Modelling quantitative structure-activity relationships between animal behaviour and environmental signal molecules.

Quantitative structure-activity relationships (QSARs) between the physicochemical properties of environmental signal molecules and animal behaviour have been determined. Past work has shown that oyster and barnacle larval settlement and mud crab abdominal pumping (for larval dispersal) are stimulated by small peptide cues. In all the peptides examined that were active at ecologically relevant concentrations, arginine or lysine was found at the carboxy terminus, but the amino acids found at preceding positions were highly variable.

The effects of walls, paternity and ageing on sperm motility.

The measurement of sperm motility is critical when studying fertilization kinetics and chemotaxis. Analysis of motility has traditionally been carried out on cells in small fluid volumes on microscope slides. Several theoretical treatments suggest that drag forces significantly affect flagellar motion within 10 sperm body lengths of the slide surface.

Chemical Induction of Larval Settlement Behavior in Flow.

The ability of dissolved chemical cues to induce larval settlement from the water column has long been debated. Through computer-assisted video motion analysis, we quantified the movements of individual oyster (Crassostrea virginica) larvae in a small racetrack flume at free-stream flow speeds of 2.8, 6.

The Relationship Between Predator Activity State and Sensitivity to Prey Odor.

Predators searching for prey commonly alternate periods of endogenous locomotory activity with rest. We examined the effects of activity state on behavioral responses to prey odor by predatory blue crabs (Callinectes sapidus) and spiny lobsters (Panulirus interruptus). All animals to be tested were placed individually in large seawater tanks (1.

Odor Plumes and Animal Navigation in Turbulent Water Flow: A Field Study.

Turbulence causes chemical stimuli to be highly variable in time and space; hence the study of animal orientation in odor plumes presents a formidable challenge. Through combined chemical and physical measurements, we characterized the transport of attractant released by clam prey in a turbulent aquatic environment. Concurrently, we quantified the locomotory responses of predatory crabs successfully searching for sources of clam attractant.