2017 ESA Annual Meeting (August 6 -- 11)

COS 19-1 - A global synthesis of phenological responses to climate change

Monday, August 7, 2017: 1:30 PM
D139, Oregon Convention Center
Jeremy M. Cohen1, Marc J. Lajeunesse1 and Jason R. Rohr2, (1)Department of Integrative Biology, University of South Florida, Tampa, FL, (2)Integrative Biology, University of South Florida, Tampa, FL
Background/Question/Methods

Phenology, or the timing of seasonal activities, is shifting with climate change, resulting in disruptions to the timing of migration and breeding and emerging asynchronies between interacting species. Recent syntheses have concluded that trophic level, latitude, and how phenological responses are measured are key to determining the strength of phenological responses to climate change. However, despite these insights, researchers still lack a comprehensive framework that can predict responses to climate change globally and across diverse taxa. For example, little is known about whether phenological shifts are driven by different climatic factors across regions or which ecologically important species characteristics (e.g., body size) predict the strength of phenological responses. Here, we address these questions by synthesizing 1,011 published time series of animal phenology from across the planet.

Results/Conclusions

We find that temperature drives phenological responses at mid-latitudes, but precipitation is more important at lower latitudes, since these climate factors drive seasonality in each of these regions. Body size is also negatively associated with the strength of phenological shift, suggesting emerging asynchronies between interacting species that differ in size, such as hosts and parasites and predators and prey. Finally, although there are many compelling biological explanations for spring phenological delays, some examples of delays are associated with short annual records prone to sampling error. As climate change intensifies, our findings arm biologists with predictions concerning which climatic variables and organismal traits drive phenological shifts.