Exposure to Environmentally Relevant Concentrations of Antibiotics Increases N 2 O Emissions and Delays Nitrate Removal: New Insights into Bacteriostatic Antibiotics at the Cellular Level

反硝化 化学 硝酸盐 环境化学 细胞内 氧化应激 活性氧 抗生素 一氧化二氮 生物化学 新陈代谢 细菌 一氧化氮 氧化还原 微生物 氧化磷酸化 四环素 活性氮物种 好氧反硝化 酶分析 氧气 微生物学 氮气 反硝化细菌 亚硝酸盐 生物物理学 代谢途径 氮气循环 转录组
作者
Xiang Li,Mengyuan Han,Shuting Shen,Yuqing Miao,Lingyan Qi,Rui Wan,Liangtao Ye
出处
期刊:Environmental Science & Technology [American Chemical Society]
卷期号:60 (1): 642-653 被引量:1
标识
DOI:10.1021/acs.est.5c09865
摘要

Antibiotics are being increasingly detected in the environment, threatening to perturb microbe-mediated nitrogen cycling. However, the cellular mechanisms through which subinhibitory concentrations of ribosome-targeting antibiotics affect denitrification and nitrous oxide (N2O) emissions remain inadequately understood. This study aimed to elucidate how tetracycline (TC), a representative ribosome-targeting antibiotic, interferes with denitrification pathways in Paracoccus denitrificans. We evaluated the effects of environmentally relevant concentration (ERC) of TC on nitrate removal kinetics, N2O production, cellular physiology, and transcription. The results indicated that TC delays nitrate removal and significantly increases N2O emissions without causing cell death. Enzyme activity assays revealed nonspecific inhibition of denitrification enzymes, whereas assessment of physiological responses and transcriptomic analyses uncovered disruptions in carbon metabolism and electron transport. TC inhibited protein synthesis, suppresses glucose utilization, and impairs electron transport, leading to intracellular redox imbalance and reactive oxygen species accumulation. Notably, this oxidative stress preferentially suppressed the activity of N2O reductase, a critical factor driving N2O accumulation. Collectively, our findings unveil a dual interference mechanism of TC at ERC, involving suppression of enzyme expression and enhancement of oxidative stress. This study has significant implications for understanding the microbial mechanisms underlying N2O emissions.
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