Impacts of Soil Faunal Community Composition on Model Grassland Ecosystems

Bradford, Mark A.; Jones, T. Hefin; Bardgett, Richard D.; Black, H. I. J.; Boag, B.; Bonkowski, Michael; Cook, R.; Eggers, Till; Gange, Alan C.; Grayston, Susan J.; Kandeler, Ellen; McCaig, Allison E.; Newington, John E.; Prosser, Jim; Setälä, Heikki; Staddon, Philip L.; Tordoff, George M.; Tscherko, Dagmar; Lawton, John H.

doi:10.1126/science.1075805

Cited by 271 publications

(202 citation statements)

References 21 publications

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“…The microcosms were maintained in the Ecotron for a period of 8.5 months. Bradford et al (2002) found significant increases in decomposition rate in the most complex faunal treatment, but both mycorrhizal colonization and root biomass were less abundant in the macrofauna treatments. Interestingly plant growth was not enhanced in these treatments, despite higher nutrient (N and P) availability.…”

Section: Models Microcosms and Soil Biodiversitymentioning

confidence: 87%

“…Bradford et al suggested that respiration was most likely buffered by the combined stimulatory effect of both mesofauna and macrofauna on microbes, which served to maintain microbial activity at a level equivalent to that in the microfauna and mesofauna communities. This study has been considered a benchmark in large-scale microcosm studies, but as Bradford et al (2002) note, it is not a substitute of longer-term in situ field studies.…”

Section: Models Microcosms and Soil Biodiversitymentioning

confidence: 99%

“…In fact, earlier analyses of similar food webs by Moore et al (1993) and Moore and de Ruiter (2000) showed that loss of top predators had much greater impacts on lower trophic levels than their low biomasses might indicate. Another approach to microcosm studies was taken by the group working in the Ecotron facility at Silwood Park, UK Constructing analogs of a temperate, acidic, sheep-grazed grassland in northern Britain, Bradford et al (2002) established terrestrial microcosms of graded complexity, with soil, plants and microorganisms, and then assemblages of microfauna, micro-and mesofauna, and then micro-, meso-and macrofauna. Thus, soil community composition was manipulated through assemblages of different animal body sizes.…”

Section: Models Microcosms and Soil Biodiversitymentioning

confidence: 99%

See 2 more Smart Citations

Linking Species Richness, Biodiversity and Ecosystem Function in Soil Systems

Coleman

Whitman

2007

ChemInform

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Section: Models Microcosms and Soil Biodiversitymentioning

confidence: 87%

Section: Models Microcosms and Soil Biodiversitymentioning

confidence: 99%

Section: Models Microcosms and Soil Biodiversitymentioning

confidence: 99%

See 1 more Smart Citation

Linking Species Richness, Biodiversity and Ecosystem Function in Soil Systems

Coleman

Whitman

2007

ChemInform

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“…A variety of other fauna, including meso-or microinvertebrates, also will contribute to the grazing effects recorded here (7,33). Indeed, the exclusion of other common macroinvertebrates, such as diplopods, from experimental chambers means that the invertebrate treatments plots are likely to underrepresent the potential for grazers to regulate the fungal community response to global change (34). However, the unique capacity of isopods to sever and ingest thick fungal cords makes this interaction a particularly strong one within forest soil (20).…”

Section: Discussionmentioning

confidence: 99%

Biotic interactions mediate soil microbial feedbacks to climate change

Crowther

Thomas

Maynard

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

209

130

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Decomposition of organic material by soil microbes generates an annual global release of 50–75 Pg carbon to the atmosphere, ∼7.5–9 times that of anthropogenic emissions worldwide. This process is sensitive to global change factors, which can drive carbon cycle–climate feedbacks with the potential to enhance atmospheric warming. Although the effects of interacting global change factors on soil microbial activity have been a widespread ecological focus, the regulatory effects of interspecific interactions are rarely considered in climate feedback studies. We explore the potential of soil animals to mediate microbial responses to warming and nitrogen enrichment within a long-term, field-based global change study. The combination of global change factors alleviated the bottom-up limitations on fungal growth, stimulating enzyme production and decomposition rates in the absence of soil animals. However, increased fungal biomass also stimulated consumption rates by soil invertebrates, restoring microbial process rates to levels observed under ambient conditions. Our results support the contemporary theory that top-down control in soil food webs is apparent only in the absence of bottom-up limitation. As such, when global change factors alleviate the bottom-up limitations on microbial activity, top-down control becomes an increasingly important regulatory force with the capacity to dampen the strength of positive carbon cycle–climate feedbacks.

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“…The role of diversity per se, however, is unclear. In experiments that removed key taxonomic groups, little change in the rates of soil respiration or above-ground productivity were found (Liiri et al 2002), perhaps because the relatively low degree of specialization among detritivores implies considerable redundancy among this functional group (Bradford et al 2002). Others caution that it may take exposure to multiple types of stresses before there is sufficient loss of buffering capacity due to redundancy within functional groups for changes in ecosystem properties to become apparent (Griffiths et al 2000).…”

Section: The Diversity Issuementioning

confidence: 99%

Biotic interactions, ecological knowledge and agriculture

Shennan

2007

Phil. Trans. R. Soc. B

179

126

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This paper discusses biotic interactions in agroecosystems and how they may be manipulated to support crop productivity and environmental health by provision of ecosystem services such as weed, pest and disease management, nutrient cycling and biodiversity conservation. Important elements for understanding biotic interactions include consideration of the effects of diversity, species composition and food web structure on ecosystem processes; the impacts of timing, frequency and intensity of disturbance; and the importance of multitrophic interactions. All of these elements need to be considered at multiple scales that depend in part on the range of the movement of the organisms involved. These issues are first discussed in general, followed by an examination of the application of these concepts in agricultural management. The potential for a greater use of ecological management approaches is high; however, owing to the nature of complex interactions in ecosystems, there is some inherent unpredictability about responses to management interventions under different conditions. Such uncertainty needs to be accommodated in the development of recommendations for farm management. This requires an increased emphasis on the effective synthesis of complex and often apparently contradictory information and on field-based adaptive research, monitoring and social learning by farmer/researcher collaborations.

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Impacts of Soil Faunal Community Composition on Model Grassland Ecosystems

Cited by 271 publications

References 21 publications

Linking Species Richness, Biodiversity and Ecosystem Function in Soil Systems

Linking Species Richness, Biodiversity and Ecosystem Function in Soil Systems

Biotic interactions mediate soil microbial feedbacks to climate change

Biotic interactions, ecological knowledge and agriculture

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