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The prevention of restenosis after percutaneous coronary intervention is a major task for researchers and clinicians in cardiovascular pharmacology. Nearly 1.5 million PTCA are performed every year worldwide and, due to the implantation of stents, most of the cases can be treated successfully. 60% of those patients develop restenosis within 6 months. SMC migration and ECM deposition are known to be responsible for neointima formation. Among many processes, integrin initiated signalling events play a central role in SMC migration. Many integrins recognize a specific RGD sequence which is present in several ECM proteins and cell surface immunoglobulin super family molecules. Until now, there are various integrin antagonists such as antibodies, cyclic peptides, peptidomimetics, and non-peptides have been shown to interfere with such pathological situations indicating the importance of integrin initiated signalling pathways in SMC migration. Therefore, in this study SMC migration induced by ECM proteins was inhibited either using pharmacological inhibitor or by overexpressing the endogenous inhibitor of FAK by AAV vector system. In the first part of the thesis, the effect of integrin-ligand stimulation on hCASMCs was studied. The tyrosine phosphorylation of many cellular proteins was observed from serum starved hCASMCs replated on VN but not on PL coated plates. The major tyrosine phosphorylated protein was identified as FAK by immunoprecipitation and also phosphorylation was found at Tyr 397, the autophosphorylation site of FAK. Further, VN induced the dose dependent migration of hCASMCs in haptotaxis assay. The integrin v inhibitor was used to block those ECM stimulated integrin signalling pathways and cell migration. It inhibited the ECM stimulated tyrosine phosphorylation in a dose dependent manner. Interestingly, specific potent antagonism of integrin v abrogated both ECM induced haptotaxis and growth factor induced chemotaxis. The inhibition of migration is consistent with the replating assay results that show interference with integrin induced signalling pathways particularly the FAK tyrosine phosphorylation. The integrin v inhibitor also is able to interfere with hCASMC invasion through matrigel by reducing MMP-2 secretion. Importantly, integrin v inhibitor did not induce the apoptosis in hCASMCs. FAK is a key player in many cellular events and its involvement in cell migration was extensively studied in various cell types. The present study explored the function of FAK in hCASMC migration by overexpression of FRNK, the C-terminal domain of FAK. Overexpression of FRNK inhibited the in vitro SMC migration as well as the neointima formation in a porcine restenosis model in vivo. The last part of this thesis focused on the identification of putative binding partners for the N-terminal domain of FAK by bacterial two-hybrid screen. One of the interesting binding partners was a putative protein of 17.9 kDa. Its human homolog is AGS4, which acts as a GTPase activator. The preliminary results revealed that it is able to interact with N-FAK domain and its expression is high in haematopoietic cells. Taken together the above results suggest that integrin v and FAK are promising targets for inhibition of SMC migration. Disruption of FAK-mediated signalling pathways by a pharmacological inhibitor or by overexpression of FRNK, which acts as dominant-negative regulator, resulted in decreased migration of SMCs and thus can lead to reduction of neointima formation.