Biogeographic context dependence of trophic cascade strength in bromeliad food webs

LeCraw, Robin M.; Srivastava, Diane S.

doi:10.1002/ecy.2692

Cited by 2 publications

(1 citation statement)

References 60 publications

(140 reference statements)

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“…differed between the two locations ( Culex erethyzonfer at MV and Culex jenningsi at UGA), because neither species was abundant enough at both locations, suggesting a degree of prior habitat filtering (Appendix A). Although natural bromeliads contain species‐rich communities (we recorded an average of 11.9 and 9.5 taxa inside bromeliads at UGA and MV, respectively), the average number of species at the scale of the leaf well is 3–7 (LeCraw & Srivastava, ; Trzcinski et al, ; D. Srivastava, unpublished data). The number of species per microcosm in our experiment is thus consistent with natural bromeliad systems, and communities in our study represent “typical” bromeliad communities (see Supporting Information: Appendix A).…”

Section: Methodsmentioning

confidence: 95%

Disentangling how climate change can affect an aquatic food web by combining multiple experimental approaches

Amundrud

Srivastava

2019

Global Change Biology

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Predicting the biological effects of climate change presents major challenges due to the interplay of potential biotic and abiotic mechanisms. Climate change can create unexpected outcomes by altering species interactions, and uncertainty over the ability of species to develop in situ tolerance or track environmental change further hampers meaningful predictions. As multiple climatic variables shift in concert, their potential interactions further complicate ecosystem responses. Despite awareness of these complexities, we still lack controlled experiments that manipulate multiple climatic stressors, species interactions, and prior exposure of species to future climatic conditions. Particularly studies that address how changes in water availability interact with other climatic stressors to affect aquatic ecosystems are still rare. Using aquatic insect communities of Neotropical tank bromeliads, we combined controlled manipulations of drought length and species interactions with a space-for-time transplant (lower elevations represent future climate) and a common garden approach.Manipulating drought length and experiment elevation revealed that adverse effects of drought were amplified at the warmer location, highlighting the potential of climatic stressors to synergistically affect communities. Manipulating the presence of omnivorous tipulid larvae showed that negative interactions from tipulids, presumably from predation, arose under drought, and were stronger at the warmer location, stressing the importance of species interactions in mediating community responses to climate change. The common garden treatments revealed that prior community exposure to potential future climatic conditions did not affect the outcome. In this powerful experiment, we demonstrated how complexities arise from the interplay of biotic and abiotic mechanisms of climate change. We stress that single species can steer ecological outcomes, and suggest that focusing on such disproportionately influential species may improve attempts at making meaningful predictions of climate change impacts on food webs. K E Y W O R D S

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Section: Methodsmentioning

confidence: 95%