Your search keyword '"Tao, Jinjin"' showing total 2 results

1. Simulated warming enhances the responses of microbial N transformations to reactive N input in a Tibetan alpine meadow.

Author

Zhang Y, Zhang N, Yin J, Zhao Y, Yang F, Jiang Z, Tao J, Yan X, Qiu Y, Guo H, and Hu S

Subjects

Carbon, Ecosystem, Grassland, Nitrogen, Tibet, Soil, Soil Microbiology

Abstract

Alpine ecosystems worldwide are characterized with high soil organic carbon (C) and low mineral nitrogen (N). Climate warming has been predicted to stimulate microbial decomposition and N mineralization in these systems. However, experimental results are highly variable, and the underlying mechanisms remain unclear. We examined the effects of warming, N input, and their combination on soil N pools and N-cycling microbes in a field manipulation experiment. Special attention was directed to the ammonia-oxidizing bacteria and archaea, and their mediated N-cycling processes (transformation rates and N 2 O emissions) in the third plant growing season after the treatments were initiated. Nitrogen input (12 g m -2 y -1 ) alone significantly increased soil mineral N pools and plant N uptake, and stimulated the growth of AOB and N 2 O emissions in the late growing season. While warming (by 1.4 °C air temperature) alone did not have significant effects on most parameters, it amplified the effects of N input on soil N concentrations and AOB abundance, eliciting a chain reaction that increased nitrification potential (+83%), soil NO 3 - -N (+200%), and N 2 O emissions (+412%) across the whole season. Also, N input reduced AOB diversity but increased the dominance of genus Nitrosospira within the AOB community, corresponding to the increased N 2 O emissions. These results showed that a small temperature increase in soil may significantly enhance N losses through NO 3 - leaching and N 2 O emissions when mineral N becomes available. These findings suggest that interactions among global change factors may predominantly affect ammonia-oxidizing microbes and their mediated N-cycling processes in alpine ecosystems under future climate change scenarios., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2020 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2020

2. Vertical distribution of ammonia-oxidizing microorganisms across a soil profile of the Chinese Loess Plateau and their responses to nitrogen inputs.

Author

Tao J, Bai T, Xiao R, Wang P, Wang F, Duryee AM, Wang Y, Zhang Y, and Hu S

Subjects

China, Nitrification, Oxidation-Reduction, Ammonia metabolism, Archaea metabolism, Bacteria metabolism, Nitrogen metabolism, Soil Microbiology

Abstract

Ammonia-oxidizing archaea (AOA) and bacteria (AOB) oxidize ammonia into nitrite, the first and rate-limiting step of microbial nitrification, and exert major controls over soil nitrogen transformations. The Loess Plateau in northwest China is characterized with deep soils that are often exposed to the surface and reactive nitrogen (N) inputs due to erosion and human removal of the surface soil. However, few have examined the distribution of AOA and AOB along the profile of Loess Plateau soils and their responses to N inputs. We examined the abundance and diversity of AOA and AOB along the soil profile (0-100cm) and their responses to two levels of N inputs (low at 10, and high at 100μgNg -1 soil) in a 55-d incubation experiment. While AOB were most numerous in the surface soil (0-20cm), AOA were most abundant in the subsoils (20-40 and 40-60cm), suggesting a niche differentiation between AOA and AOB along the soil profile. High N input increased AOB nearly ten-fold in the upper two layers of soils (0-20 and 20-40cm) and sixteen to twenty-five fold in the deeper soil layers (40-60, 60-80 and 80-100cm). However, it only increased AOA by 7% (40-60cm) to 48% (20-40cm). In addition, potential nitrification rate and N 2 O emissions correlated only with AOB. Finally, high N input significantly increased AOB diversity and led to nitrite accumulation in deep soil layers (60-80 and 80-100cm). Together, our results showed that high N input can significantly alter the diversity and function of ammonia-oxidizing microbes in the deep soil of Loess Plateau, suggesting the need to examine the generality of the observed changes and their potential environmental impacts., (Copyright © 2018 Elsevier B.V. All rights reserved.)

Published

2018