Although soil nitrification has been studied intensively, with an effort to elucidate the relative contributions of both ammonia-oxidizing archaea (AOA) and bacteria (AOB), their relative contributions to N2O production remain unclear. Understanding the temperature- and depth-dependent activities of AOA and AOB, as well as production of N2O, is of great importance for predicting their responses to climate change. This work applied the recently discovered AOB inhibitor, octyne, to soil microcosms incubated at different temperatures (20, 30, 40 degrees C) in order to differentiate ammonia-oxidation potential and N2O production by AOA and AOB, in soils from different land uses and depth. Our results showed that surface soils (0-15 cm) possessed significantly greater ammonia oxidation potential than subsurface soils (30-45 cm) at all temperatures tested, and that AOA-associated nitrification potential dominated at higher temperatures for both summer and autumn soils. The accumulation of N2O was only detected in surface agricultural soil at 30 degrees C and positively correlated with nitrite accumulation within the incubation period. The detected N2O production, along with most nitrification potential activity, were attributed to AOB, implicating AOB as major producers of this greenhouse gas in the tested agricultural soil. Higher ammonia-oxidation activity and N2O production within surface agricultural soil reinforces the importance of agricultural surface soils as sources of nitrification and N2O production, with potential implications for land management practices and responses to climate change.

• 出版日期2018-5