Comparative studies of tidal rhythms. VI. Several clocks govern the activity of two species of fiddler crabs

The tide‐associated persistent activity rhythms of the ocypod crabs, Uca pugnax and U. pugilator were observed in constant conditions, some for as long as three months. In some animals the twice/day peaks of activity were found to scan the day at significantly different rates from one another. Individual peaks in some animals split into two fragments. And at times, one peak would fade and then return, or vanish completely. These examples of the independence between tide‐related activity peaks have become the basis for a hypothesis that each peak is controlled by its own clock(s). The basic period of these clocks is “circalunidian”, with periods varying up to about 4–8% on either side of 24.8 hours.     

The visual ecology of fiddler crabs

With their eyes on long vertical stalks, their panoramic visual field and their pronounced equatorial acute zone for vertical resolving power, the visual system of fiddler crabs is exquisitely tuned to the geometry of vision in the flat world of inter-tidal mudflats. The crabs live as burrow-centred grazers in dense, mixed-sex, mixed-age and mixed-species colonies, with the active space of an individual rarely exceeding 1 m². The full behavioural repertoire of fiddler crabs can thus be monitored over extended periods of time on a moment to moment basis together with the visual information they have available to guide their actions. These attributes make the crabs superb subjects for analysing visual tasks and the design of visual processing mechanisms under natural conditions, a prerequisite for understanding the evolution of visual systems. In this review we show, on the one hand, how deeply embedded fiddler crab vision is in the behavioural and the physical ecology of these animals and, on the other hand, how their behavioural options are constrained by their perceptual limitations. Studying vision in fiddler crabs reminds us that vision has a topography, that it is context-dependent and pragmatic and that there are perceptual limits to what animals can know and therefore care about. For Mike Land     

The visual control of behaviour in fiddler crabs

Male fiddler crabs (Uca pugilator Bosc) have visual control systems that enable them to track other crabs in front or behind, and to keep potential predators to the side, where escape is easiest. The system for tracking conspecifics appears to be double, with a low-gain velocity-sensitive mechanism operating over about a 90° range, backed up by a position-sensitive mechanism at the ends of this range which is responsible for recentring the target. This system has separate front and rear ranges, with a gap in the direction of the claw. The crabs separately fixate the burrow entrance, keeping it in the direction opposite the claw. Predator evasion employs two systems simultaneously. An openloop mechanism directs the crab's translatory movements directly away from the stimulus, and a rotational mechanism using continuous feedback turns the crab so that the stimulus is kept at near 90° to the body axis. Both systems are sensitive to the angular position of the stimulus, not its velocity. Eye movements have little or no role in object tracking. An attempt is made to list Uca's known visual control systems.     

Synchronous waving in two species of fiddler crabs

In the fiddler crabs Uca saltitanta and Uca perplexa, males attract mates by waving their enlarged claws. We show that in both species waving is closely synchronised between neighbouring males in clusters, both in the presence of mate-searching females and in their absence. Wandering females visit those males in the cluster that produce more waves at faster wave rates. In U. perplexa, they also selectively visit those males that produce the greatest number of leading waves. Synchronous waving may be the result of a precedence effect causing male competition to produce leading signals.     

Synchronous waving in fiddler crabs: a review

Many animals that use acoustic communication synchronize their mate attract!on signals: individuals precisely time their calls to overlap those of their neighbors. In contrast, synchrony in the mate attraction displays of species with visual/motion-based signals is rare. It has only been documented in five species of fiddler crabs. In all of them, small groups of males wave their single large claw in close synchrony. Here, I review what we know about synchrony in fiddler crabs, comparing the five species with each other to determine whether similar mechanisms and functions are comm on to all. I also propose future research questions that, if answered, would shed light on synchronous behavior in both visual and acoustic signallers.     

Bilateral linkage of monomorphic and dimorphic limb sizes in fiddler crabs

In this study, the subject of whether investment in one bilateral structure was linked to investment in the homologous bilateral opposite structure was investigated. Male fiddler crabs (genus Uca, family Ocypodidae) displayed strong bilateral claw differentiation of function and size, which are used for feeding (minor claw) or display/combat (major claw). Females had similar‐sized feeding claws. Linkage between claw size was investigated by estimating the deviations from an overall fitted regression of claw length to body size. The positive correlations of the deviations of claw size for major and minor claws of males and between right and left claws of females, relative to body size, suggested a linkage in investment between one claw and the corresponding claw on the other side of the body, for both monomorphic females and dimorphic males. A signal to send resources may be effectively gated to the claw complex, suggesting that positively correlated resources are allocated to both claws. Positive correlations were also found at the interspecific level. The fiddler crab model, described here, gives access to study the linkage in symmetric and asymmetric bilateral structures in the same species with a connection to the macroevolutionary level.     

In situ monitoring of heart rates in shore crabs Carcinus maenas in two tidal estuaries: effects of physico-chemical parameters on tidal and diel rhythms

Heart rates were monitored in situ in the shore crab, Carcinus maenas, in relation to variations in depth, salinity, oxygen tension, temperature, light intensity and pH. Experiments were performed in the Looe Estuary, Cornwall, England and in Batson Creek in the Salcombe-Kingsbridge Estuary, Devon, England. Experiments in the Looe Estuary were conducted in the vicinity of a storm water storage discharge whereas the experiments in Batson Creek were performed on a clean site. Tidal rhythms in heart rates were commonly detected but diel rhythms in heart rate were also observed frequently. Both types of rhythm were more evident in animals from Batson Creek than from Looe. In Batson Creek, 12 out of 15 crabs expressed tidal rhythms in heart rate, whereas 6 out of 15 crabs expressed diel rhythms. In the two studies in the Looe Estuary, 6 out of 15 crabs and 3 out of 15 crabs expressed tidal and diel rhythm in heart rate, respectively. At both experimental sites, heart rates were positively correlated with increasing changes in depth and salinity, whereas heart rates were negatively correlated with light intensity. In addition, heart rates appeared to be positively correlated with increasing oxygen tension in the experiments performed in the Looe Estuary. The study suggests that depth and oxygen availability are more important to in situ heart rates in shore crabs within tidal estuaries than are salinity, light intensity and pH. Also, sewage discharge appears to cause an acute increase in heart rate, which may affect expression of biological rhythms in shore crabs.     

Interspecific assistance: fiddler crabs help heterospecific neighbours in territory defence

Theory predicts that territory owners will help established neighbours to repel intruders, when doing so is less costly than renegotiating boundaries with successful usurpers of neighbouring territories. Here, we show for the first time, to our knowledge, cooperative territory defence between heterospecific male neighbours in the fiddler crabs Uca elegans and Uca mjoebergi. We show experimentally that resident U. elegans were equally likely to help a smaller U. mjoebergi or U. elegans neighbour during simulated intrusions by intermediate sized U. elegans males (50% of cases for both). Helping was, however, significantly less likely to occur when the intruder was a U. mjoebergi male (only 15% of cases).