Desiccation resistance in megalopae of the terrestrial hermit crab Coenobita compressus: water loss and the role of the shell

Abstract. The terrestrial hermit crab Coenobita compressus H. M ilne E dwards undergoes larval development in the sea and then moves to land as a megalopa, where it metamorphoses and remains for the rest of its life. As a small organism (generally <3 mg), in a body adapted for pelagic life, the megalopa must avoid desiccating in air to make a successful sea-to-land transition. In this study, I measured rates of water loss in 1 to 26-day-old megalopae without mollusk shells to determine if there is an improvement in desiccation resistance with age. I also exposed 26-day-old megalopae with or without shells to different relative-humidity conditions for 1 h to determine if shells worn by megalopae allow them to function in air that is not fully saturated. Megalopae without shells did not survive exposure to a relative humidity (RH) of less than 99%, while those with shells survived 52% RH. Older megalopae lost water more slowly than younger ones. However, the amount of body water explained more of the variation in water-loss rate than age; individuals with smaller body-water masses showed lower rates of absolute water loss. Though megalopae of C. compressus become less water permeable as they approach metamorphosis on land, most of their ability to avoid desiccation comes from the shell. Shell-wearing can be considered a pre-adaptation to a terrestrial life-style because shell-wearing behavior predates land invasion in hermit crabs, and desiccation-proofing in air is a novel function for shells.