Expansion of visceral adipose tissue correlates with the metabolic syndrome and increased cardiovascular risk. Hypertrophied visceral fat becomes inflamed, causing increased lipolysis, decreased triglyceride storage, and lipotoxicity in skeletal muscle and liver resulting in insulin resistance. Perivascular adipose tissue is a normal component of the adventitia of arteries in humans and animals. Whether or not perivascular adipose also becomes inflamed in obesity is an important question, as this may be an additional, direct mechanism by which obesity causes vascular inflammation and disease.
Thus, for the first part of my thesis, we asked the question: does perivascular adipose in mice become inflamed with high fat feeding? In contrast to visceral adipose, macrophage gene expression was not increased in perivascular adipose in response to high fat diet, and this correlated with reduced F480 antigen positive cells as seen by immunohistochemistry and flow cytometry. Interestingly, perivascular adipose surrounding the thoracic aorta was similar to brown adipose tissue, a highly thermogenic fat depot, as shown by histology and DNA microarrays. Moreover, inter-scapular brown adipose was also resistant to diet induced inflammation in comparison to visceral adipose. These findings suggest that brown adipose in the perivascular niche may serve to protect the vasculature from diet induced inflammation, or from cold exposure, or both; whether or not brown perivascular adipose tissue exists in humans has yet to be determined.
In the second part of my thesis, we evaluated the role of perivascular adipose tissue in the apolipoprotein E knockout mouse, which exhibits severe hyperlipidemia and atherosclerosis, but is resistant to diet induced obesity and glucose intolerance. We tested the hypothesis that in this model of severe atherosclerosis, inflammation of perivascular adipose does occur. However, we were surprised to find that macrophage specific gene expression, as determined by either microarray analysis or quantitative polymerase chain reaction, was not increased in either the perivascular or the visceral adipose of high fat diet fed apolipoprotein E knockout mice. While the visceral adipose of wild type mice had extensive alterations in gene expression in response to high fat diet, in particular, enrichment of inflammatory gene expression and broad down regulation of peroxisome proliferator activated receptor gamma target genes, apolipoprotein E knockout visceral adipose did not. Importantly, the apolipoprotein E knockout visceral adipose instead showed increased expression of genes encoding enzymes in fatty acid oxidation pathways. High fat diet fed apolipoprotein E knockout visceral adipose was also characterized by smaller adipocyte size.
We conclude that, 1) inflammation in thoracic perivascular adipose does not occur in conjunction with diet induced obesity in normal animals nor with atherosclerosis in apolipoprotein E knockout mice, 2) thoracic perivascular adipose tissue is essentially identical to brown adipose tissue in mice, thus potentially protecting the vasculature from the cold, and 3) apolipoprotein E knockout mice remain lean on a high fat diet, despite hyperlipidemia and atherosclerosis, and the decreased adiposity correlates with decreased adipocyte size and adipose inflammation but increased oxidation of fatty acids. Consistent with previous work showing apolipoprotein E controls adipocyte uptake and deposition of triglyceride, its absence prevents adipocyte hypertrophy and resultant inflammation of visceral adipose tissue. Thus limiting adipocyte acquisition of fatty acids may be advantageous, provided that compensatory mechanisms to prevent sustained hyperlipidemia and peripheral organ lipotoxicity can be activated
