Dispersal evolution in temporally variable environments: implications for plant range dynamics

Oldfather, Meagan F.; Elzen, Courtney L. Van Den; Heffernan, Patrick M.; Emery, Nancy C.

doi:10.1002/ajb2.1739

Cited by 9 publications

(12 citation statements)

References 97 publications

(154 reference statements)

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“…While such a counterselection of dispersal was originally highlighted in theoretical models (Hastings, 1983; Travis and Dytham, 1999), empirical evidence for such effects has accumulated in recent years, for a large variety of species, from the weed Crepis sancta (Cheptou et al ., 2008), to the butterfly Proclossiana eunomia (Schtickzelle et al ., 2006) and the wolf spider Pardosa monticola (Bonte et al ., 2006). Fragmentation however also increases inbreeding, kin competition or temporal variation of the environment and all of these components usually select for higher dispersal abilities (Hamilton and May, 1977; Charlesworth and Charlesworth, 1987; Matthysen et al ., 1995; Gandon, 1999; Duputié and Massol, 2013; Cote et al ., 2017; Tung et al ., 2018; Oldfather et al ., 2021). In addition to the modulation of overall dispersal levels, fragmentation can also, under certain conditions, maintain contrasted dispersal strategies simultaneously.…”

Section: Introductionmentioning

confidence: 99%

Evolution of dispersal and the maintenance of fragmented metapopulations

Finand

Monnin

Loeuille

2022

Preprint

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Because it affects dispersal risk and modifies competition levels, habitat fragmentation directly constrains dispersal evolution. When dispersal is traded-off against competitive ability, increased fragmentation is often expected to select higher dispersal. Such evolutionary effects could favor the maintenance of the metapopulation by fostering spatial rescue effects. Using an evolutionary model, we first investigate how dispersal evolves in a metapopulation when fragmentation and aggregation of this fragmentation are fixed. Our results suggest that high fragmentation indeed selects for dispersal increase, but this effect is largely reduced in aggregated landscapes, to the point of being nonexistent at the highest aggregation levels. Contrasted dispersal strategies coexist at high fragmentation levels and with no or low aggregation. We then simulate time-varying fragmentation scenarios to investigate the conditions under which evolutionary rescue of the metapopulation happens. Faster evolution of dispersal favors the persistence of the metapopulation, but this effect is very reduced in aggregated landscapes. Overall, our results highlight how the speed of evolution of dispersal and the structuration of the fragmentation will largely constrain metapopulation survival in changing environments.

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Section: Introductionmentioning

confidence: 99%

Evolution of dispersal and the maintenance of fragmented metapopulations

Finand

Monnin

Loeuille

2022

Preprint

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“…Colonization is so essential that programs in assisted migration are an attempt to overcome its limitations and facilitate plant species’ climate-driven range shifts [ 120 , 121 ]. Colonization also influences ecological and evolutionary dynamics within and between plant populations, and hence source–sink dynamics [ 51 , 65 , 122 ]. Aside from vicariance (i.e., fragmentation of a continuous distribution caused by dispersal barriers), rare very long-distance dispersal events [ 27 , 123 , 124 , 125 , 126 ], the spatial extent of seed rain and number of seeds dispersed far distances (the “fat tail” of the seed dispersal curve) are known to affect the rate of plant geographic range shifts and the ability to colonize new areas and habitats [ 14 , 57 , 127 , 128 ].…”

Section: Colonization Abilitymentioning

confidence: 99%

“…Aside from vicariance (i.e., fragmentation of a continuous distribution caused by dispersal barriers), rare very long-distance dispersal events [ 27 , 123 , 124 , 125 , 126 ], the spatial extent of seed rain and number of seeds dispersed far distances (the “fat tail” of the seed dispersal curve) are known to affect the rate of plant geographic range shifts and the ability to colonize new areas and habitats [ 14 , 57 , 127 , 128 ]. Plant traits influencing colonization ability also evolve in spatially and temporally variable environments, which can facilitate range shifts during climate change [ 122 ].…”

Section: Colonization Abilitymentioning

confidence: 99%

Plant Species’ Capacity for Range Shifts at the Habitat and Geographic Scales: A Trade-Off-Based Framework

McNichol

Russo

2023

Plants

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Climate change is causing rapid shifts in the abiotic and biotic environmental conditions experienced by plant populations, but we lack generalizable frameworks for predicting the consequences for species. These changes may cause individuals to become poorly matched to their environments, potentially inducing shifts in the distributions of populations and altering species’ habitat and geographic ranges. We present a trade-off-based framework for understanding and predicting whether plant species may undergo range shifts, based on ecological strategies defined by functional trait variation. We define a species’ capacity for undergoing range shifts as the product of its colonization ability and the ability to express a phenotype well-suited to the environment across life stages (phenotype–environment matching), which are both strongly influenced by a species’ ecological strategy and unavoidable trade-offs in function. While numerous strategies may be successful in an environment, severe phenotype–environment mismatches result in habitat filtering: propagules reach a site but cannot establish there. Operating within individuals and populations, these processes will affect species’ habitat ranges at small scales, and aggregated across populations, will determine whether species track climatic changes and undergo geographic range shifts. This trade-off-based framework can provide a conceptual basis for species distribution models that are generalizable across plant species, aiding in the prediction of shifts in plant species’ ranges in response to climate change.

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“…Dispersal barriers may more likely be breached when source populations experience variability in local conditions favouring higher local dispersal. Oldfather et al [ 68 ] found empirical evidence that plants have greater dispersal at range margins when there is more temporal variability in plant demography. Sometimes, however, temporal variation favours lower dispersal [ 69 ].…”

Section: Implications Of Temporal Variation For Range Limits: Evoluti...mentioning

confidence: 99%

Temporal variation may have diverse impacts on range limits

Holt

Barfield

Peniston

2022

Phil. Trans. R. Soc. B

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Environmental fluctuations are pervasive in nature, but the influence of non-directional temporal variation on range limits has received scant attention. We synthesize insights from the literature and use simple models to make conceptual points about the potentially wide range of ecological and evolutionary effects of temporal variation on range limits. Because organisms respond nonlinearly to environmental conditions, temporal variation can directionally alter long-term growth rates, either to shrink or to expand ranges. We illustrate this diversity of outcomes with a model of competition along a mortality gradient. Temporal variation can permit transitions between alternative states, potentially facilitating range expansion. We show this for variation in dispersal, using simple source–sink population models (with strong Allee effects, or with gene flow hampering local adaptation). Temporal variation enhances extinction risk owing to demographic stochasticity, rare events, and loss of genetic variation, all tending to shrink ranges. However, specific adaptations to exploit variation (including dispersal) may permit larger ranges than in similar but constant environments. Grappling with temporal variation is essential both to understand eco-evolutionary dynamics at range limits and to guide conservation and management strategies. This article is part of the theme issue ‘Species’ ranges in the face of changing environments (Part II)’.

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Dispersal evolution in temporally variable environments: implications for plant range dynamics

Cited by 9 publications

References 97 publications

Evolution of dispersal and the maintenance of fragmented metapopulations

Evolution of dispersal and the maintenance of fragmented metapopulations

Plant Species’ Capacity for Range Shifts at the Habitat and Geographic Scales: A Trade-Off-Based Framework

Temporal variation may have diverse impacts on range limits

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