References:
- Piggott, L.A., Bauman, A., Scott, J.D., and Dessauer, C.W.: The A-Kinase Anchoring Protein Yotiao Binds and Regulates Adenylyl Cyclase in Brain. Proc. Natl. Acad. Sci., 105: 13835-13840, 2008
- Kapiloff, M.A., Piggott, L.A., Sadana, R., Li, J., Heredia, L.A., Henson, E., Efendiev, R., and Dessauer, C.W.: An adenylyl cyclase-mAKAPβ signaling complex maintains basal cAMP levels in cardiac myocytes. J. Biol. Chem., 284: 23540-23546, 2009
- Sadana, R., Dascal, N., and Dessauer, C.W.: N-terminus of Type 5 Adenylyl Cyclase Scaffolds Gs Heterotrimer. Mol Pharmacology, in press, 2009
- Gao, X., Sadana, R., Dessauer, C.W., and Patel, T.B. (2007) Conditional Stimulation of Type V and VI Adenylyl Cyclase by G protein βγ Subunits. J. Biol. Chem., 282: 294-302.
- Bauman, A., Soughayer, J., Nguyen, B.T., Willoughby, D., Wong, W., Hoshi, N., Langeberg, L.K., Cooper, D.M.F., Dessauer, C.W., and Scott, J.D. (2006) Dynamic regulation of cAMP synthesis through anchored PKA/Adenylyl cyclase V/VI complexes. Molecular Cell, 23(6): 925-931.
- Nguyen, B.T. and Dessauer, C.W. (2005) Relaxin Stimulates PKCζ Translocation via PI3K to Increase cAMP Production in THP-1 Cells. Mol. Endo., 19: 1012-1023.
- Chen-Goodspeed, M., Lukan, A.N., and Dessauer, C.W. (2005) Modeling of Gαi and Gαs Regulation by Human Types V and VI Adenylyl Cyclase. J. Biol. Chem., 280: 1808-1816.
- Salim, S., Sinnarajah, S., Kehrl, J.H., and Dessauer, C.W. (2003) Identification of RGS2 and Type V Adenylyl Cyclase Interaction Sites. J. Biol. Chem. 278: 15842 - 15849
- Nguyen, B.T., Yang, L., Sanborn, B.M., and Dessauer, C.W. (2003) Phosphoinositide 3-Kinase Activity is Required for Biphasic Stimulation of cyclic AMP by Relaxin. Mol. Endocrinol. 17(6): 1075-84.
- Dessauer, C.W., Chen-Goodspeed, M., and Chen, J. (2002) Mechanism of Gi-Mediated Inhibition of Type V Adenylyl Cyclase. J. Biol. Chem. 277: 28823-28829.
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Sinnarajah, S., Dessauer, C.W., Srikumar, D., Chen, J., Yuen, J., Yilman, S., Dennis, J.C. Morrison, E.E., Vodyanoy, V., and Kehrl, J.H. (2001) RGS2 Regulates Signal Transduction in Olfactory Neurons by Attenuating Adenylyl Cyclase III Activation. Nature 409: 1051-1055.
Carmen W. Dessauer, Ph.D.
CRB Director, Associate Professor
UTHSC, Medical School, (713) 500 - 6308
Carmen.W.Dessauer@uth.tmc.edu
Mechanisms of adenylyl cyclase regulation
The enzyme adenylyl cyclase synthesizes the intracellular second messenger cyclic AMP, which plays a key role in functions ranging from control of heart rate and force of contraction to learning and memory. Many hormones and drugs mediate their actions by binding to G protein-coupled receptors that regulate cAMP production. Our laboratory is using structural, biochemical, live-cell imaging, and molecular biology techniques to understand the complex regulation of adenylyl cyclase by heterotrimeric GTP-binding proteins and regulators of G protein signaling (RGS proteins).
Another major question in the laboratory is how the fidelity of signaling is maintained within a cell. Cyclic AMP is a small diffusible molecule, yet many hormones stimulate cAMP production but elicit different biological responses. We are examining how localization of adenylyl cyclase to specific complexes within the membrane plays a role in cellular signaling. We have discovered that specific anchoring proteins of cAMP-dependent kinase (AKAPs) recruit adenylyl cyclase as well as other regulatory molecules. These signaling complexes have important roles at post-synaptic densities in the brain to control glutamate signaling and also function in the heart to control contractile events. We are currently using biochemical and functional studies in brain and heart to further define the nature of adenylyl cyclase complexes and to understand how specificity of signaling is generated and maintained.
