Your search keyword '"He, Liyuan"' showing total 4 results

1. Dynamics of Fungal and Bacterial Biomass Carbon in Natural Ecosystems: Site‐Level Applications of the CLM‐Microbe Model

Author

He, Liyuan, Lipson, David A, Rodrigues, Jorge L Mazza, Mayes, Melanie, Björk, Robert G, Glaser, Bruno, Thornton, Peter, and Xu, Xiaofeng

Subjects

Climate Action, bacteria, biomass dynamics, fungi, model, sensitivity, Atmospheric Sciences

Abstract

Explicitly representing microbial processes has been recognized as a key improvement to Earth system models for the realistic projections of soil carbon (C) and climate dynamics. The CLM-Microbe model builds upon the CLM4.5 and explicitly represents two major soil microbial groups, fungi and bacteria. Based on the compiled time-series data of fungal (FBC) and bacterial (BBC) biomass C from nine biomes, we parameterized and validated the CLM-Microbe model, and further conducted sensitivity and uncertainty analysis for simulating C cycling. The model performance was evaluated with mean absolute error (MAE), root mean square error (RMSE), and coefficient of determination (R2) for relative change in FBC and BBC. The CLM-Microbe model is able to reasonably capture the seasonal dynamics of FBC and BBC across biomes, particularly for tropical/subtropical forest, temperate broadleaf forest, and grassland, with MAE

Published

2021

2. Global biogeography of fungal and bacterial biomass carbon in topsoil

Author

He, Liyuan, Rodrigues, Jorge L Mazza, Soudzilovskaia, Nadejda A, Barceló, Milagros, Olsson, Pål Axel, Song, Changchun, Tedersoo, Leho, Yuan, Fenghui, Yuan, Fengming, Lipson, David A, and Xu, Xiaofeng

Subjects

Environmental Sciences, Soil Sciences, Infection, Fungi, Bacteria, F:B ratio, Biogeography, Pattern, Biological Sciences, Agricultural and Veterinary Sciences, Agronomy & Agriculture, Soil sciences

Abstract

Bacteria and fungi, representing two major soil microorganism groups, play an important role in global nutrient biogeochemistry. Biogeographic patterns of bacterial and fungal biomass are of fundamental importance for mechanistically understanding nutrient cycling. We synthesized 1323 data points of phospholipid fatty acid-derived fungal biomass C (FBC), bacterial biomass C (BBC), and fungi:bacteria (F:B) ratio in topsoil, spanning 11 major biomes. The FBC, BBC, and F:B ratio display clear biogeographic patterns along latitude and environmental gradients including mean annual temperature, mean annual precipitation, net primary productivity, root C density, soil temperature, soil moisture, and edaphic factors. At the biome level, tundra has the highest FBC and BBC densities at 3684 (95% confidence interval: 1678–8084) mg kg−1 and 428 (237–774) mg kg−1, respectively; desert has the lowest FBC and BBC densities at 16.92 (14.4–19.89) mg kg−1 and 6.83 (6.1–7.65) mg kg−1, respectively. The F:B ratio varies dramatically, ranging from 1.8 (1.6–2.1) in savanna to 8.6 (6.7–11.0) in tundra. An empirical model was developed for the F:B ratio and it is combined with a global dataset of soil microbial biomass C to produce global maps for FBC and BBC in 0–30 cm topsoil. Across the globe, the highest FBC is found in boreal forest and tundra while the highest BBC is in boreal forest and tropical/subtropical forest, the lowest FBC and BBC are in shrub and desert. Global stocks of living microbial biomass C were estimated to be 12.6 (6.6–16.4) Pg C for FBC and 4.3 (0.5–10.3) Pg C for BBC in topsoil. These findings advance our understanding of the global distribution of fungal and bacterial biomass, which facilitates the incorporation of fungi and bacteria into Earth system models. The global maps of bacterial and fungal biomass serve as a benchmark for validating microbial models in simulating the global C cycle under a changing climate.

Published

2020

3. Macroecology Differentiation Between Bacteria and Fungi in Topsoil Across the United States.

Author

He, Liyuan, Viovy, Nicolas, and Xu, Xiaofeng

Subjects

MACROECOLOGY, MICROBIAL ecology, TOPSOIL, TEMPERATURE control, FUNGI, MICROBIAL metabolism

Abstract

Bacteria and fungi possess distinct physiological traits. Their macroecology is vital for ecosystem functioning such as carbon cycling. However, bacterial and fungal biogeography and underlying mechanisms remain elusive. In this study, we investigated bacterial versus fungal macroecology by integrating a microbial‐explicit model—CLM‐Microbe—with measured fungal (FBC) and bacterial biomass carbon (BBC) from 34 NEON sites. The distribution of FBC, BBC, and FBC: BBC (F:B) ratio was well simulated across sites, with variations in 99% (P < 0.001), 97% (P < 0.001), and 99% (P < 0.001) being explained by the CLM‐Microbe model, respectively. We found stronger biogeographic patterns of FBC relative to BBC across the United States. Fungal and bacterial turnover rates showed similar trends along latitude. However, latitudinal trends of their component fluxes (carbon assimilation, respiration, and necromass production) were distinct between bacteria and fungi, with those latitudinal trends following inverse unimodal patterns for fungi and showing exponential declining responses for bacteria. Carbon assimilation was dominated by vegetation productivity, and respiration was dominated by mean annual temperature for bacteria and fungi. The dominant factor for their necromass production differs, with edaphic factors controlling fungal and mean annual temperature controlling bacterial processes. The understanding of fungal and bacterial macroecology is an important step toward linking microbial metabolism and soil biogeochemical processes. Distinct fungal and bacterial macroecology contributes to the microbial ecology, particularly on microbial community structure and its association with ecosystem carbon cycling across space. Key Points: We investigated the macroecology of biomass carbon and turnover for fungi and bacteria in natural ecosystems across the United StatesFungi show stronger biogeographic patterns in biomass carbon than bacteriaEdaphic properties dominate fungal necromass formation, while mean annual temperature controls bacterial necromass formation across sites [ABSTRACT FROM AUTHOR]

Published

2023

4. TssM is essential for virulence and required for type VI secretion in Ralstonia solanacearum

Author

Zhang, Liqing, Xu, Jingsheng, Xu, Jin, Chen, Kuangyu, He, Liyuan, and Feng, Jie

Published

2012