UASOM Faculty Profiles


Name	JOHN DAVID SWEATT
Campus Address	SHEL 1010 Zip 2182
Phone	205-975-5196
E-mail	dsweatt@uab.edu
Other websites	http://www.neurobiology.uab.edu/sweatt_lab/

Appointment Type

Department

Division

Rank

Primary

Neurobiology

Professor

Secondary

Cell, Developmntl, & Integrative Biology

Professor

Secondary

Genetics

Genetic & Translational Med

Professor

Center

Neurology

Alzheimer's Disease Center

Professor

Center

Center for Aging

Professor

Center

Civitan International Research Center

Professor

Center

General Clinical Research Center

Comprehensive Neuroscience Center

Professor

Center

Ctr for Glial Bio in Med

Professor

Center

Neurology

Ctr Neurodegeneration & Exp Ther (CNET)

Professor

Cell, Molecular, & Developmental Biology

Cellular and Molecular Biology Program

Genetics and Genomic Sciences

Hughes Med-Grad Fellowship Program

Integrative Genetics Graduate Program

Medical Scientist Training Program

Neuroscience

Neuroscience Graduate Program

Pathobiology and Molecular Medicine

Dr. Sweatt received his Bachelor of Science degree in chemistry in 1981 from the University of South Alabama. He received his doctorate in pharmacology from Vanderbilt University in 1986. For the following three years, he was a research associate at Vanderbilt and then at Columbia University. At Columbia, he worked with Eric Kandel, M.D., who received the 2000 Nobel Prize in Physiology or Medicine. From 1989 to 2006, he was a Professor of Neuroscience at Baylor College of Medicine in Houston, Texas. In 2006, he joined the faculty in the Neurobiology Department at UAB as Professor and Evelyn F. McKnight Endowed Chair.

Organization Name

Position Held

Org Link

AAAS

American Physiological Society

American Society for Neurochemistry

Molecular and Cellular Cognition Society

Society for Neuroscience

Title
Signal Transduction Mechanisms in Learning and Memory
Description
Our interest is in understanding the biochemical mechanisms underlying learning and memory. One of the major advances in neurobiology in the last century was the formulation of the general theory that changes in synaptic connections between neurons underlie information storage in the CNS. From our perspective one powerful offshoot of this general theory is that it allows a reductionist approach, that is, that by studying the mechanisms of long-lasting synaptic plasticity in vitro we can generate insights into the mechanisms of learning and memory in vivo. Using this rationale, for the last decade my laboratory has been investigating the biochemical mechanisms subserving the induction and maintenance of long-term potentiation in the hippocampus. In general our focus has been on signal transduction, with a particular emphasis on the role of protein kinases in LTP. Our work, and that of many other labs, has indicated that four protein kinases play particularly prominent roles in LTP: PKA, PKC, CaMKII, and erk MAPK. By and large PKC and CaMKII have achieved notoriety for their roles as molecular information storage devices; autonomously active forms of these kinases subserve the maintenance of early LTP. In contrast, PKA and MAPK appear predominantly to be involved in triggering the induction of early and late stages of LTP. While we have investigated all of these protein kinase cascades over the last decade, of late we have focused most of our effort on studies of the MAPK and PKC cascades. A role for MAPK in synaptic plasticity Our recent discovery of a role for MAPK in LTP has been somewhat of a watershed event for us, and has led us to begin to investigate in detail the role of this signal transduction cascade in the hippocampus. We initially observed that MAPK is activated in an NMDA receptor-dependent fashion in LTP, and that this activation is necessary for LTP induction. Recently we have focused on two issues arising from these observations; how is MAPK regulated in the hippocampus and what are its downstream effectors. We have discovered that MAPK is regulated by both the PKA and PKC cascades, and via these pathways is regulated by a variety of neuromodulatory neurotransmitter receptors in the hippocampus. Thus MAPK appears to serve an important role as a signal integrator in the hippocampus. Furthermore, we have found that MAPK is a critical regulator of both CREB phosphorylation and K-channel phosphorylation in the hippocampus, indicating a broad variety in the types of cellular responses that may be regulated by MAPK. We are building on these findings through three avenues of experimentation at present. First, we are using knockout animals for specific isoforms of MAPK to test our hypothesis that p42 MAPK (erk2) is particularly important for the biochemical and physiologic roles of MAPK in the hippocampus. Second, we are evaluating new effectors of MAPK, such as transcription factors and other regulators of gene expression. Third, we are using phospho-site specific antibodies we developed in order to determine if MAPK regulates Kv4.2 phosphorylation in LTP and in response to neuromodulatory neurotransmitter stimulation. Transitioning from synaptic plasticity to behavior While we have made great progress in understanding the role of signal transduction cascades in LTP, the broader goal of my research is to understand learning and memory in the animal. Our studies in this area are guided by the general hypothesis that biochemical mechanisms for LTP will be valid predictors for mechanisms for learning and memory in vivo. We are approaching this problem in two ways, by testing two specific predictions of our overall hypothesis. First, we are determining if the LTP-associated signal transduction mechanisms are activated in vivo when the animal learns. Second, we are determining if blocking these signal transduction cascades, using pharmacologic and genetic approaches, leads to learning and memory deficits in the behaving animal. We use a variety of behavioral paradigms in our whole-animal studies, but have emphasized the cued and contextual variants of fear conditioning because of the robustness of the learning and the relatively well-defined anatomical substrates of the learning. For our biochemical studies in vivo we are using various phospho-site specific antibodies that we and others have developed, which selectively tag activated forms of PKC, MAPK, CaMKII, and CREB. Our studies to date have used Western blotting procedures to quantitate anatomical subregion-specific changes in phosphorylation of these molecules. One particularly exciting new avenue we are pursuing is utilizing these same antibodies in immunohistochemistry procedures, so that we will be able to obtain much more precise anatomical localization of biochemical changes in the animal's CNS that result from learning. We are of course coupling our behavioral and biochemical studies in vivo with the kinase isoform-selective knockouts described above, in order to investigate the necessity of these specific enzyme species for both learning and learning-associated biochemical changes. Potential insights into hippocampal pathologies We also are interested in using what we have learned about hippocampal synaptic plasticity to generate insights into human pathological conditions. With this in mind, we have been using the kainate model of epilepsy to investigate the potential role of MAPK in epileptogenesis. In our pilot studies we have observed striking hippocampal MAPK activation, CREB phosphorylation, and K-channel phosphorylation after kainate injection. We will be pursuing these observations using pharmacologic and knockout manipulations to determine if these changes are causally related to seizure generation in the animal. A second major line of investigation is related to Alzheimer's Disease. We utilize transgenic (mutant APP and presenilin) mouse models for AD to determine if hippocampal signal transduction mechanisms and transcriptional regulation mechanisms are deranged in this learning-deficient mouse strain. alpha7 Nicotinic Acetylcholine Receptors in Aging-related memory loss Another of our recent projects involves the alpha7 nicotinic acetylcholine receptor which is highly expressed in hippocampus and in cholinergic projection neurons from the basal forebrain. These structures are especially interesting to our lab since they are particularly vulnerable in aging related memory loss. Also of interest in our research, elevated levels of ß-amyloid peptide have been shown in previous studies to lead to hippocampal dysfunction, but the mechanism is not known. We are testing the hypothesis that ß-amyloid peptide directly interacts with the alpha7 nicotinic acetylcholine receptor by evaluating the effects of ß-amyloid peptide on hippocampal physiology and testing the role of the alpha 7 nicotinic receptor in these effects. Mental Retardation Syndromes Over the past few years we and several other groups have begun using a new approach to bridge the gap between specific molecules and human cognition. The essence of this approach is to identify naturally occurring human genetic mutations that result in mental retardation/learning disorders and use knockout and transgenic mouse models to generate insights into the underlying molecular and cellular basis for the defect. The rationale is that this will give insights into the humans who are missing the same gene and hence give insights into the molecular neurobiology of human cognitive processing. We have used this approach, in collaboration with several investigators across the country, to study mouse models including the mouse model for Angelman syndrome, Rett Syndrome and Fragile X syndromes. The characterization we perform on these mouse models consists of electrophysiological, biochemical and behavioral assessments which lead to a greater knowledge of the causes and implications of these disorders in humans. Overview and Future Directions In broad terms, our future scientific goal is to capitalize upon our recent insights into the signal transduction mechanisms operating in hippocampal synaptic plasticity; we will do this by utilizing a multidisciplinary approach combining in vitro biochemistry, electrophysiology, immunohistochemistry, and behavioral assays. We will use both pharmacologic and genetic experimental manipulations in order to investigate both the molecular basis of normal learning and the biochemical derangements that underlie pathological conditions affecting learning and memory.

Publication

PUBMEDID

Shalin SC, Hernandez CM, Dougherty MK, Morrison DK, Sweatt JD.
Kinase suppressor of Ras1 compartmentalizes hippocampal signal transduction and subserves synaptic plasticity and memory formation.
Neuron. 2006 Jun 1;50(5):765-79.

16731514

Levenson JM, Roth TL, Lubin FD, Miller CA, Huang IC, Desai P, Malone LM, Sweat JD
Evidence that DNA (cytosine-5) methyltransferase regulates synaptic plasticity in the hippocampus.
J Biol Chem. 2006 June 9;281(23):15763-73. Epub 2006 Apr 10.

16606618

Levenson JM, Sweatt JD.
Epigenetic mechanisms in memory formation.
Nat Rev Neurosci. 2005 Feb;6(2):108-18. Review.

15654323

Birnbaum SG, Yuan PX, Wang M, Vijayraghavan S, Bloom AK, Davis DJ, Gobeske KT, Sweatt JD, Manji HK, Arnsten AF.
Protein kinase C overactivity impairs prefrontal cortical regulation of working memory. Science. 2004 Oct 29;306(5697):882-4

15514161

Levenson JM, O'Riordan KJ, Brown KD, Trinh MA, Molfese DL, Sweatt JD.
Regulation of histone acetylation during memory formation in the hippocampus.
J Biol Chem. 2004 Sep 24;279(39):40545-59. Epub 2004 Jul 23.

15273246

O'Riordan, K.J., Huang, I.C., Pizzi, M., Spano, P., Boroni, F., Egli R., Desai, P., Fitch, O., Malone, L., Ahn, H-J., Liou, H.C., Sweatt, J.D., and Levenson, J.N. (2006) Regulation of nuclear factor kappaB in the hippocampus by group I metabotropic glutamate receptors. J Neurosci. 26:4870-9

Chwang, W.B., O'Riordan, K.J., Levenson, J.M., and Sweatt, J.D. (2006) ERK/MAPK regulates hippocampal histone phosphorylation following contextual fear conditionin. Learn Mem. 2006 May - Jun; 13(3):322-8.

Chen, X., Yuan, L.L., Zhao, C., Birnbaum S.G., Frick, A., Jung, W.E., Schwarz, T.L., Sweatt, J.D., and Johnston, D. Deletion of Kv4.2 gene eliminates dendritic A-type K+ current and enhances induction of longterm potentiation in hippocampal CA1 pyramidal neurons. J. Neuroscience, 26:12143-51.

Miller, C.A., and Sweatt, J.D. (2007) Covalent modification of DNA regulates memory formation. Neuron 53:857-69.

Kim, S.Y., Levenson, J.M., Korsmeyer, S., Sweatt, J.D., and Schumacher, A. (2007) Developmental regulation of Eed complex composition governs a switch in global histone modification in brain. J Biol chem. 282:9962-72

memory, learning, epigenetics, gene transcription, signal transduction, neurobiology

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