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Scientific Report

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Stephen F. Heinemann

 

Stephen F. Heinemann

Professor
The Salk Institute Council Endowed Chair in Genetics
Molecular Neurobiology Laboratory

"The work in our laboratory is focused on the molecular mechanism by which nerve cells communicate with each other at specialized connections, or synapses. Recent work in the laboratory has supported the idea that many diseases of the brain result from deficits in communication between nerve cells or synapses."

Before senile plaques and neurofibrillary tangles, the hallmark of Alzheimer's disease, ravage the brains of its victims, the condition is marked by memory deficits and the loss of connections between brain cells. What this suggests is that communication between nerve cells is severely hampered long before the aggregate form of beta amyloid, which makes up the plaques, appears to interrupt the connections and ultimately cause neuronal death.

This finding prompted Heinemann to ask new questions about the disease: What if Alzheimer's disease is caused by defective synapses—the specialized communication interfaces between neurons—and dying brain cells are just the results of gummed-up connections? Using a mouse model engineered to overproduce a mutant form of the human amyloid precursor protein (APP) from which a number of smaller fragments, including the infamous beta amyloid, are cleaved off, Heinemann and his team studied the communication between nerve cells.

What they discovered is that the transmission of signals between brain cells in these mice is compromised long before neurons start to wither, and the interrupted cell-to-cell communication could explain the loss of memory that is apparent in earlier stages of the disease. On closer inspection, they discovered a possible culprit: a short, C-terminal APP fragment. When the formation of the fragment was blocked, the mouse was protected from the loss of synaptic transmission: Communication and memory were normal, and brain atrophy was eliminated, suggesting a new strategy to develop drugs to treat Alzheimer's disease.

In related work, Heinemann has examined the role of synapses in another common and debilitating condition: depression. He and his team studied patients diagnosed with major depression and linked the disorder to a specific brain receptor discovered in his laboratory. This receptor was shown to regulate the communication between nerve cells at the synapse—a discovery that may lead to new drugs to treat this widespread, perplexing malady.

Left to right:
Standing: Ruadhan O'Flanagan, Corinne Teeter, Sunhwa Lee, Juan Pina-Crespo, Joe Snider, Mikio Suzuki, Conny Maron, Hosuk Lee, Jennifer Greenhall, Tresa McGranahan, Kacee Jones, Ed Han Seated: Jane Jenerette, Chuck Stevens, Steve Heinemann

Print version -
Stephen F. Heinemann

Faculty

Stephen F. Heinemann

Professor
The Salk Institute Council Endowed Chair in Genetics
Molecular Neurobiology Laboratory

Stephen F. Heinemann, a professor in the Molecular Neurobiology Laboratory, studies the molecular details of communication among brain cells. The synapse plays a key role in communicating information between brain cells and it is likely that biochemical changes at the synapse underlie some aspects of higher brain function. Most plausible theories of learning and memory depend upon changes in the efficiency of chemical synapses, which probably involves changes in receptors, ion channels and neurotransmitter release. It is also now known that these molecules can be directly involved in human disease. Most drugs that are used to treat mental illness are known to work either on the receptors or the metabolism of the transmitters at the synapse. The work in the laboratory is focused on the molecular biology and physiology of the glutamate and nicotinic receptors expressed in the brain. A major goal is to understand the regulation of synaptic function and the molecular biology of learning.

Among other notable achievements, his lab has isolated a gene containing the blueprints for a receptor critical to learning and memory, and identified the receptors that respond to nicotine. Since neurological ailments, such as Alzheimer's and Parkinson's; drug addiction; and mental disorders, such as depression and schizophrenia, are fundamentally disorders of brain cell communication, this research will provide new insights into the treatment of these disorders. Discoveries in Heinemann's lab are currently being used by pharmaceutical and biotechnology companies to develop drugs for stroke, epilepsy, Parkinson's and Alzheimer's diseases, as well as mental conditions, such as nicotine addiction, depression and schizophrenia.

Education

• B.S., California Institute of Technology
• Ph.D., Biochemistry, Harvard University
• Postdoctoral fellow, Massachusetts Institute of Technology and Stanford University

Awards and Honors

• National Academy of Sciences (USA)
• National Institute of Medicine (USA)
• American Academy of Arts & Sciences
• Bristol-Myers Squibb Distinguished Achievement in Neuroscience Research Award, 1995
• McKnight Award for Research, 1991-1997

Selected Publications

• Vetter, D.E., Li, C., Zhao, L., Contarion, A., Liberman, M.C., Smith, G.W., Marchuk, Y., Koob, G.F., Heinemann, S.F. Vale, W. and Lee, K.-F.: Urocortin-Deficient Mice Show Hearing Impairment and Increased Anxiety-like Behavior. Nat Genet. 2002 Aug;31(4):363-9.
• Contractor, A., Rogers, C., Maron, C., Henkemeyer, M., Swanson. G.T. and Heinemann, S.F.: Trans-Synaptic Eph Receptor-Ephrin Signaling in Hippocampal Mossy Fiber LTP. Scence 296: 1864-1869 (2002).
• Contractor, A., Swanson, G.T., Sailer, A. and Heinemann, S.F.: Kainate receptors modulate excitatory synaptic transmission in the CA3 region of the hippocampus. Neuron 29: 209-216 (2001).
• Vissel, B., Royle, G.A., Christie, B.R., Schiffer, H.H., Ghetti, A., Tritto, T., Perez-Otano, I., Radcliffe, R.A., Seamans, J., Sejnowski, T., Wehner, J.M., Collins, A.C., O'Gorman, S., and Heinemann, S.F.: The Role of RNA Editing of Kainate Receptors in Symaptic Plasticity and Seizures. Neuron 29: 217-227 (2001).
• Contractor, A., Swanson, G. and Heinemann, S.F.: Kainate Receptors Are Involved in Short- and Long-Term Plasticity at Mossy Fiber Synapses in the Hippocampus. Neuron 29: 209-216 (2001).
• Mulle, C., Sailer, A., Swanson, G.T., Brana, C., O'Gorman, S., Bettler, B. and Heinemann, S.F.: Subunit Composition of Kainate Receptors in Hippocampal Interneurons. Neuron 28:475-485 (2000).
• Contractor, A., Swanson, G.T., Sailer, A., O'Gorman, S. and Heinemann, S.F.: Identifiction of the Kainate Receptor Subunits Underlying Modulation of Excitatory Synaptic Transmission in the CA3 Region of the Hippocampus. Journal of Neuroscience, 20(22):8269-8278 (2000).
• Vetter, D.E., Liberman, M.C., Mann, J., Barhanin, J., Boulter, J., Brown, M.C., Saffiote-Kolman, J., Heinemann, S.F. and Elgoyhen, A.B.: Role of a9 Nicotinic Ach Receptor Subunits in the Development and Function of Cochlear Efferent Innervation. Neuron 23:93-103 (1999).
• Mulle, C., Sailer, A., Pérez-Otaño, I., Dickinson-Anson, H., Castillo, P.E. Burearu, I., Maron, C., Gage, F.H., Mann, J.R., Bettler, B. and Heinemann, S.F.: Altered Synaptic Physiology and Reduced Susceptibility to Kainate-Induced Seizures in GluR6-Deficient Mice. Nature 392:601-605 (1998).
• Vetter, D.E., Mann, J.R., Wangemann, P., Liu, Jianzhong, McLaughlin, K.J., Lesage, F., Marcus, D.C., Lazdunski, M., Heinemann, S. and Barhanin, J.: Inner Ear Defects Induced by Null Mutation of the isk Gene. Neuron 17:1251-1264 (1996).
• Elgoyhen, A.B., Johnson, D.S., Boulter, J., Vetter, D.E. and Heinemann, S.: Alpha9: An Acetylcholine Receptor with Novel Pharmacological Properties Expressed in Rat Chochlear Hair Cells, Cell 79:705-715 (1994).
• Hollmann, M., O' Shea-Greenfield, A., Rogers, S.W. and Heinemann, S.: Cloning by functional expression of a member of the glutamate receptor family. Nature 342:643-648. (1989)
• Goldman, D., Deneris, E., Kochhar, A., Patrick, J. and Heinemann, S.: Members of a nicotinic acetylcholine receptor gene family are expressed in different regions of the mammalian central nervous system. Cell 48:965-973 (1987)
• Boulter, J., Connolly, J., Deneris, E., Goldman, D., Heinemann, S., and Patrick, J.: Functional expression of two neuronal nicotinic acetylcholine receptors from cDNA clones identifies a gene family. Proc. Natl. Acad. Sci. 84:7763-7767. (1987)
• Ballivet, M., Patrick, J., Lee, J. and Heinemann, S.: Molecular cloning of cDNA coding for the gamma subunit of the Torpedo acetylcholine receptor. Proc. Nat. Acad. Sci. 79:4466-4470. (1982)

Links

• Heinemann lab
• Heinemann technologies available for licensing

Salk News Releases

• Nicotinic receptor may help trigger Alzheimer's disease, August 13, 2009
• Forget it! A biochemical pathway for blocking your worst fears?, March 24, 2009
• Residential preference for nicotinic receptors in neurons, September 27, 2007
• Salk Researchers Find That Brain Receptor May Be Involved In Epileptic Seizures, April 9, 1998

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