Thermal sensitivity predicts the establishment success of nonnative species in a mesocosm warming experiment

Fey, Samuel B.; Cottingham, Kathryn L.

doi:10.1890/12-0609.1

Cited by 25 publications

(29 citation statements)

References 38 publications

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“…Such joint effects of temperature and competition have previously been shown to control species distributions in damselflies (Nilsson-€ Ortman et al, 2013) and Daphnia (Fey & Cottingham, 2012) and have been predicted for brown trout (Hein et al, 2013) and sessile marine invertebrates (Sorte & White, 2013). Such joint effects of temperature and competition have previously been shown to control species distributions in damselflies (Nilsson-€ Ortman et al, 2013) and Daphnia (Fey & Cottingham, 2012) and have been predicted for brown trout (Hein et al, 2013) and sessile marine invertebrates (Sorte & White, 2013).…”

Section: Discussionmentioning

confidence: 83%

Predicting consequences of climate change for ecosystem functioning: variation across trophic levels, species and individuals

Best

Stone

Stachowicz

2015

Diversity and Distributions

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Aim Maintenance of ecosystem function under climate change may depend on variation in the way species within functional guilds and individuals within species respond to changes in temperature. What level of variation among and within species do we need to understand, and is it predictable from distribution and trait data? Location Northern California, USA.Methods We used a mesocosm experiment and a set of feeding trials to test the ability of a guild of marine invertebrate grazers to control benthic algal blooms along a local temperature gradient. We investigate links between the locally disjunct distributions of these species, their temperature tolerance traits and the temperature dependence of their population growth and grazing rates. Results We found that the effect of increased temperature on population growth rates is independent of species interactions, but strongly species specific. This variation among herbivores is only partly predictable from differences in species distributions and traits, but translated into large differences in their ability to control macroalgae. Further, these species effects were amplified at warmer temperatures. Finally, we found evidence for a strong response to temperature in the feeding rates of the most important consumer over the course of the experiment, resulting in almost as much variation in grazing rates within one species as the average difference between species.Main conclusions These results illustrate the importance of understanding the variation in responses to temperature among species within a trophic level, among populations within key species and potentially within populations over time. However, this variation is not easily predicted. Further research is needed to uncover links between individuals' thermal optima and their current and future temperature niche.

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Section: Discussionmentioning

confidence: 83%

Predicting consequences of climate change for ecosystem functioning: variation across trophic levels, species and individuals

Best

Stone

Stachowicz

2015

Diversity and Distributions

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“…3A), which would have generated error in our measurements of both the dynamic interaction strength and the functional response parameters (Table 1). Despite this noise, however, there is no suggestion of an increase in interaction strength with temperature in either interaction strength metric, even though measurements span 88C, which for other small crustaceans can cover almost the entire rising portion of a thermal performance curve (Fey and Cottingham 2012). In addition, R 2 values for the fits of Eq.…”

Section: Discussionmentioning

confidence: 97%

The temperature independence of interaction strength in a sit‐and‐wait predator

et al. 2014

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Abstract. The strength of interactions between consumers and their resources has important implications for the overall structure and function of food webs. These interactions can change with warming, depending on the foraging mode of the predator. Theory predicts that warming increases foraging velocity in ectotherms, but in a sit-and-wait predator that has zero velocity when foraging, the interaction strength should be temperature independent. Using the protist Urocentrum turbo and the sitand-wait copepod Orthocyclops modestus, we tested this prediction by measuring dynamic interaction strengths (effect of a predator on prey population growth rate) and by estimating the parameters of a functional response. Both of these metrics were consistent with the prediction that interaction strength is temperature independent in a sit-and-wait predator. Our results indicate that there may be considerable variability in how warming alters foraging interactions, and estimating the overall effects of climate change on food webs may require consideration of the distribution of foraging strategies and the potential asymmetries that arise with interactions that involve different strategies.

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“…The success of D. lumholtzi in North America had previously been attributed to either its morphological defenses reducing susceptibility to fish predation (Engel and Tollrian 2009) or its high thermal tolerance, which may allow it to outperform similar native Daphnia species during the warmest summer months (Lennon et al 2001, Havel et al 2002, Engel and Tollrian 2012, Fey and Cottingham 2012. The success of D. lumholtzi in North America had previously been attributed to either its morphological defenses reducing susceptibility to fish predation (Engel and Tollrian 2009) or its high thermal tolerance, which may allow it to outperform similar native Daphnia species during the warmest summer months (Lennon et al 2001, Havel et al 2002, Engel and Tollrian 2012, Fey and Cottingham 2012.…”

Section: Implications For the Future Success Of Daphnia Lumholtzimentioning

confidence: 99%

“…Few studies have tested the effects of changing temperatures on the long-term success of nonnative species in their new ecological communities (Hellmann et al 2008). While increases in temperature will likely affect the success of invasive species by altering patterns of dominance and competitive interactions between native and nonnative species (Tylianakis et al 2008, Wolkovich and Cleland 2011, Fey and Cottingham 2012, little is known about the interplay between temperature-dependent physiological processes and temperature-mediated biotic interactions. A mechanistic understanding of the link between climate warming and the success of invasive species might enhance predictions of the expected abundances of, and traits associated with, invasive species and the development of effective mitigation strategies aimed at their prevention and management.…”

Section: Introductionmentioning

confidence: 99%

Temperature‐mediated biotic interactions influence enemy release of nonnative species in warming environments

Fey

Herren

2014

Ecology

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"Enemy release" occurs when invading species suffer from interactions with pathogens, parasites, herbivores, or predators to a lesser degree than native species due to a lack of shared evolutionary history. Here we provide strong support for the hypothesis that variable thermal sensitivities between a consumer and its resources can generate temperature-dependent enemy release using both a mathematical model and a field experiment. We identify three common scenarios where changes in temperature should alter enemy release based on asymmetric responses among enemies and their resources to changes in temperature: (1) the vital rates of a shared enemy are more sensitive to changes in temperature than its resources, (2) the enemy's thermal maximum for consumption is higher than the resources' maxima for growth, and (3) the invading resource has a higher thermal maximum for growth than its native competitor. Mathematical representations indicated that warming is capable of altering enemy release in each of these three scenarios. We also tested our hypothesis using a mesocosm warming experiment in a system that exhibits variable thermal sensitivities between a predator and its native and nonnative prey. We conducted a six-week experiment manipulating the presence of Lepomis sunfish (present, absent) and water temperature (ambient, heated) using the nonnative crustacean zooplankter, Daphnia lumholtzi, whose morphological defenses reduce predation from juvenile sunfish relative to native Daphnia pulex. Our results indicate that D. lumholtzi benefited to a greater extent from the presence of Lepomis predators as temperatures increase. Taken together, our model and experiment indicate that changes in environmental temperature may directly influence the success of nonnative species and may assist with forecasting the community consequences of biological invasions in a warming world.

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Thermal sensitivity predicts the establishment success of nonnative species in a mesocosm warming experiment

Cited by 25 publications

References 38 publications

Predicting consequences of climate change for ecosystem functioning: variation across trophic levels, species and individuals

Predicting consequences of climate change for ecosystem functioning: variation across trophic levels, species and individuals

The temperature independence of interaction strength in a sit‐and‐wait predator

Temperature‐mediated biotic interactions influence enemy release of nonnative species in warming environments

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