Evolutionary rescue in a consumer-resource system: Adaptation and persistence depend on the affected ecological traits

With evolutionary rescue, a population that is declining due to an environmental change subsequently adapts to its environment, avoiding extinction. Previous work has shown that negative density-dependence reduces the probability of evolutionary rescue. However, these models make several simplifying assumptions, either that selection acts strictly on intrinsic growth rates, r , or carrying capacity, K . Here, we simulate evolutionary rescue in a consumer-resource model, making explicit several ecological traits that may differentially affect r and K , and considering a self-replenishing resource. We demonstrate that the effect of density-dependence on rescue is indeed negative but weak, and declines with an increasing degree of maladaptation. The effect of density-dependence is also shown to be trait-dependent, since an environmental perturbation that reduces fitness may also increase or decrease resource competition. Furthermore, the relationship between Malthusian fitness following an environmental change and rescue probabilities depends strongly on the affected ecological trait, such that measurements of the rate of decline alone immediately following an environmental change are likely insufficient to predict rescue outcomes. Reductions in the conversion efficiency of resources into offspring are shown to be a greater hindrance to rescue than reductions in resource acquisition rates, whereas populations are able to tolerate substantial reductions in survivorship. Lastly, an abrupt environmental change that also impacts an evolving resource always hinders the evolutionary rescue of consumers, with reductions in resource carrying capacity being more harmful than reductions in resource growth rates. This work improves our theoretical understanding of how ecology and evolution interact to affect evolutionary rescue.