Experimental evidence for the adaptive evolution of growth rate in the garter snake Thamnophis elegans

Abstract

The western terrestrial garter snake (Thamnophis elegans) varies significantly in individual growth rates and life-history traits (maturation, reproduction, and survival) among adjacent populations in nature. This study focuses on assessing the genetic and environmental components of the substantial among-population variation in growth rates. Litters of neonates from nine populations inhabiting either mountain meadow or lakeshore habitat were reared for one year in a common-garden experiment with two temperature treatments. Diet, frequency of feeding, light exposure, and daytime temperatures were identical for all individuals. The two different nighttime temperatures (20°C and 25°C) were chosen to mirror field differences in nighttime thermoregulatory constraints for mountain-meadow and lakeshore snakes, respectively. Temperature and source habitat interacted to affect first-year growth rate. Neonates from meadow dams grew fastest in the cooler treatment, whereas those from lakeshore dams grew fastest in the warmer treatment. The observation that naive neonates, which were gestated and raised under identical conditions, grew fastest in environments characteristic of their natal population is evidence both that there are genetic differences among populations for growth and that these differences reflect adaptation to local habitats at a very small geographic scale. In addition, significant directional selection for large birthweight was measured for neonates from all populations. These results are considered in the context of population colonization history, migration and selection, and competing models for growth rate variation.