Abstract
Burrowing crabs of the genus Uca inhabit tidal mudflats and beaches. They feed actively during low tide and remain in their burrows when the tide is high. The timing of this activity has been shown to persist in the absence of external light and tidal cues, indicating the presence of an internal timing mechanism. Researchers report the persistence of several variations in locomotor activity under laboratory conditions that cannot be explained by a single circatidal clock. Previous studies supported two alternative hypotheses: the presence of either two circalunidian clocks, or a circadian and circatidal clock to regulate these activity rhythms. In this paper, we formulate mathematical models to describe and test these hypotheses. The models suggested by the literature contain some important differences beyond the frequency of proposed clocks, and these are reflected in the mathematical formulations and simulation results. One hypothesis suggests independent phase oscillators, while the other hypothesis suggests that they are coupled in anti-phase. Neither model is able to recover all of the variations in locomotor acitivity observed under laboratory conditions. However, we propose a new model that incorporates aspects of both existing hypotheses and is able to reproduce all laboratory observations. (Author correspondence: [email protected])
ACKNOWLEDGMENTS
This work was supported by NSF DBI-9602226, Research Training Grant-Nonlinear Dynamics in Biology, awarded to the University of California, Davis. Diana Verzi was additionally supported by SDSU University Grant Program, spring 2009. The authors gratefully acknowledge Alex Mogilner, Carole Hom, and members of the Institute for Theoretical Dynamics at University of California, Davis, and three anonymous reviewers for helpful comments and discussions.