Cardiovascular diseases are the leading cause of death worldwide, with atherosclerosis as most common underlying pathology. Atherosclerosis is characterized by arterial narrowing due to cholesterol... Show moreCardiovascular diseases are the leading cause of death worldwide, with atherosclerosis as most common underlying pathology. Atherosclerosis is characterized by arterial narrowing due to cholesterol and lipid accumulation. Despite available effective cholesterol lowering medication, considerable risk for recurrent vascular events remains. This residual risk is at least in part explained by high blood lipid levels. The research described in this thesis revealed novel therapeutic strategies that improve lipid metabolism and reduce atherosclerosis development in mice. Inhibition of the endocannabinoid system was found to be an effective strategy, as well as concomitant activation of two incretin hormone receptors, namely those for GIP and GLP1. For combined GIP/GLP1 receptor agonism we additionally showed strongly attenuated hepatic steatosis. We were also able to identify additional targets to attenuate hyperlipidemia by studying the mechanisms underlying the strong day-night rhythm of brown adipose tissue, which is a lipid combusting tissue. In this thesis, I also stress the importance of the choice in animal model when studying lipid-modifying interventions, and describe the development of the software tool RandoMice which can be used to improve the quality of preclinical studies by creating well-balanced experimental groups. Show less
The brain is increasingly recognized as the regulator of body homeostasis and as possible treatment target for cardiovascular disease. This thesis further reveals the role of the autonomic nervous... Show moreThe brain is increasingly recognized as the regulator of body homeostasis and as possible treatment target for cardiovascular disease. This thesis further reveals the role of the autonomic nervous system (ANS) in the control of lipid metabolism and inflammation, and identified pathological consequences of disturbed regulation. Part I focuses on regulation of lipid metabolism by the ANS, with special attention for brown adipose tissue (BAT) as an emerging pharmacological target for therapy. We describe novel targets that modulate BAT, both directly (e.g. CB1R) and via the brain (e.g. MC4R, GLP-1R) to show that BAT activation improves dyslipidemia, glucose tolerance and T2D and even atherosclerosis. In addition, we identified the biological clock as an important regulator of BAT function and showed the consequences of disturbed circadian rhythmicity for lipid metabolism. Part II of this thesis describes studies on the regulation of inflammation by the ANS, with focus on the anti-inflammatory reflex. During this reflex, binding of acetylcholine to _7nAChR and subsequent intracellular signaling results in transcriptional repression of pro-inflammatory genes. We investigated the effects of hematopoietic _7nAChR deficiency and the consequences of selective parasympathetic and sympathetic denervation of the spleen for this reflex, and for inflammation and atherosclerotic plaque development. Show less