leptin and retinol-palmitate

We studied β-carotene (BC) absorption and metabolism and compared BC and retinyl palmitate (RE) for their impact on white adipose tissue (WAT) development in suckling rats.. Rat pups received daily orally from days 1-20 of life either the vehicle or vitamin A (approx. ×3 that ingested daily from maternal milk) in the form of BC or RE. Intact BC was found in serum and liver of BC-supplemented rats. Both BC and RE supplementation increased retinoic acid mediated transcriptional responses in intestine (on Isx and Bco1) and the liver (on Cyp26a1 and Cpt1a). In contrast, responses in WAT were dependent on the vitamin A source: WAT of BC-supplemented rats, like WAT of control rats, was enriched in larger adipocytes with increased adipogenic markers (peroxisome proliferator-activated receptor γ and downstream genes) and reduced markers of proliferative status (proliferating cell nuclear antigen) compared to WAT of RE-supplemented rats.. BC is partly absorbed intact by suckling rats, which resembles the situation in humans and suggests that suckling rats may be an appropriate animal model to study BC uptake, metabolism and biological activity, particularly in infants. Vitamin A supplementation with BC or RE in early life differentially affects WAT and may thus entail different outcomes regarding adiposity programming.

Topics: Adiponectin; Adipose Tissue, White; Administration, Oral; Animals; beta Carotene; Blood Glucose; Cell Proliferation; Diterpenes; Female; Insulin; Intestinal Mucosa; Intestines; Leptin; Liver; Male; PPAR gamma; Rats; Rats, Wistar; Retinyl Esters; Tretinoin; Vitamin A

Although there are changes in the postprandial lipid responses of obese patients, these are closely associated with high fasting triglycerides (TG). This study of 17 normotriglyceridemic, normoglucose-tolerant android obese subjects (body mass index, BMI = 34.3 +/- 3.1 kg/m2) and 33 normal-weight controls (BMI = 21.8 +/- 1.6 kg/m2) was done to examine their postprandial responses to an oral fat loading test containing retinol (890 calories, 85% fat) and to evaluate the possible association between clinical and biological features of obesity and/or insulin resistance and postprandial lipemia.. Blood samples were taken before giving the fat load and at 2,3,4,5,6 and 8 h after it. Insulin sensitivity was assessed using HOMA, and TG and retinyl palmitate (RP) in the plasma, chylomicrons and non-chylomicron fractions were measured each time.. The areas under the curves (AUC) of chylomicron TG for the obese and controls were not different, indicating adequate lipolytic activity. By contrast, the AUC for non-chylomicron TG was significantly greater in the obese than in the controls (512 +/- 135 vs 429 +/- 141 mmol/lmin, P < 0.01). In addition, the AUC for RP in this same fraction was significantly lower in the obese than in the controls (103 +/- 55 vs 157 +/- 88 mg/l min, P < 0.05), suggesting that the TG from endogenous lipoproteins accounted for most of the increase in TG in the non chylomicron fraction. Parameters related to obesity showed no relationship with these postprandial abnormalities, whereas HOMA, which discriminated between the groups, partly explained (r2= 23%, P < 0.01) the significant increase in non-chylomicron TG.. Android obese patients with a fasting TG in the normal range and not different from the fasting TG of lean controls had an abnormal postprandial lipemia response, indicated by a significantly greater TG in the non-chylomicron subfraction than in controls. These alterations may be partly due to postprandial changes in endogenous lipoproteins as a consequence of insulin resistance.

Topics: Adult; Area Under Curve; Blood Glucose; Case-Control Studies; Diterpenes; Eating; Fatty Acids, Nonesterified; Female; Glucose Tolerance Test; Humans; Insulin; Insulin Resistance; Leptin; Lipids; Male; Middle Aged; Obesity; Postprandial Period; Regression Analysis; Retinyl Esters; Triglycerides; Vitamin A

Postprandial hyperlipidemia is frequently accompanied with intra-abdominal visceral accumulation in human subjects. We have found that the decreased lipoprotein lipase (LPL) mass and activity is negatively associated with the amount of visceral fat accumulation. Here, we studied the postprandial hyperlipidemia using the OLETF rat, a model with visceral obesity, in order to clarify the molecular mechanism causing postprandial hyperlipidemia accompanied with visceral obesity. At the same age of 32 weeks, the OLETF rats showed obviously higher plasma leptin, total cholesterol, triglyceride, and HDL-cholesterol levels than the control LETO rats, although the plasma glucose level was not significantly different. Fat-loading test revealed the delayed metabolism of exogenous fat in the OLETF rats compared to the LETO rats, similar to human subjects with visceral obesity. In the obese rats, plasma levels of LPL mass and activities were 60 and 49% of control rats. The expression of LPL gene was decreased in subcutaneous adipose tissues and skeletal muscle of OLETF rats to 40 and 52% compared to those of LETO rats. In OLETF rats, plasma tumor necrosis factor-alpha (TNF-alpha) and insulin levels were increased to 2.0- and 2.3-folds compared to those in control rats. Furthermore, plasma insulin and TNF-alpha levels in OLETF rats were negatively correlated with the expression levels of LPL gene in subcutaneous fat and muscle. These results indicate that decreased LPL mass and activity in the animal model with visceral obesity is possibly caused by decreased expression of LPL gene in tissues mediated by the increased levels of insulin and TNF-alpha. The different expression of LPL gene in tissues associated with the increased levels of insulin and TNF-alpha possibly elucidate the underlying mechanisms involving the postprandial hyperlipidemia observed in visceral obesity.

Topics: Adipose Tissue; Animals; Blood Glucose; Blotting, Northern; Body Weight; Cholesterol; Cholesterol, HDL; Cloning, Molecular; Disease Models, Animal; Diterpenes; Humans; Hyperlipidemias; Insulin; Leptin; Lipoprotein Lipase; Male; Muscle, Skeletal; Obesity; Rats; Rats, Long-Evans; Retinyl Esters; RNA, Messenger; Time Factors; Tissue Distribution; Triglycerides; Tumor Necrosis Factor-alpha; Vitamin A