L) was removed in less than 96 hours of incubation time. It was found that the Haldane model best fitted the relationship between the specific growth rate and the initial phenol concentration, whereas the phenol biodegradation profiles with time could be adequately described by the modified Gompertz model. The obtained parameters from the Haldane equation are: 1.05 h−1, 9.14 ppm, and 329 ppm for Haldane's maximum specific growth rate, the half-saturation coefficient, and the Haldane’s growth kinetics inhibition coefficient, respectively. The Haldane equation fitted the experimental data by minimizing the sum of squared error (SSR) to 1.36 X 10-3.

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单纯芽孢杆菌降解苯酚:表征及动力学研究

苯酚是对环境有严重影响的主要污染物之一，甚至可能对人体健康非常关键。苯酚的生物降解可以被认为是一个日益重要的污染控制过程。本研究首次研究了单纯芽孢杆菌在不同生长条件下对苯酚的降解。六种不同初始浓度的苯酚作为主要底物。培养条件对这些细胞生物降解苯酚的能力有重要影响。在pH为7、温度为28℃、时间为36 h和96 h时，该菌的生长最佳，对苯酚的生物降解水平最高。细菌培养样品的GC-MS分析表明，1,2-双加氧酶通过正途径进一步降解儿茶酚生成顺式，顺式mucconic酸，或2,3-双加氧酶通过后途径进一步降解生成2-羟基mucconic半醛。苯酚初始浓度为700 mg/L时生物降解率最高。在不到96小时的孵育时间内，约90%的苯酚(700毫克/升)被去除。结果表明，Haldane模型能较好地拟合特定生长速率与苯酚初始浓度之间的关系，而改进的Gompertz模型能较好地描述苯酚随时间的生物降解曲线。由霍尔丹方程得到的霍尔丹最大比生长速率、半饱和系数和生长动力学抑制系数分别为1.05 h−1、9.14 ppm和329 ppm。Haldane方程通过最小化均方根误差(SSR)为1.36 X 10-3来拟合实验数据。

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

Applied Environmental Biotechnology Agricultural and Biological Sciences-Agricultural and Biological Sciences (miscellaneous)

CiteScore

3.70

自引率

0.00%

发文量