Cardiovascular disease (CVD) is a major cause of mortality and morbidity in the Western world. CVD is mainly caused by atherosclerosis, for which dyslipidemia, characterized by high a plasma level... Show moreCardiovascular disease (CVD) is a major cause of mortality and morbidity in the Western world. CVD is mainly caused by atherosclerosis, for which dyslipidemia, characterized by high a plasma level of (very) low density lipoprotein ((V)LDL) and a low plasma level of high density lipoprotein (HDL), is a major risk factor. To reduce the risk to develop CVD, drugs aimed at correcting dyslipidemia by lowering (V)LDL are currently the first choice of treatment. Albeit that these drugs lower (V)LDL-C very efficiently (up to ~40%), and generally result in a slight increase in HDL-C, they only prevent a fraction of all cardiovascular events (~30%). Therefore new therapeutic strategies to reduce cardiovascular events more efficiently are necessary. Since HDL is has been attributed multiple protective effects in atherosclerosis by its role in reverse cholesterol transport and its anti-inflammatory and anti-oxidative properties, HDL-raising therapy is currently considered as a promising strategy to further reduce CVD risk. In this thesis, the mechanisms underlying the HDL-raising effects of the classical lipid-lowering drugs fenofibrate, atorvastatin and niacin were elucidated. Furthermore, the effects of potential novel HDL-raising strategies, including torcetrapib, PXR agonism and apoCI, on HDL metabolism were addressed. For these studies, we used the APOE*3-Leiden.CETP (E3L.CETP) transgenic mouse, a valuable model for human-like lipoprotein metabolism Show less
The main cause of cardiovascular disease (CVD) is atherosclerosis. Several genes that affect atherosclerosis development have been identified by the use of genetically modified mice (i.e.... Show moreThe main cause of cardiovascular disease (CVD) is atherosclerosis. Several genes that affect atherosclerosis development have been identified by the use of genetically modified mice (i.e. transgenic and knock-out mouse models). Many of these genes exert their role in atherosclerosis development as a result of effects on lipoprotein metabolism and inflammation. Transgenic mouse models have also been proven to be suitable for evaluating the mechanisms underlying the anti-atherosclerotic action of experimental drugs aimed to reduce atherogenic lipoprotein levels. However, thus far no suitable animal model was present to evaluate the mechanism of action of anti-atherosclerotic effect of HDL-raising therapeutic strategies. In this thesis, we further explored the role of apolipoprotein CI (apoCI) and cholesteryl ester transfer protein (CETP) in lipoprotein metabolism, inflammation, and atherosclerosis. Furthermore, we developed a mouse model that will be suitable for testing potential high-density-lipoprotein (HDL) raising therapies as a novel strategy to treat CVD. Show less
The research described in this thesis focussed on the role of apolipoproteins in lipid metabolism, inflammation and bacterial sepsis, with specific emphasis on apoCI. From studies in human APOC1_... Show moreThe research described in this thesis focussed on the role of apolipoproteins in lipid metabolism, inflammation and bacterial sepsis, with specific emphasis on apoCI. From studies in human APOC1_-transgenic and apoc1-/- mice, we were able to identify apoCI as a potent inhibitor of triglyceride hydrolysis by inhibiting lipoprotein lipase. Since APOC1 mice have thus increased VLDL levels, and VLDL protects against bacterial infection, we studied whether apoCI could play a role in inflammation and infection. We found that apoCI was able to bind lipopolysaccharide (LPS), the main toxic component of Gram-negative bacteria. Interestingly, although other apolipoproteins which have been studied have anti-inflammatory properties, we found that apoCI is a pro-inflammatory protein. By enhancing the biological response towards LPS and Gram-negative bacteria, apoCI dose-dependently improved the anti-bacterial attack, and protected against intrapulmonal Klebsiella pneumoniae-induced sepsis. Consistent with these experimental findings we also found that subjects with high plasma apoCI levels were less prone to infection-related mortality during follow-up, independent of plasma lipid levels. Likewise, survivors of severe sepsis showed higher plasma apoCI levels as compared to non-survivors, again independent of lipid levels. Taken together, our findings indicate that apoCI is an important determinant of the inflammatory response in mice and humans. Show less
