Scavenger receptor BI (SR-BI) has been suggested to modulate adipocyte function. To uncover the potential relevance of SR-BI for the development of obesity and associated metabolic complications,... Show moreScavenger receptor BI (SR-BI) has been suggested to modulate adipocyte function. To uncover the potential relevance of SR-BI for the development of obesity and associated metabolic complications, we compared the metabolic phenotype of wild-type and SR-BI deficient mice fed an obesogenic diet enriched in fat. Both male and female SR-BI knockout mice gained significantly more weight as compared to their wild-type counterparts in response to 12 weeks high fat diet feeding (1.5-fold; P < .01 for genotype). Plasma free cholesterol levels were ~2-fold higher (P < .001) in SR-BI knockout mice of both genders, whilst plasma cholesteryl ester and triglyceride concentrations were only significantly elevated in males. Strikingly, the exacerbated obesity in SR-BI knockout mice was paralleled by a better glucose handling. In contrast, only SR-BI knockout mice developed atherosclerotic lesions in the aortic root, with a higher predisposition in females. Biochemical and histological studies in male mice revealed that SR-BI deficiency was associated with a reduced hepatic steatosis degree as evident from the 29% lower (P < .05) liver triglyceride levels. Relative mRNA expression levels of the glucose uptake transporter GLUT4 were increased (+47%; P < .05), whilst expression levels of the metabolic PPARgamma target genes CD36, HSL, ADIPOQ and ATGL were reduced 39%-58% (P < .01) in the context of unchanged PPARgamma expression levels in SR-BI knockout gonadal white adipose tissue. In conclusion, we have shown that SR-BI deficiency is associated with a decrease in adipocyte PPARgamma activity and a concomitant uncoupling of obesity development from hepatic steatosis and glucose intolerance development in high fat diet-fed mice. Show less
Metabolic disease has become pandemic in the developed world. Given our lack of understanding of its molecular pathology, we are often unable to diagnose patients before they reach an... Show moreMetabolic disease has become pandemic in the developed world. Given our lack of understanding of its molecular pathology, we are often unable to diagnose patients before they reach an irreversible state of diabetes or cardiovascular disease. Much research has been done on the role of insulin signaling in metabolic disease, as well as the resultant disturbed lipid homeostasis present in cardiovascular disease and atherosclerosis. Here we add to existing work by developing new tools and sketching out the pathology of dysregulated adipose insulin signaling. We discuss the mechanism of lipodystrophy by using adipocytes differentiated from patient-derived iPSCs. These cells mimic the clinical phenotype and hint at mechanism that reduced patients’ adipose tissue mass. In mice we find that if we knock out the adipose insulin receptor, there is disrupted adipose and liver metabolism. There is a protection from diet-induced obesity, but a dramatically reduced lifespan. We also establish a relationship between obesity and inflammation by transcriptomically assessing obese human adipocytes. We find that an immune factor is responsible for lipid droplet formation and content. Lastly, we develop a new differentiation and purification strategy for iPSC-derived hepatocytes, which we employ to in vitro model a SNP that protects against cardiovascular disease. Show less