Abstract
Rapid environmental change is driving global biodiversity declines, challenging species to persist through genetic adaptation and phenotypic plasticity. These responses can also feed back onto ecosystems ecology, a process called eco-evolutionary feedbacks, potentially reshaping both selective environments and ecosystem properties. However, how phenotypic divergence and potential eco-evolutionary feedbacks depend on the environmental context is rarely assessed in ecologically realistic settings. Here, we used an outdoor mesocosm experiment to investigate context-dependent phenotypic divergence and ecological feedbacks in amphibian tadpoles, which are key players in their native ecosystems, and show strong potential for local adaptation and phenotypic plasticity. Specifically, we assessed the extent of i) phenotypic divergence and ii) differential effects on ecosystem properties between two divergent populations of the moor frog (Rana arvalis) in ecologically contrasting conditions. To this end, we conducted a full factorial experiment rearing tadpoles from two contrasting pH populations (acidic versus neutral origin) in two contrasting pH environments (pH 4.3 versus 8.4). To assess the effects of tadpole presence per se, and the relative effects of within species phenotypic divergence on key ecosystem properties, we complemented the design with no-tadpole control mesocosms. In terms of parallel responses to the contrasting environments, both population origins showed substantial phenotypic plasticity. Tadpoles had higher corticosterone levels, developed faster and to a larger metamorphic size in the pH 4.3 than the pH 8.4 treatment. Diet also differed between pH treatments. Regarding phenotypic divergence, acid-origin tadpoles had higher survival in the pH 4.3 treatment and reached a larger metamorphic size than neutral-origin tadpoles (in both treatments). We also found genotype-by-environment interactions in dietary morphology: acid-origin tadpoles had relatively longer guts than neutral-origin tadpoles in the pH 8.4 treatment, suggesting potential for divergence in diet-mediated ecological effects. Finally, several key findings emerged from the ecological effects of tadpoles. Tadpole presence per se (relative to no-tadpole controls) influenced several ecosystem parameters (i.e. light penetration, phyto- and zooplankton abundance). While no population-origin effects were observed in the pH 4.3 treatment, the two populations had different effects on periphyton and phytoplankton abundance and vegetation biomass in the pH 8.4 treatment. These findings highlight the potential for within-species divergence in amphibians to alter ecosystem properties and call for further investigation into the context dependency of eco-evolutionary dynamics in face of the ongoing environmental changes.
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In the face of rapid environmental change, persistence of natural populations often relies on evolutionary rescue. Such rapid evolution can, in turn, affect ecosystem properties (i.e. cause evo-to-eco effects), as recently documented across taxa and ecosystems. Amphibians often act as keystone species, making them ideal candidates for studying eco-evolutionary dynamics, yet empirical studies remain rare. We aimed to bridge this gap in the moor frog (Rana arvalis), known for adaptive phenotypic plasticity and local adaptation to environmental acidification. To investigate context-dependent phenotypic divergence and potential for ecosystem feedbacks we performed an outdoor mesocosm experiment on R. arvalis tadpoles. We used a full-factorial design, rearing tadpoles from two different population origins (pH 4 vs 7) in two contrasting environments (pH 4.3 vs 8.4). Additionally, we included no-tadpole mesocosms in each pH environment to assess population origin effects relative to a no-tadpole baseline. We found that tadpoles exhibited substantial phenotypic plasticity in physiological and life-history traits (higher corticosterone levels, faster development, larger metamorphic size, and different diets in the pH 4.3 as compared to pH 8.4 environments) and environment dependent divergence between populations: acid-origin tadpoles had higher survival in the pH 4.3 environment, larger metamorphic size in both pH environments, and relatively longer guts in the pH 8.4 environment than neutral-origin tadpoles. Additionally, tadpole presence reduced light penetration in pH 4.3, and decreased zooplankton density while increasing phytoplankton density in pH 8.4. Finally, in the pH 4.3 environment, acid-origin tadpoles reduced phytoplankton (relative to neutral origin tadpoles), whereas in the pH 8.4 environment neutral origin tadpoles reduced periphyton while acid origin tadpoles reduced vegetation biomass (relative to the no-tadpole baseline). These results demonstrate marked phenotypic plasticity and divergence in R. arvalis tadpoles under ecologically relevant conditions, the central ecological role of tadpoles in ecosystems, and the potential for their evolutionary divergence of tadpoles to alter ecosystem function. These results indicate that plastic and/or evolved trait divergence of tadpoles can reshape eco-evolutionary dynamics in freshwater ecosystems. In light of global amphibian declines, understanding such context-dependent eco-evolutionary dynamics is vital for predicting ecosystem responses and informing conservation strategies.
https://doi.org/10.32942/X2JM15
Life Sciences
adaptive divergence, amphibia, dietary morphology, eco-evolutionary dynamics, evo-to-eco effects, environmental stress, pH, resource limitation, tadpoles, top-down control
Published: 2025-09-10 07:23
Last Updated: 2026-02-06 09:42
CC BY Attribution 4.0 International
Data and Code Availability Statement:
Data and code used to analyse the data and produce the figures will be uploaded in a repository and made available to reviewers at the submission of this manuscript to a peer reviewed journal. The access to data and code will be made public immediately upon publication.
Language:
English
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