Your search keyword '"Hale, Lauren"' showing total 19 results

1. Resource-dependent biodiversity and potential multi-trophic interactions determine belowground functional trait stability

Author

Zhu, Lingyue, Chen, Yan, Sun, Ruibo, Zhang, Jiabao, Hale, Lauren, Dumack, Kenneth, Geisen, Stefan, Deng, Ye, Duan, Yinghua, Zhu, Bo, Li, Yan, Liu, Wenzhao, Wang, Xiaoyue, Griffiths, Bryan S, Bonkowski, Michael, Zhou, Jizhong, and Sun, Bo

Subjects

Ecosystem, Biodiversity, Biomass, Soil, Nutritional Status, Soil biodiversity, Within trophic interactions, Cross-trophic interactions, Agroecosystem, Ecosystem functioning, Ecology, Microbiology, Medical Microbiology

Abstract

BackgroundFor achieving long-term sustainability of intensive agricultural practices, it is pivotal to understand belowground functional stability as belowground organisms play essential roles in soil biogeochemical cycling. It is commonly believed that resource availability is critical for controlling the soil biodiversity and belowground organism interactions that ultimately lead to the stabilization or collapse of terrestrial ecosystem functions, but evidence to support this belief is still limited. Here, we leveraged field experiments from the Chinese National Ecosystem Research Network (CERN) and two microcosm experiments mimicking high and low resource conditions to explore how resource availability mediates soil biodiversity and potential multi-trophic interactions to control functional trait stability.ResultsWe found that agricultural practice-induced higher resource availability increased potential cross-trophic interactions over 316% in fields, which in turn had a greater effect on functional trait stability, while low resource availability made the stability more dependent on the potential within trophic interactions and soil biodiversity. This large-scale pattern was confirmed by fine-scale microcosm systems, showing that microcosms with sufficient nutrient supply increase the proportion of potential cross-trophic interactions, which were positively associated with functional stability. Resource-driven belowground biodiversity and multi-trophic interactions ultimately feedback to the stability of plant biomass.ConclusionsOur results indicated the importance of potential multi-trophic interactions in supporting belowground functional trait stability, especially when nutrients are sufficient, and also suggested the ecological benefits of fertilization programs in modern agricultural intensification. Video Abstract.

Published

2023

2. Winter warming in Alaska accelerates lignin decomposition contributed by Proteobacteria

Author

Tao, Xuanyu, Feng, Jiajie, Yang, Yunfeng, Wang, Gangsheng, Tian, Renmao, Fan, Fenliang, Ning, Daliang, Bates, Colin T, Hale, Lauren, Yuan, Mengting M, Wu, Linwei, Gao, Qun, Lei, Jiesi, Schuur, Edward AG, Yu, Julian, Bracho, Rosvel, Luo, Yiqi, Konstantinidis, Konstantinos T, Johnston, Eric R, Cole, James R, Penton, C Ryan, Tiedje, James M, and Zhou, Jizhong

Subjects

Biological Sciences, Ecology, Climate Action, Alaska, Burkholderia, Climate Change, Hot Temperature, Lignin, Permafrost, Proteobacteria, Soil, Soil Microbiology, Tundra, Microbiology, Medical Microbiology, Evolutionary biology

Abstract

BackgroundIn a warmer world, microbial decomposition of previously frozen organic carbon (C) is one of the most likely positive climate feedbacks of permafrost regions to the atmosphere. However, mechanistic understanding of microbial mediation on chemically recalcitrant C instability is limited; thus, it is crucial to identify and evaluate active decomposers of chemically recalcitrant C, which is essential for predicting C-cycle feedbacks and their relative strength of influence on climate change. Using stable isotope probing of the active layer of Arctic tundra soils after depleting soil labile C through a 975-day laboratory incubation, the identity of microbial decomposers of lignin and, their responses to warming were revealed.ResultsThe β-Proteobacteria genus Burkholderia accounted for 95.1% of total abundance of potential lignin decomposers. Consistently, Burkholderia isolated from our tundra soils could grow with lignin as the sole C source. A 2.2 °C increase of warming considerably increased total abundance and functional capacities of all potential lignin decomposers. In addition to Burkholderia, α-Proteobacteria capable of lignin decomposition (e.g. Bradyrhizobium and Methylobacterium genera) were stimulated by warming by 82-fold. Those community changes collectively doubled the priming effect, i.e., decomposition of existing C after fresh C input to soil. Consequently, warming aggravates soil C instability, as verified by microbially enabled climate-C modeling.ConclusionsOur findings are alarming, which demonstrate that accelerated C decomposition under warming conditions will make tundra soils a larger biospheric C source than anticipated. Video Abstract.

Published

2020

3. 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

Agricultural, Veterinary and Food Sciences, Climate Change Impacts and Adaptation, Biological Sciences, Ecology, Environmental Sciences, Forestry Sciences, Climate Action, Acclimatization, Archaea, Bacteria, Carbon, Carbon Cycle, Cellulose, DNA, Environmental, Fungi, Global Warming, Grassland, Hot Temperature, Metagenome, Metagenomics, Microbiota, Models, Genetic, Plant Roots, Poaceae, Soil, Soil Microbiology

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

4. Tundra microbial community taxa and traits predict decomposition parameters of stable, old soil organic carbon

Author

Hale, Lauren, Feng, Wenting, Yin, Huaqun, Guo, Xue, Zhou, Xishu, Bracho, Rosvel, Pegoraro, Elaine, Penton, C Ryan, Wu, Liyou, Cole, James, Konstantinidis, Konstantinos T, Luo, Yiqi, Tiedje, James M, Schuur, Edward AG, and Zhou, Jizhong

Subjects

Biological Sciences, Ecology, Archaea, Bacteria, Carbon, Climate Change, Fungi, Microbiota, Permafrost, Soil, Soil Microbiology, Tundra, Environmental Sciences, Technology, Microbiology, Biological sciences, Environmental sciences

Abstract

The susceptibility of soil organic carbon (SOC) in tundra to microbial decomposition under warmer climate scenarios potentially threatens a massive positive feedback to climate change, but the underlying mechanisms of stable SOC decomposition remain elusive. Herein, Alaskan tundra soils from three depths (a fibric O horizon with litter and course roots, an O horizon with decomposing litter and roots, and a mineral-organic mix, laying just above the permafrost) were incubated. Resulting respiration data were assimilated into a 3-pool model to derive decomposition kinetic parameters for fast, slow, and passive SOC pools. Bacterial, archaeal, and fungal taxa and microbial functional genes were profiled throughout the 3-year incubation. Correlation analyses and a Random Forest approach revealed associations between model parameters and microbial community profiles, taxa, and traits. There were more associations between the microbial community data and the SOC decomposition parameters of slow and passive SOC pools than those of the fast SOC pool. Also, microbial community profiles were better predictors of model parameters in deeper soils, which had higher mineral contents and relatively greater quantities of old SOC than in surface soils. Overall, our analyses revealed the functional potential of microbial communities to decompose tundra SOC through a suite of specialized genes and taxa. These results portray divergent strategies by which microbial communities access SOC pools across varying depths, lending mechanistic insights into the vulnerability of what is considered stable SOC in tundra regions.

Published

2019

5. Microbial functional diversity: From concepts to applications.

Author

Escalas, Arthur, Hale, Lauren, Voordeckers, James W, Yang, Yunfeng, Firestone, Mary K, Alvarez-Cohen, Lisa, and Zhou, Jizhong

Subjects

functional diversity, functional traits, microbial communities, theoretical frameworks of diversity, trait‐based ecology, trait-based ecology, Human Genome, Genetics, Ecology, Evolutionary Biology

Abstract

Functional diversity is increasingly recognized by microbial ecologists as the essential link between biodiversity patterns and ecosystem functioning, determining the trophic relationships and interactions between microorganisms, their participation in biogeochemical cycles, and their responses to environmental changes. Consequently, its definition and quantification have practical and theoretical implications. In this opinion paper, we present a synthesis on the concept of microbial functional diversity from its definition to its application. Initially, we revisit to the original definition of functional diversity, highlighting two fundamental aspects, the ecological unit under study and the functional traits used to characterize it. Then, we discuss how the particularities of the microbial world disallow the direct application of the concepts and tools developed for macroorganisms. Next, we provide a synthesis of the literature on the types of ecological units and functional traits available in microbial functional ecology. We also provide a list of more than 400 traits covering a wide array of environmentally relevant functions. Lastly, we provide examples of the use of functional diversity in microbial systems based on the different units and traits discussed herein. It is our hope that this paper will stimulate discussions and help the growing field of microbial functional ecology to realize a potential that thus far has only been attained in macrobial ecology.

Published

2019

6. The spatial scale dependence of diazotrophic and bacterial community assembly in paddy soil

Author

Gao, Qun, Yang, Yunfeng, Feng, Jiajie, Tian, Renmao, Guo, Xue, Ning, Daliang, Hale, Lauren, Wang, Mengmeng, Cheng, Jingmin, Wu, Linwei, Zhao, Mengxin, Zhao, Jianshu, Wu, Liyou, Qin, Yujia, Qi, Qi, Liang, Yuting, Sun, Bo, Chu, Haiyan, and Zhou, Jizhong

Subjects

Microbiology, Biological Sciences, Ecology, Infectious Diseases, bacterial community, beta-diversity, community assembly, diazotrophic community, paddy soil, spatial scale dependence, species association

Abstract

Aim: The factors driving microbial community β-diversity (variation in composition) at different spatial scales yield fundamental insights into the mechanisms that maintain ecosystem biodiversity, which as yet are uncertain. Here, we explore whether spatial scale-dependent patterns of β-diversity vary between microbial functional groups and bacterial taxa (i.e., diazotrophic and bacterial communities) across local to regional scales (from metres to hundreds of kilometres). Location: Eastern China. Time period: October and November 2015. Major taxa studied: Diazotrophic and bacterial communities. Methods We use two complementary statistical tools to unveil biotic mechanisms (i.e., species association) underlying variation in β-diversity of diazotrophic and bacterial communities. We examined distance–decay slopes of both communities at the local (1–113 m), meso- (3.4–39 km) and regional (103–668 km) scales. We used an environmentally constrained checkerboard score and topological features of association networks as indices of species association. We then calculated contributions of species association, abiotic factors and geographical distance to explain community β-diversity. The scale-dependent distance–decay relationships were also examined in ubiquitous (high occupancy across samples) and endemic communities of diazotrophs and bacteria. Results Diazotrophs displayed steeper distance–decay slopes than bacteria, suggesting that the β-diversity of diazotrophic communities was more variable. The distance–decay slopes were dependent on spatial scales in both communities, owing to different contributions of geographical distance, abiotic factors and species association at three spatial scales. Intriguingly, species association was greater and contributed more to community β-diversity than other forces at the local scale, implying that species association could greatly alter community structures. Main conclusions Drivers of diazotrophic and bacterial community β-diversity depended on spatial scales, resulting in different distance–decay patterns. Moreover, this was the first study to use two methods to demonstrate that species association played important, but as yet unrecognized, roles in driving spatial scale-dependent β-diversity.

Published

2019

7. 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

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

8. 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

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

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

9. 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

10. Taxonomic and Functional Responses of Soil Microbial Communities to Annual Removal of Aboveground Plant Biomass

Author

Guo, Xue, Zhou, Xishu, Hale, Lauren, Yuan, Mengting, Feng, Jiajie, Ning, Daliang, Shi, Zhou, Qin, Yujia, Liu, Feifei, Wu, Liyou, He, Zhili, Van Nostrand, Joy D, Liu, Xueduan, Luo, Yiqi, Tiedje, James M, and Zhou, Jizhong

Subjects

Biological Sciences, Ecology, Life on Land, clipping land-use, taxonomic and functional response, microbial community, metagenomics, GeoChip, Environmental Science and Management, Soil Sciences, Microbiology, Medical microbiology

Abstract

Clipping, removal of aboveground plant biomass, is an important issue in grassland ecology. However, few studies have focused on the effect of clipping on belowground microbial communities. Using integrated metagenomic technologies, we examined the taxonomic and functional responses of soil microbial communities to annual clipping (2010-2014) in a grassland ecosystem of the Great Plains of North America. Our results indicated that clipping significantly (P < 0.05) increased root and microbial respiration rates. Annual temporal variation within the microbial communities was much greater than the significant changes introduced by clipping, but cumulative effects of clipping were still observed in the long-term scale. The abundances of some bacterial and fungal lineages including Actinobacteria and Bacteroidetes were significantly (P < 0.05) changed by clipping. Clipping significantly (P < 0.05) increased the abundances of labile carbon (C) degrading genes. More importantly, the abundances of recalcitrant C degrading genes were consistently and significantly (P < 0.05) increased by clipping in the last 2 years, which could accelerate recalcitrant C degradation and weaken long-term soil carbon stability. Furthermore, genes involved in nutrient-cycling processes including nitrogen cycling and phosphorus utilization were also significantly increased by clipping. The shifts of microbial communities were significantly correlated with soil respiration and plant productivity. Intriguingly, clipping effects on microbial function may be highly regulated by precipitation at the interannual scale. Altogether, our results illustrated the potential of soil microbial communities for increased soil organic matter decomposition under clipping land-use practices.

Published

2018

11. Soil organic matter availability and climate drive latitudinal patterns in bacterial diversity from tropical to cold temperate forests

Author

Tian, Jing, He, Nianpeng, Hale, Lauren, Niu, Shuli, Yu, Guirui, Liu, Yuan, Blagodatskaya, Evgenia, Kuzyakov, Yakov, Gao, Qun, and Zhou, Jizhong

Subjects

Microbiology, Biological Sciences, Ecology, Life Below Water, bacterial diversity, climate change, forest ecosystems, soil microbial biogeography, soil organic matter, Environmental Sciences, Biological sciences, Environmental sciences

Abstract

Bacteria are one of the most abundant and diverse groups of micro‐organisms and mediate many critical terrestrial ecosystem processes. Despite the crucial ecological role of bacteria, our understanding of their large‐scale biogeography patterns across forests, and the processes that determine these patterns lags significantly behind that of macroorganisms. Here, we evaluated the geographic distributions of bacterial diversity and their driving factors across nine latitudinal forests along a 3,700‐km north–south transect in eastern China, using high‐throughput 16S rRNA gene sequencing. Four of 32 phyla detected were dominant: Acidobacteria, Actinobacteria, Alphaproteobacteria and Chloroflexi (relative abundance > 5%). Significant increases in bacterial richness and phylogenetic diversity were observed for temperate forests compared with subtropical or tropical forests. The soil organic matter (SOM) mineralisation rate (SOMₘᵢₙ, an index of SOM availability) explained the largest significant variations in bacterial richness. Variation partition analysis revealed that the bacterial community structure was closely correlated with environmental variables and geographic distance, which together explained 80.5% of community variation. Among all environmental factors, climatic features (MAT and MAP) were the best predictors of the bacterial community structure, whereas soil pH and SOMₘᵢₙ emerged as the most important edaphic drivers of the bacterial community structure. Plant functional traits (community weighted means of litter N content) and diversity resulted in weak but significant correlations with the bacterial community structure. Our findings provide new evidence of bacterial biogeography patterns from tropical to cold temperate forests. Additionally, the results indicated a close linkage among soil bacterial diversity, climate and SOM decomposition, which is critical for predicting continental‐scale responses under future climate change scenarios and promoting sustainable forest ecosystem services. A plain language summary is available for this article.

Published

2018

12. Microbial functional diversity covaries with permafrost thaw-induced environmental heterogeneity in tundra soil.

Author

Yuan, Mengting M, Zhang, Jin, Xue, Kai, Wu, Liyou, Deng, Ye, Deng, Jie, Hale, Lauren, Zhou, Xishu, He, Zhili, Yang, Yunfeng, Van Nostrand, Joy D, Schuur, Edward AG, Konstantinidis, Konstantinos T, Penton, Christopher R, Cole, James R, Tiedje, James M, Luo, Yiqi, and Zhou, Jizhong

Subjects

Fungi, Carbon, Soil Microbiology, Temperature, Alaska, Climate Change, Tundra, Permafrost, geochip, functional gene array, permafrost thaw, soil microbial functional diversity, tussock tundra, geochip, Biological Sciences, Environmental Sciences, Ecology

Abstract

Permafrost soil in high latitude tundra is one of the largest terrestrial carbon (C) stocks and is highly sensitive to climate warming. Understanding microbial responses to warming-induced environmental changes is critical to evaluating their influences on soil biogeochemical cycles. In this study, a functional gene array (i.e., geochip 4.2) was used to analyze the functional capacities of soil microbial communities collected from a naturally degrading permafrost region in Central Alaska. Varied thaw history was reported to be the main driver of soil and plant differences across a gradient of minimally, moderately, and extensively thawed sites. Compared with the minimally thawed site, the number of detected functional gene probes across the 15-65 cm depth profile at the moderately and extensively thawed sites decreased by 25% and 5%, while the community functional gene β-diversity increased by 34% and 45%, respectively, revealing decreased functional gene richness but increased community heterogeneity along the thaw progression. Particularly, the moderately thawed site contained microbial communities with the highest abundances of many genes involved in prokaryotic C degradation, ammonification, and nitrification processes, but lower abundances of fungal C decomposition and anaerobic-related genes. Significant correlations were observed between functional gene abundance and vascular plant primary productivity, suggesting that plant growth and species composition could be co-evolving traits together with microbial community composition. Altogether, this study reveals the complex responses of microbial functional potentials to thaw-related soil and plant changes and provides information on potential microbially mediated biogeochemical cycles in tundra ecosystems.

Published

2018

13. Enhanced decomposition of stable soil organic carbon and microbial catabolic potentials by long‐term field warming

Author

Feng, Wenting, Liang, Junyi, Hale, Lauren E, Jung, Chang Gyo, Chen, Ji, Zhou, Jizhong, Xu, Minggang, Yuan, Mengting, Wu, Liyou, Bracho, Rosvel, Pegoraro, Elaine, Schuur, Edward AG, and Luo, Yiqi

Subjects

Biological Sciences, Ecology, Climate Action, Carbon, Climate Change, Oklahoma, Soil, Soil Microbiology, diversity, Geochip, incubation, inverse modeling, long-term warming, metagenomics, microbial community, soil organic carbon, turnover, Environmental Sciences, Biological sciences, Earth sciences, Environmental sciences

Abstract

Quantifying soil organic carbon (SOC) decomposition under warming is critical to predict carbon-climate feedbacks. According to the substrate regulating principle, SOC decomposition would decrease as labile SOC declines under field warming, but observations of SOC decomposition under warming do not always support this prediction. This discrepancy could result from varying changes in SOC components and soil microbial communities under warming. This study aimed to determine the decomposition of SOC components with different turnover times after subjected to long-term field warming and/or root exclusion to limit C input, and to test whether SOC decomposition is driven by substrate lability under warming. Taking advantage of a 12-year field warming experiment in a prairie, we assessed the decomposition of SOC components by incubating soils from control and warmed plots, with and without root exclusion for 3 years. We assayed SOC decomposition from these incubations by combining inverse modeling and microbial functional genes during decomposition with a metagenomic technique (GeoChip). The decomposition of SOC components with turnover times of years and decades, which contributed to 95% of total cumulative CO2 respiration, was greater in soils from warmed plots. But the decomposition of labile SOC was similar in warmed plots compared to the control. The diversity of C-degradation microbial genes generally declined with time during the incubation in all treatments, suggesting shifts of microbial functional groups as substrate composition was changing. Compared to the control, soils from warmed plots showed significant increase in the signal intensities of microbial genes involved in degrading complex organic compounds, implying enhanced potential abilities of microbial catabolism. These are likely responsible for accelerated decomposition of SOC components with slow turnover rates. Overall, the shifted microbial community induced by long-term warming accelerates the decomposition of SOC components with slow turnover rates and thus amplify the positive feedback to climate change.

Published

2017

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

Author

Wu, Linwei, Yang, Yunfeng, Wang, Shiping, Yue, Haowei, Lin, Qiaoyan, Hu, Yigang, He, Zhili, Van Nostrand, Joy D, Hale, Lauren, Li, Xiangzhen, Gilbert, Jack A, and Zhou, Jizhong

Subjects

Biological Sciences, Ecology, Bacteria, Biodiversity, Carbon, Climate Change, Ecosystem, Soil, Soil Microbiology, Temperature, Environmental Sciences, Technology, Microbiology, Biological sciences, Environmental sciences

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

Subjects

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

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

16. Annual Removal of Aboveground Plant Biomass Alters Soil Microbial Responses to Warming

Author

Xue, Kai, Yuan, Mengting M, Xie, Jianping, Li, Dejun, Qin, Yujia, Hale, Lauren E, Wu, Liyou, Deng, Ye, He, Zhili, Van Nostrand, Joy D, Luo, Yiqi, Tiedje, James M, and Zhou, Jizhong

Subjects

Biological Sciences, Ecology, Climate Action, Life on Land, Microbiology, Biochemistry and cell biology, Medical microbiology

Abstract

Clipping (i.e., harvesting aboveground plant biomass) is common in agriculture and for bioenergy production. However, microbial responses to clipping in the context of climate warming are poorly understood. We investigated the interactive effects of grassland warming and clipping on soil properties and plant and microbial communities, in particular, on microbial functional genes. Clipping alone did not change the plant biomass production, but warming and clipping combined increased the C4 peak biomass by 47% and belowground net primary production by 110%. Clipping alone and in combination with warming decreased the soil carbon input from litter by 81% and 75%, respectively. With less carbon input, the abundances of genes involved in degrading relatively recalcitrant carbon increased by 38% to 137% in response to either clipping or the combined treatment, which could weaken long-term soil carbon stability and trigger positive feedback with respect to warming. Clipping alone also increased the abundance of genes for nitrogen fixation, mineralization, and denitrification by 32% to 39%. Such potentially stimulated nitrogen fixation could help compensate for the 20% decline in soil ammonium levels caused by clipping alone and could contribute to unchanged plant biomass levels. Moreover, clipping tended to interact antagonistically with warming, especially with respect to effects on nitrogen cycling genes, demonstrating that single-factor studies cannot predict multifactorial changes. These results revealed that clipping alone or in combination with warming altered soil and plant properties as well as the abundance and structure of soil microbial functional genes. Aboveground biomass removal for biofuel production needs to be reconsidered, as the long-term soil carbon stability may be weakened.ImportanceGlobal change involves simultaneous alterations, including those caused by climate warming and land management practices (e.g., clipping). Data on the interactive effects of warming and clipping on ecosystems remain elusive, particularly in microbial ecology. This study found that clipping alters microbial responses to warming and demonstrated the effects of antagonistic interactions between clipping and warming on microbial functional genes. Clipping alone or combined with warming enriched genes degrading relatively recalcitrant carbon, likely reflecting the decreased quantity of soil carbon input from litter, which could weaken long-term soil C stability and trigger positive warming feedback. These results have important implications in assessing and predicting the consequences of global climate change and indicate that the removal of aboveground biomass for biofuel production may need to be reconsidered.

Published

2016

17. Zonal Soil Type Determines Soil Microbial Responses to Maize Cropping and Fertilization

Author

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

Subjects

Agricultural, Veterinary and Food Sciences, Biological Sciences, Ecology, Microbiology, Forestry Sciences, Life on Land, GeoChip, fertilization, microbial community, soil functional process, zonal soil type

Abstract

Soil types heavily influence ecological dynamics. It remains controversial to what extent soil types shape microbial responses to land management changes, largely due to lack of in-depth comparison across various soil types. Here, we collected samples from three major zonal soil types spanning from cold temperate to subtropical climate zones. We examined bacterial and fungal community structures, as well as microbial functional genes. Different soil types had distinct microbial biomass levels and community compositions. Five years of maize cropping (growing corn or maize) changed the bacterial community composition of the Ultisol soil type and the fungal composition of the Mollisol soil type but had little effect on the microbial composition of the Inceptisol soil type. Meanwhile, 5 years of fertilization resulted in soil acidification. Microbial compositions of the Mollisol and Ultisol, but not the Inceptisol, were changed and correlated (P < 0.05) with soil pH. These results demonstrated the critical role of soil type in determining microbial responses to land management changes. We also found that soil nitrification potentials correlated with the total abundance of nitrifiers and that soil heterotrophic respiration correlated with the total abundance of carbon degradation genes, suggesting that changes in microbial community structure had altered ecosystem processes. IMPORTANCE Microbial communities are essential drivers of soil functional processes such as nitrification and heterotrophic respiration. Although there is initial evidence revealing the importance of soil type in shaping microbial communities, there has been no in-depth, comprehensive survey to robustly establish it as a major determinant of microbial community composition, functional gene structure, or ecosystem functioning. We examined bacterial and fungal community structures using Illumina sequencing, microbial functional genes using GeoChip, microbial biomass using phospholipid fatty acid analysis, as well as functional processes of soil nitrification potential and CO2 efflux. We demonstrated the critical role of soil type in determining microbial responses to land use changes at the continental level. Our findings underscore the inherent difficulty in generalizing ecosystem responses across landscapes and suggest that assessments of community feedback must take soil types into consideration. Author Video: An author video summary of this article is available.

Published

2016

18. 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

19. Disruption of Gene pqqA or pqqB Reduces Plant Growth Promotion Activity and Biocontrol of Crown Gall Disease by Rahnella aquatilis HX2.

Author

Li, Lei, Jiao, Ziwei, Hale, Lauren, Wu, Wenliang, and Guo, Yanbin

Subjects

BIOLOGICAL control of crown-gall disease, GRAM-negative bacteria, CORN growth, SUNFLOWER diseases & pests, AGROBACTERIUM vitis

Abstract

Rahnella aquatilis strain HX2 has the ability to promote maize growth and suppress sunflower crown gall disease caused by Agrobacterium vitis, A. tumefaciens, and A. rhizogenes. Pyrroloquinoline quinone (PQQ), a cofactor of aldose and alcohol dehydrogenases, is required for the synthesis of an antibacterial substance, gluconic acid, by HX2. Mutants of HX2 unable to produce PQQ were obtained by in-frame deletion of either the pqqA or pqqB gene. In this study, we report the independent functions of pqqA and pqqB genes in relation to PQQ synthesis. Interestingly, both the pqqA and pqqB mutants of R. aquatilis eliminated the ability of strain HX2 to produce antibacterial substance, which in turn, reduced the effectiveness of the strain for biological control of sunflower crown gall disease. The mutation also resulted in decreased mineral phosphate solubilization by HX2, which reduced the efficacy of this strain as a biological fertilizer. These functions were restored by complementation with the wild-type pqq gene cluster. Additionally, the phenotypes of HX2 derivatives, including colony morphology, growth dynamic, and pH change of culture medium were impacted to different extents. Our findings suggested that pqqA and pqqB genes individually play important functions in PQQ biosynthesis and are required for antibacterial activity and phosphorous solubilization. These traits are essential for R. aquatilis efficacy as a biological control and plant growth promoting strain. This study enhances our fundamental understanding of the biosynthesis of an environmentally significant cofactor produced by a promising biocontrol and biological fertilizer strain. [ABSTRACT FROM AUTHOR]

Published

2014