Determining Selection across Heterogeneous Landscapes: A Perturbation-Based Method and Its Application to Modeling Evolution in Space

Wickman, Jonas; Diehl, Sebastian; Blasius, Bernd; Klausmeier, Christopher A.; Ryabov, Alexey; Brännström, Åke

doi:10.1086/690908

Cited by 19 publications

(32 citation statements)

References 75 publications

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“…For substitutable resources (

{\overset{κ}{true}}_{normalZ} < 1

), diversity declines abruptly at the diagonal

{\overset{κ}{true}}_{normalZ} = {\overset{κ}{true}}_{normalT}

, where the system undergoes a shift in selection regime. To understand this regime shift, we use ideas from Wickman et al (), who showed that selection in spatially heterogeneous systems described by reaction‐diffusion equations can be divided into sympatric and parapatric selection terms. Sympatric selection is a spatially weighted average of local disrupting or stabilising selection, and parapatric selection is, roughly speaking, a measure of the variance in local directional selection.…”

Section: Resultsmentioning

confidence: 99%

“…Ecologically, low or no movement corresponds to the species sorting scenario of metacommunity theory (Leibold et al ), for which regional coexistence of many resource competitors is possible if the landscape contains a broad range of local resource supply ratios (Tilman ). Wickman et al () showed that this also holds evolutionarily for perfectly substitutable resources and generalist‐favouring trade‐offs. The number of evolutionarily coexisting consumers increases as diffusion rates decrease, and as diffusion rates approach zero, an infinite number of consumers can coexist, which adapt locally to a continuum of spatially varying supply ratios (Wickman et al ).…”

Section: Discussionmentioning

confidence: 99%

“…Wickman et al () showed that this also holds evolutionarily for perfectly substitutable resources and generalist‐favouring trade‐offs. The number of evolutionarily coexisting consumers increases as diffusion rates decrease, and as diffusion rates approach zero, an infinite number of consumers can coexist, which adapt locally to a continuum of spatially varying supply ratios (Wickman et al ).…”

Section: Discussionmentioning

confidence: 99%

“…Conversely, the only study that included different resources types (antagonistic to substitutable to essential, Schreiber & Tobiason 2003) considered, in turn, only linear affinity trade-offs, which are neither specialist nor generalist-favouring. Finally, the few studies considering heterogeneous environments focused, again, on perfectly substitutable resources (Parvinen & Egas 2004;Nurmi & Parvinen 2008;D ebarre & Gandon 2010;Wickman et al 2017). Yet, resource types are rarely perfectly substitutable, and trade-offs are rarely perfectly linear, and their joint effects on trait evolution and coexistence of resource competitors are poorly understood.…”

Section: Introductionmentioning

confidence: 99%

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Evolution of resource specialisation in competitive metacommunities

2019

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Spatial environmental heterogeneity coupled with dispersal can promote ecological persistence of diverse metacommunities. Does this premise hold when metacommunities evolve? Using a two‐resource competition model, we studied the evolution of resource‐uptake specialisation as a function of resource type (substitutable to essential) and shape of the trade‐off between resource uptake affinities (generalist‐ to specialist‐favouring). In spatially homogeneous environments, evolutionarily stable coexistence of consumers is only possible for sufficiently substitutable resources and specialist‐favouring trade‐offs. Remarkably, these same conditions yield comparatively low diversity in heterogeneous environments, because they promote sympatric evolution of two opposite resource specialists that, together, monopolise the two resources everywhere. Consumer diversity is instead maximised for intermediate trade‐offs and clearly substitutable or clearly essential resources, where evolved metacommunities are characterised by contrasting selection regimes. Taken together, our results present new insights into resource‐competition‐mediated evolutionarily stable diversity in homogeneous and heterogeneous environments, which should be applicable to a wide range of systems.

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“…For substitutable resources (

{\overset{κ}{true}}_{normalZ} < 1

), diversity declines abruptly at the diagonal

{\overset{κ}{true}}_{normalZ} = {\overset{κ}{true}}_{normalT}

Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Evolution of resource specialisation in competitive metacommunities

2019

Self Cite

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“…In general, they may be derived from density-and frequency-dependent interactions among phenotypes, in which case the relative advantage of a trait x against a different trait y depends on the context of their interaction. For instance, in [9,13,17,29] the invasion fitness between phenotypes with different dispersal strategies is obtained in the context of reaction-diffusion equations modeling the two competiting species in a bounded spatial domain. Those results concerning pairwise interactions has implications in the mutation-selection framework [12,11,18,19,24], which concerns populations structured by space and trait.…”

mentioning

confidence: 99%

Dirac-concentrations in an integro-pde model from evolutionary game theory

Lam¹

2019

Discrete &Amp; Continuous Dynamical Systems - B

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Nonlocal Lotka-Volterra models have the property that solutions concentrate as Dirac masses in the limit of small diffusion. Motivated by the existence of moving Dirac-concentrations in the time-dependent problem, we study the qualitative properties of steady states in the limit of small diffusion. Under different conditions on the growth rate and interaction kernel as motivated by the framework of adaptive dynamics, we will show that as the diffusion rate tends to zero the steady state concentrates (i) at a single location; (ii) at two locations simultaneously; or (iii) at one of two alternative locations. The third result in particular shows that solutions need not be unique. This marks an important difference of the non-local equation with its local counterpart.

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