Abstract
Dispersal is key for maintaining biodiversity at local- and regional scales in metacommunities. However, little is known about the combined effects of dispersal and climate change on biodiversity. Theory predicts that alpha-diversity is maximized at intermediate dispersal rates, resulting in a hump-shaped diversity-dispersal relationship. This relationship is predicted to flatten when competition increases. We anticipate that this same flattening will occur with increased temperature because, in the rising part of the temperature performance curve, interspecific competition is predicted to increase. We explored this question using aquatic communities of Sarracenia purpurea from early- and late-successional stages, in which we simulated four levels of dispersal and four temperature scenarios. With increased dispersal, the hump shape was observed consistently in late successional communities, but only in higher temperature treatments in early succession. Increased temperature did not flatten the hump-shape relationship, but decreased the level of alpha- and gamma-diversity. Interestingly, higher temperatures negatively impacted small-bodied species. These metacommunity-level extinctions likely relaxed interspecific competition, which could explain the absence of flattening of the diversity-dispersal relationship. Our findings suggest that climate change will cause extinctions both at local- and global- scales and emphasize the importance of intermediate levels of dispersal as an insurance for local diversity.
Highlights
Dispersal is key for maintaining biodiversity at local- and regional scales in metacommunities
It is essential to identify the processes that are important for maintaining biodiversity and how these processes will be affected by environmental change
Little is known about if an intermediate level of dispersal will still maintain the highest level of diversity when the metacommunity is subject to environmental change
Summary
Dispersal is key for maintaining biodiversity at local- and regional scales in metacommunities. The model of Mouquet and Loreau[7] predicts that an intermediate level of dispersal is optimal for maximizing diversity at the local scale in these competition-driven metacommunities According to this theory, when no dispersal between communities occurs, alpha-diversity is expected to be low because competitively-dominant species are likely to drive other species to local extinction. As proposed by Mouquet and Loreau[7] and extended by Kneitel and Miller[8], stronger interspecific competition is one mechanism that will flatten the hump-shaped relationship between diversity and dispersal: less competitive species will become locally extinct[21] and alpha-diversity will decrease if the system contains the original gamma-diversity and if the dispersal rate is constant between patches. Since earlyand late-successional communities have different organization and dynamics, it is expected that they will respond differently to the interacting effects of global warming and dispersal rates
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