Doctoral Degrees (Medical Physiology)

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Browsing Doctoral Degrees (Medical Physiology) by Author "Genis, Amanda"

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    Exposure of cardiac microvascular endothelial cells to harmful stimuli : a study of the cellular responses and mechanisms
    (Stellenbosch : Stellenbosch University, 2014-04) Genis, Amanda; Strijdom, Hans; Huisamen, Barbara; Stellenbosch University. Faculty of Medicine and Health Sciences. Dept. of Biomedical Sciences. Division of Medical Physiology.
    ENGLISH ABSTRACT: Exposure to harmful stimuli can render vascular endothelial cells dysfunctional, characterised by reduced nitric oxide (NO) bioavailibility. Endothelial dysfunction (ED) is a reversible precursor of ischaemic heart disease (IHD), and understanding the mechanisms underlying the development of ED could lead to clinical strategies in preventing/treating IHD. Very little is known about the responses of cardiac microvascular endothelial cells (CMECs) to pro-ED stimuli, as most studies are conducted on macrovascular endothelial cells. The current dissertation set out to comprehensively investigate the responses of cultured primary adult rat CMECs to known harmful stimuli, viz. hypoxia and tumor necrosis factor-alpha (TNF-α; proinflammatory cytokine). We were interested to investigate whether this distinct endothelial cell type would develop classical features of ED, and if so, what the underlying mechanisms were. First we aimed to establish a baseline characterization of the CMECs under control conditions. Next, we developed a model of hypoxia-induced cell injury and measured apoptosis/necrosis, intracellular NO and reactive oxygen species (ROS), expression and activation of signalling proteins involved with NObiosynthesis, hypoxia and apoptosis, and differential regulation of proteins. Finally, we characterised CMEC responses to treatment with TNF-α. We assessed apoptosis/necrosis, intracellular NO and ROS levels, NO-biosynthesis pathway proteins and large-scale differential protein regulation. The above measurements were performed by morphological assessment (light and fluorescence microscopy), FACS analysis, western blotting and large-scale proteomic analyses. Data showed that CMECs shared many baseline features with other endothelial cell types, including morphological appearance, LDL-uptake, NO-production, and expression of eNOS protein. In a novel observation, proteomic analysis revealed the expression of 1387 proteins. Another novel finding was the high abundance of structural mitochondrial proteins, suggesting that CMECs require mitochondria for non-respiration purposes as well. High expression of vesicle, glycolytic and RAS signalling proteins were other features of the baseline CMECs. CMECs exposed to hypoxia responded by increased apoptosis/necrosis and expression of the hypoxia-marker, HIF-1α. Interestingly, hypoxic CMECs showed increased eNOS-NO biosynthesis, associated with increased mitochondrial ROS and reduced anti-oxidant systems, suggestive of oxidative stress. In accordance with the literature, several glycolytic proteins were up-regulated. A novel finding was the up-regulation of proteins involved with protein synthesis, not usually described in hypoxic cell studies. The CMECs responded to TNF-α-treatment by exhibiting hallmarks of ED, namely attenuated biosynthesis of PKB/Akt-eNOSderived NO and the development of outspoken response to oxidative stress as indicated by the up-regulation of several anti-oxidant systems. The data showed that TNF-α treatment elicited classical TNF-Receptor 1-mediated signalling characterized by the dual activation of pro-apoptotic pathways (BID and caspase-3) as well as the protective, pro-inflammatory IKB-alpha–NF-KB pathway. In conclusion, this is the first study of its kind to describe a comprehensive characterisation of CMECs under baseline and injury-inducing conditions. On the whole, although it appeared as if the CMECs shared many responses and mechanisms with more frequently researched endothelial cell types, the data also supplied several novel additions to the literature, particularly with the application of proteomics. We believe that this dissertation has provided more insights into endothelial heterogeneity in the vascular system and into the mechanisms adopted by CMECs when exposed to stimuli typically associated with cardiovascular risk.