School of Agriculture, Food and Ecosystem Sciences - Research Publications

Permanent URI for this collection

http://hdl.handle.net/11343/426

Filters

2020 - 2022 42
Reset filters

Settings
Statistics
Citations
Start date: 2020 × End date: 2022 × Type: Journal Article × Author: Hu, Hangwei ×

Search Results

Now showing 1 - 10 of 42
  • Item
    Thumbnail Image
    Conversion of natural grassland to cropland alters microbial community assembly across northern China
    Chen, Y ; Yang, X ; Fu, W ; Chen, B ; Hu, H ; Feng, K ; Geisen, S (WILEY, 2022-12)
    To feed the growing human population, natural grasslands are being converted to agricultural use at a massive scale. This conversion may have negative consequences for soil biodiversity, but its impact on the community assembly of differentially microbial groups remains largely unknown. Here, we investigated the diversity and community compositions of bacteria, archaea, fungi and protists, using a paired sampling of grassland and cropland soils across the agro-pastoral ecotone of northern China. Land-use conversion decreased α diversity of bacteria, fungi and protists, and altered the structures of the entire soil microbial community (archaea, bacteria, fungi and protists). The community assembly of archaea and bacteria was dominated by stochastic processes, and that of protists dominated by deterministic processes in both land-use types. By contrast, the fungal community was governed more strongly by stochastic processes in grassland soil, than by deterministic processes in cropland soil. Our findings support the 'size-plasticity' hypothesis that smaller body-sized microorganisms (archaea and bacteria) are more structured by stochastic processes, and larger one (protist) is more influenced by deterministic processes. Our study demonstrates that distinct ecological processes govern microbial community assembly, and land-use change regulates the balance between determinism and stochasticity.
  • Item
    No Preview Available
    Cross-biome antibiotic resistance decays after millions of years of soil development
    Chen, Q-L ; Hu, H-W ; Yan, Z-Z ; Zhu, Y-G ; He, J-Z ; Delgado-Baquerizo, M (SPRINGERNATURE, 2022-07)
    Soils harbor the most diverse naturally evolved antibiotic resistance genes (ARGs) on Earth, with implications for human health and ecosystem functioning. How ARGs evolve as soils develop over centuries, to millennia (i.e., pedogenesis), remains poorly understood, which introduces uncertainty in predictions of the dynamics of ARGs under changing environmental conditions. Here we investigated changes in the soil resistome by analyzing 16 globally distributed soil chronosequences, from centuries to millennia, spanning a wide range of ecosystem types and substrate age ranges. We show that ARG abundance and diversity decline only after millions of years of soil development as observed in very old chronosequences. Moreover, our data show increases in soil organic carbon content and microbial biomass as soil develops that were negatively correlated with the abundance and diversity of soil ARGs. This work reveals natural dynamics of soil ARGs during pedogenesis and suggests that such ecological patterns are predictable, which together advances our understanding of the environmental drivers of ARGs in terrestrial environments.
  • Item
    No Preview Available
    Calling for comprehensive explorations between soil invertebrates and arbuscular mycorrhizas
    Chen, Q-L ; Hu, H-W ; Zhu, D ; Zhu, Y-G ; He, J-Z (CELL PRESS, 2022-08)
    Arbuscular mycorrhizal (AM) fungi and soil invertebrates represent a large proportion of total soil biomass and biodiversity and are vital for plant performance, soil structure, and biogeochemical cycling. However, the role of soil invertebrates in AM fungi development remains elusive. In this opinion article, we summarize the ecological importance of AM fungi and soil invertebrates in the plant-soil continuum and highlight the effects of soil invertebrates on AM fungal hyphae development and functioning. In a context of global change, we envision that better mechanistic understanding of the complex feedback via chemical signaling pathways across the interactions between soil invertebrates and AM fungi is critical to predict their ecological consequences and will open new avenues for promoting ecosystem resilience and sustainability.
  • Item
    No Preview Available
    Aridity decreases soil protistan network complexity and stability
    Chen, Q-L ; Hu, H-W ; Sun, A-Q ; Zhu, Y-G ; He, J-Z (PERGAMON-ELSEVIER SCIENCE LTD, 2022-03)
  • Item
    No Preview Available
    Climate warming increases the proportions of specific antibiotic resistance genes in natural soil ecosystems
    Li, Z ; Sun, A ; Liu, X ; Chen, Q-L ; Bi, L ; Ren, P-X ; Shen, J-P ; Jin, S ; He, J-Z ; Hu, H-W ; Yang, Y (ELSEVIER, 2022-05-15)
    Understanding the future distribution of antibiotic resistance in natural soil ecosystems is important to forecast their impacts on ecosystem and human health under projected climate change scenarios. Therefore, it is critical and timely to decipher the links between climate warming and antibiotic resistance, two of Earth's most imminent problems. Here, we explored the role of five-year simulated climate warming (+ 4 °C) on the diversity and proportions of soil antibiotic resistance genes (ARGs) across three seasons in both plantation and natural forest ecosystems. We found that the positive effects of warming on the number and proportions of ARGs were dependent on the sampling seasons (summer, autumn and winter), and seasonality was a key factor driving the patterns of ARG compositions in forest soils. Fifteen ARGs, conferring resistance to common antibiotics including aminoglycoside, beta-lactam, macrolide-lincosamide-streptogramin B, multidrug, sulfonamide, and tetracycline, were significantly enriched in the warming treatment. We showed that changes in soil properties and community compositions of bacteria, fungi and protists can explain the changes in soil ARGs under climate warming. Taken together, these findings advance our understanding of environmental ARGs under the context of future climate change and suggest that elevated temperature may promote the abundance of specific soil ARGs, with important implications for ecosystem and human health.
  • Item
    No Preview Available
    Livestock manure spiked with the antibiotic tylosin significantly altered soil protist functional groups
    Nguyen, B-AT ; Chen, Q-L ; He, J-Z ; Hu, H-W (ELSEVIER, 2022-04-05)
    With the increasing global antibiotic uses in livestock husbandry, animal manures upon land application pose potential threats to the environments and soil microbiome. Nevertheless, effects of manures and antibiotic-administered manures on soil protists, an integral component of soil food web and primary regulators of bacteria, remain unknown. Here, we assessed impacts of cattle and poultry manures with or without an antibiotic tylosin on soil protists and their functional groups in a 130-day microcosm incubation. Protists were highly responsive to manure application, with a significant decline in their alpha diversity in all manure treatments. There were also significant temporal changes in the alpha diversity and composition of soil protists and their functional groups. Poultry manures had stronger negative influences on the community structure of protists compared to cattle manures, and more pronounced effects on protists were observed in tylosin-spiked manure treatments. Furthermore, many consumer, phototrophic and parasitic taxa were highly susceptible to all manure treatments at Day 50 and 130. Altogether, our findings demonstrate negative effects of animal manures and tylosin on soil protists. This study suggests that the applications of livestock manures and antibiotics may subsequently alter ecological functions of protists and their interactions with other soil microorganisms in agricultural systems.
  • Item
    No Preview Available
    Nitrous oxide production pathways in Australian forest soils
    Pan, B ; Zhang, Y ; Xia, L ; Lam, SK ; Hu, H-W ; Chen, D (ELSEVIER, 2022-08-15)
  • Item
    No Preview Available
    Contrasting ecological processes shape the Eucalyptus phyllosphere bacterial and fungal community assemblies
    Yan, ZZ ; Chen, QL ; Li, CY ; Thi Nguyen, BA ; He, JZ ; Hu, HW (Wiley, 2022-03-01)
    Abstract Introduction Phyllosphere microbiome is intrinsically linked to plant performance and ecosystem functioning. However, our knowledge about the role of ecological processes in shaping the biogeography of different phyllosphere microbial communities is scarce. Materials and Methods Here, we compared the biogeographic patterns of bacterial and fungal communities in phyllosphere samples of plants belonging to the genus of Eucalyptus of the Myrtaceae family collected from an over 4000 km transect. We investigated the relative importance of two major ecosystem processes (stochastic vs. deterministic) in shaping phyllosphere microbial community assemblies. Results Our results demonstrated that the neutral community model, which can quantify the degree of a community assembly determined by stochastic processes, explained 64.2% of the variations in bacterial community assembly, which had a normalized stochasticity ratio of 71.8%. These results suggest that the dominant role of stochastic processes in shaping bacterial community assembly. In contrast, phyllosphere fungal community assembly was mainly shaped by deterministic processes as revealed by a relatively small explanation rate of the neutral community model (48.7%) and a normalized stochasticity ratio of 25.1%. Variation partitioning analysis and random forest modelling results indicated that climatic factors, particularly mean annual precipitation and aridity index, were important in driving both bacterial and fungal biogeographic patterns in the phyllosphere. Edaphic factors, such as soil organic and mineral nitrogen content, were more closely related to fungal community assembly than to bacterial community assembly. The differential responses of bacterial and fungal communities to environmental factors could be attributed to the different traits of bacteria and fungi, that is, the higher potential dispersal rate and wider habitat niche of bacteria than fungi. Conclusion Our findings demonstrated that phyllosphere bacterial and fungal communities followed distinct community assembly processes, which is supported by the ‘size plasticity’ hypothesis that smaller organisms (bacteria) are less influenced by environmental conditions and are more homogeneous across space than larger organisms (fungi). These findings provide new insights into the microbial ecology of plant phyllosphere microbiomes.
  • Item
    No Preview Available
    Aridity differentially alters the stability of soil bacterial and fungal networks in coastal and inland areas of Australia
    Chen, Q-L ; Xiang, Q ; Sun, A-Q ; Hu, H-W (WILEY, 2022-11)
    Despite the importance of soil bacterial and fungal communities for ecosystem services and human welfare, how their ecological networks respond to climatic aridity have yet been evaluated. Here, we collected soil samples from 47 sites across 2500 km in coastal and inland areas of eastern Australia with contrasting status of aridity. We found that the diversity of both bacteria and fungi significantly differed between inland and coastal soils. Despite the significant differences in soil nutrient availability and stoichiometry between the inland and coastal regions, aridity was the most important predictor of bacterial and fungal community compositions. Aridity has altered the potential microbial migration rates and further impacted the microbial assembly processes by increasing the importance of stochasticity in bacterial and fungal communities. More importantly, ecological network analysis indicated that aridity enhanced the complexity and stability of the bacterial network but reduced that of the fungal network, possibly due to the contrasting impacts of aridity on the community-level habitat niche breadth and overlaps. Our work paves the way towards a more comprehensive understanding of how climate changes will alter soil microbial communities, which is integral to predicting their long-term consequences for ecosystem sustainability and resilience to future disturbances.
  • Item
    Thumbnail Image
    The global distribution and environmental drivers of the soil antibiotic resistome
    Delgado-Baquerizo, M ; Hu, H-W ; Maestre, FT ; Guerra, CA ; Eisenhauer, N ; Eldridge, DJ ; Zhu, Y-G ; Chen, Q-L ; Trivedi, P ; Du, S ; Makhalanyane, TP ; Verma, JP ; Gozalo, B ; Ochoa, V ; Asensio, S ; Wang, L ; Zaady, E ; Illan, JG ; Siebe, C ; Grebenc, T ; Zhou, X ; Liu, Y-R ; Bamigboye, AR ; Blanco-Pastor, JL ; Duran, J ; Rodriguez, A ; Mamet, S ; Alfaro, F ; Abades, S ; Teixido, AL ; Penaloza-Bojaca, GF ; Molina-Montenegro, MA ; Torres-Diaz, C ; Perez, C ; Gallardo, A ; Garcia-Velazquez, L ; Hayes, PE ; Neuhauser, S ; He, J-Z (BMC, 2022-12-12)
    BACKGROUND: Little is known about the global distribution and environmental drivers of key microbial functional traits such as antibiotic resistance genes (ARGs). Soils are one of Earth's largest reservoirs of ARGs, which are integral for soil microbial competition, and have potential implications for plant and human health. Yet, their diversity and global patterns remain poorly described. Here, we analyzed 285 ARGs in soils from 1012 sites across all continents and created the first global atlas with the distributions of topsoil ARGs. RESULTS: We show that ARGs peaked in high latitude cold and boreal forests. Climatic seasonality and mobile genetic elements, associated with the transmission of antibiotic resistance, were also key drivers of their global distribution. Dominant ARGs were mainly related to multidrug resistance genes and efflux pump machineries. We further pinpointed the global hotspots of the diversity and proportions of soil ARGs. CONCLUSIONS: Together, our work provides the foundation for a better understanding of the ecology and global distribution of the environmental soil antibiotic resistome. Video Abstract.