Shao BZhang RXu XNiu LFan KLin ZZhao LZhou XRen NDUU-JONG LEEChen C.2022-11-162022-11-1620220013936Xhttps://www.scopus.com/inward/record.uri?eid=2-s2.0-85128823727&doi=10.1021%2facs.est.1c08113&partnerID=40&md5=d4873589de56df4316a4288766e4e532https://scholars.lib.ntu.edu.tw/handle/123456789/625416Increasing global deoxygenation has widely formed oxygen-limited biotopes, altering the metabolic pathways of numerous microbes and causing a large greenhouse effect of nitrous oxide (N2O). Although there are many sources of N2O, denitrification is the sole sink that removes N2O from the biosphere, and the low-level oxygen in waters has been classically thought to be the key factor regulating N2O emissions from incomplete denitrification. However, through microcosm incubations with sandy sediment, we demonstrate here for the first time that the stress from oxygenated environments does not suppress, but rather boosts the complete denitrification process when the sulfur cycle is actively ongoing. This study highlights the potential of reducing N2O-driven greenhouse warming and fills a gap in pre-cognitions on the nitrogen cycle, which may impact our current understanding of greenhouse gas sinks. Combining molecular techniques and kinetic verification, we reveal that dominant inhibitions in oxygen-limited environments can interestingly undergo triple detoxification by cryptic sulfur and oxygen cycling, which may extensively occur in nature but have been long neglected by researchers. Furthermore, reviewing the present data and observations from natural and artificial ecosystems leads to the necessary revision needs of the global nitrogen cycle. © 2022 American Chemical Society. All rights reserved.denitrification; element cycling; functional genes; greenhouse gas; nitrous oxide reduction; triple detoxification[SDGs]SDG6[SDGs]SDG13Denitrification; Detoxification; Greenhouse effect; Greenhouse gases; Molecular oxygen; Nitrogen; Sulfur; Deoxygenations; Element cycling; Functional genes; Greenhouse warming; Greenhouses gas; Nitrogen cycles; Nitrous oxide; Nitrous oxide reduction; Oxide reduction; Triple detoxification; Nitrogen oxides; fresh water; nitrogen; nitrous oxide; oxygen; sulfur; sulfur; denitrification; detoxification; global warming; greenhouse effect; greenhouse gas; inhibition; metabolism; microcosm; nitrous oxide; oxygen consumption; reaction kinetics; sulfur cycle; Article; biogeochemical cycling; biotope; denitrification; detoxification; ecophysiology; ecosystem; estuary; gene expression; greenhouse; greenhouse gas; kinetics; microbial community; microcosm; nitrogen cycle; sediment; sewage treatment plant; steady state; sulfur cycle; water supply; denitrification; nitrogen cycle; Denitrification; Ecosystem; Nitrogen Cycle; Oxygen; Sulfurjournal article10.1021/acs.est.1c08113354160372-s2.0-85128823727