[ Philip Lloyd ]

Philip Lloyd, Ph.D.

Primary:

Associate Professor, Neurobiology, Pharmacology and Physiology

Secondary:

Committee on Neurobiology
Committee on Cell Physiology
The College

Education:

Degree Year Institution Area
BA
1973
Reed College
Biology
PhD
1980
University of Washington
Zoology


Phone: (773) 702-6376
E-Mail: plloyd@uchicago.edu
Address: SBRI J245 (MC 0926)
Web page:
 http://neurobiology.bsd.uchicago.edu/faculty/lloyd.htm

Research Summary

Physiological and behavioral role of neuropeptides in Aplysia

Our long-range goal is to gain insight into the mechanisms governing the release and actions of neurotransmitters. In recent years it has become clear that most neurons use multiple transmitters, commonly a single fast acting conventional transmitter and one or more peptide transmitters. While much research has focused on conventional transmitters, large gaps exist in our knowledge of the biology of neuropeptides at all stages from release to physiological function. We are currently using a number of tools including single cell biochemistry, electrophysiology, cell culture, and immunocytochemistry to identify novel transmitters and study their actions.

In our studies we have utilized the comparatively simple nervous system of Aplysia, a sea slug. This animal's nervous system consists of relatively few neurons many of which are large and can be individually identified making this preparation amenable for studies on the regulation of synaptic transmission from the molecular to the behavioral level. The results found on the molecular level can often be interpreted in terms of their behavioral significance-an advantage afforded in very few preparations.

To determine the functional roles played by neuropeptide transmitters, three experimental requirements must be satisfied. First, peptide transmitters must be characterized and localized to individual, identified neurons. We have developed procedures that permit biochemical characterization of the neuropeptides present in single identified neurons.

Second, release of the peptide transmitters must be monitored. We use several procedures, such as measuring changes in post-synaptic conductances or second messenger levels, to monitor the release of specific neuropeptides from these neurons. We have also recently succeeded in measuring the release of neuropeptides from single identified neurons placed in primary culture where they regrow axons and varicosities. We have found that each neuron regulates release of its neuropeptide differently and we are beginning to examine the cellular properties of the neurons which regulate this release.

Third, the physiological consequences of the released transmitter must be assessed. Using reduced preparations we have been able to satisfy these requirements for several neuropeptides. We are also exploring the manner in which neuropeptides modulate the effectiveness of conventional transmitters such as acetylcholine which are released from the same terminals. These studies have broad implications in our understanding of the roles of multiple transmitters in individual neurons.

Ongoing projects in the laboratory include the purification and sequencing of novel neuropeptides from Aplysia, the immunocytochemical localization of these peptides to individual neurons, and the analyses of peptide function using a variety of procedures including cyclic nucleotide radioimmunoassays, intracellular recording from identified neurons during behavior and voltage clamp recording.

Selected Publications

Hall, J.D. and Lloyd, P.E. Release of pedla peptide from identified aplysia neurons in primary culture. J. Neurobiol., 22:583-589, 1991.

Church, P.J. and Lloyd, P.E. Expression of diverse neuropeptide cotransmitters by identified motor neurons in Aplysia. J. Neurosci., 11:618-625, 1991.

Whim, M.D. and Lloyd, P.E. Modulation of peptide release from single identified Aplysia neurons in culture. J. Neurosci., 12:3545-3553, 1992.

Church, P.J., Whim, M.D. and Lloyd, P.E. Modulation of neuromuscular transmission by conventional and peptide transmitters released from excitatory and inhibitory motor neurons in Aplysia. J. Neurosci., 13:2790-2800, 1993.

Whim, M.D., Church, P.J. and Lloyd, P.E. Functional roles of peptide cotransmitters at neuromuscular synapses in Aplysia. Molecular Neurobiology, 7:335-347, 1993.

Whim, M.D. and Lloyd, P.E. Differential regulation of the release of the same peptide transmitters from individual identified motor neurons in culture. J. Neurosci., 7:4244-4251, 1994.

Lloyd, P.E. and Church, P.J. Cholinergic neuromuscular synapses in Aplysia have low endogenous acetylcholinesterase and a high affinity uptake system for acetylcholine. J. Neurosci., 14:6722-6733, 1994.

Church, P.J. and Lloyd, P.E. Activity of multiple identified motor neurons recorded intracellularly during evoked feeding-like motor programs in Aplysia.  J. Neurophysiol., 72:1794-1809,1994.

Lloyd, P.E., Phares, G.A., Phillips, N.E. and Willows, A.O.D. Purification and sequencing of neuropeptides from identified neurons in the marine mollusc, Tritonia. Peptides, 17:17-23, 1996.

Phares, G.A., J.H. Walent, R.L. Niece, S.B. Kumar, L.H. Ericsson, J.A. Kolowak, and Lloyd, P.E. Primary structure of a new neuropeptide, cerebral peptide 2, purified from cerebral ganglia of Aplysia. Biochemistry, 35:5921-5927, 1996.

Phares, G.A., and Lloyd, P.E. Purification, primary structure, and immunocytological localization of cerebral peptide 1, a new neuropeptide from Aplysia. Peptides, 17:753-761, 1996.

Phares, G.A., and Lloyd, P.E. Immunocytological and biochemical localization and biological activity of the newly sequenced cerebral peptide 2 in Aplysia.  J. Neurosci., 16:7841-7852, 1996.

Fox, L.E. and Lloyd, P.E. Serotonin and the SCPs differentially modulate two motor neurons that innervate the same muscle fibers in Aplysia. J. Neurosci., 17:6064-6074, 1997.

Updated 12/11/02.