Mingjun Zhu , Yonglin Bo , Yufeng Sun , Yaru Wang , Yuhua Su , Qiyou Liu , Yingying Gu
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引用次数: 0
Abstract
Aromatic amines, the common organic metabolites of chemical raw materials and herbicides, has attracted wide attention due to its difficult degradation and carcinogenic risk. This study aims to use microbial co-metabolism technology to efficiently degrade p-chloroaniline (PCA), which is a highly toxic aromatic amine. From the perspective of enzyme substrate specificity, a system for efficient degradation of PCA using aniline as a co-substrate was constructed. The degradation conditions were optimized by response surface methodology, and the degradation efficiency of PCA was 81.12 % (50 mg/L). Further, the co-metabolism mechanism was clarified by multiple methods. Enzyme activity assay preliminarily showed that aniline induced catechol 2,3-dioxygenase activity. Then the intermediates of PCA and aniline degradation was identified and two possible PCA degradation pathways were proposed. Transcriptomic analyzed the molecular mechanism of aniline-enhanced PCA degradation: Nitrogen utilization efficiency was accelerated by up-regulation of nitrogen metabolism-related genes. Several oxidoreductases including catechol 2,3-dioxygenase were significantly up-regulated. TCA cycle and ATP synthesis were accelerated, facilitating cell metabolism and energy supply. The work contributes a worthy theory for the remediation of PCA-aniline co-contaminated sites.
期刊介绍:
The Biochemical Engineering Journal aims to promote progress in the crucial chemical engineering aspects of the development of biological processes associated with everything from raw materials preparation to product recovery relevant to industries as diverse as medical/healthcare, industrial biotechnology, and environmental biotechnology.
The Journal welcomes full length original research papers, short communications, and review papers* in the following research fields:
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Bioseparations including scale-up and protein refolding/renaturation
Environmental Bioengineering including bioconversion, bioremediation, and microbial fuel cells
Bioreactor Systems including characterization, optimization and scale-up
Bioresources and Biorefinery Engineering including biomass conversion, biofuels, bioenergy, and optimization
Industrial Biotechnology including specialty chemicals, platform chemicals and neutraceuticals
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Cell Therapies and Stem Cells including pluripotent, mesenchymal and hematopoietic stem cells; immunotherapies; tissue-specific differentiation; and cryopreservation
Metabolic Engineering, Systems and Synthetic Biology including OMICS, bioinformatics, in silico biology, and metabolic flux analysis
Protein Engineering including enzyme engineering and directed evolution.