Intrauterine food restriction impairs the lipogenesis process in the mesenteric adipocytes from low-birth-weight rats into adulthood.

Background: Intrauterine food restriction (IFR) during pregnancy is associated with low birth weight (LBW) and obesity in adulthood. It is known that white adipose tissue (WAT) plays critical metabolic and endocrine functions; however, this tissue's behavior before weight gain and obesity into adulthood is poorly studied. Thus, we evaluated the repercussions of IFR on the lipogenesis and lipolysis processes in the offspring and described the effects on WAT inflammatory cytokine production and secretion. Methods: We induced IFR by providing gestating rats with 50% of the necessary chow daily amount during all gestational periods. After birth, we monitored the offspring for 12 weeks. The capacity of isolated fat cells from mesenteric white adipose tissue (meWAT) to perform lipogenesis (14C-labeled glucose incorporation into lipids) and lipolysis (with or without isoproterenol) was assessed. The expression levels of genes linked to these processes were measured by real-time PCR. In parallel, Multiplex assays were conducted to analyze pro-inflammatory markers, such as IL-1, IL-6, and TNF-α, in the meWAT. Results: Twelve-week-old LBW rats presented elevated serum triacylglycerol (TAG) content and attenuated lipogenesis and lipolysis compared to control animals. Inflammatory cytokine levels were increased in the meWAT of LBW rats, evidenced by augmented secretion by adipocytes and upregulated gene and protein expression by the tissue. However, there were no significant alterations in the serum cytokines content from the LBW group. Additionally, liver weight, TAG content in the hepatocytes and serum glucocorticoid levels were increased in the LBW group. Conclusion: The results demonstrate that IFR throughout pregnancy yields LBW offspring characterized by inhibited lipogenesis and lipolysis and reduced meWAT lipid storage at 12 weeks. The increased serum TAG content may contribute to the augmented synthesis and secretion of pro-inflammatory markers detected in the LBW group.

Glucocorticoids contribute to metabolic and liver impairments induced by lactation overnutrition in male adult rats.

Introduction: Lactation overnutrition is a programming agent of energy metabolism, and litter size reduction leads to the early development of obesity, which persists until adulthood. Liver metabolism is disrupted by obesity, and increased levels of circulating glucocorticoids are pointed as a possible mediator for the obesity development, since bilateral adrenalectomy (ADX) can reduce obesity in different models of obesity. Methods: This study aimed to evaluate the effects of glucocorticoids on metabolic changes and liver lipogenesis and insulin pathway induced by lactation overnutrition. For this, on the postnatal day 3 (PND), 3 pups (small litter-SL) or 10 pups (normal litter-NL) were kept with each dam. On PND 60, male Wistar rats underwent bilateral adrenalectomy (ADX) or fictitious surgery (sham), and half of ADX animals received corticosterone (CORT- 25 mg/L) diluted in the drinking fluid. On PND 74, the animals were euthanized by decapitation for trunk blood collection, and liver dissection and storage. Results and Discussion: SL rats presented increased corticosterone, free fatty acids, total and LDL-cholesterol plasma levels, without changes in triglycerides (TG) and HDL-cholesterol. The SL group also showed increased content of liver TG, and expression of fatty acid synthase (FASN), but decreased expression of PI3Kp110 in the liver, compared to NL rats. In the SL group, the ADX decreased plasma levels of corticosterone, FFA, TG and HDL cholesterol, liver TG, and liver expression of FASN, and IRS2, compared to sham animals. In SL animals, CORT treatment increased plasma levels of TG and HDL cholesterol, liver TG, and expression of FASN, IRS1, and IRS2, compared with the ADX group. In summary, the ADX attenuated plasma and liver changes observed after lactation overnutrition, and CORT treatment could reverse most ADX-induced effects. Thus, increased circulating glucocorticoids are likely to play a pivotal role in liver and plasma impairments induced by lactation overnutrition in male rats.

Dexamethasone-Induced Adipose Tissue Redistribution and Metabolic Changes: Is Gene Expression the Main Factor? An Animal Model of Chronic Hypercortisolism.

Chronic hypercortisolism has been associated with the development of several metabolic alterations, mostly caused by the effects of chronic glucocorticoid (GC) exposure over gene expression. The metabolic changes can be partially explained by the GC actions on different adipose tissues (ATs), leading to central obesity. In this regard, we aimed to characterize an experimental model of iatrogenic hypercortisolism in rats with significant AT redistribution. Male Wistar rats were distributed into control (CT) and GC-treated, which received dexamethasone sodium phosphate (0.5 mg/kg/day) by an osmotic minipump, for 4 weeks. GC-treated rats reproduced several characteristics observed in human hypercortisolism/Cushing's syndrome, such as HPA axis inhibition, glucose intolerance, insulin resistance, dyslipidemia, hepatic lipid accumulation, and AT redistribution. There was an increase in the mesenteric (meWAT), perirenal (prWAT), and interscapular brown (BAT) ATs mass, but a reduction of the retroperitoneal (rpWAT) mass compared to CT rats. Overexpressed lipolytic and lipogenic gene profiles were observed in white adipose tissue (WAT) of GC rats as BAT dysfunction and whitening. The AT remodeling in response to GC excess showed more importance than the increase of AT mass per se, and it cannot be explained just by GC regulation of gene transcription.

Physiological concentrations of ß-hydroxybutyrate do not promote adipocyte browning.

AIMS: Previous work has demonstrated that ketogenic diets promote white fat browning; however, the exact mechanisms underlying this phenomenom have yet to be elucidated. Recently, an in vitro study showed that supraphysiological concentrations of ß-hydroxybutyrate (ßHB) had a strong influence on the induction of adipocyte browning. On the other hand, concentrations in the physiological range, achieved through ketogenic diets and prolonged fasting produce values of 1-3 mM and 4-7 mM, respectively. Herein, we investigated the impact of physiological concentrations of ßHB on metabolism, and the expression of uncoupling protein 1 (UCP1) and other browning markers in adipose tissues. MAIN METHODS: The effects of ßHB on adipocyte browning were investigated in vitro, using primary cultures of isolated visceral and subcutaneous fat cells and cultured 3T3-L1 adipocytes, and in vivo. KEY FINDINGS: It was determined that ßHB failed to induce changes in the oxidative capacity, citrate synthase activity or browning gene expression patterns in isolated adipocytes, and did not exert a permissive effect on ß-adrenergic agonist-induced browning. In addition, 3T3-L1 adipocytes differentiated following ßHB treatment exhibited downregulated Ucp1 expression levels, a result that was recapitulated in the subcutaneous adipose tissue of Wistar rats after ßHB salt treatment. Rats administered ßHB salts also presented reduced brown adipose tissue UCP1 protein expression. SIGNIFICANCE: The mechanisms underlying ketogenic diet-induced browning of adipocytes are not known. The results from the present study indicate that physiological concentrations of ßHB are not responsible for this phenomenon, despite the observed ßHB-mediated downregulation of UCP1 expression.

Chronic low-dose glucocorticoid treatment increases subcutaneous abdominal fat, but not visceral fat, of male Wistar rats.

AIM: Most studies developed to investigate the effects of glucocorticoids chronic treatment on white adipose tissue uses high doses of these hormones. This study analyzes some effects of a chronic, continuous and steady infusion of low-dose hydrocortisone and the relationship with lipid accumulation in white adipose depots in rats. MAIN METHODS: Nineteen male Wistar rats were divided into control (CON) and cortisol (CORT) groups. Along six weeks CORT group received continuous infusion of 0.6mg/kg/day of hydrocortisone, while CON group received saline. After euthanasia, subcutaneous and visceral (retroperitoneal and mesenteric) fat pads were excised, weighted and analyzed for: lipogenic enzymes activity; molecular changes of 11-hydroxysteroid dehydrogenase type 1 (11ßHSD1) enzyme; enzymes involved in lipid uptake, incorporation, and metabolism and in fatty acids esterification. Besides, morphometric cell analysis was performed. KEY FINDINGS: CORT group showed increased triglycerides, changes in lipoprotein profile and 26,8% increment in central subcutaneous (SC) mass, while visceral fat pads masses remained unchanged. Adipocytes from SC, only, presented increased fatty acid synthase, ATP-citrate lyase and glucose-6-phosphate dehydrogenase activity, in addition to reduced AMP-activated protein kinase and 11ßHSD1 enzymes content. SIGNIFICANCE: Chronic low-dose hydrocortisone treatment consequences seem to be different from those commonly seen in long term hypercortisolism. While high doses promote lipid accumulation in visceral depots, a low dose showed an increase in central SC depot only. This appears to involve an increment in lipid storage and in de novo lipogenesis enzymes activity.

Oral ß-hydroxybutyrate increases ketonemia, decreases visceral adipocyte volume and improves serum lipid profile in Wistar rats.

BACKGROUND: Ketosis can be induced in humans and in animals by fasting or dietary interventions, such as ketogenic diets. However, the increasing interest on the ketogenic state has motivated the development of alternative approaches to rapidly increase ketonemia using less drastic interventions. Here, it was tested whether oral intake of a ß-hydroxybutyrate (ßHB) mineral salt mixture could increase ketonemia in Wistar rats without any other dietary changes, thereby being a useful model to study ketones effects alone on metabolism. METHODS: ßHB salts were orally administered to provoke elevation in the ketonemia. Effects of this intervention were tested acutely (by gavage) and chronically (4 weeks in drinking water). Acutely, a concomitant glucose overload was used to suppress endogenous ketogenesis and verify whether ßHB salts were really absorbed or not. Long-term administration allowed to weekly evaluate the impact on ketonemia, blood glucose and, after 4 weeks, on body weight, visceral fat mass, lipid blood profile, serum lipolysis products and adiponectinemia. RESULTS: ßHB salts increased ketonemia in acute and long-term administrations, improved blood lipid profile by raising HDL-cholesterol concentration and decreasing LDL/HDL ratio, while reduced visceral adipocyte volume. Mean ketonemia correlated positively with HDLc and negatively with adipocyte volume and serum lipolysis products. CONCLUSIONS: Oral ßHB can rapidly increase ketonemia and, therefore, be used as an acute and long-term animal model of ketosis. Long-term treatment points to important beneficial effects of ketone bodies in serum lipid concentrations and visceral fat mass. These results may help to explain the metabolic adaptations following ketogenic diets, such as a better body fat control and a serum lipid profile improvement.