Heterozygosity and asymmetry: Ectodysplasin as a form of genetic stress in marine threespine stickleback.

Abstract

Genome-wide heterozygosity has long been hypothesized to play a role in buffering organisms against developmental perturbations, potentially resulting in increased symmetry. If true, this could in part explain the maintenance of standing genetic variation in wild populations. Marine threespine sticklebacks (Gasterosteus aculeatus) were sampled across their eastern Pacific coastal distribution from Alaska to California and variations in asymmetry for both structural and nonstructural armor traits (lateral plates) were assessed. Structural plates consistently showed less asymmetry than nonstructural plates, but standardized measures of heterozygosity were not correlated with the extent of asymmetry expressed by a fish. Fish that were heterozygous for the major-effect gene controlling lateral plate variation (Ectodysplasin) had higher occurrences of asymmetry, even when the individuals were phenotypically fully plated. Collectively, this suggests that heterozygosity at a major-effect locus can have a greater impact on asymmetry than heterozygosity sampled across the genome.