Consequences of catastrophic disturbances on population persistence and adaptations

TL;DR

This study uses simulations to explore how increased climate variability and extreme weather events impact population survival and adaptation, highlighting the roles of selection, mutation, and environmental stochasticity.

Contribution

It introduces a simple population dynamics model to analyze the effects of climate variability and disturbances on adaptation and extinction risk.

Findings

Higher climate variance increases extinction risk.

Intermediate mutation rates improve adaptation to changing environments.

High mutation rates can reduce survival due to maladaptation.

Abstract

The intensification and increased frequency of weather extremes is emerging as one of the most important aspects of climate change. We use Monte Carlo simulation to understand and predict the consequences of variations in trends (i.e., directional change) and stochasticity (i.e., increase in variance) of climate variables and consequent selection pressure by using simple models of population dynamics. Higher variance of climate variables increases the probability of weather extremes and consequent catastrophic disturbances. Parameters of the model are selection pressure, mutation, directional and stochastic variation of the environment. We follow the population dynamics and the distribution of a trait that describes the adaptation of the individual to the optimum phenotype defined by the environmental conditions. The survival chances of a population depend quite strongly on the selection pressure and decrease with increasing variance of the climate variable. In general, the system is able to track the directional component of the optimum phenotype. Intermediate levels of mutation generally increase the probability of tracking the changing optimum and thus decrease the risk of extinction of a population. With high mutation, the higher probability of maladaptation decreases the survival chances of the populations, even with high variability of the optimum phenotype.