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Abstract
Cardiovascular disease, which involves the cardiac, cerebrovascular and peripheral vascular system, is the major cause of morbidity and mortality in the western world. Changes in the vascular microenvironment trigger cascades of molecular events involving altered signaling, transcription and translation of a gene. The aim of this thesis was to increase our understanding on the molecular regulation of activated vascular smooth muscle cells. The first study looking at PDGF-D expression provides new insights into the regulatory mechanisms controlling the phosphorylation of Sp1. Studies performed identified three amino acids in Sp1 (Thr668, Ser670 and Thr681) that is phosphorylated by PKC-zeta activated by AngII. In the second study, the translational regulatory role of a novel gene YrdC induced by injury was investigated. Current knowledge of translational regulators controlling altered gene expression is little and studies in this thesis shows a splice variant of YrdC playing an important role in controlling mRNA translation and thus protein synthesis in the context of injury. The final study investigated in this study was the increased expression of the apoptotic FasL by the activation of GATA6. Although FasL has been extensively studied over the years, this is the first study linking a GATA factor with FasL in any cell type and provides key insights into the transcriptional events underpinning FasL-dependent SMC apoptosis following exposure to AngII.