All living cells can sense their environment. The term directional sensing refers to the ability of a cell to determine the direction and proximity of an extracellular stimulus. Directional sensing is needed to detect morphogens that control differentiation and attractants that direct cell migration, as in chemotaxis. This fascinating response is critical in embryogenesis, angiogenesis, neuronal patterning, wound healing, and immunity. Chemotaxis is strikingly exhibited during the life cycle of the social amoebae, Dictyostelium discoideum. During growth, these cells track down and phagocytose bacteria. When starved, they move towards secreted adenosine 3'-5' cyclic monophosphate (cAMP) signals, form aggregates, and differentiate into spore and stalk cells. The fundamental role of chemotaxis in this simple eukaryote provides a powerful system for its analysis at both genetic and biochemical levels. Both amoebae and mammalian leukocytes use G protein-linked signaling pathways to respond to chemoattractants. Binding of the attractants to receptors of the seven transmembrane helix class leads to the dissociation of the G proteins into alpha and beta/gamma-subunits. In both leukocytes and amoebae, chemoattractants elicit a variety of rapid responses including transient increases in Ca2+ influx, in the intracellular messengers IP3, cAMP and guanosine 3'-5' cyclic monophosphate (cGMP), and in the phosphorylation of myosins I and II. Chemoattractants also induce actin polymerization, most likely through the activation of the Rho family of small guanosine trisphosphatases. All these events rapidly subside in the presence of persistent stimulation. This rapid inhibition may allow a migrating cell to """"""""subtract"""""""" the ambient concentration of attractant and more accurately sense the direction of a gradient. Our research program is focused on learning how specific G protein-coupled signaling events translate into complex cellular responses such as cell migration and differentiation. In D.discoideum, genetic analyses have established that the activation of adenylyl cyclase (ACA) requires, in addition to the beta/gamma-subunits of G proteins, a novel protein called CRAC (cytosolic regulator of adenylyl cyclase). We have shown that CRAC, which contains a pleckstrin homology (PH) domain at its N-terminus, translocates rapidly and transiently to the plasma membrane upon addition of a chemoattractant. Remarkably, this translocation occurs selectively at the leading edge of chemotaxing cells. In both leukocytes and amoebae, other PH domain-containing proteins such as PKB (Akt) behave similarly. We have proposed that the appearance of specific binding sites for PH domain-containing proteins at the leading edge of chemotaxing cells spatially targets signaling events. My group is interested in identifying the molecular mechanisms that regulate these pathways and in particular the role of adenylyl cyclase in chemotaxis. Our research plan is comprised of three interconnected specific aims: (1) Identify the molecular mechanisms involved in the activation of CRAC, (2) Study the spatial and temporal localization of adenylyl cyclases in chemotaxing cells, and (3) Identify the mechanisms of activation of adenylyl cyclases in neutrophils. These studies have direct bearing on our understanding of clinically important processes such leukocyte migration to sites of inflammation as well as cancer metastasis.

Agency
National Institute of Health (NIH)
Institute
Division of Basic Sciences - NCI (NCI)
Type
Intramural Research (Z01)
Project #
1Z01BC010418-04
Application #
6951733
Study Section
(LCMB)
Project Start
Project End
Budget Start
Budget End
Support Year
4
Fiscal Year
2003
Total Cost
Indirect Cost
Name
Basic Sciences
Department
Type
DUNS #
City
State
Country
United States
Zip Code
Bagorda, Anna; Parent, Carole A (2008) Eukaryotic chemotaxis at a glance. J Cell Sci 121:2621-4
Garcia, G L; Parent, C A (2008) Signal relay during chemotaxis. J Microsc 231:529-34
Rericha, Erin C; Parent, Carole A (2008) Steering in quadruplet: the complex signaling pathways directing chemotaxis. Sci Signal 1:pe26
Comer, Frank I; Parent, Carole A (2007) Phosphoinositides specify polarity during epithelial organ development. Cell 128:239-40
Mahadeo, Dana C; Parent, Carole A (2006) Signal relay during the life cycle of Dictyostelium. Curr Top Dev Biol 73:115-40
Bagorda, Anna; Mihaylov, Vassil A; Parent, Carole A (2006) Chemotaxis: moving forward and holding on to the past. Thromb Haemost 95:12-21
Comer, Frank I; Lippincott, Christopher K; Masbad, Joseph J et al. (2005) The PI3K-mediated activation of CRAC independently regulates adenylyl cyclase activation and chemotaxis. Curr Biol 15:134-9
Lee, Susan; Comer, Frank I; Sasaki, Atsuo et al. (2005) TOR complex 2 integrates cell movement during chemotaxis and signal relay in Dictyostelium. Mol Biol Cell 16:4572-83
Shrimali, Rajeev K; Lobanov, Alexey V; Xu, Xue-Ming et al. (2005) Selenocysteine tRNA identification in the model organisms Dictyostelium discoideum and Tetrahymena thermophila. Biochem Biophys Res Commun 329:147-51
Brzostowski, Joseph A; Parent, Carole A; Kimmel, Alan R (2004) A G alpha-dependent pathway that antagonizes multiple chemoattractant responses that regulate directional cell movement. Genes Dev 18:805-15

Showing the most recent 10 out of 18 publications