JSTOR is a not-for-profit service that helps scholars, researchers, and students discover, use, and build upon a wide range of content in a trusted digital archive. We use information technology and tools to increase productivity and facilitate new forms of scholarship. For more information about JSTOR, please contact support@jstor.org.. Ecological Society of America is collaborating with JSTOR to digitize, preserve and extend access to Ecology.Abstract. Most amphibian species with an aquatic larval stage use one of two types of breeding habitats: ephemeral or permanent water bodies. A common assumption is that, once a minimum developmental threshold has passed, tadpoles of species that use temporary ponds can respond adaptively to a drying larval habitat by hastening development to metamorphose before the pond dries. We investigated how different pond drying regimes affected the timing of metamorphosis and body size at metamorphosis of two closely related species of hylid treefrogs, one of which commonly breeds in temporary ponds (Hyla gratiosa) and the other in permanent ponds (Hyla cinerea). We experimentally manipulated the water level in cattle-tank communities, exposing tadpoles of each species to a slow drying treatment, a fast drying treatment, and a constant water level treatment. There was no direct effect of pond drying on the larval period or body size at metamorphosis of either species. The drying treatments indirectly affected these traits by increasing larval densities, which extended the larval period and produced smaller sizes at metamorphosis. The timing of metamorphosis and body size at metamorphosis of H. gratiosa were more plastic than the corresponding traits in H. cinerea, but this greater plasticity cannot be interpreted as adaptive. Our results emphasize the utility of the comparative approach in interpreting the potential adaptive responses of species to environmental variation.The distinctive distributions of different species of larval amphibians among ponds of different duration (due to the species-specific breeding habitat choice of their parents) represent an excellent system in which to examine the relationship between habitat variability and adaptive phenotypic plasticity. Ponds with characteristically different hydroperiods create different selective pressures on two larval life-history traits, the larval period and the size at metamorphosis. Both traits are under active, demonstrable selection, but the direction of their relationship with fitness changes with pond duration. In favorable conditions (low predation risk, no risk of desiccation) longer larval periods result in larger body size at metamorphosis; larger size enhances male mating success, increases the probability of overwinter survival, decreases the time to first reproduction, and increases female fecundity (Howard 1978, Berven 1981, 1982, Berven and Gill 1983, Pough and Kamel 1984, Smith 1987). In less favorable conditions (high predation risk, habitat drying), shortened larval periods will minimize the cumulative r...
