Downregulation of uncoupling protein 2 mRNA in women treated with glucocorticoids.

OBJECTIVE: Glucocorticoids are well-known regulators of energy turnover and adipose tissue metabolism. We investigated the effect of glucocorticoids on the expression of the human uncoupling protein 2 (UCP 2) gene, which has been implicated in energy expenditure. DESIGN: Prednisolone (25 mg) was administered orally daily for 7 days. Subcutaneous adipose tissue UCP 2 mRNA was measured before and after treatment. SUBJECTS: Eight healthy female subjects (age 52-63 y; body mass index 25-34 kg/m2). RESULTS: No differences in body weight, waist-to-hip ratio or plasma-values of FFA or glucose were found after prednisolone treatment, as compared to pre-treatment values under these conditions. In contrast, plasma insulin levels were significantly increased by glucocorticoid administration, 54+/-6 before vs 70+/-12 (mean+/-sem) pmol/l after treatment (P=0.028). Furthermore, using RT-competitive-PCR, the UCP 2 mRNA level in abdominal subcutaneous adipose tissue was found to be down-regulated by half (6.3+/-0.4 vs 3.1+/-0.8 amol/microg RNA, P=0.012) after glucocorticoid treatment. No difference in expression levels of the reference gene 18SrRNA was observed before, as compared to after prednisolone exposure (249+/-11 vs 248+/-30 amol/microg RNA, P=0.87). CONCLUSION: These data suggest that glucocorticoids may play a role in the regulation of UCP 2 mRNA expression in human adipose tissue in vivo.     

Evidence for a compensated thermogenic defect in transgenic mice lacking the mitochondrial glycerol-3-phosphate dehydrogenase gene

A role for mitochondrial glycerol-3-phosphate dehydrogenase (mGPD) in thermogenesis was investigated in transgenic mice lacking the mGPD gene (mGPD-/-). Reared and studied at 22 C, these mice have a small, but significant, reduction (7-10%) in energy expenditure, as evidenced by oxygen consumption (QO2) and food intake, and show signs of increased brown adipose tissue (BAT) stimulation, higher plasma T4 and T3 concentrations, as well as increased uncoupling protein 3 (UCP3) expression in muscle. When acclimated at thermoneutrality temperature (32 C), QO2 decreased in both genotypes, but the difference between them widened to 16%, whereas BAT underwent atrophy, and plasma T4 and T3 levels and UCP3 mRNA decreased, yet T3 and UCP3 persisted at significantly higher levels in mGPD-/- mice. Such differences disappeared when the mice were rendered hypothyroid. A compensatory role for the observed changes in BAT, thyroid hormone levels, and UCP3 was investigated with a 2-h cold challenge of 12 C in euthyroid and hypothyroid mice. No hypothermia ensued if the mice had been acclimated at 22 C, but when acclimated at 32 C, euthyroid mGPD-/- mice became significantly more hypothermic than the wild-type controls. When rendered hypothyroid, this difference was accentuated, and the mGPD-/- mice developed profound hypothermia ( approximately 28 vs. 34 C in wild-type mice; P < 0.001). Thus, mGPD-deficient mice have, despite increased plasma T4 and T3, a small, but distinct, reduction in obligatory thermogenesis, which is compensated by increased BAT facultative thermogenesis and by thyroid hormone-dependent mechanisms using other proteins, possibly UCP3. The results support a role for mGPD in thyroid hormone thermogenesis.     

Changes in FAT/CD36, UCP2, UCP3 and GLUT4 gene expression during lipid infusion in rat skeletal and heart muscle

OBJECTIVE: It has been reported that an increased availability of free fatty acids (NEFA) not only interferes with glucose utilization in insulin-dependent tissues, but may also result in an uncoupling effect of heart metabolism. We aimed therefore to investigate the effect of an increased availability of NEFA on gene expression of proteins involved in transmembrane fatty acid (FAT/CD36) and glucose (GLUT4) transport and of the uncoupling proteins UCP2 and 3 at the heart and skeletal muscle level. STUDY DESIGN: Euglycemic hyperinsulinemic clamp was performed after 24 h Intralipid(R) plus heparin or saline infusion in lean Zucker rats. Skeletal and heart muscle glucose utilization was calculated by 2-deoxy-[1-(3)H]-D-glucose technique. Quantification of FAT/CD36, GLUT4, UCP2 and UCP3 mRNAs was obtained by Northern blot analysis or RT-PCR. RESULTS: In Intralipid(R) plus heparin infused animals a significant decrease in insulin-mediated glucose uptake was observed both in the heart (22.62+/-2.04 vs 10.37+/-2.33 ng/mg/min; P<0.01) and in soleus muscle (13.46+/-1.53 vs 6.84+/-2.58 ng/mg/min; P<0.05). FAT/CD36 mRNA was significantly increased in skeletal muscle tissue (+117.4+/-16.3%, P<0.05), while no differences were found at the heart level in respect to saline infused rats. A clear decrease of GLUT4 mRNA was observed in both tissues. The 24 h infusion of fat emulsion resulted in a clear enhancement of UCP2 and UCP3 mRNA levels in the heart (99.5+/-15.3 and 80+/-4%) and in the skeletal muscle (291.5+/-24.7 and 146.9+/-12.7%). CONCLUSIONS: As a result of the increased availability of NEFA, FAT/CD36 gene expression increases in skeletal muscle, but not at the heart level. The augmented lipid fuel supply is responsible for the depression of insulin-mediated glucose transport and for the increase of UCP2 and 3 gene expression in both skeletal and heart muscle.     

The effect of weight reduction on skeletal muscle UCP2 and UCP3 mRNA expression and UCP3 protein content in Type II diabetic subjects

Aims/hypothesis. The aim of this study was to examine the effect of weight loss on UCP2/UCP3 mRNA expression and UCP3 protein content in subjects with Type II (non-insulin-dependent) diabetes mellitus.¶Methods. We studied seven Type II diabetic subjects who followed a 10-week very low calorie diet. Expression of skeletal muscle UCP2 and UCP3 mRNA was measured using RT-competitive PCR and UCP3 protein content by western blotting, before and after the diet. Total and plasma fatty acid oxidation was measured using infusion of ¹³C labelled palmitate.¶Results. Body weight decreased from 105.5 ± 8.2 kg to 91.6 ± 7.2 kg (p < 0.001), after 10 weeks of diet intervention. Expression of UCP2 and UCP3 mRNA were significantly reduced after 10 weeks of diet (p < 0.05) but UCP3 protein contents were not significantly altered. Notably, the change in UCP3L mRNA expression and UCP3 protein content after the very low calorie diet were negatively associated with changes in body weight (r = – 0.97, p = 0.006 and r = – 0.83, p = 0.043, respectively) and BMI (r = – 0.99, p = 0.0007 and r = – 0.9, p = 0.016, respectively). Furthermore, changes in UCP3L mRNA expression and UCP3 protein content induced by the diet were positively correlated with changes in cytosolic fatty acid-binding protein content (r = 0.93, p = 0.023 and r = 0.84, p = 0.039, respectively). No correlation between diet-induced changes in UCP3 protein and resting energy expenditure or plasma non-esterified fatty acid concentrations were found.¶Conclusion/interpretation. The negative correlation between the change in UCP3 protein content after weight loss and the change in BMI, suggests that the decrease in UCP3 during weight loss could prevent further weight loss. The finding that the change in UCP3 protein content correlates with the change in skeletal muscle fatty acid-binding protein content, suggests a role for UCPs in the handling of lipids as a fuel. [Diabetologia (2000) 43: 1408–1416]     

Fiber type dependent upregulation of human skeletal muscle UCP2 and UCP3 mRNA expression by high-fat diet

OBJECTIVE: To test the hypothesis that consumption of a high-fat diet leads to an increase in UCP mRNA expression in human skeletal muscle. In a group of endurance athletes, with a range in fiber type distribution, we hypothesized that the effect of the high-fat diet on UCP2 and UCP3 mRNA expression is more pronounced in muscle fibers which are known to have a high capacity to shift from carbohydrate to fat oxidation (type IIA fibers). DESIGN: Ten healthy trained athletes (five males, five females) consumed a low-fat diet (17+/-0.9 en% of fat) and high-fat diet (41.4+/-1.4 en% fat) for 4 weeks, separated by a 4 week wash-out period. Muscle biopsies were collected at the end of both dietary periods. MEASUREMENTS: Using RT-PCR, levels of UCP2 and UCP3 mRNA expression were measured and the percentage of type I, IIA and IIB fibers were determined using the myofibrillar ATPase method in all subjects. RESULTS: UCP3L mRNA expression tended to be higher on the high-fat diet, an effect which reached significance when only males were considered (P=0.037). Furthermore, diet-induced change in mRNA expression of UCP3T (r: 0.66, P=0.037), UCP3L (r: 0.61, P=0.06) and UCP2 (r: 0.70, P=0.025), but not UCP3S, correlated significantly with percentage dietary fat on the high-fat diet. Plasma FFA levels were not different during the two diets. Finally, the percentage of type IIA fibers was positively correlated with the diet-induced change in mRNA expression for UCP2 (r: 0.7, P=0.03), UCP3L (r: 0.73, P=0.016) and UCP3T (r: 0.68, P=0.03) but not with UCP3S (r: 0.06, NS). CONCLUSION: UCP2 and UCP3 mRNAs are upregulated by a high-fat diet. This upregulation is more pronounced in humans with high proportions of type IIA fibers, suggesting a role for UCPs in lipid utilization.     

非酒精性脂肪性肝病大鼠肝脏解偶联蛋白2表达及其与能量贮备的关系

目的探讨非酒精性脂肪性肝病(NAFLD)大鼠肝脏线粒体解偶联蛋白2(UCP2)表达及其与能量贮备的关系。方法模型组SD大鼠给予高脂肪高胆固醇饮食饲养,分批于实验第8、12、16、24 周处死,同期设普通饮食饲养大鼠作对照。免疫组织化学和逆转录聚合酶链反应(RT-PCR)检测肝脏UCP2 mRNA转录及其蛋白表达。荧光测定法检测肝脏三磷酸腺苷(ATP)含量。结果模型组大鼠8周呈现单纯性脂肪肝,12-24周从脂肪性肝炎进展为脂肪性肝炎伴肝纤维化。免疫组织化学和RT-PCR显示,随着造模时间延长,模型组肝脏UCP2表达逐渐增强,UCP mRNA转录于24周达高峰,较对照组升高4.2倍, t=16.474,P<0.01;模型组肝脏ATP含量则随造模时间延长而逐渐减低,24周为(1.99±0.66) ×108μmol/g,对照组为(2.97±0.48)×108μmol/g,t=3.248,P<0.01。模型组肝脏UCP2 mRNA 转录的相对数值与其ATP含量呈密切负相关,r=-0.93,P<0.01。结论持续24周高脂饮食成功复制大鼠NAFLD模型,模型大鼠肝脏UCP2表达增强而ATP含量减少,两者之间关系密切。     

Leptin is required for uncoupling protein-1-independent thermogenesis during cold stress

We investigated the role of leptin in regulating energy metabolism through induction of uncoupling protein (UCP)-1-based brown fat thermogenesis by comparing phenotypes of energy balance in ob/ob and double-mutant ob/ob.Ucp1(-/-) mice. Measurements of adiposity and lean body mass (nuclear magnetic resonance), energy expenditure (indirect calorimetry), body weight, food intake, and core body temperature were determined in the two mutant stocks of 3-month-old mice maintained at an initial ambient temperature of 28 C for 21 d and then at 21 C for 16 d, and finally with leptin administration for 8 d at 21 C. No phenotypic differences between ob/ob and ob/ob.Ucp1(-/-) mice were detected, suggesting that UCP1-based thermogenesis is not essential for the regulation of adiposity in ob/ob mice at temperatures between 21 and 28 C. Although both Ucp1(-/-) and ob/ob mice can survive in extreme cold at 4 C, provided they are adapted to the cold by gradually lowering ambient temperature, ob/ob.Ucp1(-/-) mice could not adapt and survive at temperatures lower than 12 C unless they were administered leptin. As the ambient temperature was reduced from 20 to 16 C, ob/ob.Ucp1(-/-) mice treated with leptin have elevated levels of circulating T(3) that correlate with elevated sarcoendoplasmic reticulum Ca(2+) ATPase 2a mRNA levels in gastrocnemius muscle. Furthermore, ob/ob.Ucp1(-/-) mice, treated with T(3), were able to maintain body temperature and stimulate sarcoendoplasmic reticulum Ca(2+) ATPase 2a expression when the ambient temperature was gradually reduced to 4 C. Thus, in the absence of UCP1, leptin-induced thermogenesis protects body temperature in part through its action on the thyroid hormone axis.     

Involvement of UCP3 in mild uncoupling and lipotoxicity

Although vital to life, mitochondria are also the major source of ROS production, which may have unwanted detrimental effects on DNA, RNA and protein structures Therefore, mitochondria must exhibit well-developed mechanisms to regulate its ROS production. One such mechanism might be mild uncoupling of the mitochondrial respiratory chain, thereby lowering the proton gradient across the inner mitochondrial membrane and directly lowering ROS production. Mitochondrial uncoupling proteins have been shown to possess mild uncoupling activity and may therefore be important regulator of mitochondrial ROS production. The skeletal muscle isoform of the uncoupling protein family, UCP3, seems to be specifically active under conditions of high fatty acid availability. Although the exact function of UCP3 is not yet unravelled, UCP3 is activated by lipid peroxides and suggested to export fatty acid anions and/or peroxides from the mitochondrial matrix, thereby specifically protecting fatty acids from ROS-induced oxidative damage. Protein levels of UCP3 are reduced with aging and in the (pre)-diabetic state, both conditions characterized by increased levels of oxidative damage to lipids and proteins and reduced mitochondrial function. Whether UCP3 is causally related to mitochondrial dysfunction and is essential in the prevention and treatment of lipid-induced mitochondrial dysfunction requires further study.     

COPD results in a reduction in UCP3 long mRNA and UCP3 protein content in types I and IIa skeletal muscle fibers

PURPOSE: Findings recently have shown coupling protein-3 (UCP3) content to be decreased in the skeletal muscle of patients with chronic obstructive pulmonary disease (COPD). Uncoupling protein-3 mRNA exists as two isoforms: long (UCP3L) and short (UCP3S). The UCP3 protein is expressed the least in oxidative and the most in glycolytic muscle fibers. Levels of UCP3 have been associated positively with intramyocellular triglyceride (IMTG) contents in conditions of altered fatty acid metabolism. As a source for muscle free fatty acid metabolism, IMTG is decreased in COPD. The current study completely characterized all the parameters of UCP3 expression (ie, UCP3L and UCP3S mRNA expression in whole muscle samples) and UCP3 protein content as well as IMTG content in the different fiber types in patients with COPD and healthy control subjects. METHODS: Using real-time polymerase chain reaction, UCP3 gene expression was quantified. Skeletal muscle fiber type and UCP3 protein and IMTG content were measured using immunofluorescence and Oil red oil staining, respectively. RESULTS: The findings showed that UCP3L mRNA expression was 44% lower (P < .005) in the patients with COPD than in the control subjects, whereas the UCP3S mRNA content was similar in the two groups. As compared with control subjects, UCP3 protein content was decreased by 89% and 83% and the IMTG content by 64% and 54%, respectively, in types I and IIa fibers (P < .0167) of patients with COPD, whereas they were unchanged in IIx fibers. CONCLUSIONS: The reduced UCP3 and IMTG content in the more oxidative fibers may be linked to the altered muscle fatty acid metabolism associated with COPD. Further studies are required to determine the exact role and clinical relevance of the reduced UCP3 content in patients with COPD.     

Reduced gene expression of UCP2 but not UCP3 in skeletal muscle of human obese subjects

Summary Massive overweight is an increasing health problem and underlies several complications which in turn result in premature death. The mechanisms underlying the imbalance between energy intake and energy expenditure, that lead to obesity in humans, are still only partly understood. In rodents, heat generation and the burning of calories by the mitochondrial uncoupling protein 1 (UCP1) are important for metabolic control. However, UCP1 is exclusively expressed in brown fat which is only present in limited amounts in human adults. The recent characterization of two new uncoupling proteins, UCP2 and UCP3, may elucidate potentially important pathways for energy expenditure regulation in man. The aim of this study was to investigate whether obesity is accompanied by aberrations in UCP2 and UCP3 regulation. Expression of these two genes was examined using in situ hybridization in six lean and six obese, but otherwise healthy, men. The UCP2 expression was decreased by 28 % (p = 0.001) in the abdominal muscle of the obese subjects. No differences in UCP3 expression were observed between obese and control subjects, although there was great variation in the expression between subjects. In conclusion, these data suggest an impaired activity of the mitochondrial uncoupling protein UCP2, but probably not UCP3, in obese subjects. This may result in decreased energy expenditure and contribute to the development and maintenance of obesity. [Diabetologia (1998) 41: 935–939] Received: 5 December 1997 and in revised form: 18 February 1998