Abstract
There is a critical need to understand patterns and causes of intraspecific variation in physiological performance in order to predict the distribution and dynamics of wild populations under natural and human‐induced environmental change. However, the usual explanation for trait differences, local adaptation, fails to account for the small‐scale phenotypic and genetic divergence observed in fishes and other species with dispersive early life stages. We tested the hypothesis that local‐scale variation in the strength of selective mortality in early life mediates the trait composition in later life stages. Through in situ experiments, we manipulated exposure to predators in the coral reef damselfish Dascyllus aruanus and examined consequences for subsequent growth performance under common garden conditions. Groups of 20 recently settled D. aruanus were outplanted to experimental coral colonies in Moorea lagoon and either exposed to natural predation mortality (52% mortality in three days) or protected from predators with cages for three days. After postsettlement mortality, predator‐exposed groups were shorter than predator‐protected ones, while groups with lower survival were in better condition, suggesting that predators removed the longer, thinner individuals. Growth of both treatment groups was subsequently compared under common conditions. We did not detect consequences of predator exposure for subsequent growth performance: Growth over the following 37 days was not affected by the prior predator treatment or survival. Genotyping at 10 microsatellite loci did indicate, however, that predator exposure significantly influenced the genetic composition of groups. We conclude that postsettlement mortality did not have carryover effects on the subsequent growth performance of cohorts in this instance, despite evidence for directional selection during the initial mortality phase.
Highlights
While physiological traits have long been known to vary among members of the same species, systematic spatial variations in the performance of wild populations have recently become a major re‐ search focus (Gaston et al, 2009)
Local adaptation occurs when barriers to dispersal are sufficient to allow phenotypic differ‐ ences to accumulate through natural selection (Kawecki & Ebert, 2004)
For example, the prevailing view was that spatial diver‐ gence in high fecundity species, such as many marine fishes and in‐ vertebrates, would be homogenized by dispersive early life stages
Summary
While physiological traits have long been known to vary among members of the same species, systematic spatial variations in the performance of wild populations have recently become a major re‐ search focus (Gaston et al, 2009). Larval and juvenile fishes experience strong selection on size (Carr & Hixon, 1995; Holmes & McCormick, 2006; McCormick & Meekan, 2007), nutritional condition (Booth & Beretta, 2004; Hoey & McCormick, 2004), and growth rate (Houde, 1997; Searcy & Sponaugle, 2001; Sogard, 1997; Takasuka, Aoki, & Oozeki, 2007), at the larval–juvenile transition when individuals settle to benthic habitats (Doherty et al, 2004; Hoey & McCormick, 2004; Schmitt & Holbrook, 1999b; Steele & Forrester, 2002) This process of selective mortality is so integral to our understanding of high fecundity species that it forms the basis for theories of pop‐ ulation regulation (Houde, 1989). Our study provides one of the first direct tests of the consequences of early‐life mortal‐ ity for subsequent physiological performance in wild populations of high fecundity species
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