Abstract
Natural selection is inherently a multivariate phenomenon. The selection pressure on size (natural and artificial) and the age at which selection occurs is likely to induce evolutionary changes in growth rates across the entire life history. However, the covariance structure that will determine the path of evolution for size at age has been studied in only a few fish species. We therefore estimated the genetic covariance function for size throughout ontogeny using Atlantic silversides (Menidia menidia) as the model system. Over a 3‐year period, a total of 542 families were used to estimate the genetic covariance in length at age from hatch through maturity. The function‐valued trait approach was employed to estimate the genetic covariance functions. A Bayesian hierarchical model was used to account for the unbalanced design, unequal measurement intervals, unequal sample sizes, and family‐aggregated data. To improve mixing, we developed a two‐stage sampler using a Gibbs sampler to generate the posterior of a well‐mixing approximate model followed by an importance sampler to draw samples from posterior of the completely specified model. We found that heritability of length is age‐specific and there are strong genetic correlations in length across ages that last 30 days or more. We used these estimates in a hypothetical model predicting the evolutionary response to harvesting following a single generation of selection under both sigmoidal and unimodal patterns of gear selectivity to illustrate the potential outcomes of ignoring the genetic correlations. In these scenarios, genetic correlations were found to have a strong effect on both the direction and magnitude of the response to harvest selection.
Highlights
The effects of harvest can lead to important, potentially irrevers‐ ible, evolutionary changes in life‐history characteristics (Haugen & Vøllestad, 2001; Conover & Munch, 2002; Law, 2007; Enberg et al, 2011)
The rate and direction of fishery‐induced evolution will depend on the balance of these opposing forces of selection, the amount of standing genetic variation in the popula‐ tion, and the degree to which size early and late in life are geneti‐ cally correlated
To evaluate the importance of genetic correlations for fisheries‐induced evolution, we evaluated the response to selection under two alternative mod‐ els for the genetic covariance of length at age
Summary
The effects of harvest can lead to important, potentially irrevers‐ ible, evolutionary changes in life‐history characteristics (Haugen & Vøllestad, 2001; Conover & Munch, 2002; Law, 2007; Enberg et al, 2011). The rate and direction of fishery‐induced evolution will depend on the balance of these opposing forces of selection, the amount of standing genetic variation in the popula‐ tion, and the degree to which size early and late in life are geneti‐ cally correlated. These correlations are substantial enough that the response to harvest selection will depend on the balance of selection across multiple ages In this case, scalar estimates of heritability would be insufficient to predict either the rate or direction of evolution. In the presence of strong genetic correlations, or a large number of correlated traits, the indirect effects can outweigh the direct response In this case, predicting evolution from a scalar heritability estimate may underestimate the rate of change or even get the sign wrong. To evaluate the importance of genetic correlations for fisheries‐induced evolution, we evaluated the response to selection under two alternative mod‐ els for the genetic covariance of length at age
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