Browsing by Author "Dibble, Christopher J."
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Item Does phylogeny matter? Assessing the impact of phylogenetic information in ecological meta-analysis(Blackwell Publishing Ltd/CNRS, 2012) Chamberlain, Scott A.; Hovick, Stephen M.; Dibble, Christopher J.; Rasmussen, Nick L.; Van Allen, Benjamin G.; Maitner, Brian S.; Ahern, Jeffrey R.; Bell-Dereske, Lukas P.; Roy, Christopher L.; Meza-Lopez, Maria; Carrillo, Juli; Siemann, Evan; Lajeunesse, Marc J.; Whitney, Kenneth D.Item Intraspecific priority effects and disease interact to alter population growth(Ecological Society of America, 2014) Dibble, Christopher J.; Hall, Spencer R.; Rudolf, Volker H.W.Intraspecific variation may shape colonization of new habitat patches through a variety of mechanisms. In particular, trait variation among colonizing individuals can produce intraspecific priority effects (IPEs), where early arrivers of a single species affect the establishment or growth of later conspecifics. While we have some evidence for the importance of IPEs, we lack a general understanding of factors affecting their presence or magnitude across a landscape. Specifically, IPEs should depend strongly on success of colonizers in the new habitat patch. This success hinges on interactions between colonizer traits and local selective pressures, but such context dependence remains unexplored experimentally. We addressed this gap by looking for the dynamical signature of IPEs in environments with and without a selective (parasite) pressure. We tested whether IPEs affected the population dynamics of a zooplankton host species (Daphnia dentifera) collected from two populations showing a tradeoff between growth rate and resistance to a fungal parasite (Metschnikowia bicuspidata). Differences in arrival order significantly altered population growth during a period of rapid resource depletion, driving large (up to 65%) differences in population abundance. Furthermore, the presence of IPEs was context dependent, as parasites reduced the impact of early arrivers on later arrivers. Such context-dependent IPEs, mediated by colonizer traits, colonization order, and selective pressures, may play an unanticipated role in the ecological and evolutionary dynamics of natural metapopulations. This mechanism highlights the overall importance of intraspecific variation for understanding ecological patterns.Item Resolving the roles of body size and species identity in driving functional diversity(the Royal Society, 2014) Rudolf, Volker H.W.; Rasmussen, Nick L.; Dibble, Christopher J.; Van Allen, Benjamin G.Efforts to characterize food webs have generated two influential approaches that reduce the complexity of natural communities. The traditional approach groups individuals based on their species identity, while recently developed approaches group individuals based on their body size. While each approach has provided important insights, they have largely been used in parallel in different systems. Consequently, it remains unclear how body size and species identity interact, hampering our ability to develop a more holistic framework that integrates both approaches. We address this conceptual gap by developing a framework which describes how both approaches are related to each other, revealing that both approaches share common but untested assumptions about how variation across size classes or species influences differences in ecological interactions among consumers. Using freshwater mesocosms with dragonfly larvae as predators, we then experimentally demonstrate that while body size strongly determined how predators affected communities, these size effects were species specific and frequently nonlinear, violating a key assumption underlying both size- and species-based approaches. Consequently, neither purely species- nor size-based approaches were adequate to predict functional differences among predators. Instead, functional differences emerged from the synergistic effects of body size and species identity. This clearly demonstrates the need to integrate size- and species-based approaches to predict functional diversity within communities.