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18 results on '"Straathof, Angela L."'

1. Detecting macroecological patterns in bacterial communities across independent studies of global soils.

Author

Ramirez, Kelly S, Knight, Christopher G, de Hollander, Mattias, Brearley, Francis Q, Constantinides, Bede, Cotton, Anne, Creer, Si, Crowther, Thomas W, Davison, John, Delgado-Baquerizo, Manuel, Dorrepaal, Ellen, Elliott, David R, Fox, Graeme, Griffiths, Robert I, Hale, Chris, Hartman, Kyle, Houlden, Ashley, Jones, David L, Krab, Eveline J, Maestre, Fernando T, McGuire, Krista L, Monteux, Sylvain, Orr, Caroline H, van der Putten, Wim H, Roberts, Ian S, Robinson, David A, Rocca, Jennifer D, Rowntree, Jennifer, Schlaeppi, Klaus, Shepherd, Matthew, Singh, Brajesh K, Straathof, Angela L, Bhatnagar, Jennifer M, Thion, Cécile, van der Heijden, Marcel GA, and de Vries, Franciska T

Subjects
Bacteria, DNA, Bacterial, RNA, Ribosomal, 16S, Soil, Ecology, Soil Microbiology, Ecosystem, Biodiversity, Phylogeny, Bacterial Physiological Phenomena, Microbial Interactions, High-Throughput Nucleotide Sequencing, Microbiota, Machine Learning
Abstract

The emergence of high-throughput DNA sequencing methods provides unprecedented opportunities to further unravel bacterial biodiversity and its worldwide role from human health to ecosystem functioning. However, despite the abundance of sequencing studies, combining data from multiple individual studies to address macroecological questions of bacterial diversity remains methodically challenging and plagued with biases. Here, using a machine-learning approach that accounts for differences among studies and complex interactions among taxa, we merge 30 independent bacterial data sets comprising 1,998 soil samples from 21 countries. Whereas previous meta-analysis efforts have focused on bacterial diversity measures or abundances of major taxa, we show that disparate amplicon sequence data can be combined at the taxonomy-based level to assess bacterial community structure. We find that rarer taxa are more important for structuring soil communities than abundant taxa, and that these rarer taxa are better predictors of community structure than environmental factors, which are often confounded across studies. We conclude that combining data from independent studies can be used to explore bacterial community dynamics, identify potential 'indicator' taxa with an important role in structuring communities, and propose hypotheses on the factors that shape bacterial biogeography that have been overlooked in the past.

Published
2018

6. Supplementary material to "Are researchers following best storage practices for measuring soil biochemical properties?"

Author

Rhymes, Jennifer M., primary, Cordero, Irene, additional, Chomel, Mathilde, additional, Lavallee, Jocelyn M., additional, Straathof, Angela L., additional, Ashworth, Deborah, additional, Langridge, Holly, additional, Semchenko, Marina, additional, de Vries, Franciska T., additional, Johnson, David, additional, and Bardgett, Richard D., additional

Published
2020
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8. Root functional traits explain root exudation rate and composition across a range of grassland species.

Author

Williams, Alex, Langridge, Holly, Straathof, Angela L., Muhamadali, Howbeer, Hollywood, Katherine A., Goodacre, Royston, and de Vries, Franciska T.

Subjects
RHIZOSPHERE, GRASSLAND soils, GRASSLANDS, PLANT exudates, NUTRIENT uptake, SOIL microbiology, PLANT roots
Abstract

Plant root exudation is a crucial means through which plants communicate with soil microbes and influence rhizosphere processes. Exudation can also underlie ecosystem response to changing environmental conditions. Different plant species vary in their root exudate quantity and quality, but our understanding of the plant characteristics that drive these differences is fragmentary. We hypothesised that root exudates would be under phylogenetic control and fit within an exploitative root nutrient uptake strategy, specifically that high rates of root exudation would link to root traits indicative of exploitative growth.We collected root exudates from plants grown in field soil, as well as leachates of the entire plant–soil system, to assess both the quantity and quality of root exudates, and their interaction with the soil metabolome, across 18 common grassland species.We found that exudation varied with plant functional group and that differences were trait dependent. Particularly, root diameter, root tissue density and root nitrogen content explained much of the variation in exudate metabolome, along with plant phylogeny. Specific root exudation rate was highest in forbs and was negatively correlated with root tissue density, a trait indicative of conservative resource‐use strategy, and positively correlated with root diameter, which is associated with microbial collaboration and resource uptake 'outsourcing'.Synthesis. We provide novel insight into species‐specific differences in root exudates and identify root functional traits that might underlie these differences. Our results show that root exudation fits, although not entirely, within current models of the root economic space, with strong positive relationships to outsourcing traits like high root diameter. Determining the role of root exudates as a key facet of the resource‐outsourcing strategy necessitates further research into the fundamental controls on root exudation quantity and quality, particularly during environmental change. [ABSTRACT FROM AUTHOR]

Published
2022
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9. Detecting macroecological patterns in bacterial communities across independent studies of global soils

Author

Ramirez, Kelly S., Knight, Christopher G., de Hollander, Mattias, Brearley, Francis Q., Constantinides, Bede, Cotton, Anne, Creer, Si, Crowther, Thomas W., Davison, John, Delgado-Baquerizo, Manuel, Dorrepaal, Ellen, Elliott, David R., Fox, Graeme, Griffiths, Robert I., Hale, Chris, Hartman, Kyle, Houlden, Ashley, Jones, David L., Krab, Eveline J., Maestre, Fernando T., McGuire, Krista L., Monteux, Sylvain, Orr, Caroline H., van der Putten, Wim H., Roberts, Ian S., Robinson, David A., Rocca, Jennifer D., Rowntree, Jennifer, Schlaeppi, Klaus, Shepherd, Matthew, Singh, Brajesh K., Straathof, Angela L., Bhatnagar, Jennifer M., Thion, Cécile, van der Heijden, Marcel G.A., de Vries, Franciska T., Ramirez, Kelly S., Knight, Christopher G., de Hollander, Mattias, Brearley, Francis Q., Constantinides, Bede, Cotton, Anne, Creer, Si, Crowther, Thomas W., Davison, John, Delgado-Baquerizo, Manuel, Dorrepaal, Ellen, Elliott, David R., Fox, Graeme, Griffiths, Robert I., Hale, Chris, Hartman, Kyle, Houlden, Ashley, Jones, David L., Krab, Eveline J., Maestre, Fernando T., McGuire, Krista L., Monteux, Sylvain, Orr, Caroline H., van der Putten, Wim H., Roberts, Ian S., Robinson, David A., Rocca, Jennifer D., Rowntree, Jennifer, Schlaeppi, Klaus, Shepherd, Matthew, Singh, Brajesh K., Straathof, Angela L., Bhatnagar, Jennifer M., Thion, Cécile, van der Heijden, Marcel G.A., and de Vries, Franciska T.

Abstract

The emergence of high-throughput DNA sequencing methods provides unprecedented opportunities to further unravel bacterial biodiversity and its worldwide role from human health to ecosystem functioning. However, despite the abundance of sequencing studies, combining data from multiple individual studies to address macroecological questions of bacterial diversity remains methodically challenging and plagued with biases. Here, using a machine-learning approach that accounts for differences among studies and complex interactions among taxa, we merge 30 independent bacterial data sets comprising 1,998 soil samples from 21 countries. Whereas previous meta-analysis efforts have focused on bacterial diversity measures or abundances of major taxa, we show that disparate amplicon sequence data can be combined at the taxonomy-based level to assess bacterial community structure. We find that rarer taxa are more important for structuring soil communities than abundant taxa, and that these rarer taxa are better predictors of community structure than environmental factors, which are often confounded across studies. We conclude that combining data from independent studies can be used to explore bacterial community dynamics, identify potential ‘indicator’ taxa with an important role in structuring communities, and propose hypotheses on the factors that shape bacterial biogeography that have been overlooked in the past.

Published
2018

10. Detecting macroecological patterns in bacterial communities across independent studies of global soils

Author

British Ecological Society, European Commission, Yorkshire Agricultural Society, Northumbria University, Wallenberg Academy, Delgado-Baquerizo, Manuel [0000-0002-6499-576X], Griffiths, Robert [0000-0002-3341-4547], Maestre, Fernando T. [0000-0002-7434-4856], Singh, Brajesh K. [0000-0003-4413-4185], Vries, Franciska T. de [0000-0002-6822-8883], Ramirez, Kelly S., Knight, Christopher G., Hollander, Mattias de, Brearley, Francis Q., Constantinides, Bede, Cotton, Anne, Creer, Si, Crowther, Thomas W., Davinson, John, Delgado-Baquerizo, Manuel, Dorrepaal, Ellen, Elliott, David R., Fox, Graeme, Griffiths, Robert, Hale, Chris, Hartman, Kyle, Houlden, Ashley, Jones, David L., Krab, Eveline J., Maestre, Fernando T., McGuire, Krista L., Monteux, Sylvain, Orr, Caroline H., Putten, Wim H. van der, Roberts. Ian S., Robinson, David A., Rocca, Jennifer, Rowntree, Jennifer, Schlaeppi, Klaus, Shepherd, Matthew, Singh, Brajesh K., Straathof, Angela L., Bhatnagar, Jennifer M., Thion, Cécile, Heijden, Marcel G. A. van der, Vries, Franciska T. de, British Ecological Society, European Commission, Yorkshire Agricultural Society, Northumbria University, Wallenberg Academy, Delgado-Baquerizo, Manuel [0000-0002-6499-576X], Griffiths, Robert [0000-0002-3341-4547], Maestre, Fernando T. [0000-0002-7434-4856], Singh, Brajesh K. [0000-0003-4413-4185], Vries, Franciska T. de [0000-0002-6822-8883], Ramirez, Kelly S., Knight, Christopher G., Hollander, Mattias de, Brearley, Francis Q., Constantinides, Bede, Cotton, Anne, Creer, Si, Crowther, Thomas W., Davinson, John, Delgado-Baquerizo, Manuel, Dorrepaal, Ellen, Elliott, David R., Fox, Graeme, Griffiths, Robert, Hale, Chris, Hartman, Kyle, Houlden, Ashley, Jones, David L., Krab, Eveline J., Maestre, Fernando T., McGuire, Krista L., Monteux, Sylvain, Orr, Caroline H., Putten, Wim H. van der, Roberts. Ian S., Robinson, David A., Rocca, Jennifer, Rowntree, Jennifer, Schlaeppi, Klaus, Shepherd, Matthew, Singh, Brajesh K., Straathof, Angela L., Bhatnagar, Jennifer M., Thion, Cécile, Heijden, Marcel G. A. van der, and Vries, Franciska T. de

Abstract

The emergence of high-throughput DNA sequencing methods provides unprecedented opportunities to further unravel bacterial biodiversity and its worldwide role from human health to ecosystem functioning. However, despite the abundance of sequencing studies, combining data from multiple individual studies to address macroecological questions of bacterial diversity remains methodically challenging and plagued with biases. Here, using a machine-learning approach that accounts for differences among studies and complex interactions among taxa, we merge 30 independent bacterial data sets comprising 1,998 soil samples from 21 countries. Whereas previous meta-analysis efforts have focused on bacterial diversity measures or abundances of major taxa, we show that disparate amplicon sequence data can be combined at the taxonomy-based level to assess bacterial community structure. We find that rarer taxa are more important for structuring soil communities than abundant taxa, and that these rarer taxa are better predictors of community structure than environmental factors, which are often confounded across studies. We conclude that combining data from independent studies can be used to explore bacterial community dynamics, identify potential ‘indicator’ taxa with an important role in structuring communities, and propose hypotheses on the factors that shape bacterial biogeography that have been overlooked in the past.

Published
2018

12. Detecting macroecological patterns in bacterial communities across independent studies of global soils

Author

Ramirez, Kelly S., Knight, Christopher G., de Hollander, Mattias, Brearley, Francis Q., Constantinides, Bede, Cotton, Anne, Creer, Si, Crowther, Thomas W., Davison, John, Delgado-baquerizo, Manuel, Dorrepaal, Ellen, Elliott, David R., Fox, Graeme, Griffiths, Robert I., Hale, Chris, Hartman, Kyle, Houlden, Ashley, Jones, David L., Krab, Eveline J., Maestre, Fernando T., Mcguire, Krista L., Monteux, Sylvain, Orr, Caroline H., Van Der Putten, Wim H., Roberts, Ian S., Robinson, David A., Rocca, Jennifer D., Rowntree, Jennifer, Schlaeppi, Klaus, Shepherd, Matthew, Singh, Brajesh K., Straathof, Angela L., Bhatnagar, Jennifer M., Thion, Cécile, Van Der Heijden, Marcel G. A., De Vries, Franciska T., Ramirez, Kelly S., Knight, Christopher G., de Hollander, Mattias, Brearley, Francis Q., Constantinides, Bede, Cotton, Anne, Creer, Si, Crowther, Thomas W., Davison, John, Delgado-baquerizo, Manuel, Dorrepaal, Ellen, Elliott, David R., Fox, Graeme, Griffiths, Robert I., Hale, Chris, Hartman, Kyle, Houlden, Ashley, Jones, David L., Krab, Eveline J., Maestre, Fernando T., Mcguire, Krista L., Monteux, Sylvain, Orr, Caroline H., Van Der Putten, Wim H., Roberts, Ian S., Robinson, David A., Rocca, Jennifer D., Rowntree, Jennifer, Schlaeppi, Klaus, Shepherd, Matthew, Singh, Brajesh K., Straathof, Angela L., Bhatnagar, Jennifer M., Thion, Cécile, Van Der Heijden, Marcel G. A., and De Vries, Franciska T.

Abstract

The emergence of high-throughput DNA sequencing methods provides unprecedented opportunities to further unravel bacterial biodiversity and its worldwide role from human health to ecosystem functioning. However, despite the abundance of sequencing studies, combining data from multiple individual studies to address macroecological questions of bacterial diversity remains methodically challenging and plagued with biases. Here, using a machine-learning approach that accounts for differences among studies and complex interactions among taxa, we merge 30 independent bacterial data sets comprising 1,998 soil samples from 21 countries. Whereas previous meta-analysis efforts have focused on bacterial diversity measures or abundances of major taxa, we show that disparate amplicon sequence data can be combined at the taxonomy-based level to assess bacterial community structure. We find that rarer taxa are more important for structuring soil communities than abundant taxa, and that these rarer taxa are better predictors of community structure than environmental factors, which are often confounded across studies. We conclude that combining data from independent studies can be used to explore bacterial community dynamics, identify potential ‘indicator’ taxa with an important role in structuring communities, and propose hypotheses on the factors that shape bacterial biogeography that have been overlooked in the past.

Published
2017

13. Detecting macroecological patterns in bacterial communities across independent studies of global soils

Author

Plant Microbe Interactions, Sub Plant-Microbe Interactions, Ramirez, Kelly S., Knight, Christopher G., de Hollander, Mattias, Brearley, Francis Q., Constantinides, Bede, Cotton, Anne, Creer, Si, Crowther, Thomas W., Davison, John, Delgado-baquerizo, Manuel, Dorrepaal, Ellen, Elliott, David R., Fox, Graeme, Griffiths, Robert I., Hale, Chris, Hartman, Kyle, Houlden, Ashley, Jones, David L., Krab, Eveline J., Maestre, Fernando T., Mcguire, Krista L., Monteux, Sylvain, Orr, Caroline H., Van Der Putten, Wim H., Roberts, Ian S., Robinson, David A., Rocca, Jennifer D., Rowntree, Jennifer, Schlaeppi, Klaus, Shepherd, Matthew, Singh, Brajesh K., Straathof, Angela L., Bhatnagar, Jennifer M., Thion, Cécile, Van Der Heijden, Marcel G. A., De Vries, Franciska T., Plant Microbe Interactions, Sub Plant-Microbe Interactions, Ramirez, Kelly S., Knight, Christopher G., de Hollander, Mattias, Brearley, Francis Q., Constantinides, Bede, Cotton, Anne, Creer, Si, Crowther, Thomas W., Davison, John, Delgado-baquerizo, Manuel, Dorrepaal, Ellen, Elliott, David R., Fox, Graeme, Griffiths, Robert I., Hale, Chris, Hartman, Kyle, Houlden, Ashley, Jones, David L., Krab, Eveline J., Maestre, Fernando T., Mcguire, Krista L., Monteux, Sylvain, Orr, Caroline H., Van Der Putten, Wim H., Roberts, Ian S., Robinson, David A., Rocca, Jennifer D., Rowntree, Jennifer, Schlaeppi, Klaus, Shepherd, Matthew, Singh, Brajesh K., Straathof, Angela L., Bhatnagar, Jennifer M., Thion, Cécile, Van Der Heijden, Marcel G. A., and De Vries, Franciska T.

Published
2017

15. Detecting macroecological patterns in bacterial communities across independent studies of global soils

Author

Ramirez, Kelly S., primary, Knight, Christopher G., additional, de Hollander, Mattias, additional, Brearley, Francis Q., additional, Constantinides, Bede, additional, Cotton, Anne, additional, Creer, Si, additional, Crowther, Thomas W., additional, Davison, John, additional, Delgado-Baquerizo, Manuel, additional, Dorrepaal, Ellen, additional, Elliott, David R., additional, Fox, Graeme, additional, Griffiths, Robert I., additional, Hale, Chris, additional, Hartman, Kyle, additional, Houlden, Ashley, additional, Jones, David L., additional, Krab, Eveline J., additional, Maestre, Fernando T., additional, McGuire, Krista L., additional, Monteux, Sylvain, additional, Orr, Caroline H., additional, van der Putten, Wim H., additional, Roberts, Ian S., additional, Robinson, David A., additional, Rocca, Jennifer D., additional, Rowntree, Jennifer, additional, Schlaeppi, Klaus, additional, Shepherd, Matthew, additional, Singh, Brajesh K., additional, Straathof, Angela L., additional, Bhatnagar, Jennifer M., additional, Thion, Cécile, additional, van der Heijden, Marcel G. A., additional, and de Vries, Franciska T., additional

Published
2017
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16. Changes in root‐exudate‐induced respiration reveal a novel mechanism through which drought affects ecosystem carbon cycling.

Author

Vries, Franciska T., Williams, Alex, Stringer, Fiona, Willcocks, Robert, McEwing, Rosie, Langridge, Holly, and Straathof, Angela L.

Subjects
CARBON cycle, DROUGHT management, DROUGHTS, SOIL respiration, HETEROTROPHIC respiration, RESPIRATION, ECOSYSTEMS, KNOWLEDGE gap theory
Abstract

Summary: Root exudates play an important role in ecosystem response to climate change, but the functional consequences of drought‐induced changes in the quality of root exudates are unknown. Here, we addressed this knowledge gap in a unique experimental approach.We subjected two common grassland species that differ widely in their growth strategies and root systems, the grass Holcus lanatus and the forb Rumex acetosa, to 2 wk of drought. We collected root exudates and soils at the end of the drought and after 2 wk of recovery and readded all root exudates to all soils in a fully reciprocal set‐up to measure root‐exudate‐induced respiration.We found that soil treatment was unimportant for determining root‐exudate‐induced respiration. By contrast, root exudates collected from plants that had experienced drought clearly triggered more soil respiration than exudates from undroughted plants. Importantly, this increased respiration compensated for the lower rates of root exudation in droughted plants.Our findings reveal a novel mechanism through which drought can continue to affect ecosystem carbon cycling, and a potential plant strategy to facilitate regrowth through stimulating microbial activity. These findings have important implications for understanding plant and ecosystem response to drought. [ABSTRACT FROM AUTHOR]

Published
2019
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17. Nitrous oxide emission rates and abundances of nitrogen-cycling genes in soils of willow trees inoculated with mycorrhizal fungi

Author

Straathof, Angela L., Dunfield, Kari E., and Wagner-Riddle, Claudia

Subjects
N-cycling, mycorrhizal inoculation, native abundance, microbial communities, N2O emission rate, complex mixtures
Abstract

A greenhouse experiment was designed to explore the effects of mycorrhizal inoculation on native abundances of N-cycling microbial communities and N2O emission rates. Six different soil types were examined as a medium for growing willow ('Salix spp.') trees, which were inoculated with arbuscular mycorrhizae (AM), ectomycorrhizae (EM), AM + EM, or neither. Nitrogen-cycling gene abundances were found to be significantly different between soil types and influenced by rhizosphere presence but not inoculation. While inoculation effects were seen in one clay soil's NO 3-, NH4+, and N2O measurements, this was not reflected in gene abundance. Principal component analysis on environmental variables and gene abundances indicated correlations, though the nature of the relationship depended on the soil type and was largely texturally-driven. Strong evidence for primarily nitrifier-driven N2 O emissions was found in bulk soil. This research broadens the understanding of mycorrhizal-bacterial interactions and their effects on N-cycling in different soil ecosystems.

Published
2010

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