Mammalian engineers drive soil microbial communities and ecosystem functions across a disturbance gradient

Eldridge, David J.; Delgado‐Baquerizo, Manuel; Woodhouse, Jason N.; Neilan, Brett A.

doi:10.1111/1365-2656.12574

Cited by 46 publications

(37 citation statements)

References 48 publications

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“…Fungi and microbial communities were least reported in studies (4%). The research on these taxa focussed on species richness and composition, particularly as a response to soil disturbance by burrowing engineers (Eldridge, Delgado‐Baquerizo, Woodhouse, & Neilan, ), and following reintroduction of regionally extinct engineer species (Clarke, Weyrich, & Cooper, ).…”

Section: Which Species Act As Ecosystem Engineers and With Whom Do Thmentioning

confidence: 99%

“…Three of the eight species studied were reintroduced. Because these engineers were reintroduced after long periods of regional extinction, it was possible to observe how the presence of burrowing species not only facilitated the survival and establishment of other threatened species (Hayward et al., ), but was also strongly associated with changes in ground‐dwelling arthropod, fungal and microbial communities (Clarke et al., ; Eldridge et al., ; Silvey et al., ), and changes in abundance and behaviour that affected the function of other engineers (Coggan, Hayward, & Gibb, ). The role of all burrowing species (particularly vertebrates) in supporting diversity by providing shelter is reflected in observations globally (see reviews by Davidson et al., ; Root‐Bernstein & Ebensperger, ).…”

Section: What Are the Impacts Of Ecosystem Engineers In Terrestrial Hmentioning

confidence: 99%

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A global database and “state of the field” review of research into ecosystem engineering by land animals

Coggan

Hayward

Gibb

2018

Journal of Animal Ecology

118

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Ecosystem engineers have been widely studied for terrestrial systems, but global trends in research encompassing the range of taxa and functions have not previously been synthesised. We reviewed contemporary understanding of engineer fauna in terrestrial habitats and assessed the methods used to document patterns and processes, asking: (a) which species act as ecosystem engineers and with whom do they interact? (b) What are the impacts of ecosystem engineers in terrestrial habitats and how are they distributed? (c) What are the primary methods used to examine engineer effects and how have these developed over time? We considered the strengths, weaknesses and gaps in knowledge related to each of these questions and suggested a conceptual framework to delineate "significant impacts" of engineering interactions for all terrestrial animals. We collected peer-reviewed publications examining ecosystem engineer impacts and created a database of engineer species to assess experimental approaches and any additional covariates that influenced the magnitude of engineer impacts. One hundred and twenty-two species from 28 orders were identified as ecosystem engineers, performing five ecological functions. Burrowing mammals were the most researched group (27%). Half of all studies occurred in dry/arid habitats. Mensurative studies comparing sites with and without engineers (80%) were more common than manipulative studies (20%). These provided a broad framework for predicting engineer impacts upon abundance and species diversity. However, the roles of confounding factors, processes driving these patterns and the consequences of experimentally adjusting variables, such as engineer density, have been neglected. True spatial and temporal replication has also been limited, particularly for emerging studies of engineer reintroductions. Climate change and habitat modification will challenge the roles that engineers play in regulating ecosystems, and these will become important avenues for future research. We recommend future studies include simulation of engineer effects and experimental manipulation of engineer densities to determine the potential for ecological cascades through trophic and engineering pathways due to functional decline. We also recommend improving knowledge of long-term engineering effects and replication of engineer reintroductions across landscapes to better understand how large-scale ecological gradients alter the magnitude of engineering impacts.

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Section: Which Species Act As Ecosystem Engineers and With Whom Do Thmentioning

confidence: 99%

Section: What Are the Impacts Of Ecosystem Engineers In Terrestrial Hmentioning

confidence: 99%

A global database and “state of the field” review of research into ecosystem engineering by land animals

Coggan

Hayward

Gibb

2018

Journal of Animal Ecology

118

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“…Decomposition rates are influenced by climate, litter chemistry (Aerts, ), soil microbial and fungal communities (Beare et al., ) as well as litter position (above‐ vs. below‐ground) and microhabitat characteristics (Austin et al., ). Buried litter decomposes faster than surface litter (Austin et al., ), potentially due to the increased exposure to microbial and fungal communities (Beare et al., ), with microbial communities varying in association with animal foraging activities (Eldridge et al., ).…”

Section: Discussionmentioning

confidence: 99%

Bioturbation by bandicoots facilitates seedling growth by altering soil properties

et al. 2018

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Animals that forage for food via bioturbation can alter their habitat, influencing soil turnover, nutrient cycling and seedling recruitment, effectively acting as ecosystem engineers. Many digging mammals forage for food by digging small pits and creating spoil heaps with the discarded soil. We examined how small‐scale bioturbation, created by the foraging actions of an ecosystem engineer, can alter soil nutrients and subsequently improve growth of plants. We investigated the microbial and chemical properties of soil disturbed by the foraging of an Australian marsupial bandicoot, quenda (Isoodon fusciventer). Soil was collected from the base of 20 recent foraging pits (pit), the associated spoil heaps (spoil) and adjacent undisturbed soil (control) and analysed for nutrients (phosphorus, potassium, sulphur, organic carbon and conductivity) and microbial activity. Soil cores were collected from the same locations and seeds of the dominant canopy species, tuart (Eucalyptus gomphocephala), added to the soil under glasshouse conditions. The growth of seedlings was measured (height, maximum growth, basal stem width, shoot and root biomass) over a 4‐month period and arbuscular mycorrhizae (AM) fungi colonisation rates of seedling roots investigated. Soil from the spoil heaps had the greatest levels of conductivity and potassium. Both the spoil and undisturbed soil had greater amounts of microbial activity and organic carbon. In contrast, the pits had less nutrients and microbial activity. Seedlings grown in spoil soil were taller, heavier, with thicker stems and grew at a faster rate than seedlings in the pit or control soil. Colonisation with AM fungi was greatest for seedlings grown in pit soil. The best predictors of seedling growth were greater amounts of potassium, electrical conductivity and microbial activity. The best predictor of higher colonisation rates of AM fungi was less phosphorus. Bioturbation by ecosystem engineers, like quenda, can alter soil nutrients and microbial activity, facilitating seedling growth. We propose this may be caused by enhanced litter decomposition beneath the discarded spoil heaps. As the majority of Australian digging mammals are threatened, with many suffering substantial population and range contractions, the loss of these species will have long‐term impacts on ecosystem processes. A http://onlinelibrary.wiley.com/doi/10.1111/1365-2435.13179/suppinfo is available for this article.

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“…Digging and burrowing animals not only enhance habitat heterogeneity (Parsons et al ., ), thus creating habitat for other small mammals, reptiles and invertebrates (Davidson, Lightfoot & McIntyre, ; Ewacha et al ., ), but can influence ecosystems through non‐engineering pathways such as predation and competition (Prugh & Brashares, ). Therefore, maintaining or enhancing ecosystem engineer populations may be a cost‐effective tool to lessen the negative impacts of grazing on soil health, restore degraded habitats and assist in the recovery of other species of conservation concern (Eldridge & James, ; Eldridge et al ., ; McCullough Hennessy et al ., ).…”

Section: Discussionmentioning

confidence: 99%

Heavy livestock grazing negatively impacts a marsupial ecosystem engineer

Neilly

Schwarzkopf

2018

Journal of Zoology

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Ecosystem engineers play an important role in resource availability and can be negatively impacted by anthropogenic disturbances, such as livestock grazing. The decline of digging and burrowing mammals in Australia is partly attributed to agriculture, however little is known about their use of microhabitats, and thus, how they respond to different cattle grazing regimes. Here, we examine the response of a marsupial ecosystem engineer, the rufous bettong (Aepyprymnus rufescens) to cattle grazing strategies and vegetation types, and examine whether microhabitat selection is driving this response. We hypothesized that rufous bettongs would be negatively impacted by heavy cattle grazing due to their use of ground‐level microhabitat features. We conducted a mark‐recapture trapping survey among four grazing treatments and in two vegetation types (box and ironbark woodlands), at a 20‐year grazing trial in northern Australia. We modelled rufous bettong abundance in response to grazing treatment and vegetation type and determined microhabitat preference using Manly selection ratios. We found that rufous bettongs preferred ironbark and avoided heavy grazing. Thus, they avoided the areas of highest cattle utilization. On average, individuals preferred high grass and other terrestrial microhabitat variables of moderate complexity. Our results indicate that habitat selection is contributing to the response of a marsupial ecosystem engineer to different grazing strategies. Mammalian digging and burrowing ecosystem engineers should be a conservation focus on rangelands due to their positive influence on a suite of species, and their ability to potentially mitigate some of the negative impacts of cattle grazing on soil health.

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Mammalian engineers drive soil microbial communities and ecosystem functions across a disturbance gradient

Cited by 46 publications

References 48 publications

A global database and “state of the field” review of research into ecosystem engineering by land animals

A global database and “state of the field” review of research into ecosystem engineering by land animals

Bioturbation by bandicoots facilitates seedling growth by altering soil properties

Heavy livestock grazing negatively impacts a marsupial ecosystem engineer

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