Energy allocation strategies of young temperate fish: an eco-genetic modeling approach

Authored by Tomas O Hoeoek, Lori N Ivan

Date Published: 2015

DOI: 10.1139/cjfas-2014-0197

Sponsors: United States National Oceanic and Atmospheric Administration (NOAA)

Platforms: No platforms listed

Model Documentation: ODD Flow charts Mathematical description

Model Code URLs: Model code not found

Abstract

We use an individual-based eco-genetic model to explore the relative selective pressures of size-dependent predation, overwinter mortality, and density-dependent energy acquisition in structuring plastic and adaptive energy allocation during the first year of life of a temperate fish population. While several patterns emerging from a suite of eco-genetic model simulations were consistent with past theoretical models and empirical evaluations of energy allocation by young fishes, results also highlight the utility of eco-genetic models for simultaneous consideration of plastic and adaptive processes. Across simulations, variation in genetic control of energy allocation was limited during very early ontogeny when size-dependent predation pressure was particularly high. While this stabilizing selection on energy allocation diminished later in the growing season, predation, overwinter mortality, and density-dependent processes simultaneously structured energy partitioning later in ontogeny through the interactive influence of plastic and adaptive processes. Specifically, high risk of overwinter mortality and low predation selected for high prioritization of energy storage. We suggest that simulations demonstrate the utility of eco-genetic models for generating null predictions of how selective pressures may structure expression of life history traits, such as early life energy allocation.

Tags

Individual-based model Life-history evolution Lake-michigan Saginaw bay Perch perca-flavescens Age-0 yellow perch Winter mortality Overwinter mortality Bioenergetic models Smallmouth bass