Life‐history evolution in response to changes in metapopulation structure in an arthropod herbivore

Roissart, Annelies De; Wybouw, Nicky; Renault, David; Leeuwen, Thomas Van; Bonte, Dries

doi:10.1111/1365-2435.12612

Cited by 21 publications

(28 citation statements)

References 57 publications

(103 reference statements)

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“…We build on earlier experimental work demonstrating a profound impact of metapopulation structure on both local and metapopulation-level demography, life-history evolution and gene expression in the spider mite Tetranychus urticae [18,39]. In short, we found divergent multivariate trait evolution in metapopulations with either stable patches of variable size (mainland-island metapopulations) or with patch size varying in space and time (classical metapopulation) relative to metapopulations with equal and temporally stable patch sizes (patchy metapopulation).…”

Section: Introductionmentioning

confidence: 57%

“…The model is individual-based and simulates mite development and population dynamics as in the experiments [18,39] on a daily basis for 1200 days, after an initialization phase of 100 time steps. In the experimental evolution [18,39], mites from one genetically variable source population were either placed in a metapopulation consisting of nine equally sized patches (patchy metapopulation), nine patches with the same amount of resources randomly assigned to each patch every week until the metapopulation carrying capacity was reached (classical metapopulation), or six patches of which three were of double size (mainland-island metapopulation).…”

Section: Methodsmentioning

confidence: 99%

“…In the experimental evolution [18,39], mites from one genetically variable source population were either placed in a metapopulation consisting of nine equally sized patches (patchy metapopulation), nine patches with the same amount of resources randomly assigned to each patch every week until the metapopulation carrying capacity was reached (classical metapopulation), or six patches of which three were of double size (mainland-island metapopulation). Patches consist of leaves of 20 cm², or 40 cm² for the large patches in the mainland-island metapopulations.…”

Section: Methodsmentioning

confidence: 99%

“…The metapopulation-level carrying capacity as defined by the total availability of leaf surface over subsequent generations was thus identical among treatments. The evolved traits, as determined at the end of the experimental evolution (see [18] and schematic overview in Table 1) were used to parameterize the model. Individuals carry alleles that determine survival rate during development, age at maturity, longevity, probability of being female (sex ratio) .…”

Section: Cc-by-nc-nd 40 International License Not Peer-reviewed) Is mentioning

confidence: 99%

“…While dispersal is a central trait in life history [5], other traits have been documented to evolve in parallel, and often in unpredictable ways [15,16]. Few empirical studies tested theoretical predictions beyond dispersal evolution, but recent work provides evidence of multivariate life-history evolution in metapopulations [17,18]. These studies suggest that fitness can be maximized through the optimization of different trait combinations.…”

Section: Introductionmentioning

confidence: 99%

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The importance and adaptive value of life history evolution for metapopulation dynamics

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Bafort

2017

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Abstract:The performance of populations is affected by environmental change and the resulting evolutionary dynamics. The spatial configuration and size of patches is known to directly influence metapopulation dynamics (spatial forcing). These metapopulation dynamics are also affecting and affected by life history evolution. Given the relevance of metapopulation persistence for biological conservation, and the potential rescuing role of evolution, a firm understanding of the relevance of these eco-evolutionary processes is essential.We here follow a system's modelling approach to disentangle the role of metapopulation structure relative to evolution for metapopulation performance. We developed an individual based systems model that is strongly based and parameterized by results from experimental metapopulations with spider mites. This model enables us to perform virtual translocation and invasion experiments that would have been impossible to conduct in our experimental systems.We show that (1) metapopulation demography is more affected by spatial forcing than by observed life history evolution, but that life history evolution contributes up to 20% of the variation in demographic measures related to spatiotemporal variance in population sizes, (2) metapopulation performance is not enhanced by evolution, and (3) evolution is optimising individual performance in metapopulations when considering the importance of so far overlooked stress resistance evolution.We thus provide evidence that metapopulation-level selection maximises individual performance and more importantly, that -at least in our system-evolutionary changes impact metapopulation dynamics, especially factors related to local and metapopulation sizes.

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Section: Introductionmentioning

confidence: 57%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Cc-by-nc-nd 40 International License Not Peer-reviewed) Is mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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The importance and adaptive value of life history evolution for metapopulation dynamics

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2017

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Metapopulation Ecology

Nouhuys

2016

Encyclopedia of Life Sciences

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A metapopulation is a spatially structured population that persists over time as a set of local populations with limited dispersal between them. At equilibrium, the frequencies of local extinctions and colonisations are in balance. Starting in 1969, and accelerating in the early 1990s, mathematical models of metapopulations have shown the importance of landscape connectivity and dispersal for persistence of a species in fragmented landscapes. Metapopulation ecology is a key concept in conservation ecology. Although pure metapopulations may be rare, there are many empirical studies in which metapopulation processes, primarily local colonisation and extinction, have been useful in explaining dynamics of natural, managed and experimental systems. Metapopulation structure also affects population genetics, the rate of evolution, and the evolution of traits related to habitat use. Finally, just as a population can be structured as a metapopulation, communities inhabiting a heterogeneous landscape can form a metacommunity. Key Concepts A metapopulation is made up of semi‐independent local populations, with interplay between local and regional population dynamics. While few species may live as metapopulations in the strict sense, many species depend on metapopulation processes. That is, a species regional persistence depends on asynchronous local dynamics and dispersal. Models of the persistence of species in fragmented landscapes become more realistic if the metapopulation dynamics of the species is taken into account. Closely interacting species, such as a predator and its prey or strong competitors, may persist on a landscape scale owing to metapopulation dynamics of the species involved. Metapopulation structure imposes genetic structure on a population, influencing its genetic viability, rate of evolution and what traits evolve. Communities of species that are distributed in a landscape form a metacommunity. This concept shares important characteristics with metapopulations.

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Landscape genetics reveals unique and shared effects of urbanization for two sympatric pool‐breeding amphibians

Homola

Loftin

Kinnison

2019

Ecology and Evolution

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Metapopulation‐structured species can be negatively affected when landscape fragmentation impairs connectivity. We investigated the effects of urbanization on genetic diversity and gene flow for two sympatric amphibian species, spotted salamanders (Ambystoma maculatum) and wood frogs (Lithobates sylvaticus), across a large (>35,000 km2) landscape in Maine, USA, containing numerous natural and anthropogenic gradients. Isolation‐by‐distance (IBD) patterns differed between the species. Spotted salamanders showed a linear and relatively high variance relationship between genetic and geographic distances (r = .057, p < .001), whereas wood frogs exhibited a strongly nonlinear and lower variance relationship (r = 0.429, p < .001). Scale dependence analysis of IBD found gene flow has its most predictable influence (strongest IBD correlations) at distances up to 9 km for spotted salamanders and up to 6 km for wood frogs. Estimated effective migration surfaces revealed contrasting patterns of high and low genetic diversity and gene flow between the two species. Population isolation, quantified as the mean IBD residuals for each population, was associated with local urbanization and less genetic diversity in both species. The influence of geographic proximity and urbanization on population connectivity was further supported by distance‐based redundancy analysis and multiple matrix regression with randomization. Resistance surface modeling found interpopulation connectivity to be influenced by developed land cover, light roads, interstates, and topography for both species, plus secondary roads and rivers for wood frogs. Our results highlight the influence of anthropogenic landscape features within the context of natural features and broad spatial genetic patterns, in turn supporting the premise that while urbanization significantly restricts interpopulation connectivity for wood frogs and spotted salamanders, specific landscape elements have unique effects on these two sympatric species.

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Life‐history evolution in response to changes in metapopulation structure in an arthropod herbivore

Cited by 21 publications

References 57 publications

The importance and adaptive value of life history evolution for metapopulation dynamics

The importance and adaptive value of life history evolution for metapopulation dynamics

Metapopulation Ecology

Landscape genetics reveals unique and shared effects of urbanization for two sympatric pool‐breeding amphibians

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