TY - JOUR
T1 - Dispersal asymmetries and deleterious mutations influence metapopulation persistence and range dynamics
AU - Henry, Roslyn C.
AU - Coulon, Aurélie
AU - Travis, Justin M.J.
PY - 2015/11/1
Y1 - 2015/11/1
N2 - Asymmetric dispersal within and between populations is more often the norm than the exception. For example, prevailing winds and currents can result in directional dispersal of many passively dispersed species and inter-individual variability in physical condition can generate asymmetric dispersal rates between individuals and populations. Despite this, very little theory incorporates asymmetric dispersal into spatial ecological or genetic models. We therefore present three illustrative scenarios incorporating asymmetric dispersal into spatially and genetically explicit individual based models. In the first, asymmetric dispersal due to environmental forces, such as wind or currents, interacts with the accumulation of mutation load across an environmental gradient, with consequences for range dynamics. In the second, asymmetric dispersal rates arise as individuals disperse according to their physical condition, such that individuals carrying more mutation load disperse less. We demonstrate that this condition-dependent asymmetric dispersal substantially reduces metapopulation persistence. Finally, we turn to the potential implications of condition-dependent dispersal for range expansions. Simulations demonstrate that asymmetric dispersal of individuals according to their load status can substantially slow the rate of range expansion. Taken together, these results highlight that overlooking asymmetric dispersal can result in major biases of our estimates of species persistence and range expansion dynamics.
AB - Asymmetric dispersal within and between populations is more often the norm than the exception. For example, prevailing winds and currents can result in directional dispersal of many passively dispersed species and inter-individual variability in physical condition can generate asymmetric dispersal rates between individuals and populations. Despite this, very little theory incorporates asymmetric dispersal into spatial ecological or genetic models. We therefore present three illustrative scenarios incorporating asymmetric dispersal into spatially and genetically explicit individual based models. In the first, asymmetric dispersal due to environmental forces, such as wind or currents, interacts with the accumulation of mutation load across an environmental gradient, with consequences for range dynamics. In the second, asymmetric dispersal rates arise as individuals disperse according to their physical condition, such that individuals carrying more mutation load disperse less. We demonstrate that this condition-dependent asymmetric dispersal substantially reduces metapopulation persistence. Finally, we turn to the potential implications of condition-dependent dispersal for range expansions. Simulations demonstrate that asymmetric dispersal of individuals according to their load status can substantially slow the rate of range expansion. Taken together, these results highlight that overlooking asymmetric dispersal can result in major biases of our estimates of species persistence and range expansion dynamics.
KW - Dispersal asymmetries
KW - Environmental gradients
KW - Gene flow
KW - Mutation load
UR - http://www.scopus.com/inward/record.url?scp=84946912163&partnerID=8YFLogxK
U2 - 10.1007/s10682-015-9777-4
DO - 10.1007/s10682-015-9777-4
M3 - Article
AN - SCOPUS:84946912163
VL - 29
SP - 833
EP - 850
JO - Evolutionary ecology
JF - Evolutionary ecology
SN - 0269-7653
IS - 6
ER -