Hepatic stellate cells mediate the liver's response to injury. Consequently, these perisinusoidally-located non-parenchymal cells control normal wound healing and the development of fibrosis. The broad, long-term objective of this project is to elucidate the signal transduction pathways that direct stellate cell responses in order to facilitate development of novel strategies for the prevention and treatment of cirrhosis from diverse causes, including alcoholism and viral hepatitis. We have developed new assays and reagents for quantitatively measuring myosin-dependent contractility in stellate cells. Employing these new methods, and other more standard procedures, we have started to demonstrate the role of myosin and focal adhesion kinase (FAK) in the regulation of essential cell functions. These results have led to this proposal's main hypothesis that the coordinated regulation of myosin and FAK, by injury induced factors, play a central role in the signal transduction pathways that mediate the stellate cell behaviors responsible for fibrosis. This hypothesis will be tested by the following specific aims: 1) Characterize the mechanisms by which injury-induced factors regulate myosin-dependent contractility. To address this aim we will determine the relative roles of myosin light chain kinase and rho-associated kinase signal transduction pathways in myosin-dependent contractility. 2) Elucidate the mechanisms by which injury-induced factors regulate activation of FAK. This will be achieved by testing our proposal that ET-1, LPA, and PDGF-BB stimulate FAK activation through distinct signaling pathways involving myosin-dependent contractility and membrane ruffling. 3) Test the hypothesis that myosin-dependent contractility and FAK activation control stellate cell behaviors responsible for fibrosis. We will demonstrate the roles of myosin and FAK in the regulation of stellate cell morphology, contraction, migration, proliferation, and collagen synthesis. In summary, the signal transduction mechanisms through which the injury-induced mediators, ET-1, LPA, and PDGF-BB, regulate critical stellate cell responses will be systematically defined using established pharmacological and genetic interventions in primary cultures of hepatic stellate cells isolated from normal rats and rats that have undergone chronic hepatic injury.
Chen, Yishi; Chitapanarux, Taned; Wu, Jianfeng et al. (2013) Inducible NOS mediates CNP-induced relaxation of intestinal myofibroblasts. Am J Physiol Gastrointest Liver Physiol 304:G673-9 |
Wu, Jianfeng; Chitapanarux, Taned; Chen, Yishi et al. (2013) Intestinal myofibroblasts produce nitric oxide in response to combinatorial cytokine stimulation. J Cell Physiol 228:572-80 |
Soon Jr, Russell K; Yee Jr, Hal F (2008) Stellate cell contraction: role, regulation, and potential therapeutic target. Clin Liver Dis 12:791-803, viii |
Melton, Andrew C; Soon Jr, Russell K; Park, J Genevieve et al. (2007) Focal adhesion disassembly is an essential early event in hepatic stellate cell chemotaxis. Am J Physiol Gastrointest Liver Physiol 293:G1272-80 |
Melton, Andrew C; Yee, Hal F (2007) Hepatic stellate cell protrusions couple platelet-derived growth factor-BB to chemotaxis. Hepatology 45:1446-53 |
Loudon, Robert P; Silver, Lee D; Yee Jr, Hal F et al. (2006) RhoA-kinase and myosin II are required for the maintenance of growth cone polarity and guidance by nerve growth factor. J Neurobiol 66:847-67 |
Melton, Andrew C; Datta, Anuj; Yee Jr, Hal F (2006) [Ca2+]i-independent contractile force generation by rat hepatic stellate cells in response to endothelin-1. Am J Physiol Gastrointest Liver Physiol 290:G7-13 |
Chitapanarux, Taned; Chen, Stephen L; Lee, Helen et al. (2004) C-type natriuretic peptide induces human colonic myofibroblast relaxation. Am J Physiol Gastrointest Liver Physiol 286:G31-6 |
Wang, Rex T; Koretz, Ronald L; Yee Jr, Hal F (2003) Is weight reduction an effective therapy for nonalcoholic fatty liver? A systematic review. Am J Med 115:554-9 |