Your search keyword '"Yang, Jun-Jie"' showing total 7 results

1. Gene horizontal transfers and functional diversity negatively correlated with bacterial taxonomic diversity along a nitrogen gradient.

Author

Yang JX, Peng Y, Yu QY, Yang JJ, Zhang YH, Zhang HY, Adams CA, Willing CE, Wang C, Li QS, Han XG, and Gao C

Subjects

Soil chemistry, RNA, Ribosomal, 16S genetics, Metagenome, Soil Microbiology, Nitrogen metabolism, Nitrogen pharmacology, Biodiversity, Bacteria genetics, Bacteria metabolism, Gene Transfer, Horizontal drug effects

Abstract

Horizontal gene transfer (HGT) mediated diversification is a critical force driving evolutionary and ecological processes. However, how HGT might relate to anthropogenic activity such as nitrogen addition, and its subsequent effect on functional diversity and cooccurrence networks remain unknown. Here we approach this knowledge gap by blending bacterial 16S rRNA gene amplicon and shotgun metagenomes from a platform of cessation of nitrogen additions and continuous nitrogen additions. We found that bacterial HGT events, functional genes, and virus diversities increased whereas bacterial taxonomic diversity decreased by nitrogen additions, resulting in a counterintuitive strong negative association between bacterial taxonomic and functional diversities. Nitrogen additions, especially the ceased one, complexified the cooccurrence network by increasing the contribution of vitamin B12 auxotrophic Acidobacteria, indicating cross-feeding. These findings advance our perceptions of the causes and consequences of the diversification process in community ecology., Competing Interests: Competing interests The authors declare no competing interests., (© 2024. The Author(s).)

Published

2024

2. Increasing rates of long-term nitrogen deposition consistently increased litter decomposition in a semi-arid grassland.

Author

Hou SL, Hättenschwiler S, Yang JJ, Sistla S, Wei HW, Zhang ZW, Hu YY, Wang RZ, Cui SY, Lü XT, and Han XG

Subjects

Grassland, Plant Leaves, Plants, Poaceae, Soil, Ecosystem, Nitrogen

Abstract

The continuing nitrogen (N) deposition observed worldwide alters ecosystem nutrient cycling and ecosystem functioning. Litter decomposition is a key process contributing to these changes, but the numerous mechanisms for altered decomposition remain poorly identified. We assessed these different mechanisms with a decomposition experiment using litter from four abundant species (Achnatherum sibiricum, Agropyron cristatum, Leymus chinensis and Stipa grandis) and litter mixtures representing treatment-specific community composition in a semi-arid grassland under long-term simulation of six different rates of N deposition. Decomposition increased consistently with increasing rates of N addition in all litter types. Higher soil manganese (Mn) availability, which apparently was a consequence of N addition-induced lower soil pH, was the most important factor for faster decomposition. Soil C : N ratios were lower with N addition that subsequently led to markedly higher bacterial to fungal ratios, which also stimulated litter decomposition. Several factors contributed jointly to higher rates of litter decomposition in response to N deposition. Shifts in plant species composition and litter quality played a minor role compared to N-driven reductions in soil pH and C : N, which increased soil Mn availability and altered microbial community structure. The soil-driven effect on decomposition reported here may have long-lasting impacts on nutrient cycling, soil organic matter dynamics and ecosystem functioning., (© 2020 The Authors New Phytologist © 2020 New Phytologist Trust.)

Published

2021

3. The relative contributions of intra- and inter-specific variation in driving community stoichiometric responses to nitrogen deposition and mowing in a grassland.

Author

Hou SL, Lü XT, Yin JX, Yang JJ, Hu YY, Wei HW, Zhang ZW, Yang GJ, Liu ZY, and Han XG

Subjects

China, Species Specificity, Fertilizers analysis, Grassland, Nitrogen metabolism, Plants metabolism

Abstract

Aims: The stoichiometric characteristics of plant communities are important controller for several fundamental ecological processes. The effects of environmental changes on community stoichiometric characteristics are driven by intra- and inter-specific variation. However, the relative importance of both pathways has seldom been empirically examined., Methods: We quantified the relative contribution of intra- and inter-specific variation to the changes of community nitrogen (N) and phosphorus (P) concentrations after seven-year factorial N addition and mowing treatments in a semi-arid grassland of northern China., Results: Nitrogen addition significantly increased community N and P concentrations and N:P ratio. Mowing significantly increased community N concentration and N:P. Intra-specific variation contributed more than inter-specific variation to the total variability of all the nutritional and stoichiometric characteristics, with intra-specific variation accounting for 68%, 70%, and 75% of the total variation in community-level N, P, and N:P, respectively. Negative covariations between the contribution of intra- and inter-specific variation occurred for community N and P concentrations. Further, N addition and mowing interacted to affect the impacts of intra- and inter-specific variation on community N concentration and N:P stoichiometry., Conclusions: Our results highlight different ways of trait selection for N addition and mowing treatments. Interactions between those two factors make it more difficult to accurately predict the responses of plant-mediated biogeochemical cycles under co-occurrence of environmental changes., (Copyright © 2019 Elsevier B.V. All rights reserved.)

Published

2019

4. Impacts of leguminous shrub encroachment on neighboring grasses include transfer of fixed nitrogen.

Author

Zhang HY, Yu Q, Lü XT, Trumbore SE, Yang JJ, and Han XG

Subjects

Caragana metabolism, Fabaceae growth & development, Fabaceae metabolism, Plant Shoots growth & development, Plant Shoots metabolism, Poaceae metabolism, Rhizome, Species Specificity, Biomass, Caragana growth & development, Ecology, Ecosystem, Nitrogen metabolism, Nitrogen Fixation, Poaceae growth & development

Abstract

Shrub encroachment induced by global change and human disturbance strongly affects ecosystem structure and function. In this study, we explore the degree to which invading leguminous shrubs affected neighboring grasses, including via the transfer of fixed nitrogen (N). We measured N concentrations and natural abundance (15)N of shoot tissues from three dominant grasses from different plant functional groups across seven distances along a local transect (up to 500 cm) to the leguminous shrub, Caragana microphylla. C. microphylla did transfer fixed N to neighboring grasses, but the amount and distance of N transferred were strongly species-specific. Shoot N concentrations decreased significantly with distance from C. microphylla, for a rhizomatous grass, Leymus chinensis, and a bunchgrass, Achnatherum sibiricum. However, N concentrations of another bunchgrass, Stipa grandis, were higher only directly underneath the shrub canopy. Shoot δ(15)N values of L. chinensis were enriched up to 500 cm from the shrub, but for S. grandis were enriched only below the shrub canopy. In contrast, δ(15)N of A. sibiricum did not change along the 500-cm transect. Our results indicated the rhizomatous grass transferred fixed N over long distances while bunchgrasses did not. The presence of C. microphylla increased the shoot biomass of L. chinensis but decreased that of S. grandis and A. sibiricum. These findings highlight the potential role of nutrient-acquisition strategies of neighboring grasses in moderating the interspecific variation of fixed N transfer from the leguminous shrub. Overall, leguminous shrubs have either positive or negative effects on the neighboring grasses and dramatically affect plant community composition and structure.

Published

2016

5. Changes of community composition strengthen the positive effects of nitrogen deposition on litter N:P stoichiometry in a semi-arid grassland.

Author

Hou, Shuang-Li, Yang, Jun-Jie, Yin, Jiang-Xia, Wei, Hai-Wei, Hu, Yan-Yu, Zhang, Zhi-Wei, Yang, Guo-Jiao, and Lü, Xiao-Tao

Subjects

*NUTRIENT cycles, *COMMUNITY change, *GRASSLANDS, *STOICHIOMETRY, *NITROGEN

Abstract

Aims: The stoichiometric traits of litter play an important role in driving litter decomposition and ecosystem nutrient cycling. While the impacts of nitrogen (N) deposition on the species-level litter stoichiometric traits have been well addressed, we know little about that at community-level, which is supposed to be driven by both intra-specific variation and changes in community composition. Methods: We examined the effects of N deposition on litter phosphorus (P) concentration and N:P ratio at both species- and community-level in a semi-arid grassland of northern China. We further decomposed the community-level variations of litter nutritional traits into intra- and inter-specific variation. Results: Nitrogen addition, especially at high rates, substantially changed community composition. Litter P concentrations and N:P ratios significantly varied among different species. Litter P concentrations and N:P ratios at both species- and community-level were positively correlated with N addition rates. Biomass-weighted community-level N:P ratios were more sensitive to N addition than the non-weighted ones, indicating that community composition strengthened the positive impacts of N addition on litter N:P ratios. There was positive co-variation between intra- and inter-specific variation for litter N:P ratio, indicating the consistency of community composition and intra-specific variation in their effects on litter N:P ratio. Conclusions: Our results indicated that the imbalance of N and P following N enrichment would be much larger than the expectation based on the findings from species-level, and thus highlight the importance of changes in community composition in driving the responses of community-level litter N:P stoichiometry to N deposition in the semi-arid grassland. [ABSTRACT FROM AUTHOR]

Published

2022

6. Neutral responses of plant community Ca concentration to nitrogen enrichment in a semiarid grassland.

Author

Hou, Shuang-Li, Lü, Xiao-Tao, and Yang, Jun-Jie

Subjects

GRASSLANDS, PLANT biomass, NITROGEN in soils, PLANT nutrients, ESSENTIAL nutrients, NITROGEN, COMMUNITIES

Abstract

Calcium (Ca) is an essential nutrient for plant growth and Ca concentrations in forage have important implications for ruminant diet and health. It remains an open question whether forage Ca concentration would be decreased by increasing nitrogen (N) deposition. We manipulated the increasing rates of N addition (2008–2015) in a semiarid grassland, northern China. Plant Ca concentrations for all species were examined in each plot under N treatment. The Ca concentrations at functional group and community levels were calculated based on the concentration of each species presented and their relative biomass in each plot. We found that community-level Ca concentration remained stable across a gradient of wide-ranged N addition rates, although Ca concentration at both species and functional group levels showed negative responses to N enrichment. Given that forbs had higher Ca concentration than grasses, the increasing relative biomass of forbs canceled out the negative responses of species-level and functional group-level Ca concentration. Our results further showed that community Ca pool showed a positive but saturating response to N addition, with a threshold at the rate of 10 g N m−2 yr−1. Our findings highlight the role of changes in plant relative biomass in controlling the responses of forage Ca concentration and stock to N enrichment. [ABSTRACT FROM AUTHOR]

Published

2022

7. Home-field advantages of litter decomposition increase with increasing N deposition rates: a litter and soil perspective.

Author

Li, Ying‐Bin, Li, Qi, Yang, Jun‐Jie, Lü, Xiao‐Tao, Liang, Wen‐Ju, Han, Xing‐Guo, Martijn Bezemer, T., and Sayer, Emma

Subjects

ANIMAL litters, SOIL microbiology, NITROGEN, CARBON, CHEMICAL decomposition

Abstract

Differences in litter quality and in soil microbial community composition can influence the litter decomposition and 'home-field advantage' ( HFA). However, our knowledge about the relative role of litter and soil characteristics on litter decomposition and HFA effects is still limited, especially under long-term N deposition., We collected soil and two types of litter (monospecific and mixed species litter) from five replicate plots from a long-term N deposition field experiment with seven N addition treatments (0, 2, 5, 10, 15, 20, 50 g N m−2 year−1). We examined the effects of N addition on litter quality and soil characteristics. We then carried out a three-pronged microcosm decomposition experiment with (i) litter from different N addition treatments decomposed on a standard field soil; (ii) standard litter decomposed on soils from the different N addition treatments; and (iii) litter decomposed on soil from the same N addition treatment plot., Decomposition of litter on standard soil was influenced strongly by the N addition treatment, but did not consistently decrease or increase with increasing N addition rates. Instead, decomposition of standard litter on soils collected from different N addition treatments decreased with increasing rates of N addition. Decomposition of litter on soil collected from the same plot increased with increasing N addition rates. Soil characteristics explained more of the variation in litter decomposition than litter characteristics., There was a clear HFA effect for litter decomposition, both from a litter and from a soil perspective. HFA effects increased when the dissimilarity in litter quality (N content and C : N ratio) increase among the different N addition treatments and the soil effect was strongest at high N addition rates., N addition influenced litter decomposition by changing both litter and soil characteristics. Importantly, N addition decreased the capability of soils to decompose litter and it increased the HFA effect indicating that soils decomposed local litter better than other litter, due to specialization in soil communities. Nitrogen deposition is an important threat to ecosystems worldwide and our study emphasizes that ecosystem functions such as decomposition can be greatly influenced by these global changes., A is available for this article. [ABSTRACT FROM AUTHOR]

Published

2017