精噁唑禾草灵降解菌株Rhodococcus sp.DSB-1分离鉴定、降解机制及其应用研究

【目的】分离并鉴定精噁唑禾草灵高效降解菌株,为开发高效降解菌剂,强化精噁唑禾草灵原位修复,保证黄瓜产品安全提供菌株资源和理论依据。【方法】利用富集培养的方法分离降解菌株,并通过形态学、生理生化特征和16S rRNA基因进化分析进行鉴定;HPLC/MS鉴定菌株降解精噁唑禾草灵的中间产物,采用鸟枪法建库克隆降解过程中关键的水解酶基因,并进行异源表达,利用Michaelis-Menten双倒数曲线图测定酶动力学参数;通过正交试验确定菌株液态发酵参数,并通过对黄瓜灌根接种的方式,研究降解菌株对黄瓜根际土壤中精噁唑禾草灵的降解以及甘露醇对降解效率的强化作用。【结果】Rhodococcus sp. DSB-1在24 h内能将100 mg/L精噁唑禾草灵完全转化为精噁唑禾草灵酸,降解最适温度和pH分别为30℃和8.0。克隆得到一个精噁唑禾草灵水解酶基因,命名为pepE。水解酶PepE对精噁唑禾草灵的K_m为28.2μmol/L,k_(cat)/K_m为11.0 L/(μmol·s)。在发酵温度30℃、通气量1:0.4、搅拌速度200 r/min、培养时间48 h条件下,液态发酵所得菌剂对精噁唑禾草灵的降解效率最高。投加至黄瓜根际的菌株DSB-1可以在黄瓜根系定殖,12d内完全降解黄瓜根际环境中10mg/kg的精噁唑禾草灵。此外还发现添加甘露醇可强化菌株的修复能力,降解效率相对于未添加的处理提高14.8%。【结论】菌株DSB-1具有原位修复精噁唑禾草灵污染土壤的潜力。     

The enantioselective enrichment,metabolism, and toxicity of fenoxaprop-ethyl and its metabolites in zebrafish

To investigate the impacts of the widely used chiral herbicide fenoxaprop-ethyl (FE) on aquatic organisms, the enrichment, metabolism, acute toxicity, and oxidative stress of fenoxaprop-ethyl and its main metabolites fenoxaprop (FA), ethyl-2-(4-hydroxyphenoxy)propanoate (EHPP), 2-(4-hydroxyphenoxy)propanoic acid (HPPA), and 6-chloro-2,3-dihydrobenzoxazol-2-one (CDHB) in zebrafish were studied. The enantioselectivity of fenoxaprop-ethyl and its chiral metabolites was also determined. Fenoxaprop-ethyl quickly degraded in zebrafish by aquatic exposure. FA, HPPA, and CDHB were the main metabolites that were enriched in the zebrafish. In the metabolism experiment, the half-lives of the metabolites were 0.92–1.72 days in zebrafish. The R-enantiomers of FA and HPPA were preferentially enriched and metabolized with enantiomeric fractions (EFs) of 0.65–0.85. According to the 96-h acute toxicity, FA, HPPA, EHPP, and CDHB were less toxic to zebrafish than FE, following the order of FE > CDHB > EHPP > FA > HPPA. The S-enantiomers of FE, FA, CDHB, and EHPP were more toxic than the R-enantiomers. FE and its metabolites could significantly increase catalase (CAT) and superoxide dismutase (SOD) activity and the malondialdehyde (MDA) content in gill and liver tissues, indicating their oxidative stress, and these effects were also enantioselective. This work could supply more information for evaluating the risks of fenoxaprop-ethyl on aquatic organisms concerning their metabolites and enantiomers.