Rudrashetti Ashwinkumar P, Jadeja Niti B, Gandhi Deepa, Juwarkar Asha A, Sharma Abhinav, Kapley Atya, Pandey R A
CSIR-National Environmental Engineering Research Institute (NEERI), Nagpur, India.
World J Microbiol Biotechnol. 2017 Jun;33(6):121. doi: 10.1007/s11274-017-2284-8. Epub 2017 May 18.
The engineered-Soil Aquifer Treatment (e-SAT) system was exploited for the biological degradation of Sulfamethoxazole (SMX) which is known to bio-accumulate in the environment. The fate of SMX in soil column was studied through laboratory simulation for a period of 90 days. About 20 ppm SMX concentration could be removed in four consecutive cycles in e-SAT. To understand the microbial community change and biological degradation of SMX in e-SAT system, metagenomic analysis was performed for the soil samples before (A-EBD) and after SMX exposure (B-EBD) in the e-SAT. Four bacterial phyla were found to be present in both the samples, with sample B-EBD showing increased abundance for Actinobacteria, Bacteroidetes, Firmicutes and decreased Proteobacterial abundance compared to A-EBD. The unclassified bacteria were found to be abundant in B-EBD compared to A-EBD. At class level, classes such as Bacilli, Negativicutes, Deltaproteobacteria, and Bacteroidia emerged in sample B-EBD owing to SMX treatment, while Burkholderiales and Nitrosomonadales appeared to be dominant at order level after SMX treatment. Furthermore, in response to SMX treatment, the family Nitrosomonadaceae appeared to be dominant. Pseudomonas was the most dominating bacterial genus in A-EBD whereas Cupriavidus dominated in sample B-EBD. Additionally, the sulfur oxidizing bacteria were enriched in the B-EBD sample, signifying efficient electron transfer and hence organic molecule degradation in the e-SAT system. Results of this study offer new insights into understanding of microbial community shift during the biodegradation of SMX.
工程土壤含水层处理(e-SAT)系统被用于磺胺甲恶唑(SMX)的生物降解,已知该物质会在环境中生物累积。通过实验室模拟对SMX在土壤柱中的归宿进行了为期90天的研究。在e-SAT中,连续四个循环可去除约20 ppm的SMX浓度。为了解e-SAT系统中SMX的微生物群落变化和生物降解情况,对e-SAT中SMX暴露前(A-EBD)和暴露后(B-EBD)的土壤样本进行了宏基因组分析。在两个样本中均发现存在四个细菌门,与A-EBD相比,样本B-EBD中放线菌门、拟杆菌门、厚壁菌门的丰度增加,变形菌门的丰度降低。与A-EBD相比,未分类细菌在B-EBD中更为丰富。在纲水平上,由于SMX处理,芽孢杆菌纲、厌氧杆菌纲、δ-变形菌纲和拟杆菌纲等纲出现在样本B-EBD中,而伯克霍尔德菌目和亚硝化单胞菌目在SMX处理后似乎在目水平上占主导地位。此外,响应SMX处理,亚硝化单胞菌科似乎占主导地位。假单胞菌是A-EBD中最主要的细菌属,而贪铜菌在样本B-EBD中占主导地位。此外,硫氧化细菌在B-EBD样本中富集,这表明在e-SAT系统中电子转移效率高,从而实现了有机分子的降解。本研究结果为理解SMX生物降解过程中的微生物群落变化提供了新的见解。
