Causes and consequences of dispersal in biodiverse spatially structured systems: what is old and what is new?

Dispersal is a well recognized driver of ecological and evolutionary dynamics, and simultaneously an evolving trait. Dispersal evolution has traditionally been studied in single-species metapopulations so that it remains unclear how dispersal evolves in spatially structured communities and food webs. Since most natural systems are biodiverse and spatially structured, and thus affected by dispersal and its evolution, this knowledge gap should be bridged. Here we discuss whether knowledge established in single-species systems holds in spatially structured multispecies systems and highlight generally valid and fundamental principles. Most biotic interactions form the ecological theatre for the evolutionary dispersal play because interactions mediate patterns of fitness expectations in space and time. While this allows for a simple transposition of certain known drivers to a multispecies context, other drivers may require more complex transpositions, or might not be transferred. We discuss an important quantitative modulator of dispersal evolution in the increased trait dimensionality of biodiverse meta-systems and an additional driver in co-dispersal. We speculate that scale and selection pressure mismatches due to co-dispersal, together with increased trait dimensionality may lead to slower and more "diffuse" evolution in biodiverse meta-systems. Open questions and potential consequences in both ecological and evolutionary terms call for more investigation

Evolutionary ecology of dispersal in biodiverse spatially structured systems : what is old and what is new?

Dispersal is a well-recognized driver of ecological and evolutionary dynamics, and simultaneously an evolving trait. Dispersal evolution has traditionally been studied in single-species metapopulations so that it remains unclear how dispersal evolves in metacommunities and metafoodwebs, which are characterized by a multitude of species interactions. Since most natural systems are both species-rich and spatially structured, this knowledge gap should be bridged. Here, we discuss whether knowledge from dispersal evolutionary ecology established in single-species systems holds in metacommunities and metafoodwebs and we highlight generally valid and fundamental principles. Most biotic interactions form the backdrop to the ecological theatre for the evolutionary dispersal play because interactions mediate patterns of fitness expectations across space and time. While this allows for a simple transposition of certain known principles to a multispecies context, other drivers may require more complex transpositions, or might not be transferred. We discuss an important quantitative modulator of dispersal evolution-increased trait dimensionality of biodiverse meta-systems-and an additional driver: co-dispersal. We speculate that scale and selection pressure mismatches owing to co-dispersal, together with increased trait dimensionality, may lead to a slower and more 'diffuse' evolution in biodiverse meta-systems. Open questions and potential consequences in both ecological and evolutionary terms call for more investigation. This article is part of the theme issue 'Diversity-dependence of dispersal: interspecific interactions determine spatial dynamics'

Impact du changement climatique sur un vertébré ectotherme : de l'individu à la communauté

Le changement climatique récent a des conséquences dramatiques pour la biodiversité, à travers des modifications des conditions abiotiques et biotiques. La vulnérabilité d'une espèce au changement climatique peut dépendre de son habitat, de sa position au sein de sa communauté ainsi que de sa physiologie thermique. A cet égard, les espèces ectothermes, dont la température interne dépend directement du milieu extérieur, sont considérées comme particulièrement vulnérables à l'augmentation de température. Nous avons étudié expérimentalement l'impact du réchauffement climatique futur sur une espèce de vertébré ectotherme, le lézard vivipare (Zootoca vivipara). Pour cela nous avons utilisé le Métatron, un système de grands enclos semi-naturels dans lesquels les conditions climatiques peuvent être manipulées. Nous avons étudié l'impact d'un climat futur plus chaud (+2°C) sur la dynamique des populations et leur risque d'extinction, ainsi que sur les capacités d'adaptation des populations par la plasticité phénotypique, la sélection et la dispersion. De plus, nous avons considéré l'impact du changement climatique à l'échelle de la communauté. Nous démontrons que le changement climatique futur a un impact négatif sur les populations de lézard vivipare, avec un risque d'extinction à court terme. Cependant, des moyens d'adaptation existent, à travers des changements de phénologie et de physiologie (mélanisme, préférences thermiques). Enfin, les conséquences du changement climatique ne sont pas limitées à l'impact sur les populations de lézard, mais affectent la communauté toute entière, depuis les communautés de plantes et d'insectes jusqu'aux communautés microbiennes.Recent global change has dramatic impacts on biodiversity, through modifications in abiotic and biotic factors. Species vulnerability to changing climates depend for instance of its habitat, its position within the community and its thermal physiology. In this respect, ectotherm species are considered particularly vulnerable as their body temperature depend directly on their environment. We experimentally studied the impact of future climate change on an ectotherm vertebrate species, the common lizard (Zootoca vivipara). We used the Metatron, a system of semi-natural enclosures in which climatic conditions can be manipulated. We studied the impact of warmer climatic conditions (+2°C) on common lizard's population dynamics and extinction risk, and on population adaptation capacity through plasticity, selection and dispersal. We further investigated the impact of climate change at the community scale. We demonstrated that future climatic conditions pose a threat to common lizard. However, possibilities of adaptation exist through changes in phenology and physiology (preferred temperature and melanism). Finally, we show that changing climatic conditions have an impact on the entire communities, from plants and insects to microbial communities

Impacts of climate change on a vertebrate ectotherm : from individuals to the community

Le changement climatique récent a des conséquences dramatiques pour la biodiversité, à travers des modifications des conditions abiotiques et biotiques. La vulnérabilité d'une espèce au changement climatique peut dépendre de son habitat, de sa position au sein de sa communauté ainsi que de sa physiologie thermique. A cet égard, les espèces ectothermes, dont la température interne dépend directement du milieu extérieur, sont considérées comme particulièrement vulnérables à l'augmentation de température. Nous avons étudié expérimentalement l'impact du réchauffement climatique futur sur une espèce de vertébré ectotherme, le lézard vivipare (Zootoca vivipara). Pour cela nous avons utilisé le Métatron, un système de grands enclos semi-naturels dans lesquels les conditions climatiques peuvent être manipulées. Nous avons étudié l'impact d'un climat futur plus chaud (+2°C) sur la dynamique des populations et leur risque d'extinction, ainsi que sur les capacités d'adaptation des populations par la plasticité phénotypique, la sélection et la dispersion. De plus, nous avons considéré l'impact du changement climatique à l'échelle de la communauté. Nous démontrons que le changement climatique futur a un impact négatif sur les populations de lézard vivipare, avec un risque d'extinction à court terme. Cependant, des moyens d'adaptation existent, à travers des changements de phénologie et de physiologie (mélanisme, préférences thermiques). Enfin, les conséquences du changement climatique ne sont pas limitées à l'impact sur les populations de lézard, mais affectent la communauté toute entière, depuis les communautés de plantes et d'insectes jusqu'aux communautés microbiennes.Recent global change has dramatic impacts on biodiversity, through modifications in abiotic and biotic factors. Species vulnerability to changing climates depend for instance of its habitat, its position within the community and its thermal physiology. In this respect, ectotherm species are considered particularly vulnerable as their body temperature depend directly on their environment. We experimentally studied the impact of future climate change on an ectotherm vertebrate species, the common lizard (Zootoca vivipara). We used the Metatron, a system of semi-natural enclosures in which climatic conditions can be manipulated. We studied the impact of warmer climatic conditions (+2°C) on common lizard's population dynamics and extinction risk, and on population adaptation capacity through plasticity, selection and dispersal. We further investigated the impact of climate change at the community scale. We demonstrated that future climatic conditions pose a threat to common lizard. However, possibilities of adaptation exist through changes in phenology and physiology (preferred temperature and melanism). Finally, we show that changing climatic conditions have an impact on the entire communities, from plants and insects to microbial communities

Species Responses to Climate Change: Integrating Individual-Based Ecology Into Community and Ecosystem Studies

International audienc

Presence of a resident species aids invader evolution

Interactions between phytoplankton species shape their physiological and evolutionary responses. Yet, studies addressing the evolutionary responses of phytoplankton in changing environments often lack an explicit element of biotic interactions. Here, we ask (1) how the presence of a locally adapted phytoplankton species will affect an invading phytoplankton species' evolutionary response to a physiologically challenging environment; (2) whether this response is conserved across environments varying in quality; and (3) which traits are associated with being a successful invader under climate change scenarios. In a conceptual first step to disentangle these broad questions, we experimentally evolved populations of fresh‐ and seawater phytoplankton in a novel salinity (the freshwater green algae Chlamydomonas in salt water, and the marine Ostreococcus in freshwater), either as mono‐cultures (colonizers) or as co‐cultures (invaders: invading a novel salinity occupied by a resident species, for example, Chlamydomonas invading salt water occupied by resident Ostreococcus) for 200 generations. We superimposed a temperature treatment (control (22°C), mild warming (26°C), drastic warming (32°C), and fluctuating (22°C/32°C) warming) as a representative aspect of climate change with the potential to ameliorate or deteriorate existing environmental conditions. Invaders had systematically lower extinction rates and evolved overall higher growth rates, as well as broader salinity and temperature preferences than colonizers. The invading species' evolutionary responses differed from those of colonizers in a replicable way across environments of differing quality. The evolution of small cell size and high reactive oxygen species tolerance may explain the invaders' higher fitness under the scenarios tested here.British Ecological Society http://dx.doi.org/10.13039/501100000409https://doi.org/10.5281/zenodo.688404

Data from: Matching habitat choice promotes species persistence under climate change

Species may survive under contemporary climate change by either shifting their range or adapting locally to the warmer conditions. Theoretical and empirical studies recently underlined that dispersal, the central mechanism behind these responses, may depend on the match between an individuals’ phenotype and local environment. Such matching habitat choice is expected to induce an adaptive gene flow, but it now remains to be studied whether this local process could promote species’ responses to climate change. Here, we investigate this by developing an individual-based model including either random dispersal or temperature-dependent matching habitat choice. We monitored population composition and distribution through space and time under climate change. Relative to random dispersal, matching habitat choice induced an adaptive gene flow that lessened spatial range loss during climate warming by improving populations' viability within the range (i.e. limiting range fragmentation) and by facilitating colonization of new habitats at the cold margin. The model even predicted in some cases range contraction under random dispersal but range expansion under optimal matching habitat choice. These benefits of matching habitat choice for population persistence mostly resulted from adaptive immigration decision and were greater for populations with larger dispersal distance and higher emigration probability. We also found that environmental stochasticity resulted in suboptimal matching habitat choice, decreasing the benefits of this dispersal mode under climate change. However population persistence was still better under suboptimal matching habitat choice than under random dispersal. Our results highlight the urgent need to implement more realistic mechanisms of dispersal such as matching habitat choice into models predicting the impacts of ongoing climate change on biodiversity

Matching habitat choice promotes species persistence under climate change

International audienceSpecies may survive under contemporary climate change by either shifting their range or adapting locally to the warmer conditions. Theoretical and empirical studies recently underlined that dispersal, the central mechanism behind these responses, may depend on the match between an individuals' phenotype and local environment. Such matching habitat choice is expected to induce an adaptive gene flow, but it now remains to be studied whether this local process could promote species' responses to climate change. Here, we investigate this by developing an individual-based model including either random dispersal or temperature-dependent matching habitat choice. We monitored population composition and distribution through space and time under climate change. Relative to random dispersal, matching habitat choice induced an adaptive gene flow that lessened spatial range loss during climate warming by improving populations' viability within the range (i.e. limiting range fragmentation) and by facilitating colonization of new habitats at the cold margin. The model even predicted range contraction under random dispersal but range expansion under optimal matching habitat choice. These benefits of matching habitat choice for population persistence mostly resulted from adaptive immigration decision and were greater for populations with larger dispersal distance and higher emigration probability. We also found that environmental stochasticity resulted in suboptimal matching habitat choice, decreasing the benefits of this dispersal mode under climate change. However population persistence was still better under suboptimal matching habitat choice than under random dispersal. Our results highlight the urgent need to implement more realistic mechanisms of dispersal such as matching habitat choice into models predicting the impacts of ongoing climate change on biodiversity

Data from: Non-consumptive effects of a top-predator decrease the strength of the trophic cascade in a four-level terrestrial food web

The fear of predators can strongly impact food web dynamics and ecosystem functioning through effects on herbivores morphology, physiology or behaviour. While non-consumptive predator effects have been mostly studied in three-level food chains, we lack evidence for the propagation of non-consumptive indirect effects of apex predators in four level food-webs, notably in terrestrial ecosystems. In experimental mesocosms, we manipulated a four-level food chain including top-predator cues (snakes), mesopredators (lizards), herbivores (crickets), and primary producers (plants). The strength of the trophic cascade induced by mesopredators through the consumption of herbivores decreased in the presence of top-predator cues. Specifically, primary production was higher in mesocosms where mesopredators were present relative to mesocosms with herbivores only, and this difference was reduced in presence of top-predator cues, probably through a trait-mediated effect on lizard foraging. Our study demonstrates that non-consumptive effects of predation risk can cascade down to affect both herbivores and plants in a four-level terrestrial food chain and emphasises the need to quantify the importance of such indirect effects in natural communities