Your search keyword '"Yang Yunfeng"' showing total 49 results

1. Long term impact of electrical resistance heating on soil bacterial community based on a field test.

Author

Xu W, Cao L, Ge R, Li S, Wei Y, Yang Y, Li G, and Zhang F

Subjects

Soil Pollutants analysis, Electric Impedance, Heating, Environmental Restoration and Remediation methods, Hot Temperature, Soil Microbiology, Soil chemistry, Bacteria, Microbiota

Abstract

Thermal remediation is an effective technology for organic contaminant remediation. However, the application of thermal remediation may have negative effects on soil properties and ecological functions, which requires further investigation. Based on a pilot test of electrical resistance heating remediation (ERH), soil samples were collected at different locations after heating for 116 days. Most soil physicochemical properties were less affected by the heating temperature difference. Application of high temperature increased microbial abundance but inhibited alpha diversity of the bacterial community. More significant changes in microbial communities were observed at temperatures above 60 °C. The genera mainly affected by heating temperature included Flavobacteria, Brockia, and S085, while the increase in temperature also inhibited the abundance of nitrochlorobenzene functional genes. At 140 days after the end of the pilot test, the bacterial community affected by thermal remediation could recover effectively, and the recovery of the bacterial community was not affected by temperature difference during the heating period. This study provides valuable field evidence of the long term impact of soil ERH treatment on soil properties and microbial communities, and provides further references for optimization of remediation performance with coupled technologies., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 Elsevier B.V. All rights reserved.)

Published

2024

2. Asymmetric winter warming reduces microbial carbon use efficiency and growth more than symmetric year-round warming in alpine soils.

Author

Li L, Xu Q, Jiang S, Jing X, Shen Q, He JS, Yang Y, and Ling N

Subjects

Global Warming, Ecosystem, Grassland, Carbon Cycle, Soil Microbiology, Seasons, Carbon metabolism, Soil chemistry, Bacteria growth & development, Bacteria metabolism, Bacteria classification

Abstract

Asymmetric seasonal warming trends are evident across terrestrial ecosystems, with winter temperatures rising more than summer ones. Yet, the impact of such asymmetric seasonal warming on soil microbial carbon metabolism and growth remains poorly understood. Using 18 O isotope labeling, we examined the effects of a decade-long experimental seasonal warming on microbial carbon use efficiency (CUE) and growth in alpine grassland ecosystems. Moreover, the quantitative stable isotope probing with 18 O-H 2 O was employed to evaluate taxon-specific bacterial growth in these ecosystems. Results show that symmetric year-round warming decreased microbial growth rate by 31% and CUE by 22%. Asymmetric winter warming resulted in a further decrease in microbial growth rate of 27% and microbial CUE of 59% compared to symmetric year-round warming. Long-term warming increased microbial carbon limitations, especially under asymmetric winter warming. Long-term warming suppressed the growth rates of most bacterial genera, with asymmetric winter warming having a stronger inhibition on the growth rates of specific genera (e.g., Gp10 , Actinomarinicola , Bosea , Acidibacter , and Gemmata ) compared to symmetric year-round warming. Bacterial growth was phylogenetically conserved, but this conservation diminished under warming conditions, primarily due to shifts in bacterial physiological states rather than the number of bacterial species and community composition. Overall, long-term warming escalated microbial carbon limitations, decreased microbial growth and CUE, with asymmetric winter warming having a more pronounced effect. Understanding these impacts is crucial for predicting soil carbon cycling as global warming progresses., Competing Interests: Competing interests statement:The authors declare no competing interest.

Published

2024

3. Enhancing soil petrochemical contaminant remediation through nutrient addition and exogenous bacterial introduction.

Author

Chen J, Zhuang J, Dai T, Zhang R, Zeng Y, Jiang B, Guo H, Guo X, and Yang Y

Subjects

Hydrocarbons metabolism, Nutrients metabolism, Petroleum Pollution, Soil Pollutants metabolism, Biodegradation, Environmental, Petroleum metabolism, Soil Microbiology, Bacteria metabolism, Bacteria genetics, Bacteria drug effects

Abstract

Biostimulation (providing favorable environmental conditions for microbial growth) and bioaugmentation (introducing exogenous microorganisms) are effective approaches in the bioremediation of petroleum-contaminated soil. However, uncertainty remains in the effectiveness of these two approaches in practical application. In this study, we constructed mesocosms using petroleum hydrocarbon-contaminated soil. We compared the effects of adding nutrients, introducing exogenous bacterial degraders, and their combination on remediating petroleum contamination in the soil. Adding nutrients more effectively accelerated total petroleum hydrocarbon (TPH) degradation than other treatments in the initial 60 days' incubation. Despite both approaches stimulating bacterial richness, the community turnover caused by nutrient addition was gentler than bacterial degrader introduction. As TPH concentrations decreased, we observed a succession in microbial communities characterized by a decline in copiotrophic, fast-growing bacterial r-strategists with high rRNA operon (rrn) copy numbers. Ecological network analysis indicated that both nutrient addition and bacterial degrader introduction enhanced the complexity and stability of bacterial networks. Compared to the other treatment, the bacterial network with nutrient addition had more keystone species and a higher proportion of negative associations, factors that may enhance microbial community stability. Our study demonstrated that nutrient addition effectively regulates community succession and ecological interaction to accelerate the soil TPH degradation., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 Elsevier B.V. All rights reserved.)

Published

2024

4. A case study showing highly traceable sources of bacteria on surfaces of university buildings.

Author

Ye Z, Huang J, Liang Z, Liu S, Lei J, Deng S, Zheng B, Hong C, Wang Y, Wang X, Gao Q, and Yang Y

Subjects

Universities, Humans, Staphylococcus aureus, Skin microbiology, Microbiota, Environmental Monitoring, Risk Assessment, Bacteria isolation & purification, Bacteria classification

Abstract

University students predominantly spend their time indoors, where prolonged exposure raises the risk of contact with microorganisms of concern. However, our knowledge about the microbial community characteristics on university campus and their underpinnings is limited. To address it, we characterized bacterial communities from the surfaces of various built environments typical of a university campus, including cafeterias, classrooms, dormitories, offices, meeting rooms, and restrooms, in addition to human skin. The classrooms harbored the highest α-diversity, while the cafeterias had the lowest α-diversity. The bacterial community composition varied significantly across different building types. Proteobacteria, Actinobacteria, Firmicutes, Bacteroidetes, and Cyanobacteria were common phyla in university buildings, accounting for more than 90 % of total abundance. Staphylococcus aureus was the most abundant potential pathogen in classrooms, dormitories, offices, restrooms, and on human skin, indicating a potential risk for skin disease infections in these buildings. We further developed a new quantitative pathogenic risk assessment method according to the threat of pathogens to humans and found that classrooms exhibited the highest potential risk. The fast expectation-maximization algorithm identified 59 %-86 % of bacterial sources in buildings, with the human skin as the largest bacterial source for most buildings. As the sources of bacteria were highly traceable, we showed that homogeneous selection, dispersal limitation, and ecological drift were major ecological forces that drove community assembly. Our findings have important implications for predicting the distribution and sources of indoor dust bacterial communities on university campus., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

5. The neglected roles of adjacent natural ecosystems in maintaining bacterial diversity in agroecosystems.

Author

Peng Z, Yang Y, Liu Y, Bu L, Qi J, Gao H, Chen S, Pan H, Chen B, Liang C, Li X, An Y, Wang S, Wei G, and Jiao S

Subjects

Biodiversity, Soil chemistry, Forests, Soil Microbiology, Ecosystem, Bacteria

Abstract

A central aim of community ecology is to understand how local species diversity is shaped. Agricultural activities are reshaping and filtering soil biodiversity and communities; however, ecological processes that structure agricultural communities have often overlooked the role of the regional species pool, mainly owing to the lack of large datasets across several regions. Here, we conducted a soil survey of 941 plots of agricultural and adjacent natural ecosystems (e.g., forest, wetland, grassland, and desert) in 38 regions across diverse climatic and soil gradients to evaluate whether the regional species pool of soil microbes from adjacent natural ecosystems is important in shaping agricultural soil microbial diversity and completeness. Using a framework of multiscales community assembly, we revealed that the regional species pool was an important predictor of agricultural bacterial diversity and explained a unique variation that cannot be predicted by historical legacy, large-scale environmental factors, and local community assembly processes. Moreover, the species pool effects were associated with microbial dormancy potential, where taxa with higher dormancy potential exhibited stronger species pool effects. Bacterial diversity in regions with higher agricultural intensity was more influenced by species pool effects than that in regions with low intensity, indicating that the maintenance of agricultural biodiversity in high-intensity regions strongly depends on species present in the surrounding landscape. Models for community completeness indicated the positive effect of regional species pool, further implying the community unsaturation and increased potential in bacterial diversity of agricultural ecosystems. Overall, our study reveals the indubitable role of regional species pool from adjacent natural ecosystems in predicting bacterial diversity, which has useful implication for biodiversity management and conservation in agricultural systems., (© 2023 John Wiley & Sons Ltd.)

Published

2024

6. Bacteria are better predictive biomarkers of environmental estrogen transmission than fungi.

Author

Liu S, Gao H, Dong Q, Su Y, Dai T, Qin Z, Yang Y, and Gao Q

Subjects

Animals, Biomarkers, Estrogens, Manure, Soil, Soil Microbiology, Swine, Bacteria genetics, Fungi

Abstract

The heavy reliance on estrogens in the food industry worldwide greatly contributes to the environmental release of these compounds, begetting serious public concern of their fate. Various microorganisms capable of estrogen degradation, and their catabolic pathways, have been isolated, suggesting that they can eliminate estrogens in both engineered and natural environments. Nonetheless, it remains little understood as to how potential estrogen-degrading microorganisms are distributed within those habitats. An estrogen transmission chain from swine manure to compost, compost-amended soil, and neighboring agricultural soil was investigated in five suburban areas of Beijing, China. The concentrations of major estrogen classes decreased by > 90% from manure to soils, which did not co-vary with environmental antibiotics and heavy metal concentrations. Many bacterial taxa, such as Lactobacillus and Bacteroides, could serve as potential biomarkers of estrogen concentrations, while fungi were only occasionally accurate. To explain this phenomenon, stochasticity was found to be dominant in shaping the fungal communities across all samples, while deterministic selection, arising from biotic interactions, was important for bacterial communities. Metabolic genes involved in oxidizing phenol and catalyzing oxidative ring cleavage of catechol were detected, co-varying with estrogen concentrations. These findings are important as identifying microbial biomarkers of estrogen dynamics, spanning the levels of both taxonomy and functional genes, provides valuable information for assessing estrogen bioavailability and biomarking of estrogen fate in the environment., (Copyright © 2022 Elsevier Ltd. All rights reserved.)

Published

2022

7. Emerging Patterns of Microbial Functional Traits.

Author

Yang Y

Subjects

Bacteria classification, Bacteria isolation & purification, Bacterial Physiological Phenomena, Ecosystem, Environment, Phenotype, Bacteria genetics, Biodiversity

Abstract

Functional traits are measurable characteristics that affect an organism's fitness under certain environmental conditions. The use of functional traits in microbial ecology holds great promise for improving our ability to develop biogeochemical models and predict ecosystem responses to global changes. Notably, functional traits could be decoupled from taxonomic relatedness, owing to horizontal gene transfer among microorganisms and adaptive evolution. In recent years, our knowledge about microbial functional traits has been substantially enhanced, thereby revealing the multitude of ecological processes in driving community assembly and dynamics. Here, I summarize the emerging patterns of how microbial functional traits respond to changing environments, which considerably differ from better-studied microbial taxonomy. I use niche and neutral theories to explain microbial functional traits. Finally, I highlight future challenges to analyze, elucidate, and utilize functional traits in microbial ecology., Competing Interests: Declaration of Interests There are no interests to declare., (Copyright © 2021 Elsevier Ltd. All rights reserved.)

Published

2021

8. Long-term warming in a Mediterranean-type grassland affects soil bacterial functional potential but not bacterial taxonomic composition.

Author

Gao Y, Ding J, Yuan M, Chiariello N, Docherty K, Field C, Gao Q, Gu B, Gutknecht J, Hungate BA, Le Roux X, Niboyet A, Qi Q, Shi Z, Zhou J, and Yang Y

Subjects

Bacteria genetics, Bacteria isolation & purification, Carbon metabolism, Gene Expression Profiling, Genes, Archaeal, Genes, Bacterial, Genes, Fungal, Global Warming, Grassland, High-Throughput Nucleotide Sequencing, Nitrogen metabolism, Oligonucleotide Array Sequence Analysis, Phylogeny, RNA, Ribosomal, 16S genetics, Soil Microbiology, Archaea genetics, Bacteria classification, Fungi genetics, Sequence Analysis, RNA methods

Abstract

Climate warming is known to impact ecosystem composition and functioning. However, it remains largely unclear how soil microbial communities respond to long-term, moderate warming. In this study, we used Illumina sequencing and microarrays (GeoChip 5.0) to analyze taxonomic and functional gene compositions of the soil microbial community after 14 years of warming (at 0.8-1.0 °C for 10 years and then 1.5-2.0 °C for 4 years) in a Californian grassland. Long-term warming had no detectable effect on the taxonomic composition of soil bacterial community, nor on any plant or abiotic soil variables. In contrast, functional gene compositions differed between warming and control for bacterial, archaeal, and fungal communities. Functional genes associated with labile carbon (C) degradation increased in relative abundance in the warming treatment, whereas those associated with recalcitrant C degradation decreased. A number of functional genes associated with nitrogen (N) cycling (e.g., denitrifying genes encoding nitrate-, nitrite-, and nitrous oxidereductases) decreased, whereas nifH gene encoding nitrogenase increased in the warming treatment. These results suggest that microbial functional potentials are more sensitive to long-term moderate warming than the taxonomic composition of microbial community.

Published

2021

9. Small and mighty: adaptation of superphylum Patescibacteria to groundwater environment drives their genome simplicity.

Author

Tian R, Ning D, He Z, Zhang P, Spencer SJ, Gao S, Shi W, Wu L, Zhang Y, Yang Y, Adams BG, Rocha AM, Detienne BL, Lowe KA, Joyner DC, Klingeman DM, Arkin AP, Fields MW, Hazen TC, Stahl DA, Alm EJ, and Zhou J

Subjects

Fermentation, Metabolic Networks and Pathways, Metagenomics, Adaptation, Physiological, Bacteria genetics, Genome Size, Genome, Bacterial, Groundwater microbiology

Abstract

Background: The newly defined superphylum Patescibacteria such as Parcubacteria (OD1) and Microgenomates (OP11) has been found to be prevalent in groundwater, sediment, lake, and other aquifer environments. Recently increasing attention has been paid to this diverse superphylum including > 20 candidate phyla (a large part of the candidate phylum radiation, CPR) because it refreshed our view of the tree of life. However, adaptive traits contributing to its prevalence are still not well known., Results: Here, we investigated the genomic features and metabolic pathways of Patescibacteria in groundwater through genome-resolved metagenomics analysis of > 600 Gbp sequence data. We observed that, while the members of Patescibacteria have reduced genomes (~ 1 Mbp) exclusively, functions essential to growth and reproduction such as genetic information processing were retained. Surprisingly, they have sharply reduced redundant and nonessential functions, including specific metabolic activities and stress response systems. The Patescibacteria have ultra-small cells and simplified membrane structures, including flagellar assembly, transporters, and two-component systems. Despite the lack of CRISPR viral defense, the bacteria may evade predation through deletion of common membrane phage receptors and other alternative strategies, which may explain the low representation of prophage proteins in their genomes and lack of CRISPR. By establishing the linkages between bacterial features and the groundwater environmental conditions, our results provide important insights into the functions and evolution of this CPR group., Conclusions: We found that Patescibacteria has streamlined many functions while acquiring advantages such as avoiding phage invasion, to adapt to the groundwater environment. The unique features of small genome size, ultra-small cell size, and lacking CRISPR of this large lineage are bringing new understandings on life of Bacteria. Our results provide important insights into the mechanisms for adaptation of the superphylum in the groundwater environments, and demonstrate a case where less is more, and small is mighty.

Published

2020

10. Microbial functional traits are sensitive indicators of mild disturbance by lamb grazing.

Author

Ma X, Zhang Q, Zheng M, Gao Y, Yuan T, Hale L, Van Nostrand JD, Zhou J, Wan S, and Yang Y

Subjects

Animals, Bacteria classification, Bacteria genetics, Feeding Behavior, Grassland, Microbiota, Soil chemistry, Bacteria isolation & purification, Sheep physiology, Soil Microbiology

Abstract

Mild disturbances are prevalent in the environment, which may not be easily notable but could have considerable ecological consequences over prolonged periods. To evaluate this, a field study was designed to examine the effects of very light-intensity lamb grazing on grassland soil microbiomes with different soil backgrounds. No significant change (P > 0.05) was observed in any vegetation and soil variables. Nonetheless, hundreds of microbial functional gene families, but not bacterial taxonomy, were significantly (P < 0.05) shifted. The relative abundances of both taxonomic markers and functional genes related to nitrifying bacteria were also changed. The observation highlighted herein, showing a high level of sensitivity with respect to functional traits (functionally categorized taxa or genes) in differentiating mild environmental disturbance, suggests that the key level at which to address microbial responses may not be "species" (by means of rRNA taxonomy), but rather at the functional gene level.

Published

2019

11. High variations of methanogenic microorganisms drive full-scale anaerobic digestion process.

Author

Zhang Q, Wang M, Ma X, Gao Q, Wang T, Shi X, Zhou J, Zuo J, and Yang Y

Subjects

Anaerobiosis, Archaea genetics, Bacteria genetics, Genes, Archaeal, Genes, Bacterial, Waste Disposal, Fluid, Archaea metabolism, Bacteria metabolism, Biofuels, Bioreactors microbiology, Methane metabolism, Microbiota

Abstract

Anaerobic digestion is one of the most successful waste management strategies worldwide, wherein microorganisms play an essential role in reducing organic pollutants and producing renewable energy. However, variations of microbial community in full-scale anaerobic digesters, particularly functional groups relevant to biogas production, remain elusive. Here, we examined microbial community in a year-long monthly time series of 3 full-scale anaerobic digesters. We observed substantial diversification in community composition, with only a few abundant OTUs (e.g. Clostridiales, Anaerolineaceae and Methanosaeta) persistently present across different samples. Similarly, there were high variations in relative abundance of methanogenic archaea and methanogenic genes, which were positively correlated (r 2  = 0.530, P < 0.001). Variations of methanogens explained 55.7% of biogas producing rates, much higher than the explanatory percentage of environmental parameters (16.4%). Hydrogenotrophic methanogens, especially abundant Methanomicrobiales taxa, were correlated with biogas production performance (r = 0.665, P < 0.001) and nearly all methanogenic genes (0.430 < r < 0.735, P < 0.012). Given that methanogenic archaea or genes are well established for methanogenesis, we conclude that high variations in methanogenic traits (e.g. taxa or genes) are responsible for biogas production variations in full-scale anaerobic digesters., (Copyright © 2019 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2019

12. Dissimilar responses of fungal and bacterial communities to soil transplantation simulating abrupt climate changes.

Author

Zhao M, Sun B, Wu L, Wang F, Wen C, Wang M, Liang Y, Hale L, Zhou J, and Yang Y

Subjects

China, Mycobiome, Bacteria classification, Carbon Cycle, Climate Change, Fungi classification, Soil Microbiology

Abstract

Both fungi and bacteria play essential roles in regulating soil carbon cycling. To predict future carbon stability, it is imperative to understand their responses to environmental changes, which is subject to large uncertainty. As current global warming is causing range shifts toward higher latitudes, we conducted three reciprocal soil transplantation experiments over large transects in 2005 to simulate abrupt climate changes. Six years after soil transplantation, fungal biomass of transplanted soils showed a general pattern of changes from donor sites to destination, which were more obvious in bare fallow soils than in maize cropped soils. Strikingly, fungal community compositions were clustered by sites, demonstrating that fungi of transplanted soils acclimatized to the destination environment. Several fungal taxa displayed sharp changes in relative abundance, including Podospora, Chaetomium, Mortierella and Phialemonium. In contrast, bacterial communities remained largely unchanged. Consistent with the important role of fungi in affecting soil carbon cycling, 8.1%-10.0% of fungal genes encoding carbon-decomposing enzymes were significantly (p < 0.01) increased as compared with those from bacteria (5.7%-8.4%). To explain these observations, we found that fungal occupancy across samples was mainly determined by annual average air temperature and rainfall, whereas bacterial occupancy was more closely related to soil conditions, which remained stable 6 years after soil transplantation. Together, these results demonstrate dissimilar response patterns and resource partitioning between fungi and bacteria, which may have considerable consequences for ecosystem-scale carbon cycling., (© 2019 John Wiley & Sons Ltd.)

Published

2019

13. Microbial functional trait of rRNA operon copy numbers increases with organic levels in anaerobic digesters.

Author

Wu L, Yang Y, Chen S, Jason Shi Z, Zhao M, Zhu Z, Yang S, Qu Y, Ma Q, He Z, Zhou J, and He Q

Subjects

Anaerobiosis, Ecology, Gene Dosage, Phenotype, Bacteria genetics, Bacteria metabolism, rRNA Operon

Abstract

The ecological concept of the r-K life history strategy is widely applied in macro-ecology to characterize functional traits of taxa. However, its adoption in microbial communities is limited, owing to the lack of a measureable, convenient functional trait for classification. In this study, we performed an experiment of stepwise organic amendments in triplicate anaerobic digesters. We found that high resource availability significantly favored microbial r-strategists such as Bacillus spp. Incremental resource availability heightened average rRNA operon copy number of microbial community, resulting in a strong, positive correlation (r>0.74, P<0.008). This study quantifies how resource availability manipulations influence microbial community composition and supports the idea that rRNA operon copy number is an ecologically meaningful trait which reflects resource availability.

Published

2017

14. Alpine soil carbon is vulnerable to rapid microbial decomposition under climate cooling.

Author

Wu L, Yang Y, Wang S, Yue H, Lin Q, Hu Y, He Z, Van Nostrand JD, Hale L, Li X, Gilbert JA, and Zhou J

Subjects

Bacteria classification, Bacteria genetics, Bacteria isolation & purification, Biodiversity, Carbon analysis, Climate Change, Ecosystem, Soil chemistry, Temperature, Bacteria metabolism, Carbon metabolism, Soil Microbiology

Abstract

As climate cooling is increasingly regarded as important natural variability of long-term global warming trends, there is a resurging interest in understanding its impact on biodiversity and ecosystem functioning. Here, we report a soil transplant experiment from lower to higher elevations in a Tibetan alpine grassland to simulate the impact of cooling on ecosystem community structure and function. Three years of cooling resulted in reduced plant productivity and microbial functional potential (for example, carbon respiration and nutrient cycling). Microbial genetic markers associated with chemically recalcitrant carbon decomposition remained unchanged despite a decrease in genes associated with chemically labile carbon decomposition. As a consequence, cooling-associated changes correlated with a decrease in soil organic carbon (SOC). Extrapolation of these results suggests that for every 1 °C decrease in annual average air temperature, 0.1 Pg (0.3%) of SOC would be lost from the Tibetan plateau. These results demonstrate that microbial feedbacks to cooling have the potential to differentially impact chemically labile and recalcitrant carbon turnover, which could lead to strong, adverse consequences on soil C storage. Our findings are alarming, considering the frequency of short-term cooling and its scale to disrupt ecosystems and biogeochemical cycling.

Published

2017

15. Divergent taxonomic and functional responses of microbial communities to field simulation of aeolian soil erosion and deposition.

Author

Ma X, Zhao C, Gao Y, Liu B, Wang T, Yuan T, Hale L, Nostrand JDV, Wan S, Zhou J, and Yang Y

Subjects

Carbon analysis, China, Nitrogen analysis, Phosphorus analysis, Potassium analysis, Bacteria classification, Grassland, Soil chemistry, Soil Microbiology

Abstract

Aeolian soil erosion and deposition have worldwide impacts on agriculture, air quality and public health. However, ecosystem responses to soil erosion and deposition remain largely unclear in regard to microorganisms, which are the crucial drivers of biogeochemical cycles. Using integrated metagenomics technologies, we analysed microbial communities subjected to simulated soil erosion and deposition in a semiarid grassland of Inner Mongolia, China. As expected, soil total organic carbon and plant coverage were decreased by soil erosion, and soil dissolved organic carbon (DOC) was increased by soil deposition, demonstrating that field simulation was reliable. Soil microbial communities were altered (p < .039) by both soil erosion and deposition, with dramatic increase in Cyanobacteria related to increased stability in soil aggregates. amyA genes encoding α-amylases were specifically increased (p = .01) by soil deposition and positively correlated (p = .02) to DOC, which likely explained changes in DOC. Surprisingly, most of microbial functional genes associated with carbon, nitrogen, phosphorus and potassium cycling were decreased or unaltered by both erosion and deposition, probably arising from acceleration of organic matter mineralization. These divergent responses support the necessity to include microbial components in evaluating ecological consequences. Furthermore, Mantel tests showed strong, significant correlations between soil nutrients and functional structure but not taxonomic structure, demonstrating close relevance of microbial function traits to nutrient cycling., (© 2017 John Wiley & Sons Ltd.)

Published

2017

16. Land scale biogeography of arsenic biotransformation genes in estuarine wetland.

Author

Zhang SY, Su JQ, Sun GX, Yang Y, Zhao Y, Ding J, Chen YS, Shen Y, Zhu G, Rensing C, and Zhu YG

Subjects

Bacteria genetics, Biotransformation genetics, China, Environment, RNA, Ribosomal, 16S genetics, Wetlands, Arsenic metabolism, Bacteria classification, Bacteria metabolism, Biotransformation physiology, Geologic Sediments microbiology

Abstract

As an analogue of phosphorus, arsenic (As) has a biogeochemical cycle coupled closely with other key elements on the Earth, such as iron, sulfate and phosphate. It has been documented that microbial genes associated with As biotransformation are widely present in As-rich environments. Nonetheless, their presence in natural environment with low As levels remains unclear. To address this issue, we investigated the abundance levels and diversities of aioA, arrA, arsC and arsM genes in estuarine sediments at low As levels across Southeastern China to uncover biogeographic patterns at a large spatial scale. Unexpectedly, genes involved in As biotransformation were characterized by high abundance and diversity. The functional microbial communities showed a significant decrease in similarity along the geographic distance, with higher turnover rates than taxonomic microbial communities based on the similarities of 16S rRNA genes. Further investigation with niche-based models showed that deterministic processes played primary roles in shaping both functional and taxonomic microbial communities. Temperature, pH, total nitrogen concentration, carbon/nitrogen ratio and ferric iron concentration rather than As content in these sediments were significantly linked to functional microbial communities, while sediment temperature and pH were linked to taxonomic microbial communities. We proposed several possible mechanisms to explain these results., (© 2017 Society for Applied Microbiology and John Wiley & Sons Ltd.)

Published

2017

17. The Composition and Spatial Patterns of Bacterial Virulence Factors and Antibiotic Resistance Genes in 19 Wastewater Treatment Plants.

Author

Zhang B, Xia Y, Wen X, Wang X, Yang Y, Zhou J, and Zhang Y

Subjects

Anti-Bacterial Agents therapeutic use, Bacteria pathogenicity, China, Disease Reservoirs microbiology, Humans, Plants microbiology, Virulence Factors isolation & purification, Bacteria genetics, Drug Resistance, Bacterial genetics, Virulence Factors genetics, Wastewater microbiology

Abstract

Bacterial pathogenicity and antibiotic resistance are of concern for environmental safety and public health. Accumulating evidence suggests that wastewater treatment plants (WWTPs) are as an important sink and source of pathogens and antibiotic resistance genes (ARGs). Virulence genes (encoding virulence factors) are good indicators for bacterial pathogenic potentials. To achieve a comprehensive understanding of bacterial pathogenic potentials and antibiotic resistance in WWTPs, bacterial virulence genes and ARGs in 19 WWTPs covering a majority of latitudinal zones of China were surveyed by using GeoChip 4.2. A total of 1610 genes covering 13 virulence factors and 1903 genes belonging to 11 ARG families were detected respectively. The bacterial virulence genes exhibited significant spatial distribution patterns of a latitudinal biodiversity gradient and a distance-decay relationship across China. Moreover, virulence genes tended to coexist with ARGs as shown by their strongly positive associations. In addition, key environmental factors shaping the overall virulence gene structure were identified. This study profiles the occurrence, composition and distribution of virulence genes and ARGs in current WWTPs in China, and uncovers spatial patterns and important environmental variables shaping their structure, which may provide the basis for further studies of bacterial virulence factors and antibiotic resistance in WWTPs., Competing Interests: The authors have declared that no competing interests exist.

Published

2016

18. The shifts of sediment microbial community phylogenetic and functional structures during chromium (VI) reduction.

Author

Yu Z, He Z, Tao X, Zhou J, Yang Y, Zhao M, Zhang X, Zheng Z, Yuan T, Liu P, Chen Y, Nolan V, and Li X

Subjects

Bacteria classification, Biodegradation, Environmental, Phylogeny, RNA, Ribosomal, 16S, Rivers, Bacteria drug effects, Chromium toxicity, Environmental Monitoring, Geologic Sediments microbiology, Water Microbiology, Water Pollutants, Chemical toxicity

Abstract

The Lanzhou reach of the Yellow River, located at the upstream of Lanzhou, has been contaminated by heavy metals and polycyclic aromatic hydrocarbons over a long-time. We hypothesized that indigenous microbial communities would remediate those contaminants and some unique populations could play an important role in this process. In this study, we investigated the sediment microbial community structure and function from the Lanzhou reach. Sediment samples were collected from two nearby sites (site A and site B) in the Lanzhou reach along the Yellow River. Sediment geochemical property data showed that site A sediment samples contained significantly (p < 0.05) higher heavy metals than site B, such as chromium (Cr), manganese (Mn), and copper (Cu). Both site A and B samples were incubated with or without hexavalent chromium (Cr (VI)) for 30 days in the laboratory, and Cr (VI) reduction was only observed in site A sediment samples. After incubation, MiSeq sequencing of 16S rRNA gene amplicons revealed that the phylogenetic composition and structure of microbial communities changed in both samples, and especially Proteobacteria, as the most abundant phylum increased from 45.1 % to 68.2 % in site A, and 50.1 % to 71.3 % in site B, respectively. Some unique OTUs and populations affiliated with Geobacter, Clostridium, Desulfosporosinus and Desulfosporosinus might be involved in Cr (VI) reduction in site A. Furthermore, GeoChip 4.0 (a comprehensive functional gene array) data showed that genes involved in carbon and nitrogen cycling and metal resistance significantly (p < 0.05) increased in site A sediment samples. All the results indicated that indigenous sediment microbial communities might be able to remediate contaminants like Cr (VI), and this information provides possible strategies for future bioremediation of the Lanzhou reach.

Published

2016

19. Distance-Decay Relationship for Biological Wastewater Treatment Plants.

Author

Wang X, Wen X, Deng Y, Xia Y, Yang Y, and Zhou J

Subjects

Archaea genetics, Bacteria genetics, China, Fungi genetics, Oligonucleotide Array Sequence Analysis, Waste Disposal, Fluid, Archaea metabolism, Bacteria metabolism, Bioreactors microbiology, Fungi metabolism, Wastewater microbiology

Abstract

Unlabelled: Patterns in the spatial distribution of organisms provide important information about mechanisms underlying biodiversity and the complexity of ecosystems. One of the most well-documented spatial patterns is the distance-decay relationship, which is a universal biogeographic pattern observed repeatedly for plant and animal communities, particularly for microorganisms in natural ecosystems such as soil, ocean, and salt marsh sediment. However, it is uncertain whether the microorganisms exhibit a distance-decay pattern in engineered ecosystems. Therefore, we measured the distance-decay relationship across various microbial functional and phylogenetic groups in 26 biological wastewater treatment plants (WWTPs) in China using a functional gene array (GeoChip 4.2). We found that microbial communities of activated sludge in WWTPs exhibited a significant but very weak distance-decay relationship. The taxon-area z values for different functional and phylogenetic groups were <0.0065, which is about 1 to 2 orders of magnitude lower than those observed in microbial communities elsewhere. Variation-partitioning analysis (VPA) showed that the relationships were driven by both environmental heterogeneity and geographic distance. Collectively, these results provided new insights into the spatial scaling of microbial communities in engineering ecosystems and highlighted the importance of environmental heterogeneity and geographic distance in shaping biogeographic patterns., Importance: Determining the distance-decay relationship of microbial biodiversity is important but challenging in microbial ecology. All studies to date are based on natural environments; thus, it remains unclear whether there is such a relationship in an engineered ecosystem. The present study shows that there is a very weak distance-decay relationship in an engineered ecosystem (WWTPs) at the regional-to-continental scale. This study makes fundamental contributions to a mechanistic, predictive understanding of microbial biogeography., (Copyright © 2016, American Society for Microbiology. All Rights Reserved.)

Published

2016

20. Temperature mediates continental-scale diversity of microbes in forest soils.

Author

Zhou J, Deng Y, Shen L, Wen C, Yan Q, Ning D, Qin Y, Xue K, Wu L, He Z, Voordeckers JW, Nostrand JD, Buzzard V, Michaletz ST, Enquist BJ, Weiser MD, Kaspari M, Waide R, Yang Y, and Brown JH

Subjects

Archaea genetics, Archaea isolation & purification, Bacteria genetics, Bacteria isolation & purification, Biodiversity, Climate Change, Forests, Fungi genetics, Fungi isolation & purification, Hydrogen-Ion Concentration, Nitrogen Fixation, Panama, RNA, Ribosomal, 16S genetics, RNA, Ribosomal, 28S genetics, Soil chemistry, Temperature, United States, Archaea classification, Bacteria classification, Fungi classification, Models, Statistical, Plants microbiology, Soil Microbiology

Abstract

Climate warming is increasingly leading to marked changes in plant and animal biodiversity, but it remains unclear how temperatures affect microbial biodiversity, particularly in terrestrial soils. Here we show that, in accordance with metabolic theory of ecology, taxonomic and phylogenetic diversity of soil bacteria, fungi and nitrogen fixers are all better predicted by variation in environmental temperature than pH. However, the rates of diversity turnover across the global temperature gradients are substantially lower than those recorded for trees and animals, suggesting that the diversity of plant, animal and soil microbial communities show differential responses to climate change. To the best of our knowledge, this is the first study demonstrating that the diversity of different microbial groups has significantly lower rates of turnover across temperature gradients than other major taxa, which has important implications for assessing the effects of human-caused changes in climate, land use and other factors.

Published

2016

21. Bacterial responses to environmental change on the Tibetan Plateau over the past half century.

Author

Liu Y, Priscu JC, Yao T, Vick-Majors TJ, Xu B, Jiao N, Santibáñez P, Huang S, Wang N, Greenwood M, Michaud AB, Kang S, Wang J, Gao Q, and Yang Y

Subjects

Bacteria classification, Bacteria genetics, Biodiversity, Climate Change, Ecosystem, Temperature, Tibet, Bacteria isolation & purification, Ice Cover microbiology

Abstract

Climate change and anthropogenic factors can alter biodiversity and can lead to changes in community structure and function. Despite the potential impacts, no long-term records of climatic influences on microbial communities exist. The Tibetan Plateau is a highly sensitive region that is currently undergoing significant alteration resulting from both climate change and increased human activity. Ice cores from glaciers in this region serve as unique natural archives of bacterial abundance and community composition, and contain concomitant records of climate and environmental change. We report high-resolution profiles of bacterial density and community composition over the past half century in ice cores from three glaciers on the Tibetan Plateau. Statistical analysis showed that the bacterial community composition in the three ice cores converged starting in the 1990s. Changes in bacterial community composition were related to changing precipitation, increasing air temperature and anthropogenic activities in the vicinity of the plateau. Collectively, our ice core data on bacteria in concert with environmental and anthropogenic proxies indicate that the convergence of bacterial communities deposited on glaciers across a wide geographical area and situated in diverse habitat types was likely induced by climatic and anthropogenic drivers., (© 2015 Society for Applied Microbiology and John Wiley & Sons Ltd.)

Published

2016

22. Network succession reveals the importance of competition in response to emulsified vegetable oil amendment for uranium bioremediation.

Author

Deng Y, Zhang P, Qin Y, Tu Q, Yang Y, He Z, Schadt CW, and Zhou J

Subjects

Bacteria genetics, Ecosystem, Microbiota genetics, Phylogeny, Bacteria metabolism, Biodegradation, Environmental, Groundwater microbiology, Plant Oils metabolism, Uranium metabolism

Abstract

Discerning network interactions among different species/populations in microbial communities has evoked substantial interests in recent years, but little information is available about temporal dynamics of microbial network interactions in response to environmental perturbations. Here, we modified the random matrix theory-based network approach to discern network succession in groundwater microbial communities in response to emulsified vegetable oil (EVO) amendment for uranium bioremediation. Groundwater microbial communities from one control and seven monitor wells were analysed with a functional gene array (GeoChip 3.0), and functional molecular ecological networks (fMENs) at different time points were reconstructed. Our results showed that the network interactions were dramatically altered by EVO amendment. Dynamic and resilient succession was evident: fairly simple at the initial stage (Day 0), increasingly complex at the middle period (Days 4, 17, 31), most complex at Day 80, and then decreasingly complex at a later stage (140-269 days). Unlike previous studies in other habitats, negative interactions predominated in a time-series fMEN, suggesting strong competition among different microbial species in the groundwater systems after EVO injection. Particularly, several keystone sulfate-reducing bacteria showed strong negative interactions with their network neighbours. These results provide mechanistic understanding of the decreased phylogenetic diversity during environmental perturbations., (© 2015 Society for Applied Microbiology and John Wiley & Sons Ltd.)

Published

2016

23. Long-term soil transplant simulating climate change with latitude significantly alters microbial temporal turnover.

Author

Liang Y, Jiang Y, Wang F, Wen C, Deng Y, Xue K, Qin Y, Yang Y, Wu L, Zhou J, and Sun B

Subjects

Agriculture, Bacteria classification, Bacteria genetics, Bacteria growth & development, Biodiversity, China, Climate, Climate Change, Molecular Sequence Data, Phylogeny, Soil chemistry, Time Factors, Bacteria isolation & purification, Soil Microbiology

Abstract

To understand soil microbial community stability and temporal turnover in response to climate change, a long-term soil transplant experiment was conducted in three agricultural experiment stations over large transects from a warm temperate zone (Fengqiu station in central China) to a subtropical zone (Yingtan station in southern China) and a cold temperate zone (Hailun station in northern China). Annual soil samples were collected from these three stations from 2005 to 2011, and microbial communities were analyzed by sequencing microbial 16S ribosomal RNA gene amplicons using Illumina MiSeq technology. Our results revealed a distinctly differential pattern of microbial communities in both northward and southward transplantations, along with an increase in microbial richness with climate cooling and a corresponding decrease with climate warming. The microbial succession rate was estimated by the slope (w value) of linear regression of a log-transformed microbial community similarity with time (time-decay relationship). Compared with the low turnover rate of microbial communities in situ (w=0.046, P<0.001), the succession rate at the community level was significantly higher in the northward transplant (w=0.058, P<0.001) and highest in the southward transplant (w=0.094, P<0.001). Climate warming lead to a faster succession rate of microbial communities as well as lower species richness and compositional changes compared with in situ and climate cooling, which may be related to the high metabolic rates and intense competition under higher temperature. This study provides new insights into the impacts of climate change on the fundamental temporal scaling of soil microbial communities and microbial phylogenetic biodiversity.

Published

2015

24. Microbial responses to southward and northward Cambisol soil transplant.

Author

Wang M, Liu S, Wang F, Sun B, Zhou J, and Yang Y

Subjects

Bacteria classification, Bacteria genetics, Bacteria metabolism, Bacterial Proteins genetics, Bacterial Proteins metabolism, Biodiversity, Carbon analysis, Carbon metabolism, Ecosystem, Nitrogen analysis, Nitrogen metabolism, Zea mays growth & development, Bacteria isolation & purification, Soil chemistry, Soil Microbiology

Abstract

Soil transplant serves as a proxy to simulate climate changes. Recently, we have shown that southward transplant of black soil and northward transplant of red soil altered soil microbial communities and biogeochemical variables. However, fundamental differences in soil types have prevented direct comparison between southward and northward transplants. To tackle it, herein we report an analysis of microbial communities of Cambisol soil in an agriculture field after 4 years of adaptation to southward and northward soil transplants over large transects. Analysis of bare fallow soils revealed concurrent increase in microbial functional diversity and coarse-scale taxonomic diversity at both transplanted sites, as detected by GeoChip 3.0 and DGGE, respectively. Furthermore, a correlation between microbial functional diversity and taxonomic diversity was detected, which was masked in maize cropped soils. Mean annual temperature, soil moisture, and nitrate (NO3 ¯-N) showed strong correlations with microbial communities. In addition, abundances of ammonium-oxidizing genes (amoA) and denitrification genes were correlated with nitrification capacity and NO3 ¯-N contents, suggesting that microbial responses to soil transplant could alter microbe-mediated biogeochemical cycle at the ecosystem level., (© 2015 The Authors. MicrobiologyOpen published by John Wiley & Sons Ltd.)

Published

2015

25. Planting increases the abundance and structure complexity of soil core functional genes relevant to carbon and nitrogen cycling.

Author

Wang F, Liang Y, Jiang Y, Yang Y, Xue K, Xiong J, Zhou J, and Sun B

Subjects

Archaea metabolism, Bacteria metabolism, Biodiversity, China, Ecosystem, Genetic Variation genetics, High-Throughput Nucleotide Sequencing, Nitrogen, Soil Microbiology, Archaea genetics, Bacteria genetics, Microbiota genetics, Nitrogen Cycle physiology, Soil chemistry, Zea mays microbiology

Abstract

Plants have an important impact on soil microbial communities and their functions. However, how plants determine the microbial composition and network interactions is still poorly understood. During a four-year field experiment, we investigated the functional gene composition of three types of soils (Phaeozem, Cambisols and Acrisol) under maize planting and bare fallow regimes located in cold temperate, warm temperate and subtropical regions, respectively. The core genes were identified using high-throughput functional gene microarray (GeoChip 3.0), and functional molecular ecological networks (fMENs) were subsequently developed with the random matrix theory (RMT)-based conceptual framework. Our results demonstrated that planting significantly (P < 0.05) increased the gene alpha-diversity in terms of richness and Shannon - Simpson's indexes for all three types of soils and 83.5% of microbial alpha-diversity can be explained by the plant factor. Moreover, planting had significant impacts on the microbial community structure and the network interactions of the microbial communities. The calculated network complexity was higher under maize planting than under bare fallow regimes. The increase of the functional genes led to an increase in both soil respiration and nitrification potential with maize planting, indicating that changes in the soil microbial communities and network interactions influenced ecological functioning.

Published

2015

26. The microbe-mediated mechanisms affecting topsoil carbon stock in Tibetan grasslands.

Author

Yue H, Wang M, Wang S, Gilbert JA, Sun X, Wu L, Lin Q, Hu Y, Li X, He Z, Zhou J, and Yang Y

Subjects

Geography, Glutamate Dehydrogenase genetics, Nitrogen chemistry, Nitrogen Oxides chemistry, Oligonucleotide Array Sequence Analysis, Oxidoreductases genetics, Soil chemistry, Temperature, Tibet, Urease genetics, Bacteria metabolism, Carbon chemistry, Grassland, Poaceae microbiology, Soil Microbiology

Abstract

Warming has been shown to cause soil carbon (C) loss in northern grasslands owing to accelerated microbial decomposition that offsets increased grass productivity. Yet, a multi-decadal survey indicated that the surface soil C stock in Tibetan alpine grasslands remained relatively stable. To investigate this inconsistency, we analyzed the feedback responses of soil microbial communities to simulated warming by soil transplant in Tibetan grasslands. Whereas microbial functional diversity decreased in response to warming, microbial community structure did not correlate with changes in temperature. The relative abundance of catabolic genes associated with nitrogen (N) and C cycling decreased with warming, most notably in genes encoding enzymes associated with more recalcitrant C substrates. By contrast, genes associated with C fixation increased in relative abundance. The relative abundance of genes associated with urease, glutamate dehydrogenase and ammonia monoxygenase (ureC, gdh and amoA) were significantly correlated with N2O efflux. These results suggest that unlike arid/semiarid grasslands, Tibetan grasslands maintain negative feedback mechanisms that preserve terrestrial C and N pools. To examine whether these trends were applicable to the whole plateau, we included these measurements in a model and verified that topsoil C stocks remained relatively stable. Thus, by establishing linkages between microbial metabolic potential and soil biogeochemical processes, we conclude that long-term C loss in Tibetan grasslands is ameliorated by a reduction in microbial decomposition of recalcitrant C substrates.

Published

2015

27. Responses of Bacterial Communities to Simulated Climate Changes in Alpine Meadow Soil of the Qinghai-Tibet Plateau.

Author

Rui J, Li J, Wang S, An J, Liu WT, Lin Q, Yang Y, He Z, and Li X

Subjects

Altitude, Bacteria classification, Bacteria genetics, Climate Change, DNA, Bacterial genetics, Ecosystem, Molecular Sequence Data, RNA, Ribosomal, 16S genetics, Tibet, Bacteria isolation & purification, Soil Microbiology

Abstract

The soil microbial community plays an important role in terrestrial carbon and nitrogen cycling. However, microbial responses to climate warming or cooling remain poorly understood, limiting our ability to predict the consequences of future climate changes. To address this issue, it is critical to identify microbes sensitive to climate change and key driving factors shifting microbial communities. In this study, alpine soil transplant experiments were conducted downward or upward along an elevation gradient between 3,200 and 3,800 m in the Qinghai-Tibet plateau to simulate climate warming or cooling. After a 2-year soil transplant experiment, soil bacterial communities were analyzed by pyrosequencing of 16S rRNA gene amplicons. The results showed that the transplanted soil bacterial communities became more similar to those in their destination sites and more different from those in their "home" sites. Warming led to increases in the relative abundances in Alphaproteobacteria, Gammaproteobacteria, and Actinobacteria and decreases in Acidobacteria, Betaproteobacteria, and Deltaproteobacteria, while cooling had opposite effects on bacterial communities (symmetric response). Soil temperature and plant biomass contributed significantly to shaping the bacterial community structure. Overall, climate warming or cooling shifted the soil bacterial community structure mainly through species sorting, and such a shift might correlate to important biogeochemical processes such as greenhouse gas emissions. This study provides new insights into our understanding of soil bacterial community responses to climate warming and cooling., (Copyright © 2015, American Society for Microbiology. All Rights Reserved.)

Published

2015

28. Over 150 years of long-term fertilization alters spatial scaling of microbial biodiversity.

Author

Liang Y, Wu L, Clark IM, Xue K, Yang Y, Van Nostrand JD, Deng Y, He Z, McGrath S, Storkey J, Hirsch PR, Sun B, and Zhou J

Subjects

Archaea genetics, Bacteria genetics, Fungi genetics, Microarray Analysis, Oligonucleotide Array Sequence Analysis, Soil Microbiology, Agriculture methods, Archaea classification, Bacteria classification, Biota, Fertilizers statistics & numerical data, Fungi classification, Plants classification

Abstract

Unlabelled: Spatial scaling is a critical issue in ecology, but how anthropogenic activities like fertilization affect spatial scaling is poorly understood, especially for microbial communities. Here, we determined the effects of long-term fertilization on the spatial scaling of microbial functional diversity and its relationships to plant diversity in the 150-year-old Park Grass Experiment, the oldest continuous grassland experiment in the world. Nested samples were taken from plots with contrasting inorganic fertilization regimes, and community DNAs were analyzed using the GeoChip-based functional gene array. The slopes of microbial gene-area relationships (GARs) and plant species-area relationships (SARs) were estimated in a plot receiving nitrogen (N), phosphorus (P), and potassium (K) and a control plot without fertilization. Our results indicated that long-term inorganic fertilization significantly increased both microbial GARs and plant SARs. Microbial spatial turnover rates (i.e., z values) were less than 0.1 and were significantly higher in the fertilized plot (0.0583) than in the control plot (0.0449) (P < 0.0001). The z values also varied significantly with different functional genes involved in carbon (C), N, P, and sulfur (S) cycling and with various phylogenetic groups (archaea, bacteria, and fungi). Similarly, the plant SARs increased significantly (P < 0.0001), from 0.225 in the control plot to 0.419 in the fertilized plot. Soil fertilization, plant diversity, and spatial distance had roughly equal contributions in shaping the microbial functional community structure, while soil geochemical variables contributed less. These results indicated that long-term agricultural practice could alter the spatial scaling of microbial biodiversity., Importance: Determining the spatial scaling of microbial biodiversity and its response to human activities is important but challenging in microbial ecology. Most studies to date are based on different sites that may not be truly comparable or on short-term perturbations, and hence, the results observed could represent transient responses. This study examined the spatial patterns of microbial communities in response to different fertilization regimes at the Rothamsted Research Experimental Station, which has become an invaluable resource for ecologists, environmentalists, and soil scientists. The current study is the first showing that long-term fertilization has dramatic impacts on the spatial scaling of microbial communities. By identifying the spatial patterns in response to long-term fertilization and their underlying mechanisms, this study makes fundamental contributions to predictive understanding of microbial biogeography., (Copyright © 2015 Liang et al.)

Published

2015

29. The interactive effects of soil transplant into colder regions and cropping on soil microbiology and biogeochemistry.

Author

Liu S, Wang F, Xue K, Sun B, Zhang Y, He Z, Van Nostrand JD, Zhou J, and Yang Y

Subjects

Ammonia metabolism, Archaea genetics, Bacteria genetics, Biomass, China, Climate, Nitrification, Nitrogen analysis, Nitrogen Cycle, Oxidation-Reduction, Soil, Zea mays growth & development, Zea mays microbiology, Archaea metabolism, Bacteria metabolism, Cold Temperature adverse effects, Microbial Consortia genetics, Soil Microbiology

Abstract

Soil transplant into warmer regions has been shown to alter soil microbiology. In contrast, little is known about the effects of soil transplant into colder regions, albeit that climate cooling has solicited attention in recent years. To address this question, we transplanted bare fallow soil over large transects from southern China (subtropical climate zone) to central (warm temperate climate zone) and northern China (cold temperate climate zone). After an adaptation period of 4 years, soil nitrogen components, microbial biomass and community structures were altered. However, the effects of soil transplant on microbial communities were dampened by maize cropping, unveiling a negative interaction between cropping and transplant. Further statistical analyses with Canonical correspondence analysis and Mantel tests unveiled annual average temperature, relative humidity, aboveground biomass, soil pH and NH4 (+) -N content as environmental attributes closely correlated with microbial functional structures. In addition, average abundances of amoA-AOA (ammonia-oxidizing archaea) and amoA-AOB (ammonia-oxidizing bacteria) genes were significantly (P < 0.05) correlated with soil nitrification capacity, hence both AOA and AOB contributed to the soil functional process of nitrification. These results suggested that the soil nitrogen cycle was intimately linked with microbial community structure, and both were subjected to disturbance by soil transplant to colder regions and plant cropping., (© 2014 Society for Applied Microbiology and John Wiley & Sons Ltd.)

Published

2015

30. High-throughput metagenomic technologies for complex microbial community analysis: open and closed formats.

Author

Zhou J, He Z, Yang Y, Deng Y, Tringe SG, and Alvarez-Cohen L

Subjects

Bacteria classification, Ecosystem, Soil Microbiology, Bacteria genetics, Bacteria isolation & purification, High-Throughput Nucleotide Sequencing methods, Metagenomics methods

Abstract

Understanding the structure, functions, activities and dynamics of microbial communities in natural environments is one of the grand challenges of 21st century science. To address this challenge, over the past decade, numerous technologies have been developed for interrogating microbial communities, of which some are amenable to exploratory work (e.g., high-throughput sequencing and phenotypic screening) and others depend on reference genes or genomes (e.g., phylogenetic and functional gene arrays). Here, we provide a critical review and synthesis of the most commonly applied "open-format" and "closed-format" detection technologies. We discuss their characteristics, advantages, and disadvantages within the context of environmental applications and focus on analysis of complex microbial systems, such as those in soils, in which diversity is high and reference genomes are few. In addition, we discuss crucial issues and considerations associated with applying complementary high-throughput molecular technologies to address important ecological questions., (Copyright © 2015 Zhou et al.)

Published

2015

31. Contrasting soil microbial community functional structures in two major landscapes of the Tibetan alpine meadow.

Author

Chu H, Wang S, Yue H, Lin Q, Hu Y, Li X, Zhou J, and Yang Y

Subjects

Bacteria genetics, Bacteria metabolism, Bacterial Proteins genetics, Bacterial Proteins metabolism, Biodiversity, Carbon analysis, Carbon metabolism, Ecosystem, Nitrogen analysis, Nitrogen metabolism, Soil chemistry, Tibet, Bacteria classification, Bacteria isolation & purification, Soil Microbiology

Abstract

The grassland and shrubland are two major landscapes of the Tibetan alpine meadow, a region very sensitive to the impact of global warming and anthropogenic perturbation. Herein, we report a study showing that a majority of differences in soil microbial community functional structures, measured by a functional gene array named GeoChip 4.0, in two adjacent shrubland and grassland areas, were explainable by environmental properties, suggesting that the harsh environments in the alpine grassland rendered niche adaptation important. Furthermore, genes involved in labile carbon degradation were more abundant in the shrubland than those of the grassland but genes involved in recalcitrant carbon degradation were less abundant, which was conducive to long-term carbon storage and sequestration in the shrubland despite low soil organic carbon content. In addition, genes of anerobic nitrogen cycling processes such as denitrification and dissimilatory nitrogen reduction were more abundant, shifting soil nitrogen cycling toward ammonium biosynthesis and consequently leading to higher soil ammonium contents. We also noted higher abundances of stress genes responsive to nitrogen limitation and oxygen limitation, which might be attributed to low total nitrogen and higher water contents in the shrubland. Together, these results provide mechanistic knowledge about microbial linkages to soil carbon and nitrogen storage and potential consequences of vegetation shifts in the Tibetan alpine meadow., (© 2014 The Authors. MicrobiologyOpen published by John Wiley & Sons Ltd.)

Published

2014

32. Linkages between microbial functional potential and wastewater constituents in large-scale membrane bioreactors for municipal wastewater treatment.

Author

Sun Y, Shen YX, Liang P, Zhou J, Yang Y, and Huang X

Subjects

Bacterial Proteins metabolism, Cities, Gene Expression Regulation, Bacterial physiology, Water Pollutants, Bacteria metabolism, Bioreactors, Membranes, Artificial, Waste Disposal, Fluid methods, Wastewater microbiology

Abstract

Large-scale membrane bioreactors (MBRs) have been widely used for the municipal wastewater treatment, whose performance relies on microbial communities of activated sludge. Nevertheless, microbial functional structures in MBRs remain little understood. To gain insight into functional genes and their steering environmental factors, we adopted GeoChip, a high-throughput microarray-based tool, to examine microbial genes in four large-scale, in-operation MBRs located in Beijing, China. The results revealed substantial microbial gene heterogeneity (43.7-85.1% overlaps) among different MBRs. Mantel tests indicated that microbial nutrient cycling genes were significantly (P < 0.05) correlated to influent COD, [Formula: see text] -N, TP or sulfate, which signified the importance of microbial mediation of wastewater constituent removal. In addition, functional genes shared by all four MBRs contained a large number of genes involved in antibiotics resistance, metal resistance and organic remediation, suggesting that they were required for degradation or resistance to toxic compounds in wastewater. The linkages between microbial functional structures and environmental variables were also unveiled by the finding of hydraulic retention time, influent COD, [Formula: see text] -N, mixed liquid temperature and humic substances as major factors shaping microbial communities. Together, the results presented demonstrate the utility of GeoChip-based microarray approach in examining microbial communities of wastewater treatment plants and provide insights into the forces driving important processes of element cycling., (Copyright © 2014 Elsevier Ltd. All rights reserved.)

Published

2014

33. An integrated study to analyze soil microbial community structure and metabolic potential in two forest types.

Author

Zhang Y, Cong J, Lu H, Yang C, Yang Y, Zhou J, and Li D

Subjects

Bacteria classification, Biodiversity, Carbon metabolism, Genetic Variation, High-Throughput Nucleotide Sequencing, Nitrogen metabolism, Plants microbiology, Bacteria genetics, Bacteria metabolism, Forests, Soil Microbiology

Abstract

Soil microbial metabolic potential and ecosystem function have received little attention owing to difficulties in methodology. In this study, we selected natural mature forest and natural secondary forest and analyzed the soil microbial community and metabolic potential combing the high-throughput sequencing and GeoChip technologies. Phylogenetic analysis based on 16S rRNA sequencing showed that one known archaeal phylum and 15 known bacterial phyla as well as unclassified phylotypes were presented in these forest soils, and Acidobacteria, Protecobacteria, and Actinobacteria were three of most abundant phyla. The detected microbial functional gene groups were related to different biogeochemical processes, including carbon degradation, carbon fixation, methane metabolism, nitrogen cycling, phosphorus utilization, sulfur cycling, etc. The Shannon index for detected functional gene probes was significantly higher (P<0.05) at natural secondary forest site. The regression analysis showed that a strong positive (P<0.05) correlation was existed between the soil microbial functional gene diversity and phylogenetic diversity. Mantel test showed that soil oxidizable organic carbon, soil total nitrogen and cellulose, glucanase, and amylase activities were significantly linked (P<0.05) to the relative abundance of corresponded functional gene groups. Variance partitioning analysis showed that a total of 81.58% of the variation in community structure was explained by soil chemical factors, soil temperature, and plant diversity. Therefore, the positive link of soil microbial structure and composition to functional activity related to ecosystem functioning was existed, and the natural secondary forest soil may occur the high microbial metabolic potential. Although the results can't directly reflect the actual microbial populations and functional activities, this study provides insight into the potential activity of the microbial community and associated feedback responses of the terrestrial ecosystem to environmental changes.

Published

2014

34. The microbial gene diversity along an elevation gradient of the Tibetan grassland.

Author

Yang Y, Gao Y, Wang S, Xu D, Yu H, Wu L, Lin Q, Hu Y, Li X, He Z, Deng Y, and Zhou J

Subjects

Bacteria metabolism, Metagenomics, Poaceae microbiology, Tibet, Altitude, Bacteria genetics, Ecosystem, Genes, Microbial genetics, Genetic Variation, Metagenome, Soil Microbiology

Abstract

Tibet is one of the most threatened regions by climate warming, thus understanding how its microbial communities function may be of high importance for predicting microbial responses to climate changes. Here, we report a study to profile soil microbial structural genes, which infers functional roles of microbial communities, along four sites/elevations of a Tibetan mountainous grassland, aiming to explore the potential microbial responses to climate changes via a strategy of space-for-time substitution. Using a microarray-based metagenomics tool named GeoChip 4.0, we showed that microbial communities were distinct for most but not all of the sites. Substantial variations were apparent in stress, N and C-cycling genes, but they were in line with the functional roles of these genes. Cold shock genes were more abundant at higher elevations. Also, gdh converting ammonium into urea was more abundant at higher elevations, whereas ureC converting urea into ammonium was less abundant, which was consistent with soil ammonium contents. Significant correlations were observed between N-cycling genes (ureC, gdh and amoA) and nitrous oxide flux, suggesting that they contributed to community metabolism. Lastly, we found by Canonical correspondence analysis, Mantel tests and the similarity tests that soil pH, temperature, NH4(+)-N and vegetation diversity accounted for the majority (81.4%) of microbial community variations, suggesting that these four attributes were major factors affecting soil microbial communities. On the basis of these observations, we predict that climate changes in the Tibetan grasslands are very likely to change soil microbial community functional structure, with particular impacts on microbial N-cycling genes and consequently microbe-mediated soil N dynamics.

Published

2014

35. Phylogenetic molecular ecological network of soil microbial communities in response to elevated CO2.

Author

Zhou J, Deng Y, Luo F, He Z, and Yang Y

Subjects

Archaea genetics, Bacteria genetics, Carbon analysis, Cluster Analysis, DNA, Archaeal chemistry, DNA, Archaeal genetics, DNA, Bacterial chemistry, DNA, Bacterial genetics, DNA, Ribosomal chemistry, DNA, Ribosomal genetics, Genes, rRNA, High-Throughput Nucleotide Sequencing, Minnesota, Nitrogen analysis, Phylogeny, RNA, Archaeal genetics, RNA, Bacterial genetics, RNA, Ribosomal, 16S genetics, Sequence Homology, Nucleic Acid, Soil chemistry, Archaea classification, Bacteria classification, Biodiversity, Carbon Dioxide metabolism, Ecosystem, Metagenome, Soil Microbiology

Abstract

Unlabelled: Understanding the interactions among different species and their responses to environmental changes, such as elevated atmospheric concentrations of CO(2), is a central goal in ecology but is poorly understood in microbial ecology. Here we describe a novel random matrix theory (RMT)-based conceptual framework to discern phylogenetic molecular ecological networks using metagenomic sequencing data of 16S rRNA genes from grassland soil microbial communities, which were sampled from a long-term free-air CO(2) enrichment experimental facility at the Cedar Creek Ecosystem Science Reserve in Minnesota. Our experimental results demonstrated that an RMT-based network approach is very useful in delineating phylogenetic molecular ecological networks of microbial communities based on high-throughput metagenomic sequencing data. The structure of the identified networks under ambient and elevated CO(2) levels was substantially different in terms of overall network topology, network composition, node overlap, module preservation, module-based higher-order organization, topological roles of individual nodes, and network hubs, suggesting that the network interactions among different phylogenetic groups/populations were markedly changed. Also, the changes in network structure were significantly correlated with soil carbon and nitrogen contents, indicating the potential importance of network interactions in ecosystem functioning. In addition, based on network topology, microbial populations potentially most important to community structure and ecosystem functioning can be discerned. The novel approach described in this study is important not only for research on biodiversity, microbial ecology, and systems microbiology but also for microbial community studies in human health, global change, and environmental management., Importance: The interactions among different microbial populations in a community play critical roles in determining ecosystem functioning, but very little is known about the network interactions in a microbial community, owing to the lack of appropriate experimental data and computational analytic tools. High-throughput metagenomic technologies can rapidly produce a massive amount of data, but one of the greatest difficulties is deciding how to extract, analyze, synthesize, and transform such a vast amount of information into biological knowledge. This study provides a novel conceptual framework to identify microbial interactions and key populations based on high-throughput metagenomic sequencing data. This study is among the first to document that the network interactions among different phylogenetic populations in soil microbial communities were substantially changed by a global change such as an elevated CO(2) level. The framework developed will allow microbiologists to address research questions which could not be approached previously, and hence, it could represent a new direction in microbial ecology research.

Published

2011

36. Warming effects on grassland soil microbial communities are amplified in cool months

Author

Lei, Jiesi, Su, Yuanlong, Jian, Siyang, Guo, Xue, Yuan, Mengting, Bates, Colin T, Shi, Zhou Jason, Li, Jiabao, Su, Yifan, Ning, Daliang, Wu, Liyou, Zhou, Jizhong, and Yang, Yunfeng

Subjects

Biological Sciences, Ecology, Soil Microbiology, Grassland, Microbiota, Seasons, Soil, Global Warming, Bacteria, Carbon, Temperature, soil respiration, microbial functional traits, seasonal succession, global warming, carbon decomposition, Environmental Sciences, Technology, Microbiology, Biological sciences, Environmental sciences

Abstract

Global warming modulates soil respiration (RS) via microbial decomposition, which is seasonally dependent. Yet, the magnitude and direction of this modulation remain unclear, partly owing to the lack of knowledge on how microorganisms respond to seasonal changes. Here, we investigated the temporal dynamics of soil microbial communities over 12 consecutive months under experimental warming in a tallgrass prairie ecosystem. The interplay between warming and time altered (P

Published

2024

37. Reduction of microbial diversity in grassland soil is driven by long-term climate warming

Author

Wu, Linwei, Zhang, Ya, Guo, Xue, Ning, Daliang, Zhou, Xishu, Feng, Jiajie, Yuan, Mengting Maggie, Liu, Suo, Guo, Jiajing, Gao, Zhipeng, Ma, Jie, Kuang, Jialiang, Jian, Siyang, Han, Shun, Yang, Zhifeng, Ouyang, Yang, Fu, Ying, Xiao, Naijia, Liu, Xueduan, Wu, Liyou, Zhou, Aifen, Yang, Yunfeng, Tiedje, James M, and Zhou, Jizhong

Subjects

Microbiology, Biological Sciences, Ecology, Life Below Water, Climate Action, Bacteria, Biodiversity, Ecosystem, Grassland, Soil, Soil Microbiology, Medical Microbiology

Abstract

Anthropogenic climate change threatens ecosystem functioning. Soil biodiversity is essential for maintaining the health of terrestrial systems, but how climate change affects the richness and abundance of soil microbial communities remains unresolved. We examined the effects of warming, altered precipitation and annual biomass removal on grassland soil bacterial, fungal and protistan communities over 7 years to determine how these representative climate changes impact microbial biodiversity and ecosystem functioning. We show that experimental warming and the concomitant reductions in soil moisture play a predominant role in shaping microbial biodiversity by decreasing the richness of bacteria (9.6%), fungi (14.5%) and protists (7.5%). Our results also show positive associations between microbial biodiversity and ecosystem functional processes, such as gross primary productivity and microbial biomass. We conclude that the detrimental effects of biodiversity loss might be more severe in a warmer world.

Published

2022

38. Gene-informed decomposition model predicts lower soil carbon loss due to persistent microbial adaptation to warming.

Author

Guo, Xue, Gao, Qun, Yuan, Mengting, Wang, Gangsheng, Zhou, Xishu, Feng, Jiajie, Shi, Zhou, Hale, Lauren, Wu, Linwei, Zhou, Aifen, Tian, Renmao, Liu, Feifei, Wu, Bo, Chen, Lijun, Jung, Chang Gyo, Niu, Shuli, Li, Dejun, Xu, Xia, Jiang, Lifen, Escalas, Arthur, Wu, Liyou, He, Zhili, Van Nostrand, Joy D, Ning, Daliang, Liu, Xueduan, Yang, Yunfeng, Schuur, Edward AG, Konstantinidis, Konstantinos T, Cole, James R, Penton, C Ryan, Luo, Yiqi, Tiedje, James M, and Zhou, Jizhong

Subjects

Bacteria, Fungi, Poaceae, Plant Roots, Archaea, Carbon, Cellulose, Soil, Soil Microbiology, Acclimatization, Models, Genetic, Hot Temperature, Metagenome, Metagenomics, Global Warming, Carbon Cycle, Microbiota, Grassland, Environmental DNA, Models, Genetic

Abstract

Soil microbial respiration is an important source of uncertainty in projecting future climate and carbon (C) cycle feedbacks. However, its feedbacks to climate warming and underlying microbial mechanisms are still poorly understood. Here we show that the temperature sensitivity of soil microbial respiration (Q10) in a temperate grassland ecosystem persistently decreases by 12.0 ± 3.7% across 7 years of warming. Also, the shifts of microbial communities play critical roles in regulating thermal adaptation of soil respiration. Incorporating microbial functional gene abundance data into a microbially-enabled ecosystem model significantly improves the modeling performance of soil microbial respiration by 5-19%, and reduces model parametric uncertainty by 55-71%. In addition, modeling analyses show that the microbial thermal adaptation can lead to considerably less heterotrophic respiration (11.6 ± 7.5%), and hence less soil C loss. If such microbially mediated dampening effects occur generally across different spatial and temporal scales, the potential positive feedback of soil microbial respiration in response to climate warming may be less than previously predicted.

Published

2020

39. A quantitative framework reveals ecological drivers of grassland microbial community assembly in response to warming.

Author

Ning, Daliang, Yuan, Mengting, Wu, Linwei, Zhang, Ya, Guo, Xue, Zhou, Xishu, Yang, Yunfeng, Arkin, Adam P, Firestone, Mary K, and Zhou, Jizhong

Subjects

Animals, Bacteria, Sensitivity and Specificity, Ecology, Biodiversity, Phylogeny, Models, Biological, Droughts, Global Warming, Microbiota, Grassland, Models, Biological

Abstract

Unraveling the drivers controlling community assembly is a central issue in ecology. Although it is generally accepted that selection, dispersal, diversification and drift are major community assembly processes, defining their relative importance is very challenging. Here, we present a framework to quantitatively infer community assembly mechanisms by phylogenetic bin-based null model analysis (iCAMP). iCAMP shows high accuracy (0.93-0.99), precision (0.80-0.94), sensitivity (0.82-0.94), and specificity (0.95-0.98) on simulated communities, which are 10-160% higher than those from the entire community-based approach. Application of iCAMP to grassland microbial communities in response to experimental warming reveals dominant roles of homogeneous selection (38%) and 'drift' (59%). Interestingly, warming decreases 'drift' over time, and enhances homogeneous selection which is primarily imposed on Bacillales. In addition, homogeneous selection has higher correlations with drought and plant productivity under warming than control. iCAMP provides an effective and robust tool to quantify microbial assembly processes, and should also be useful for plant and animal ecology.

Published

2020

40. Global diversity and biogeography of bacterial communities in wastewater treatment plants

Author

Wu, Linwei, Ning, Daliang, Zhang, Bing, Li, Yong, Zhang, Ping, Shan, Xiaoyu, Zhang, Qiuting, Brown, Mathew Robert, Li, Zhenxin, Van Nostrand, Joy D, Ling, Fangqiong, Xiao, Naijia, Zhang, Ya, Vierheilig, Julia, Wells, George F, Yang, Yunfeng, Deng, Ye, Tu, Qichao, Wang, Aijie, Zhang, Tong, He, Zhili, Keller, Jurg, Nielsen, Per H, Alvarez, Pedro JJ, Criddle, Craig S, Wagner, Michael, Tiedje, James M, He, Qiang, Curtis, Thomas P, Stahl, David A, Alvarez-Cohen, Lisa, Rittmann, Bruce E, Wen, Xianghua, and Zhou, Jizhong

Subjects

Microbiology, Biological Sciences, Ecology, Infection, Bacteria, Biodiversity, DNA, Bacterial, Geography, Microbiota, RNA, Ribosomal, 16S, Sequence Analysis, DNA, Sewage, Water Purification, Global Water Microbiome Consortium, Medical Microbiology

Abstract

Microorganisms in wastewater treatment plants (WWTPs) are essential for water purification to protect public and environmental health. However, the diversity of microorganisms and the factors that control it are poorly understood. Using a systematic global-sampling effort, we analysed the 16S ribosomal RNA gene sequences from ~1,200 activated sludge samples taken from 269 WWTPs in 23 countries on 6 continents. Our analyses revealed that the global activated sludge bacterial communities contain ~1 billion bacterial phylotypes with a Poisson lognormal diversity distribution. Despite this high diversity, activated sludge has a small, global core bacterial community (n = 28 operational taxonomic units) that is strongly linked to activated sludge performance. Meta-analyses with global datasets associate the activated sludge microbiomes most closely to freshwater populations. In contrast to macroorganism diversity, activated sludge bacterial communities show no latitudinal gradient. Furthermore, their spatial turnover is scale-dependent and appears to be largely driven by stochastic processes (dispersal and drift), although deterministic factors (temperature and organic input) are also important. Our findings enhance our mechanistic understanding of the global diversity and biogeography of activated sludge bacterial communities within a theoretical ecology framework and have important implications for microbial ecology and wastewater treatment processes.

Published

2019

41. High variations of methanogenic microorganisms drive full-scale anaerobic digestion process.

Author

Zhang, Qiuting, Wang, Mengmeng, Ma, Xingyu, Gao, Qun, Wang, Tengxu, Shi, Xuchuan, Zhou, Jizhong, Zuo, Jiane, and Yang, Yunfeng

Subjects

Bacteria, Archaea, Methane, Bioreactors, Waste Disposal, Fluid, Anaerobiosis, Genes, Archaeal, Genes, Bacterial, Biofuels, Microbiota, Anaerobic digestion, Methane production, Succession, Temporal stability, Environmental Sciences

Abstract

Anaerobic digestion is one of the most successful waste management strategies worldwide, wherein microorganisms play an essential role in reducing organic pollutants and producing renewable energy. However, variations of microbial community in full-scale anaerobic digesters, particularly functional groups relevant to biogas production, remain elusive. Here, we examined microbial community in a year-long monthly time series of 3 full-scale anaerobic digesters. We observed substantial diversification in community composition, with only a few abundant OTUs (e.g. Clostridiales, Anaerolineaceae and Methanosaeta) persistently present across different samples. Similarly, there were high variations in relative abundance of methanogenic archaea and methanogenic genes, which were positively correlated (r2 = 0.530, P

Published

2019

42. Climate warming accelerates temporal scaling of grassland soil microbial biodiversity

Author

Guo, Xue, Zhou, Xishu, Hale, Lauren, Yuan, Mengting, Ning, Daliang, Feng, Jiajie, Shi, Zhou, Li, Zhenxin, Feng, Bin, Gao, Qun, Wu, Linwei, Shi, Weiling, Zhou, Aifen, Fu, Ying, Wu, Liyou, He, Zhili, Van Nostrand, Joy D, Qiu, Guanzhou, Liu, Xueduan, Luo, Yiqi, Tiedje, James M, Yang, Yunfeng, and Zhou, Jizhong

Subjects

Environmental Sciences, Biological Sciences, Ecology, Bacteria, Biodiversity, Climate Change, DNA, Bacterial, DNA, Fungal, Fungi, Grassland, RNA, Ribosomal, 16S, Soil Microbiology, Evolutionary biology, Environmental management

Abstract

Determining the temporal scaling of biodiversity, typically described as species-time relationships (STRs), in the face of global climate change is a central issue in ecology because it is fundamental to biodiversity preservation and ecosystem management. However, whether and how climate change affects microbial STRs remains unclear, mainly due to the scarcity of long-term experimental data. Here, we examine the STRs and phylogenetic-time relationships (PTRs) of soil bacteria and fungi in a long-term multifactorial global change experiment with warming (+3 °C), half precipitation (-50%), double precipitation (+100%) and clipping (annual plant biomass removal). Soil bacteria and fungi all exhibited strong STRs and PTRs across the 12 experimental conditions. Strikingly, warming accelerated the bacterial and fungal STR and PTR exponents (that is, the w values), yielding significantly (P

Published

2019

43. Correspondence: Reply to 'Analytical flaws in a continental-scale forest soil microbial diversity study'.

Author

Zhou, Jizhong, Deng, Ye, Shen, Lina, Wen, Chongqing, Yan, Qingyun, Ning, Daliang, Qin, Yujia, Xue, Kai, Wu, Liyou, He, Zhili, Voordeckers, James W, Van Nostrand, Joy D, Buzzard, Vanessa, Michaletz, Sean T, Enquist, Brian J, Weiser, Michael D, Kaspari, Michael, Waide, Robert, Yang, Yunfeng, and Brown, James H

Subjects

Bacteria, Fungi, Soil, Data Interpretation, Statistical, Soil Microbiology, Biodiversity, Temperature, North America, Data Interpretation, Statistical, MD Multidisciplinary

Published

2017

44. Molecular mechanisms of water table lowering and nitrogen deposition in affecting greenhouse gas emissions from a Tibetan alpine wetland

Author

Wang, Hao, Yu, Lingfei, Zhang, Zhenhua, Liu, Wei, Chen, Litong, Cao, Guangmin, Yue, Haowei, Zhou, Jizhong, Yang, Yunfeng, Tang, Yanhong, and He, Jin‐Sheng

Subjects

Climate Action, Bacteria, Carbon Dioxide, Climate Change, Greenhouse Effect, Groundwater, Methane, Nitrogen, Nitrous Oxide, Tibet, Wetlands, carbon cycle, climate warming, methane, microbial functional gene, nitrous oxide, the Tibetan Plateau, Environmental Sciences, Biological Sciences, Ecology

Abstract

Rapid climate change and intensified human activities have resulted in water table lowering (WTL) and enhanced nitrogen (N) deposition in Tibetan alpine wetlands. These changes may alter the magnitude and direction of greenhouse gas (GHG) emissions, affecting the climate impact of these fragile ecosystems. We conducted a mesocosm experiment combined with a metagenomics approach (GeoChip 5.0) to elucidate the effects of WTL (-20 cm relative to control) and N deposition (30 kg N ha-1  yr-1 ) on carbon dioxide (CO2 ), methane (CH4 ) and nitrous oxide (N2 O) fluxes as well as the underlying mechanisms. Our results showed that WTL reduced CH4 emissions by 57.4% averaged over three growing seasons compared with no-WTL plots, but had no significant effect on net CO2 uptake or N2 O flux. N deposition increased net CO2 uptake by 25.2% in comparison with no-N deposition plots and turned the mesocosms from N2 O sinks to N2 O sources, but had little influence on CH4 emissions. The interactions between WTL and N deposition were not detected in all GHG emissions. As a result, WTL and N deposition both reduced the global warming potential (GWP) of growing season GHG budgets on a 100-year time horizon, but via different mechanisms. WTL reduced GWP from 337.3 to -480.1 g CO2 -eq m-2 mostly because of decreased CH4 emissions, while N deposition reduced GWP from 21.0 to -163.8 g CO2 -eq m-2 , mainly owing to increased net CO2 uptake. GeoChip analysis revealed that decreased CH4 production potential, rather than increased CH4 oxidation potential, may lead to the reduction in net CH4 emissions, and decreased nitrification potential and increased denitrification potential affected N2 O fluxes under WTL conditions. Our study highlights the importance of microbial mechanisms in regulating ecosystem-scale GHG responses to environmental changes.

Published

2017

45. Microbial functional traits are sensitive indicators of mild disturbance by lamb grazing

Author

Ma, Xingyu, Zhang, Qiuting, Zheng, Mengmei, Gao, Ying, Yuan, Tong, Hale, Lauren, Van Nostrand, Joy D, Zhou, Jizhong, Wan, Shiqiang, and Yang, Yunfeng

Subjects

Soil, Technology, Sheep, Bacteria, Microbiota, Genetics, Animals, Feeding Behavior, Biological Sciences, Grassland, Microbiology, Soil Microbiology, Environmental Sciences

Abstract

Mild disturbances are prevalent in the environment, which may not be easily notable but could have considerable ecological consequences over prolonged periods. To evaluate this, a field study was designed to examine the effects of very light-intensity lamb grazing on grassland soil microbiomes with different soil backgrounds. No significant change (P > 0.05) was observed in any vegetation and soil variables. Nonetheless, hundreds of microbial functional gene families, but not bacterial taxonomy, were significantly (P

Published

2019

46. Dissimilar responses of fungal and bacterial communities to soil transplantation simulating abrupt climate changes

Author

Zhao, Mengxin, Sun, Bo, Wu, Linwei, Wang, Feng, Wen, Chongqing, Wang, Mengmeng, Liang, Yuting, Hale, Lauren, Zhou, Jizhong, and Yang, Yunfeng

Subjects

China, Evolutionary Biology, Bacteria, Climate Change, soil microbial community, Fungi, high-throughput sequencing, soil transplantation, Biological Sciences, Soil Microbiology, carbon-decomposing genes, Mycobiome, Carbon Cycle

Abstract

Both fungi and bacteria play essential roles in regulating soil carbon cycling. To predict future carbon stability, it is imperative to understand their responses to environmental changes, which is subject to large uncertainty. As current global warming is causing range shifts toward higher latitudes, we conducted three reciprocal soil transplantation experiments over large transects in 2005 to simulate abrupt climate changes. Six years after soil transplantation, fungal biomass of transplanted soils showed a general pattern of changes from donor sites to destination, which were more obvious in bare fallow soils than in maize cropped soils. Strikingly, fungal community compositions were clustered by sites, demonstrating that fungi of transplanted soils acclimatized to the destination environment. Several fungal taxa displayed sharp changes in relative abundance, including Podospora, Chaetomium, Mortierella and Phialemonium. In contrast, bacterial communities remained largely unchanged. Consistent with the important role of fungi in affecting soil carbon cycling, 8.1%-10.0% of fungal genes encoding carbon-decomposing enzymes were significantly (p

Published

2019

47. Global diversity and biogeography of bacterial communities in wastewater treatment plants

Author

Wu, Linwei, Ning, Daliang, Zhang, Bing, Li, Yong, Zhang, Ping, Shan, Xiaoyu, Zhang, Qiuting, Brown, Mathew, Li, Zhenxin, Van Nostrand, Joy D., Ling, Fangqiong, Xiao, Naijia, Zhang, Ya, Vierheilig, Julia, Wells, George F., Yang, Yunfeng, Deng, Ye, Tu, Qichao, Wang, Aijie, Zhang, Tong, He, Zhili, Keller, Jurg, Nielsen, Per H., Alvarez, Pedro J.J., Criddle, Craig S., Wagner, Michael, Tiedje, James M., He, Qiang, Curtis, Thomas P., Stahl, David A., Alvarez-Cohen, Lisa, Rittmann, Bruce E., Wen, Xianghua, Zhou, Jizhong, Acevedo, Dany, Agullo-Barcelo, Miriam, Andersen, Gary L., de Araujo, Juliana Calabria, Boehnke, Kevin, Bond, Philip, Bott, Charles B., Bovio, Patricia, Brewster, Rebecca K., Bux, Faizal, Cabezas, Angela, Cabrol, Léa, Chen, Si, Etchebehere, Claudia, Ford, Amanda, Frigon, Dominic, Gómez, Janeth Sanabria, Griffin, James S., Gu, April Z., Habagil, Moshe, Hale, Lauren, Hardeman, Steven D., Harmon, Marc, Horn, Harald, Hu, Zhiqiang, Jauffur, Shameem, Johnson, David R., Keucken, Alexander, Kumari, Sheena, Leal, Cintia Dutra, Lebrun, Laura A., Lee, Jangho, Lee, Minjoo, Lee, Zarraz M.P., Li, Mengyan, Li, Xu, Liu, Yu, Luthy, Richard G., Mendonça-Hagler, Leda C., de Menezes, Francisca Gleire Rodriguez, Meyers, Arthur J., Mohebbi, Amin, Oehmen, Adrian, Palmer, Andrew, Parameswaran, Prathap, Park, Joonhong, Patsch, Deborah, Reginatto, Valeria, de los Reyes, Francis L., Noyola, Adalberto, Rossetti, Simona, Sidhu, Jatinder, Sloan, William T., Smith, Kylie, de Sousa, Oscarina Viana, Stephens, Kyle, Tian, Renmao, Tooker, Nicholas B., De los Cobos Vasconcelos, Daniel, Wakelin, Steve, Wang, Bei, Weaver, Joseph E., West, Stephanie, Wilmes, Paul, Woo, Sung Geun, Wu, Jer Horng, University of Oklahoma (OU), Tsinghua University [Beijing] (THU), College of Resource and Environment Southwest University, Newcastle University [Newcastle], Northeastern Normal University, Washington University in Saint Louis (WUSTL), University of Vienna [Vienna], Northwestern University [Evanston], Shandong University, Chinese Academy of Sciences [Beijing] (CAS), The University of Hong Kong (HKU), Sun Yat-Sen University [Guangzhou] (SYSU), University of Queensland [Brisbane], Aalborg University [Denmark] (AAU), Rice University [Houston], Stanford University, Michigan State University System, The University of Tennessee [Knoxville], University of Washington [Seattle], University of California [Berkeley] (UC Berkeley), University of California (UC), Arizona State University [Tempe] (ASU), University of California [Berkeley], and University of California

Subjects

[SDV.BIO]Life Sciences [q-bio]/Biotechnology, Biodiversity, microbiome, Applied Microbiology and Biotechnology, Global Water Microbiome Consortium, Wastewater treatment plants, RNA, Ribosomal, 16S, activated sludge, 0303 health sciences, Geography, Sewage, Ecology, [SDE.IE]Environmental Sciences/Environmental Engineering, Microbiota, Bacterial, 6. Clean water, Wastewater, Medical Microbiology, Sewage treatment, Infection, Sequence Analysis, Microbiology (medical), DNA, Bacterial, 16S, [SDE.MCG]Environmental Sciences/Global Changes, Immunology, BACTÉRIAS, Theoretical ecology, Microbiology, Water Purification, 03 medical and health sciences, Microbial ecology, Genetics, 14. Life underwater, 030304 developmental biology, Ribosomal, Bacteria, 030306 microbiology, Species diversity, Cell Biology, DNA, Sequence Analysis, DNA, bacterial communities, [SDV.MP.BAC]Life Sciences [q-bio]/Microbiology and Parasitology/Bacteriology, Activated sludge, 13. Climate action, Biological dispersal, RNA, [SDE.BE]Environmental Sciences/Biodiversity and Ecology

Abstract

International audience; Microorganisms in wastewater treatment plants (WWTPs) are essential for water purification to protect public and environmental health. However, the diversity of microorganisms and the factors that control it are poorly understood. Using a systematic global-sampling effort, we analysed the 16S ribosomal RNA gene sequences from ~1,200 activated sludge samples taken from 269 WWTPs in 23 countries on 6 continents. Our analyses revealed that the global activated sludge bacterial communities contain ~1 billion bacterial phylotypes with a Poisson lognormal diversity distribution. Despite this high diversity, activated sludge has a small, global core bacterial community (n = 28 operational taxonomic units) that is strongly linked to activated sludge performance. Meta-analyses with global datasets associate the activated sludge microbiomes most closely to freshwater populations. In contrast to macroorganism diversity, activated sludge bacterial communities show no latitudinal gradient. Furthermore, their spatial turnover is scale-dependent and appears to be largely driven by stochastic processes (dispersal and drift), although deterministic factors (temperature and organic input) are also important. Our findings enhance our mechanistic understanding of the global diversity and biogeography of activated sludge bacterial communities within a theoretical ecology framework and have important implications for microbial ecology and wastewater treatment processes.

Published

2018

48. Divergent taxonomic and functional responses of microbial communities to field simulation of aeolian soil erosion and deposition

Author

Ma, Xingyu, Zhao, Cancan, Gao, Ying, Liu, Bin, Wang, Tengxu, Yuan, Tong, Hale, Lauren, Nostrand, Joy D Van, Wan, Shiqiang, Zhou, Jizhong, and Yang, Yunfeng

Subjects

China, Evolutionary Biology, Bacteria, Nitrogen, Phosphorus, geochip 5.0, Biological Sciences, complex mixtures, Grassland, Carbon, 16S rRNA sequencing, Soil, soil deposition, Potassium, functional traits, microbial community, wind erosion, Soil Microbiology

Abstract

Aeolian soil erosion and deposition have worldwide impacts on agriculture, air quality and public health. However, ecosystem responses to soil erosion and deposition remain largely unclear in regard to microorganisms, which are the crucial drivers of biogeochemical cycles. Using integrated metagenomics technologies, we analysed microbial communities subjected to simulated soil erosion and deposition in a semiarid grassland of Inner Mongolia, China. As expected, soil total organic carbon and plant coverage were decreased by soil erosion, and soil dissolved organic carbon (DOC) was increased by soil deposition, demonstrating that field simulation was reliable. Soil microbial communities were altered (p

Published

2017

49. Abundance of kinless hubs within soil microbial networks are associated with high functional potential in agricultural ecosystems.

Author

Shi, Yu, Delgado-Baquerizo, Manuel, Li, Yuntao, Yang, Yunfeng, Zhu, Yong-Guan, Peñuelas, Josep, and Chu, Haiyan

Subjects

*SOIL microbial ecology, *FUNGAL communities, *STRUCTURAL equation modeling, *ECOSYSTEMS, *SOILS, *SOIL sampling, *MICROBIAL communities, *SILVER phosphates

Abstract

• We built a correlation network using fungal and bacterial taxa. • Kinless hubs were highly positively correlated with the abundance of functional genes. • SEM results highlighted the positive effect of kinless hubs on the functional genes. Microbial taxa within complex ecological networks can be classified by their universal roles based on their level of connectivity with other taxa. Highly connected taxa within an ecological network (kinless hubs) are theoretically expected to support higher levels of ecosystem functions than less connected taxa (peripherals). Empirical evidence of the role of kinless hubs in regulating the functional potential of soil microbial communities, however, is largely unexplored and poorly understood in agricultural ecosystems. Here, we built a correlation network of fungal and bacterial taxa using a large-scale survey consisting of 243 soil samples across functionally and economically important agricultural ecosystems (wheat and maize); and found that the relative abundance of taxa classified as kinless hubs within the ecological network are positively and significantly correlated with the abundance of functional genes including genes for C fixation, C degradation, C methanol, N cycling, P cycling and S cycling. Structural equation modeling of multiple soil properties further indicated that kinless hubs, but not provincial, connector or peripheral taxa, had direct significant and positive relationships with the abundance of multiple functional genes. Our findings provide novel evidence that the relative abundance of soil taxa classified as kinless hubs within microbial networks are associated with high functional potential, with implications for understanding and managing (through manipulating microbial key species) agricultural ecosystems at a large spatial scale. [ABSTRACT FROM AUTHOR]

Published

2020