Subcutaneous lipectomy causes a metabolic syndrome in hamsters.

The insulin resistance syndrome X is related to excess intra-abdominal adipose tissue. With lipectomy of >50% of subcutaneous adipose tissue (SQAT) in nonhibernating, adult female Syrian hamsters on high-fat (HF; 50 calorie%) diet and measurements of oral glucose tolerance, oral [(14)C]oleic acid disposal, serum triglycerides, serum leptin, liver fat, perirenal (PR) adipose tissue cellularity, and body composition, we studied the role of SQAT. Sham-operated (S) animals on HF or low-fat (LF; 12.5 calorie%) diets served as controls. After 3 mo there was no visible regrowth of SQAT but HF diet led to similar levels of body weight and body fat in lipectomized and sham-operated animals. Lipectomized (L) animals had more intra-abdominal fat as a percentage of total body fat, higher insulinemic index, a strong trend toward increased liver fat content, and markedly elevated serum triglycerides compared with S-HF and S-LF. Liver and PR adipose tissue uptake of fatty acid were similar in L-HF and S-HF but reduced vs. S-LF, and were inversely correlated with liver fat content and insulin sums during the oral glucose tolerance test. In summary, lipectomy of SQAT led to compensatory fat accumulation implying regulation of total body fat mass. In conjunction with HF diet these lipectomized hamsters developed a metabolic syndrome with significant hypertriglyceridemia, relative increase in intra-abdominal fat, and insulin resistance. We propose that SQAT, via disposal and storage of excess ingested energy, acts as a metabolic sink and protects against the metabolic syndrome of obesity.

Obesity potentiates AOM-induced colon cancer.

Obesity and diet affect the incidence and severity of various types of cancer, including colon cancer. It is not known whether obesity, independent of diet, is a risk factor for colon adenocarcinoma. We used azoxymethane (AOM) to induce colon cancer in mature genetically obese male Zucker rats (fa/fa) on low-fat crude diet (LFC, 10% fat) and their lean counterparts (Fa/fa and Fa/fa) on high-fat crude diet (HFC, 40% fat) for three months. At death visible tumors, histopathology, and colonic aberrant crypt (AC) formation were studied by blinded investigators. At death the obese animals were heavier (719 +/- 19 g; mean +/- SEM) than lean animals regardless of diet or genotype (Fa/fa-LFC:451 = 6 g; Fa/fa-HFC:441 +/-10 g; Fa/Fa-HFC:412 +/- 9 g; P < 0.001 vs fa/fa by ANOVA). All AOM-treated rats developed AC, compared to none of the saline-injected controls. Macroscopic adenocarcinoma developed in 8/9 obese rats on LFC (P < 0.001), compared to none in lean rats regardless of diet. Obese rats had significantly more AC (876 +/- 116) than any of the lean rats (Fa/fa-LFC:550 +/- 99; Fa/fa-HFC:325 +/- 37; Fa/Fa-HFC:360 +/- 36; P < 0.05 vs fa/fa). We conclude that obesity more than exposure to high-fat diet was associated with colon carcinogenesis in these rats.

Identification of estrogen receptor beta RNA in human breast and abdominal subcutaneous adipose tissue.

This study reports the initial observation of the novel estrogen receptor, ER beta, in human subcutaneous adipose tissue. Human adipose tissue was obtained from various anatomic sites including the subcutaneous depots of lipectomy patients (healthy controls), and from subcutaneous abdominal and breast depots of lean and obese women with breast cancer. ER beta mRNA expression, determined by reverse transcription and polymerase chain reaction (RT-PCR), was present in each adipose tissue sample examined. Cloning and sequencing of the PCR product confirmed its identity as ER beta. Separation of adipose tissue into component fractions indicated that ER beta was expressed in both adipocytes and the stroma-vasculature. Primary culture of human preadipocytes indicated that ER beta mRNA was present only after differentiation to the adipocyte phenotype. This novel observation of ER beta mRNA indicates that this receptor subtype may have a role in ER-mediated responses in human adipose tissue.