Your search keyword '"Shuohong Zhang"' showing total 5 results

1. Microbial traits determine soil C emission in response to fresh carbon inputs in forests across biomes

Author

Chengjie Ren, Jun Wang, Felipe Bastida, Xinhui Han, Sha Zhou, Zhenghu Zhou, Gaihe Yang, Manuel Delgado-Baquerizo, Jieying Wang, Yaoxin Guo, Fazhu Zhao, Shuohong Zhang, Zekun Zhong, Yuanhe Yang, Gehong Wei, National Natural Science Foundation of China, Chinese Academy of Sciences, Shaanxi Province, Ministry of Science and Technology of the People's Republic of China, Qinghai Province, Consejo Superior de Investigaciones Científicas (España), Ministerio de Ciencia e Innovación (España), and Agencia Estatal de Investigación (España)

Subjects

Forest biomes, Biome, chemistry.chemical_element, Subtropics, Forests, Biology, Soil, Negatively associated, Environmental Chemistry, Genomes, Priming effect, Ecosystem, Soil Microbiology, General Environmental Science, Global and Planetary Change, Ecology, Simple sugar, Carbon, chemistry, Metagenomics, Temperate rainforest, Priming (psychology), Metagenomic sequencing, Microbial functional profiles

Abstract

Soil priming is a microbial-driven process, which determines key soil–climate feedbacks in response to fresh carbon inputs. Despite its importance, the microbial traits behind this process are largely undetermined. Knowledge of the role of these traits is integral to advance our understanding of how soil microbes regulate carbon (C) emissions in forests, which support the largest soil carbon stocks globally. Using metagenomic sequencing and C-glucose, we provide unprecedented evidence that microbial traits explain a unique portion of the variation in soil priming across forest biomes from tropical to cold temperature regions. We show that microbial functional profiles associated with the degradation of labile C, especially rapid simple sugar metabolism, drive soil priming in different forests. Genes involved in the degradation of lignin and aromatic compounds were negatively associated with priming effects in temperate forests, whereas the highest level of soil priming was associated with β-glucosidase genes in tropical/subtropical forests. Moreover, we reconstructed, for the first time, 42 whole bacterial genomes associated with the soil priming effect and found that these organisms support important gene machinery involved in priming effect. Collectively, our work demonstrates the importance of microbial traits to explain soil priming across forest biomes and suggests that rapid carbon metabolism is responsible for priming effects in forests. This knowledge is important because it advances our understanding on the microbial mechanisms mediating soil–climate feedbacks at a continental scale., This work were financially supported by the National Natural Science Foundation of China (41907031), the Chinese Academy of Sciences “Light of West China” Program for Introduced Talent in the West, the National Natural Science Foundation of China (31570440, 31270484), the Key International Scientific and Technological Cooperation and Exchange Project of Shaanxi Province, China (2020KWZ-010), the 2021 First Funds for Central Government to Guide Local Science and Technology Development in Qinghai Province (2021ZY002), the i-LINK +2018 (LINKA20069) from CSIC, and a Ramón y Cajal grant from the Spanish Ministry of Science and Innovation (RYC2018-025483-I)

Published

2021

2. N-Cycle Genes Abundance Determined N Mineralization Rate Following Afforestation in the Loess Plateau of China

Author

Yaping Zhao, Yuqing Zhao, Shuohong Zhang, Yulin Xu, Gaihe Yang, Xinhui Han, and Chengjie Ren

Published

2022

3. Altered microbial P cycling genes drive P availability in soil after afforestation

Author

Ruochen Zhi, Jian Deng, Yuling Xu, Miaoping Xu, Shuohong Zhang, Xinhui Han, Gaihe Yang, and Chengjie Ren

Subjects

Environmental Engineering, General Medicine, Management, Monitoring, Policy and Law, Waste Management and Disposal

Abstract

Soil Phosphorous (P) availability is a limiting factor for plant growth and regulates biological metabolism in plantation ecosystems. The effect of variations in soil microbial P cycling potential on the availability of soil P during succession in plantation ecosystems is unclear. In this study, a metagenomics approach was used to explore variations in the composition and diversity of microbial P genes along a 45-year recovery sequence of Robinia pseudoacacia on the Loess Plateau, as well soil properties were measured. Our results showed that the diversity of P cycling genes (inorganic P solubilization and organic P mineralization genes) increased significantly after afforestation, and the community composition showed clear differences. The gcd and ppx genes were dominant in inorganic P transformation, whereas phnM gene dominated the transformation of organic P. The abundance of genes involved in inorganic P solubilization and organic P mineralization was significantly positively correlated with P availability, particularly for phnM, gcd, ppx, and phnI genes, corresponding to the phyla Gemmatimonadetes, Acidobacteria, Bacteroidetes, and Planctomycetes. The critical drivers of the microbial main genes of soil P cycling were available P (AP) and total N (TN) in soil. Overall, these findings highlight afforestation-induced increases in microbial P cycling genes enhanced soil P availability. and help to better understand how microbial growth metabolism caused by vegetation restoration in ecologically fragile areas affects the soil P cycling.

Published

2023

4. Global scaling the leaf nitrogen and phosphorus resorption of woody species: Revisiting some commonly held views

Author

Yongzhong Feng, Shuohong Zhang, Xinhui Han, Wei Zhang, Miaoping Xu, and Yu-Fan Zhu

Subjects

Environmental Engineering, 010504 meteorology & atmospheric sciences, Nitrogen, chemistry.chemical_element, 010501 environmental sciences, Biology, 01 natural sciences, Soil, Nutrient, Temperate climate, Environmental Chemistry, Waste Management and Disposal, Ecosystem, 0105 earth and related environmental sciences, Phosphorus, fungi, food and beverages, Evergreen, Plants, Pollution, Resorption, Plant Leaves, Deciduous, Agronomy, chemistry, Terrestrial ecosystem, Woody plant

Abstract

Leaf nutrient resorption is one of the important mechanisms for nutrient conservation in plants. Element stoichiometry is crucial to characterizing nutrient limitations and terrestrial ecosystem function. Here, we use nitrogen (N) and phosphorus (P) resorption efficiencies (NRE and PRE) and their stoichiometry to evaluate the response patterns of leaf nutrient resorption efficiency (NuRE) to plant functional groups, species traits, climate, and soil nutrients on the global scale. In light of the findings from the global data set of published literature on N and P resorption by woody plants, we revisit the commonly held views that: The strong N fixation ability of N-fixers weakened the NRE, which was consistent with the general views. The NuRE was linearly negatively correlated with plant growth rate. The higher NuRE of evergreen species than deciduous plants revealed how leaf life span constrains nutrient conservation. From the perspective of NRE, PRE and their ratios, woody plants were limited by P in the tropical zone and the limiting nutrient gradually transformed into N in the temperate zone (23.43-66.57°). The NuRE of woody plants in the frigid zone was the largest than that of others implied that low temperature may limit the nutrient absorption by plant roots, thereby enhancing the retranslocation of nutrients by senesced leaves. Furthermore, Akaike weights analysis found that mean annual precipitation (MAP) and temperature (MAT), N-fixers, soil nutrients, and leaf life span have significant effects on nutrient resorption patterns, sequentially. Overall, these results showed that the plasticity of plant nutrient resorption patterns was strongly sensitive to plant functional groups and soil nutrients, but the regularity of NuRE on a global scale was controlled by temperature and precipitation. And the resorption stoichiometry pattern better interprets plant nutrient limitation and the synergy effect of N and P in plant and soil on multiple scales.

Published

2021

5. Resource limitation and modeled microbial metabolism along an elevation gradient

Author

Jian Deng, Chengjie Ren, Fazhu Zhao, Yaoxin Guo, Gaihe Yang, Guangxin Ren, Yongzhong Feng, Xinhui Han, Ying Pan, Zhenghu Zhou, and Shuohong Zhang

Subjects

Biomass (ecology), Nutrient, chemistry, Phosphorus, Environmental chemistry, Microbial metabolism, chemistry.chemical_element, Soil carbon, Precipitation, Decomposition, Nitrogen, Earth-Surface Processes

Abstract

Soil microbes have a great influence on the feedbacks of carbon (C)-climate, and their metabolic activities are limited by resource availability. Altitudinal gradients strongly affect soil microbial communities, but the effects on microbial resource limitation and their regulation for C dynamics remain unclear. In this study, we designed an altitudinal gradient experiment that included six altitudinal sites from 1308 m to 2600 m in the Qinling Mountains, China. The enzymatic stoichiometry was determined and modeled to investigate microbial resource limitations and major microbial metabolism processes (e.g., organic C decomposition rate and microbial respiration rate) along the elevation gradient. Other environmental variables including mean annual temperature (MAT) and mean annual precipitation (MAP), the C: nitrogen (N): phosphorus (P) ratio in soil total nutrients, available nutrients, and microbial biomass were also measured. The results showed that soil microbes suffered from N limitation in our study and microbial N limitation significantly increased with increasing elevation. But the rates of both organic C decomposition and microbial respiration greatly decreased with increased elevation. These trends suggest that warming induced by elevation change might relieve N limitation for microbes and lead to increased soil C release. Redundancy analysis (RDA) showed that MAT and soil nutrient stoichiometry, particularly for the DOC: TDN ratio, explained more variations for changes in microbial N limitation and major microbial processes. Collectively, our study demonstrated that the higher microbial N limitation at high elevation may be beneficial to soil carbon accumulation by changing the C: N ratio, which provided insights into microbially mediated soil carbon release under global warming.

Published

2022