Assessing the biodegradation efficiency and underlying molecular pathway of strain AEPI 0-0: a newly isolated tetracycline-degrading Serratia marcescens

Huike Ye, Zhennan Wang, Xiaojing Li, Yang Sun, Lixia Zhao, Mohan Bai, Liping Weng, Yongtao Li
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Abstract

With the development of aquaculture and animal husbandry, the use of tetracycline antibiotics (TCs) has increased, thereby leading to negative impacts on naturally-occurring microbial communities. Microbial degradation is an effective and environmental friendly method to degrade TCs, but so far, very few cultured strains are suitable for this purpose. In this study, a bacterial strain, AEPI 0-0, with the potential to degrade TCs was isolated, with phylogenetic analysis subsequently classifying it as Serratia marcescens. The single factors that affected the strain’s degradation efficiency on TC-HCl were then studied using an orthogonal experimental design. The results showed that the biodegradation efficiency could reach about 85% on the 4th day, with the process following the degradation kinetic equation. Subsequently, RNA-seq was used and the differentially expressed genes(DEGs)were annotated and analyzed. The results showed that more genes were enriched in biological processes such as amino acid metabolism, carbohydrate metabolism, and cell membrane transport metabolism pathway. In addition, TetR family transcription factors may play an important role in the physiological process of AEPI 0-0 tolerance and degradation of tetracycline. In conclusion, a Serratia marcescens strain with high potential for TCs degradation was obtained, with the conditions for maximum degradation efficiency subsequently optimized, changes in the metabolic pathways were also preliminarily discussed. This strain could potentially be applied for the bioremediation of soil and water contaminated by TCs antibiotics. At the same time, this study also provides strains as well as theoretical support for microbial-based remediation of the environment.
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新分离的四环素降解粘质沙雷菌AEPI 0-0的生物降解效率和潜在分子途径的评估
随着水产畜牧业的发展,四环素类抗生素(TCs)的使用不断增加,从而对自然存在的微生物群落造成负面影响。微生物降解是一种有效的、环境友好的降解TCs的方法,但迄今为止,很少有培养菌株适合于这一目的。在本研究中,分离出一株具有降解TCs潜力的菌株AEPI 0-0,通过系统发育分析将其归类为粘质沙雷氏菌。采用正交试验设计研究了影响菌株对TC-HCl降解效率的单因素。结果表明,第4天生物降解效率可达85%左右,降解过程符合降解动力学方程。随后,使用RNA-seq对差异表达基因(DEGs)进行注释和分析。结果表明,氨基酸代谢、碳水化合物代谢和细胞膜转运代谢途径等生物过程中富集的基因较多。此外,TetR家族转录因子可能在AEPI 0-0耐受和四环素降解的生理过程中发挥重要作用。综上所述,获得了一株对TCs具有高降解潜力的粘质沙雷菌,并对其降解效率最大化的条件进行了优化,初步探讨了其代谢途径的变化。该菌株可用于TCs类抗生素污染土壤和水体的生物修复。同时,本研究也为微生物修复环境提供了菌株和理论支持。
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