Your search keyword '"Bardgett, Richard D."' showing total 10 results

1. Defoliation modifies the impact of drought on the transfer of recent plant-assimilated carbon to soil and arbuscular mycorrhizal fungi

Author

Xu, Tianyang, Johnson, David, and Bardgett, Richard D.

Published

2024

2. Defoliation modifies the response of arbuscular mycorrhizal fungi to drought in temperate grassland

Author

Xu, Tianyang, Johnson, David, and Bardgett, Richard D.

Published

2024

3. Diana Wall obituary: ecologist who foresaw the importance of soil biodiversity

Author

Bardgett, Richard D.

Published

2024

4. Deforestation impacts soil biodiversity & ecosystem services worldwide

Author

National Key Research and Development Program (China), National Natural Science Foundation of China, Ministerio de Ciencia e Innovación (España), Agencia Estatal de Investigación (España), European Commission, Kazan Federal University, Li, Xiaogang [0000-0002-7976-1122], Bardgett, Richard D. [0000-0002-5131-0127], Kuzyakov, Yakov [0000-0002-9863-8461], Revillini, Daniel [0000-0002-0380-4106], Sonne, Christian [0000-0001-5723-5263], Ruan, Honghua [0000-0002-6075-474X], Liu, Yurong [0000-0003-1112-4255], Reich, Peter B. [0000-0003-4424-662X], Delgado-Baquerizo, Manuel [0000-0002-6499-576X], Qu, Xinjing, Li, Xiaogang, Bardgett, Richard D., Kuzyakov, Yakov, Revillini, Daniel, Sonne, Christian, Xia, Changlei, Ruan, Honghua, Liu, Yurong, Fuliang, Cao, Reich, Peter B., Delgado-Baquerizo, Manuel, National Key Research and Development Program (China), National Natural Science Foundation of China, Ministerio de Ciencia e Innovación (España), Agencia Estatal de Investigación (España), European Commission, Kazan Federal University, Li, Xiaogang [0000-0002-7976-1122], Bardgett, Richard D. [0000-0002-5131-0127], Kuzyakov, Yakov [0000-0002-9863-8461], Revillini, Daniel [0000-0002-0380-4106], Sonne, Christian [0000-0001-5723-5263], Ruan, Honghua [0000-0002-6075-474X], Liu, Yurong [0000-0003-1112-4255], Reich, Peter B. [0000-0003-4424-662X], Delgado-Baquerizo, Manuel [0000-0002-6499-576X], Qu, Xinjing, Li, Xiaogang, Bardgett, Richard D., Kuzyakov, Yakov, Revillini, Daniel, Sonne, Christian, Xia, Changlei, Ruan, Honghua, Liu, Yurong, Fuliang, Cao, Reich, Peter B., and Delgado-Baquerizo, Manuel

Abstract

Deforestation poses a global threat to biodiversity and its capacity to deliver ecosystem services. Yet, the impacts of deforestation on soil biodiversity and its associated ecosystem services remain virtually unknown. We generated a global dataset including 696 paired-site observations to investigate how native forest conversion to other land uses affects soil properties, biodiversity, and functions associated with the delivery of multiple ecosystem services. The conversion of native forests to plantations, grasslands, and croplands resulted in higher bacterial diversity and more homogeneous fungal communities dominated by pathogens and with a lower abundance of symbionts. Such conversions also resulted in significant reductions in carbon storage, nutrient cycling, and soil functional rates related to organic matter decomposition. Responses of the microbial community to deforestation, including bacterial and fungal diversity and fungal guilds, were predominantly regulated by changes in soil pH and total phosphorus. Moreover, we found that soil fungal diversity and functioning in warmer and wetter native forests is especially vulnerable to deforestation. Our work highlights that the loss of native forests to managed ecosystems poses a major global threat to the biodiversity and functioning of soils and their capacity to deliver ecosystem services.

Published

2024

5. Land management shapes drought responses of dominant soil microbial taxa across grasslands

Author

Natural Environment Research Council (UK), Lavallee, Jocelyn M. [0000-0002-3028-7087], Chomel, Mathilde [0000-0001-5110-2355], Álvarez-Segura, N. [0000-0003-3759-6189], Castro, Francisco de [0000-0001-8834-3363], Goodall, Tim [0000-0002-1526-4071], Magilton, Matthew [0000-0002-7142-4877], Rhymes J. M. [0000-0001-9347-9863], Delgado-Baquerizo, Manuel [0000-0002-6499-576X], Griffiths, Robert [0000-0002-3341-4547], Baggs. E. M. [0000-0003-2014-2148], Caruso, Tancredi [0000-0002-3607-9609], Vries, Franciska T. de [0000-0002-6822-8883], Emmerson, Mark [0000-0003-1034-8572], Johnson, David [0000-0003-2299-2525], Bardgett, Richard D. [0000-0002-5131-0127], Lavallee, Jocelyn M., Chomel, Mathilde, Álvarez-Segura, N., Castro, Francisco de, Goodall, Tim, Magilton, Matthew, Rhymes J. M., Delgado-Baquerizo, Manuel, Griffiths, Robert, Baggs. E. M., Caruso, Tancredi, Emmerson, Mark, Johnson, David, Bardgett, Richard D., Natural Environment Research Council (UK), Lavallee, Jocelyn M. [0000-0002-3028-7087], Chomel, Mathilde [0000-0001-5110-2355], Álvarez-Segura, N. [0000-0003-3759-6189], Castro, Francisco de [0000-0001-8834-3363], Goodall, Tim [0000-0002-1526-4071], Magilton, Matthew [0000-0002-7142-4877], Rhymes J. M. [0000-0001-9347-9863], Delgado-Baquerizo, Manuel [0000-0002-6499-576X], Griffiths, Robert [0000-0002-3341-4547], Baggs. E. M. [0000-0003-2014-2148], Caruso, Tancredi [0000-0002-3607-9609], Vries, Franciska T. de [0000-0002-6822-8883], Emmerson, Mark [0000-0003-1034-8572], Johnson, David [0000-0003-2299-2525], Bardgett, Richard D. [0000-0002-5131-0127], Lavallee, Jocelyn M., Chomel, Mathilde, Álvarez-Segura, N., Castro, Francisco de, Goodall, Tim, Magilton, Matthew, Rhymes J. M., Delgado-Baquerizo, Manuel, Griffiths, Robert, Baggs. E. M., Caruso, Tancredi, Emmerson, Mark, Johnson, David, and Bardgett, Richard D.

Abstract

Soil microbial communities are dominated by a relatively small number of taxa that may play outsized roles in ecosystem functioning, yet little is known about their capacities to resist and recover from climate extremes such as drought, or how environmental context mediates those responses. Here, we imposed an in situ experimental drought across 30 diverse UK grassland sites with contrasting management intensities and found that: (1) the majority of dominant bacterial (85%) and fungal (89%) taxa exhibit resistant or opportunistic drought strategies, possibly contributing to their ubiquity and dominance across sites; and (2) intensive grassland management decreases the proportion of drought-sensitive and non-resilient dominant bacteria—likely via alleviation of nutrient limitation and pH-related stress under fertilisation and liming—but has the opposite impact on dominant fungi. Our results suggest a potential mechanism by which intensive management promotes bacteria over fungi under drought with implications for soil functioning.

Published

2024

6. Contrasting responses of plant, soil fungal and above‐ground arthropod communities to plant invasion across latitudes.

Author

Gao, Lunlun, Fan, Fengyan, He, Yifan, Wei, Chunqiang, Xu, Hao, Liu, Xiaoyan, Lu, Xinmin, and Bardgett, Richard D.

Subjects

PLANT communities, PLANT ecology, PLANT-fungus relationships, INVASIVE plants, SOIL fungi

Abstract

Copyright of Journal of Ecology is the property of Wiley-Blackwell and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

7. Climate change disrupts the seasonal coupling of plant and soil microbial nutrient cycling in an alpine ecosystem

Author

Broadbent, Arthur A.D., Newbold, Lindsay K., Pritchard, William J., Michas, Antonios, Goodall, Tim, Cordero, Irene, Giunta, Andrew, Snell, Helen S.K., Pepper, Violette V.L.H., Grant, Helen K., Soto Arrojo, David X., Kaufmann, Ruediger, Schloter, Michael, Griffiths, Robert I., Bahn, Michael, Bardgett, Richard D., Broadbent, Arthur A.D., Newbold, Lindsay K., Pritchard, William J., Michas, Antonios, Goodall, Tim, Cordero, Irene, Giunta, Andrew, Snell, Helen S.K., Pepper, Violette V.L.H., Grant, Helen K., Soto Arrojo, David X., Kaufmann, Ruediger, Schloter, Michael, Griffiths, Robert I., Bahn, Michael, and Bardgett, Richard D.

Abstract

The seasonal coupling of plant and soil microbial nutrient demands is crucial for efficient ecosystem nutrient cycling and plant production, especially in strongly seasonal alpine ecosystems. Yet, how these seasonal nutrient cycling processes are modified by climate change and what the consequences are for nutrient loss and retention in alpine ecosystems remain unclear. Here, we explored how two pervasive climate change factors, reduced snow cover and shrub expansion, interactively modify the seasonal coupling of plant and soil microbial nitrogen (N) cycling in alpine grasslands, which are warming at double the rate of the global average. We found that the combination of reduced snow cover and shrub expansion disrupted the seasonal coupling of plant and soil N-cycling, with pronounced effects in spring (shortly after snow melt) and autumn (at the onset of plant senescence). In combination, both climate change factors decreased plant organic N-uptake by 70% and 82%, soil microbial biomass N by 19% and 38% and increased soil denitrifier abundances by 253% and 136% in spring and autumn, respectively. Shrub expansion also individually modified the seasonality of soil microbial community composition and stoichiometry towards more N-limited conditions and slower nutrient cycling in spring and autumn. In winter, snow removal markedly reduced the fungal:bacterial biomass ratio, soil N pools and shifted bacterial community composition. Taken together, our findings suggest that interactions between climate change factors can disrupt the temporal coupling of plant and soil microbial N-cycling processes in alpine grasslands. This could diminish the capacity of these globally widespread alpine ecosystems to retain N and support plant productivity under future climate change.

Published

2024

8. Deforestation impacts soil biodiversity and ecosystem services worldwide.

Author

Xinjing Qu, Xiaogang Li, Bardgett, Richard D., Kuzyakov, Yakov, Revillini, Daniel, Sonne, Christian, Changlei Xia, Honghua Ruan, Yurong Liu, Fuliang Cao, Reich, Peter B., and Delgado-Baquerizo, Manuel

Subjects

SOIL biodiversity, ECOSYSTEM services, DEFORESTATION, FOREST conversion, BACTERIAL diversity

Abstract

Deforestation poses a global threat to biodiversity and its capacity to deliver ecosystem services. Yet, the impacts of deforestation on soil biodiversity and its associated ecosystem services remain virtually unknown. We generated a global dataset including 696 paired-site observations to investigate how native forest conversion to other land uses affects soil properties, biodiversity, and functions associated with the delivery of multiple ecosystem services. The conversion of native forests to plantations, grasslands, and croplands resulted in higher bacterial diversity and more homogeneous fungal communities dominated by pathogens and with a lower abundance of symbionts. Such conversions also resulted in significant reductions in carbon storage, nutrient cycling, and soil functional rates related to organic matter decomposition. Responses of the microbial community to deforestation, including bacterial and fungal diversity and fungal guilds, were predominantly regulated by changes in soil pH and total phosphorus. Moreover, we found that soil fungal diversity and functioning in warmer and wetter native forests is especially vulnerable to deforestation. Our work highlights that the loss of native forests to managed ecosystems poses a major global threat to the biodiversity and functioning of soils and their capacity to deliver ecosystem services. [ABSTRACT FROM AUTHOR]

Published

2024

9. Climate change disrupts the seasonal coupling of plant and soil microbial nutrient cycling in an alpine ecosystem.

Author

Broadbent, Arthur A. D., Newbold, Lindsay K., Pritchard, William J., Michas, Antonios, Goodall, Tim, Cordero, Irene, Giunta, Andrew, Snell, Helen S. K., Pepper, Violette V. L. H., Grant, Helen K., Soto, David X., Kaufmann, Ruediger, Schloter, Michael, Griffiths, Robert I., Bahn, Michael, and Bardgett, Richard D.

Subjects

NUTRIENT cycles, CLIMATE change, PLANT-soil relationships, SEASONS, TUNDRAS, MOUNTAIN ecology, GRASSLAND soils, SNOW cover, SNOW removal

Abstract

The seasonal coupling of plant and soil microbial nutrient demands is crucial for efficient ecosystem nutrient cycling and plant production, especially in strongly seasonal alpine ecosystems. Yet, how these seasonal nutrient cycling processes are modified by climate change and what the consequences are for nutrient loss and retention in alpine ecosystems remain unclear. Here, we explored how two pervasive climate change factors, reduced snow cover and shrub expansion, interactively modify the seasonal coupling of plant and soil microbial nitrogen (N) cycling in alpine grasslands, which are warming at double the rate of the global average. We found that the combination of reduced snow cover and shrub expansion disrupted the seasonal coupling of plant and soil N‐cycling, with pronounced effects in spring (shortly after snow melt) and autumn (at the onset of plant senescence). In combination, both climate change factors decreased plant organic N‐uptake by 70% and 82%, soil microbial biomass N by 19% and 38% and increased soil denitrifier abundances by 253% and 136% in spring and autumn, respectively. Shrub expansion also individually modified the seasonality of soil microbial community composition and stoichiometry towards more N‐limited conditions and slower nutrient cycling in spring and autumn. In winter, snow removal markedly reduced the fungal:bacterial biomass ratio, soil N pools and shifted bacterial community composition. Taken together, our findings suggest that interactions between climate change factors can disrupt the temporal coupling of plant and soil microbial N‐cycling processes in alpine grasslands. This could diminish the capacity of these globally widespread alpine ecosystems to retain N and support plant productivity under future climate change. [ABSTRACT FROM AUTHOR]

Published

2024

10. Deforestation impacts soil biodiversity and ecosystem services worldwide.

Author

Qu X, Li X, Bardgett RD, Kuzyakov Y, Revillini D, Sonne C, Xia C, Ruan H, Liu Y, Cao F, Reich PB, and Delgado-Baquerizo M

Subjects

Soil chemistry, Conservation of Natural Resources, Biodiversity, Forests, Bacteria, Soil Microbiology, Ecosystem, Microbiota

Abstract

Deforestation poses a global threat to biodiversity and its capacity to deliver ecosystem services. Yet, the impacts of deforestation on soil biodiversity and its associated ecosystem services remain virtually unknown. We generated a global dataset including 696 paired-site observations to investigate how native forest conversion to other land uses affects soil properties, biodiversity, and functions associated with the delivery of multiple ecosystem services. The conversion of native forests to plantations, grasslands, and croplands resulted in higher bacterial diversity and more homogeneous fungal communities dominated by pathogens and with a lower abundance of symbionts. Such conversions also resulted in significant reductions in carbon storage, nutrient cycling, and soil functional rates related to organic matter decomposition. Responses of the microbial community to deforestation, including bacterial and fungal diversity and fungal guilds, were predominantly regulated by changes in soil pH and total phosphorus. Moreover, we found that soil fungal diversity and functioning in warmer and wetter native forests is especially vulnerable to deforestation. Our work highlights that the loss of native forests to managed ecosystems poses a major global threat to the biodiversity and functioning of soils and their capacity to deliver ecosystem services., Competing Interests: Competing interests statement:The authors declare no competing interest.

Published

2024