Research interests:

Petra Lenz

Neuroecology of zooplankton sensory systems

Sensory capabilities underlie the behavior of any organism. My research focuses on understanding mechanosensory phenomena utilizing a model crustacean system. I am examining the relation between physiological and structural properties of a mechanosensory system and its relation to the behavior and ecology of the organism possessing it. Working on marine copepods, an important group in marine ecosystems, my collaborators and I have found exceptional mechanosensitivities (in the nanometer range, close to vertebrate ear capabilities), exceedingly fast reaction times (1 msec), and unusually high power-output rates associated with the sensory-triggering of behavioral (escape) reactions.

Studies on sensory mechanisms involve electrophysiological recordings of primary afferent discharges from mechanoreceptors. Research includes investigation of sensitivities and timing relations in sensory responses. Mechanisms for extremely high-frequency (5 kHZ, higher than most mammals) nerve impulse firing capabilities are under investigation.

Structure-function approaches are being used in studies of sensory transduction. Unusual rigidity of sensory structures derived from dense microtubule elaboration helps explain the high mechanical sensitivities and exceptional frequency response of receptors.

Escape responses ("jumps") triggered by abrupt mechanical stimuli are a primary focus of behavioral investigations. Reaction times have been correlated, among different species, with morphological adaptations for increasing nerve impulse propagation speed, including the development of myelin. Studies on the energetics of the behavioral reaction have been pursued through kinematic measurements and modeling of the biomechanical components of the escape swim system.

Bioluminescence, triggered by strong mechanical stimulation in certain deep-sea copepods, is another predator-evasion response being investigated. Simultaneous recording of the forces produced during kicks with the light produced in bioluminescence permits a comparison of triggering conditions and timing for the two different responses.

These studies are providing insights into the exceptional physiological capabilities of organisms under strong evolutionary selection pressure. They are leading to the discovery of novel design principles for both sensory and motor systems in a model organism capable of high performances. They are helping explain the extraordinary success of the copepod group in penetrating so many ecological niches in the aquatic environment.

For brief summaries of these different research areas in copepod biology click here

For selected publications from the lab in this area click here

For general documents and links on zooplankton sensory systems click here

Lab Research in the News

4/13/99 "Crustation insulation" by Eleanor Lawrence (Nature Science Update)(alternate loc)
4/14/99 "Myelin for the masses" by Meher Antia (inScight) (alternate loc)
4/20/99 "Speedy crustaceans" by Henry Fountain (NY Times Science Observatory; requires registration) (alternate loc)
4/23/99 Ku Lama article by Cheryl Ernst
4/23/99 Ku Lama profile of April Davis by Cheryl Ernst

Population biology of Artemia

Past work has dealt with various aspects of the population biology of the brine shrimp in Mono Lake, California (Artemia monica). See:

Lenz, P.H. (1987) "Ecological studies on Artemia: a review" in Sorgeloos, P., Bengtson, D.A., Decleir, W. and Jaspers, E., eds. Artemia Research and its Applications Vol. 3. Ecology, Culturing, Use in aquaculture Universa Press, Wetteren, Belgium pp 5-18.

Updated 4/23/99 Return to Lenz Home Page. Return to PBRC Home Page.