Linking degradation status with ecosystem vulnerability to environmental change

Environmental change can cause regime shifts in ecosystems, potentially threatening ecosystem services. It is unclear if the degradation status of ecosystems correlates with their vulnerability to environmental change, and thus the risk of future regime shifts. We assessed resilience in acidified (d...

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Bibliographic Details
Published in:Oecologia 2015-07, Vol.178 (3), p.899-913
Main Authors: Angeler, David G, Baho, Didier L, Allen, Craig R, Johnson, Richard K
Format: Article
Language:English
Subjects:
Analysis
Animals
Biomedical and Life Sciences
Ecological adaptation
Ecology
Ecosystem
Ecosystem services
Ecosystems
Ekologi
Environmental changes
Freshwater
GLOBAL CHANGE ECOLOGY
Global change ecology - Original research
Hydrogen-Ion Concentration
Hydrology/Water Resources
Invertebrates
Lakes
Life Sciences
Models, Biological
Plant Sciences
Population biology
Population Dynamics
prediction
risk
Species diversity
time series analysis
uncertainty
Water Pollution
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Summary:Environmental change can cause regime shifts in ecosystems, potentially threatening ecosystem services. It is unclear if the degradation status of ecosystems correlates with their vulnerability to environmental change, and thus the risk of future regime shifts. We assessed resilience in acidified (degraded) and circumneutral (undegraded) lakes with long-term data (1988–2012), using time series modeling. We identified temporal frequencies in invertebrate assemblages, which identifies groups of species whose population dynamics vary at particular temporal scales. We also assessed species with stochastic dynamics, those whose population dynamics vary irregularly and unpredictably over time. We determined the distribution of functional feeding groups of invertebrates within and across the temporal scales identified, and in those species with stochastic dynamics, and assessed attributes hypothesized to contribute to resilience. Three patterns of temporal dynamics, consistent across study lakes, were identified in the invertebrates. The first pattern was one of monotonic change associated with changing abiotic lake conditions. The second and third patterns appeared unrelated to the environmental changes we monitored. Acidified and the circumneutral lakes shared similar levels and patterns of functional richness, evenness, diversity, and redundancy for species within and across the observed temporal scales and for stochastic species groups. These similar resilience characteristics suggest that both lake types did not differ in vulnerability to the environmental changes observed here. Although both lake types appeared equally vulnerable in this study, our approach demonstrates how assessing systemic vulnerability by quantifying ecological resilience can help address uncertainty in predicting ecosystem responses to environmental change across ecosystems.
ISSN:0029-8549
1432-1939
1432-1939
DOI:10.1007/s00442-015-3281-y