An evolutionary maximum principle for density-dependent population dynamics in a fluctuating environment |
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| Authors: | Russell Lande Steinar Engen Bernt-Erik S?ther |
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| Affiliation: | 1.Division of Biology, Imperial College London, Silwood Park Campus, Ascot, Berkshire SL5 7PY, UK;2.Centre for Conservation Biology, Department of Biology, Norwegian University of Science and Technology, 7491 Trondheim, Norway;3.Centre for Conservation Biology, Department of Mathematical Sciences, Norwegian University of Science and Technology, 7491 Trondheim, Norway |
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| Abstract: | The evolution of population dynamics in a stochastic environment is analysed under a general form of density-dependence with genetic variation in r and K, the intrinsic rate of increase and carrying capacity in the average environment, and in σe2, the environmental variance of population growth rate. The continuous-time model assumes a large population size and a stationary distribution of environments with no autocorrelation. For a given population density, N, and genotype frequency, p, the expected selection gradient is always towards an increased population growth rate, and the expected fitness of a genotype is its Malthusian fitness in the average environment minus the covariance of its growth rate with that of the population. Long-term evolution maximizes the expected value of the density-dependence function, averaged over the stationary distribution of N. In the θ-logistic model, where density dependence of population growth is a function of Nθ, long-term evolution maximizes E[Nθ]=[1−σe2/(2r)]Kθ. While σe2 is always selected to decrease, r and K are always selected to increase, implying a genetic trade-off among them. By contrast, given the other parameters, θ has an intermediate optimum between 1.781 and 2 corresponding to the limits of high or low stochasticity. |
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| Keywords: | density-dependent selection, environmental stochasticity, expected fitness, r and K selection, θ -logistic model, genetic trade-off |
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