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RESEARCH PRODUCT
Conceptualizing ecosystem tipping points within a physiological framework
Sean D. ConnellBrendan P. KelaherBrian HelmuthChristopher D. G. HarleyGianluca SaràZoë A. DoubledayBayden D. Russellsubject
multiple stressorperformance curveSettore BIO/07 - Ecologia0106 biological sciencesIssue Informationfood web dynamics; multiple stressors; performance curves; phase shifts; physiological stress; species interactions; Ecology Evolution Behavior and Systematics; Ecology; Nature and Landscape Conservation010603 evolutionary biology01 natural sciencesfood web dynamicphase shiftEcosystemSociologyEcology Evolution Behavior and SystematicsPhysiological stressOriginal Researchphysiological stressNature and Landscape Conservationspecies interactionsspecies interactionEcologyphysiological streEcology010604 marine biology & hydrobiologyperformance curvesEnvironmental ethicsEcology Evolution Behavior and Systematicmultiple stressorsphase shiftsPerformance curvesfood web dynamicsdescription
Connecting the nonlinear and often counterintuitive physiological effects of multiple environmental drivers to the emergent impacts on ecosystems is a fundamental challenge. Unfortunately, the disconnect between the way “stressors” (e.g., warming) is considered in organismal (physiological) and ecological (community) contexts continues to hamper progress. Environmental drivers typically elicit biphasic physiological responses, where performance declines at levels above and below some optimum. It is also well understood that species exhibit highly variable response surfaces to these changes so that the optimum level of any environmental driver can vary among interacting species. Thus, species interactions are unlikely to go unaltered under environmental change. However, while these nonlinear, species-specific physiological relationships between environment and performance appear to be general, rarely are they incorporated into predictions of ecological tipping points. Instead, most ecosystem-level studies focus on varying levels of “stress” and frequently assume that any deviation from “normal” environmental conditions has similar effects, albeit with different magnitudes, on all of the species within a community. We consider a framework that realigns the positive and negative physiological effects of changes in climatic and nonclimatic drivers with indirect ecological responses. Using a series of simple models based on direct physiological responses to temperature and ocean pCO2, we explore how variation in environment-performance relationships among primary producers and consumers translates into community-level effects via trophic interactions. These models show that even in the absence of direct mortality, mismatched responses resulting from often subtle changes in the physical environment can lead to substantial ecosystem-level change. Refereed/Peer-reviewed
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2017-01-01 | Ecology and Evolution |