Your search keyword '"Cai, Yun"' showing total 3 results

1. Additive effects of warming and grazing on fine-root decomposition and loss of nutrients in an alpine meadow.

Author

Zhou, Yang, Lv, Wang-Wang, Wang, Shi-Ping, Zhang, Li-Rong, Sun, Jian-Ping, Jiang, Li-Li, Liu, Pei-Pei, Wang, Qi, Li, Bo-Wen, Wang, A, Hong, Huan, Zhang, Su-Ren, Xia, Lu, Ji, Nan, Xie, Zheng-Xin, Luo, Cai-Yun, Zhang, Zhen-Hua, Wang, Chang-Hui, Wang, Jin-Zhi, and Yang, Ci

Subjects

MOUNTAIN meadows, GRAZING, NUTRIENT cycles, CARBON cycle, SOIL fertility, NITROGEN in soils, PLATEAUS

Abstract

Fine-root decomposition is a critical process regulating ecosystem carbon cycles and affecting nutrient cycling and soil fertility. However, whether interaction between warming and grazing affects fine-root decomposition is still under-researched in natural grasslands. A two-factorial experiment with asymmetric warming (i.e. daytime vs. nighttime and growing season vs. nongrowing season) and moderate grazing (i.e. about average 50% forage utilization rate) was conducted to explore whether warming and grazing affect fine-root decomposition and loss of nutrients during a 2-year decomposition period in an alpine meadow on the Tibetan Plateau. Both warming and grazing facilitated carbon cycling through increase in fine-root decomposition, and influenced element cycling which varies among elements. The effects of warming and grazing on fine-root decomposition and loss of nutrients were additive. Both warming and grazing significantly increased cumulative percentage mass loss and total organic carbon loss of fine roots during the 2-year experiment. Only warming with grazing treatment reduced percentage nitrogen loss, whereas warming, regardless of grazing, decreased percentage phosphorus loss. Warming and grazing alone increased percentage loss of potassium, sodium, calcium and magnesium compared with control. There were no interactions between warming and grazing on fine-root decomposition and loss of nutrients. There was greater temperature sensitivity of decreased phosphorus loss than that of decreased nitrogen loss. Different temperature sensitivities of percentage loss of nutrients from fine-root decomposition would alter ratios of the available nutrients in soils, and may further affect ecosystem structure and functions in future warming. [ABSTRACT FROM AUTHOR]

Published

2022

2. Ammonia oxidizers and denitrifiers in response to reciprocal elevation translocation in an alpine meadow on the Tibetan Plateau.

Author

Zheng, Yong, Yang, Wei, Hu, Hang-Wei, Kim, Yong-Chan, Duan, Ji-Chuang, Luo, Cai-Yun, Wang, Shi-Ping, and Guo, Liang-Dong

Subjects

AMMONIA-oxidizing bacteria, MOUNTAIN meadows, CLIMATE change, SOIL microbiology, SOIL chemistry, SOIL composition, POLYMERASE chain reaction

Abstract

Purpose: Global climate change, in particular temperature variation, is likely to alter soil microbial abundance and composition, with consequent impacts on soil biogeochemical cycling and ecosystem functioning. However, responses of belowground nitrogen transformation microorganisms to temperature changes in high-elevation terrestrial ecosystems are not well understood. Materials and methods: Here, the effects of simulated cooling and warming on the abundance and community composition of ammonia-oxidizing archaea (AOA) and bacteria (AOB), as well as the abundance of denitrifiers, were investigated using quantitative polymerase chain reaction and clone library approaches, on the basis of a 2-year reciprocal elevation translocation experiment along an elevation gradient from 3,200 to 3,800 m above sea level on the Tibetan Plateau. Results and discussion: We found that, compared with the temperature variations caused by elevation translocation, the soil origin exerted a much stronger influence on AOA abundance. There were significant effects of both soil origin and elevation translocation on AOB abundance, which was particularly decreased by elevation-enhanced (simulated cooling) and increased by elevation-decreased (simulated warming) treatments. Altered temperature affected the abundance of nirK rather than nirS and nosZ genes, and the latter two seemed to be associated tightly with the soil origin. Furthermore, the results showed that temperature changes had obvious influences on the community structure and diversity of AOB, but not AOA. More apparent response of AOB to warming than in other studies on grassland and forest ecosystems may be attributed to higher elevation and lower mean annual temperature in this study. Conclusions: Our findings thus suggest that, in comparison with AOA and denitrifying populations, AOB may respond more sensitively to natural temperature variation caused by elevation translocation in this alpine grassland ecosystem on the Tibetan Plateau. [ABSTRACT FROM AUTHOR]

Published

2014

3. Methanotrophic community structure and activity under warming and grazing of alpine meadow on the Tibetan Plateau.

Author

Zheng, Yong, Yang, Wei, Sun, Xiang, Wang, Shi-Ping, Rui, Yi-Chao, Luo, Cai-Yun, and Guo, Liang-Dong

Subjects

METHANOTROPHS, MOUNTAIN meadows, GREENHOUSE gases, CLIMATE change, GRAZING, OXIDATION

Abstract

Knowledge about methanotrophs and their activities is important to understand the microbial mediation of the greenhouse gas CH under climate change and human activities in terrestrial ecosystems. The effects of simulated warming and sheep grazing on methanotrophic abundance, community composition, and activity were studied in an alpine meadow soil on the Tibetan Plateau. There was high abundance of methanotrophs (1.2-3.4 × 10 pmoA gene copies per gram of dry weight soil) assessed by real-time PCR, and warming significantly increased the abundance regardless of grazing. A total of 64 methanotrophic operational taxonomic units (OTUs) were obtained from 1,439 clone sequences, of these OTUs; 63 OTUs (98.4%) belonged to type I methanotrophs, and only one OTU was Methylocystis of type II methanotrophs. The methanotroph community composition and diversity were not apparently affected by the treatments. Warming and grazing significantly enhanced the potential CH oxidation activity. There were significantly negative correlations between methanotrophic abundance and soil moisture and between methanotrophic abundance and NH-N content. The study suggests that type I methanotrophs, as the dominance, may play a key role in CH oxidation, and the alpine meadow has great potential to consume more CH under future warmer and grazing conditions on the Tibetan Plateau. [ABSTRACT FROM AUTHOR]

Published

2012