Evolution to alternative levels of stable diversity leaves areas of niche space unexplored

Rubin, Ilan N.; Ispolatov, Iaroslav; Doebeli, Michael

doi:10.1371/journal.pcbi.1008650

Cited by 8 publications

(12 citation statements)

References 55 publications

(86 reference statements)

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“…These two communities can be viewed as alternative stable states where the former is not reachable through gradual evolution starting with a single ancestral species. That gradual evolution in two‐dimensional trait spaces need not lead to globally stable communities has also been reported by Rubin et al (2021). In their Lotka‐Volterra competition model the competition coefficient and carrying capacity are functions of a two‐dimensional trait vector.…”

Section: Discussionsupporting

confidence: 75%

Complex life cycles drive community assembly through immigration and adaptive diversification

2023

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Most animals undergo ontogenetic niche shifts during their life. Yet, standard ecological theory builds on models that ignore this complexity. Here, we study how complex life cycles, where juvenile and adult individuals each feed on different sets of resources, affect community richness. Two different modes of community assembly are considered: gradual adaptive evolution and immigration of new species with randomly selected phenotypes. We find that under gradual evolution complex life cycles can lead to both higher and lower species richness when compared to a model of species with simple life cycles that lack an ontogenetic niche shift. Thus, complex life cycles do not per se increase the scope for gradual adaptive diversification. However, complex life cycles can lead to significantly higher species richness when communities are assembled trough immigration, as immigrants can occupy isolated peaks of the dynamic fitness landscape that are not accessible via gradual evolution.

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Section: Discussionsupporting

confidence: 75%

Complex life cycles drive community assembly through immigration and adaptive diversification

2023

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“…While we will not fully comment on higher dimensional landscapes, the general results we focus on here largely stem from the relative curvature of the carrying capacity and competition functions and are thus likely replicated in higher dimensions. However, multi-dimensional evolutionary dynamics are notoriously complex and can result in cyclic and chaotic dynamics (Doebeli and Ispolatov, 2014, 2017; Rubin et al, 2021). How these complex evolutionary dynamics interact with rugged carrying capacity landscapes remains unexplored and could prove insightful to both the peak-shift and adaptive dynamics theories.…”

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

“…), all communities have a globally stable equilibrium and are therefore indifferent to initial population sizes (Hernández-García et al, 2009; Rubin et al, 2022). Likewise, as we only consider 1-dimensional phenotypes and symmetric competition, evolutionary dynamics always result in a stationary equilibrium (for discussions of non-stationary evolutionary dynamics see Doebeli and Ispolatov, 2014, 2017; Rubin et al, 2021).…”

Section: Modelmentioning

confidence: 99%

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Adaptive diversification and niche packing on rugged fitness landscapes

Rubin

Ispolatov

Doebeli

2022

Preprint

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Explaining the emergence of diversity and the coexistence of competing types has long been one of the main goals of ecological theory. Rugged fitness landscape have often been used to explain diversity through the presence of local peaks, or adaptive zones, in the fitness landscape acting as available niches for different species. Alternatively, niche-packing and theories based on limiting similarity describe frequency-dependent selection leading to the organic differentiation of a continuous phenotype space into multiple coexisting types. By combing rugged carrying capacity landscapes with frequency-dependent selection, here we investigate the effects of ruggedness on adaptive diversification and stably maintained diversity. We show that while increased ruggedness often leads to a decreased opportunity for adaptive diversification, it is the shape of the global carrying capacity function, not the local ruggedness, that determines the diversity of the ESS and the total diversity a system can stably maintain.

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“…As nicely summarised by Edwards et al (2018), communities not at an ESS will experience selective pressure towards the ESS (however, see Doebeli & Ispolatov, 2014;Doebeli et al, 2017;Rubin et al, 2021, for discussions of non-equilibrium evolutionary dynamics). On evolutionary timescales, super-saturated communities (those with a larger diversity than the ESS) will often experience the extinction of certain species and collapse to the ESS (e.g.…”

Section: Us Sionmentioning

confidence: 99%

Maximal ecological diversity exceeds evolutionary diversity in model ecosystems

2023

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Understanding community saturation is fundamental to ecological theory. While investigations of the diversity of evolutionary stable states (ESSs) are widespread, the diversity of communities that have yet to reach an evolutionary endpoint is poorly understood. We use Lotka-Volterra dynamics and trait-based competition to compare the diversity of randomly assembled communities to the diversity of the ESS. We show that, with a large enough founding diversity (whether assembled at once or through sequential invasions), the number of long-time surviving species exceeds that of the ESS. However, the excessive founding diversity required to assemble a saturated community increases rapidly with the dimension of phenotype space. Additionally, traits present in communities resulting from random assembly are more clustered in phenotype space compared to random, although still markedly less ordered than the ESS. By combining theories of random assembly and ESSs we bring a new viewpoint to both the saturation and random assembly literature.

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Evolution to alternative levels of stable diversity leaves areas of niche space unexplored

Cited by 8 publications

References 55 publications

Complex life cycles drive community assembly through immigration and adaptive diversification

Complex life cycles drive community assembly through immigration and adaptive diversification

Adaptive diversification and niche packing on rugged fitness landscapes

Maximal ecological diversity exceeds evolutionary diversity in model ecosystems

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