Within this thesis, several diseases central in the field of cardiovascular disease will be outlined. First, the central dogma of molecular biology, RNA biology in general, RNA (alternative... Show moreWithin this thesis, several diseases central in the field of cardiovascular disease will be outlined. First, the central dogma of molecular biology, RNA biology in general, RNA (alternative)splicing and the role of RNA-binding proteins within these processes will be discussed to enhance the accessibility to non-molecular biologists. Subsequently, the current literature and insights into the RNA-binding protein Quaking will be outlined. Thereafter, a brief summary of the role of many distinct RNA-binding proteins (RBPs) in the cardiovascular system is provided, detailing their importance in the heart and cells of the blood vessels. This review provides some historical and biological perspectives, while simultaneously highlighting many recent advances in our understanding of RBP function in cardiovascular health and disease. By harnessing established and novel techniques, including RNA-sequencing, this thesis will describe the role of Quaking in vascular stenosis, atherosclerosis, inflammation and endothelial barrier function. Collectively, Quaking can be described as a genome-wide governor of RNA-processing that results in the proper translation into functional proteins. This thesis describes which RNA transcripts are under control of Quaking, which alternative transcripts are being generated through modulation by Quaking, while also describing the unique role for this protein in health and cardiovascular and renal disease. Show less
Blood-flow-induced shear stress plays an important role in cardiovascular development and disease. How endothelial cells sense shear stress remains to be elucidated. We postulated that the primary... Show moreBlood-flow-induced shear stress plays an important role in cardiovascular development and disease. How endothelial cells sense shear stress remains to be elucidated. We postulated that the primary cilium is a component of the endothelial shear sensor. This luminal cell protrusion contains microtubules and is connected to the microtubular cytoskeleton. We identified cilia on endothelial cells of the embryonic heart in areas of low or oscillatory shear stress. This shear-related distribution is reminiscent of the distribution of atherosclerotic lesions in the adult arterial system, as lesions develop at sites of low or oscillating shear (athero-prone flow). Ciliated endothelial cells are exclusively present at these atherosclerotic predilection sites in adult mice. Athero-prone (oscillatory) but not athero-protective (steady or pulsatile) flow induces ciliation of cultured endothelial cells. Moreover, the endothelial shear response is dependent on the microtubular cytoskeleton and primary cilia sensitise the endothelium for shear. Taken together, these data demonstrate that primary cilia are induced by athero-prone flow and that ciliated cells are more sensitive to shear stress. We conclude that the endothelial biosensor for shear stress is the microtubular cytoskeleton and that the attached primary cilium functions as a signal amplifier in areas subjected to athero-prone flow. Show less
