Prolonged survival out of water is linked to a slow pace of life in a self-fertilizing amphibious fish.

Metabolic rate and life-history traits vary widely both among and within species, reflecting trade-offs in energy allocation, but the proximate and ultimate causes of variation are not well understood. We tested the hypothesis that these trade-offs are mediated by environmental heterogeneity, using isogenic strains of the amphibious fish that vary in the amount of time each can survive out of water. Consistent with pace of life theory, the strain that survived air exposure the longest generally exhibited a 'slow' phenotype, including the lowest metabolic rate, largest scope for metabolic depression, slowest consumption of energy stores and least investment in reproduction under standard conditions. Growth rates were fastest in the otherwise slow strain, however. We then tested for fitness trade-offs between 'fast' and 'slow' strains using microcosms where fish were held either with constant water availability or under fluctuating conditions where water was absent for half of the experiment. Under both conditions the slow strain grew larger and was in better condition, and under fluctuating conditions the slow strain produced more embryos. However, the fast strain had larger adult population sizes under both conditions, indicating that fecundity is not the sole determinant of population size in this species. We conclude that genetically based differences in the pace of life of amphibious fish determine survival duration out of water. Relatively slow fish tended to perform better under conditions of limited water availability, but there was no detectable cost under control conditions. Thus, pace of life differences may reflect a conditionally neutral instead of antagonistic trade-off.