Advanced Water Management Centre , The University of Queensland , St. Lucia , Brisbane , QLD 4072 , Australia.
College of Environmental Science and Engineering and Key Laboratory of Environmental Biology and Pollution Control, Ministry of Education , Hunan University , Changsa 410082 , China.
Environ Sci Technol. 2018 May 1;52(9):5386-5397. doi: 10.1021/acs.est.7b04273. Epub 2018 Apr 16.
Free nitrous acid (FNA) exerts a broad range of antimicrobial effects on bacteria, although susceptibility varies considerably among microorganisms. Among nitrifiers found in activated sludge of wastewater treatment processes (WWTPs), nitrite-oxidizing bacteria (NOB) are more susceptible to FNA compared to ammonia-oxidizing bacteria (AOB). This selective inhibition of NOB over AOB in WWTPs bypasses nitrate production and improves the efficiency and costs of the nitrogen removal process in both the activated sludge and anaerobic ammonium oxidation (Anammox) system. However, the molecular mechanisms governing this atypical tolerance of AOB to FNA have yet to be understood. Herein we investigate the varying effects of the antimicrobial FNA on activated sludge containing AOB and NOB using an integrated metagenomics and label-free quantitative sequential windowed acquisition of all theoretical fragment ion mass spectra (SWATH-MS) metaproteomic approach. The Nitrosomonas genus of AOB, on exposure to FNA, maintains internal homeostasis by upregulating a number of known oxidative stress enzymes, such as pteridine reductase and dihydrolipoyl dehydrogenase. Denitrifying enzymes were upregulated on exposure to FNA, suggesting the detoxification of nitrite to nitric oxide. Interestingly, proteins involved in stress response mechanisms, such as DNA and protein repair enzymes, phage prevention proteins, and iron transport proteins, were upregulated on exposure to FNA. In addition enzymes involved in energy generation were also upregulated on exposure to FNA. The total proteins specifically derived from the NOB genus Nitrobacter was low and, as such, did not allow for the elucidation of the response mechanism to FNA exposure. These findings give us an understanding of the adaptive mechanisms of tolerance within the AOB Nitrosomonas to the biocidal agent FNA.
游离亚硝酸盐(FNA)对细菌具有广泛的抗菌作用,尽管不同微生物对其敏感性差异很大。在废水处理工艺(WWTP)的活性污泥中发现的硝化菌中,亚硝酸盐氧化菌(NOB)比氨氧化菌(AOB)更容易受到 FNA 的影响。这种对 WWTP 中 NOB 的选择性抑制绕过了硝酸盐的产生,提高了活性污泥和厌氧氨氧化(Anammox)系统中氮去除过程的效率和成本。然而,控制 AOB 对 FNA 这种非典型耐受性的分子机制尚未得到理解。在此,我们使用整合的宏基因组学和无标记定量顺序窗口采集所有理论片段离子质谱(SWATH-MS)宏蛋白质组学方法,研究了抗菌 FNA 对含有 AOB 和 NOB 的活性污泥的不同影响。AOB 的硝化单胞菌属在暴露于 FNA 时,通过上调许多已知的氧化应激酶,如蝶呤还原酶和二氢乳清酸脱氢酶,维持内部动态平衡。在暴露于 FNA 时,反硝化酶被上调,表明亚硝酸盐被解毒为一氧化氮。有趣的是,与应激反应机制相关的蛋白质,如 DNA 和蛋白质修复酶、噬菌体预防蛋白和铁转运蛋白,在暴露于 FNA 时被上调。此外,与能量生成相关的酶在暴露于 FNA 时也被上调。来自 NOB 属 Nitrobacter 的特定总蛋白含量较低,因此无法阐明对 FNA 暴露的反应机制。这些发现使我们了解了 AOB 硝化单胞菌对杀菌剂 FNA 的耐受的适应机制。
