Predators drive community reorganization during experimental range shifts

Jones, Natalie T.; Symons, Celia C.; Cavalheri, Hamanda B.; Pedroza-Ramos, Adriana; Shurin, Jonathan B.

doi:10.1111/1365-2656.13289

Cited by 9 publications

(13 citation statements)

References 71 publications

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“…These priority effects can either positively or negatively impact species richness within a metacommunity, depending on local adaptation and generation times of early colonists, as well as dispersal rates of later colonists (Vanoverbeke et al, 2016). If early colonists acclimate quickly to local conditions or late colonists have low dispersal rates, then the early colonists will dominate the metacommunity and decrease overall diversity (Grainger & Gilbert, 2016;Jones et al, 2020;Lawler & Morin, 1993;Shurin, 2001). If the reverse is true, or if early colonists are predators that relieve competitive exclusion effects, then early colonists can cause a net increase in species diversity (Beisner, 2001;McCauley & Briand, 1979;Sarnelle, 2005).…”

Section: Introductionmentioning

confidence: 99%

Patch size drives colonization by aquatic insects, with minor priority effects of a cohabitant

Scott

Pintar

Resetarits

2021

Ecology and Evolution

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Section: Introductionmentioning

confidence: 99%

Patch size drives colonization by aquatic insects, with minor priority effects of a cohabitant

Scott

Pintar

Resetarits

2021

Ecology and Evolution

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“…The communities shifted to smaller body sizes with predation, resulting in reduced community biomass despite increased zooplankton abundance. Intraspecific reductions in body size and increased population sizes indicate that smaller body sizes may be adaptive for many taxa in the presence of size‐selective predators (Brooks and Dodson 1965, Fisk et al 2007, Jones et al 2020). The intraspecific shifts that we observed may have driven by adaptive reductions in adult body size or by demographic shifts toward juvenile life stages.…”

Section: Discussionmentioning

confidence: 99%

“…Convict Lake, the source of our experienced zooplankton community, is larger, deeper and lower elevation than Eastern Brook, our fishless lake. A considerable body of work shows that the presence/absence of fish is a significant selective pressure on zooplankton communities in lakes of the Sierra Nevada (Knapp 1996, Knapp et al 2001, Sarnelle and Knapp 2005, Symons and Shurin 2016, Jones et al 2020). Prior experiments from the region demonstrated intraspecific differences in adaptive constitutive and plastic anti‐predator traits in zooplankton from several lakes with fish, relative to trout‐naive zooplankton (Fisk et al 2007, Latta et al 2007).…”

Section: Discussionmentioning

confidence: 99%

Section: Caveats and Future Directionsmentioning

confidence: 99%

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Prey naiveté alters the balance of consumptive and non‐consumptive predator effects and shapes trophic cascades in freshwater plankton

Baker

Samu

et al. 2022

Oikos

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Predators drive trophic cascades by reducing prey biomass and altering prey traits, selecting for prey that exhibit constitutive and induced anti‐predator defenses that decrease susceptibility to consumption. These defense traits are often costly, generating a tradeoff between consumptive (CEs) and non‐consumptive predator effects (NCEs). The ecological and evolutionary experience that prey share with a given predator may determine their position along this tradeoff curve, affecting the nature and strength of top–down control of ecosystems. Conceptual models predict that predator‐experienced prey suffer greater NCEs than predator–naive prey, which suffer stronger CEs and total predator effects (CEs + NCEs), but this has not been tested in diverse prey communities. We tested these predictions by comparing the effects of predation (CEs + NCEs) and predation risk (NCEs only) of planktivorous fish on food web structure in pond mesocosms with diverse natural communities of either predator‐naive or predator‐experienced zooplankton. Contrary to expectations, top–down control of zooplankton and phytoplankton biomass was strengthened by prey community experience: in systems with experienced relative to naive zooplankton communities both predation risk (NCEs only) and predation (CEs + NCEs) had stronger effects on zooplankton prey biomass and trophic cascades were twice as strong. These results show that the ecological and evolutionary experience of diverse prey communities alters the balance of consumptive and non‐consumptive predator effects and influences trophic cascade strength.

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“…The outcome of any such shift will depend on the balance of these interactions (Lurgi et al, 2012). For example, resident predators may play important roles in altering competitive or other intraguild interactions between resident and shifting species of lower trophic levels (Chase et al, 2002;Chesson & Kuang, 2008;Jones et al, 2020). Disentangling the roles that these various, simultaneous, interactions play in the outcomes of shifts in habitat use should be one of the primary objectives of studies seeking to understand the outcomes of species responses to climate change.…”

Section: Introductionmentioning

confidence: 99%

Predators balance consequences of climate‐change‐induced habitat shifts for range‐shifting and resident species

Shepard

Wissinger

Wood

et al. 2021

Journal of Animal Ecology

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1. While many species distributions are shifting poleward or up in elevation in response to a changing climate, others are shifting their habitats along localized gradients in environmental conditions as abiotic conditions become more stressful.Whether species are moving across regional or local environmental gradients in response to climate change, range-shifting species become embedded in established communities of competitors and predators. The consequences of these shifts for both resident and shifting species are often unknown, as it can be difficult to isolate the effects of multiple species interactions.2. Using a model system of insects in high-elevation ponds in the Rocky Mountains of Colorado, we sought to disentangle the effects of predation and intraguild interactions on the survival and development of a semi-permanent pond resident caddisfly Limnephilus externus and the habitat-shifting caddis Asynarchus nigriculus that is being forced into semi-permanent ponds as temporary ponds dry too quickly to complete development.3. We conducted a manipulative in-situ pond cage experiment in which L. externus and A. nigriculus caddisfly larvae in single-species treatments and together were exposed to the presence/absence of predatory Dytiscus diving beetle larvae. This approach allowed us to isolate the effects of intraguild interactions and predation on the survival and development of both the resident and habitat-shifting species.4. We found that intraguild interactions had strong negative effects on the resident and habitat-shifting species. Intraguild interactions reduced the survival of the resident L. externus and increased the variation in survival of the shifting A. nigriculus. However, Dytiscus predators reduced these negative effects, stabilizing the community by increasing L. externus survival and reducing variation in A. nigriculus survival. We also found that intraguild interactions reduced L. externus biomass but resulted in increased A. nigriculus development. A. nigriculus development was also increased by predation. 5. Our results show that strong intraguild interactions between resident and shifting species are likely to have negative consequences for both species. However, the presence of predators reduces these negative consequences of the habitat shift on both the resident and the shifting.

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Predators drive community reorganization during experimental range shifts

Cited by 9 publications

References 71 publications

Patch size drives colonization by aquatic insects, with minor priority effects of a cohabitant

Patch size drives colonization by aquatic insects, with minor priority effects of a cohabitant

Prey naiveté alters the balance of consumptive and non‐consumptive predator effects and shapes trophic cascades in freshwater plankton

Predators balance consequences of climate‐change‐induced habitat shifts for range‐shifting and resident species

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