Departments & Organizations
Membrane Proteins - Pumps and Transporters
Neurobiology and Physiology of Synapses
Yale Combined Program in the Biological and Biomedical Sciences (BBS): Biochemistry, Quantitative Biology, Biophysics and Structural Biology (BQBS): Drug Design, Discovery and Mechanism; Membrane Biology; Neuroscience | Molecular Medicine, Pharmacology, and Physiology: Ion Channels, Pumps and Transporters; Neurobiology, Neural Networks and Neuropharmacology; Structural Biology | Neuroscience: Drug Abuse; Neuropharmacology; Neurophysiology
Professor Rudnick is a graduate of Antioch College, where he received a B.S. in Chemistry in 1968. He performed graduate studies in the enzymology of amino acid racemases in the laboratory of Robert H. Abeles in the Graduate Department of Biochemistry at Brandeis University, receiving a Ph.D. in Biochemistry in 1974. His graduate studies led to an understanding of the structure and mechanism of proline racemase that was confirmed by the crystal structure of a homologous protein in 2006. From 1973-1975, Professor Rudnick performed postdoctoral research on lactose permease with H. Ronald Kaback at the Roche Institute of Molecular Biology. This work provided a greater understanding of binding and transport reactions using photoaffinity reagents and substrate analogs. In 1975, he left Roche to become an Assistant Professor in the Department of Pharmacology at Yale, and was promoted to Associate Professor in 1980 and Professor in 1991.
Professor Rudnick’s research at Yale has focused on the mechanism and structure of mammalian serotonin transporter (SERT). He developed a system of platelet plasma membrane vesicles with which to study the bioenergetics and mechanism of transport. These studies provided an understanding of the coupling of ion gradients to serotonin accumulation and also identified SERT as the molecular target for the antidepressant imipramine and the psychostimulant MDMA (ecstasy).
Beginning in the 1990s, Professor Rudnick’s laboratory has been studying the molecular characteristics of SERT and other neurotransmitter transporters expressed in cultured cells. These studies led to the identification of the serotonin binding site in SERT and of regions in the protein undergoing conformational changes during transport. The availability of a crystal structure for a homologous bacterial transporter in 2005 allowed Professor Rudnick and his colleagues to use the conformational changes to propose a conformational mechanism of transport that is gaining wide acceptance. Because SERT is structurally related to many other transporters, the proposed mechanism is likely to apply to transporters functioning in many diverse biological systems.
In addition to these mechanistic studies, Professor Rudnick’s laboratory has been investigating a spontaneously occurring SERT mutant associated with several psychiatric disorders. The mutation apparently inhibits removal of a phosphate group added to SERT by cGMP-dependent protein kinase. The mechanism by which this phosphate increases SERT activity is an active area of investigation.
Education & Training
|PhD||Brandeis University (1974)|
|Postdoc||Roche Institute of Molecular Biology|