Insulin resistance (IR) is a major contributor to obesity-related morbidities such as diabetes and cardiovascular disease. While obesity is associated with IR, the biological basis for this association is unclear, and not all obese individuals are IR. The once-popular portal hypothesis, which states that lipolysis from VAT in particular accounts for IR, has been questioned because VAT contributes only 15% of the total systemic free fatty acid (FFA) flux. Other proposed mechanisms linking obesity to IR include inflammation, adiponectin, and ectopic fat. It is unclear whether VAT mass is more closely linked to IR than is subcutaneous adipose tissue (SAT) mass. Furthermore, evidence linking differential biological activity to IR in VAT or SAT is indirect, largely derived from studies comparing lean to obese or VAT to SAT without evaluation of IR. Thus, the purpose of this study is to investigate the biological mechanisms by which SAT and/or VAT contribute to IR. Specifically, we will explore two related hypotheses- that impaired adipocyte differentiation in SAT is related to IR, ectopic fat deposition and expansion of VAT depot, and that inflammation in VAT is associated with IR. Utilizing adipose cell size/distribution obtained by Beckman Coulter Multisizer, gene expression via quantitative PCR, in-vivo quantification of IR via a modified insulin suppression test, and imaging of intramyocellular, intraabdominal and intrahepatic fat, our specific aims are to: 1) Confirm that impairment of adipocyte differentiation in SAT is associated with IR by comparing cell size characteristics and differentiation markers in IR and IS subjects undergoing elective surgery;2) Test the hypothesis that the same relationship will not be seen in VAT;3) Demonstrate that VAT mass is expanded in the presence of impaired differentiation of adipocytes in SAT;4) Demonstrate that intramuscular fat is related to both IR and impaired differentiation of adipocytes in SAT using cell size characteristics and differentiation markers;5) Demonstrate that increased inflammation in omental fat is associated with IR independent of obesity using inflammation markers (gene and protein). Supportive data for #1,3,4 above will be derived from pioglitazone vs placebo administration to 20-23 IR individuals for 16 weeks, with hypothesized improvement in adipose cell differentiation/fat storage and associated reduction in ectopic and visceral fat with improved insulin sensitivity.
The prevalence of obesity continues to rise in the United States and worldwide, bringing with it associated complications of type 2 diabetes and cardiovascular disease. Insulin resistance (IR) is associated with increasing body mass index (1), and is likely to account for the majority of these complications (2). Not all obese individuals are IR, however (3,4), and there exist sufficient data to justify investigating biological characteristics of adipose tissue that might explain the development of obesity- associated IR in select individuals: 1) weight gain/loss and drugs targeting fat cells (thiazolidinediones) have the ability to alter insulin sensitivity (5,6);2) lipodystrophy models in humans and animals are associated with altered deposition of fat and IR (7-9);3) fat deposition in the abdominal cavity, liver, and skeletal muscle is associated with IR (10);4) inflammatory activity in adipose tissue is higher in obese vs lean individuals (11), suggesting a possible link with IR;5) adipose tissue produces hormones such as adiponectin (12), that may protect individuals from IR. By comparing biological properties of subcutaneous and visceral adipose tissue from obese individuals who are IR vs insulin sensitive, we will explore the hypothesis that impaired differentiation/maturation of adipose cells in subcutaneous fat, and inflammation in visceral fat contributes to IR in the setting of human obesity.
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