Leptin Directly Alters Lipid Partitioning in Skeletal Muscle

Muoio, Deborah M.; Dohn, G Lynis; Fiedorek, Frederick T.; Tapscott, Edward B.; Coleman, Rosalind A.

doi:10.2337/diab.46.8.1360

Cited by 341 publications

(165 citation statements)

References 21 publications

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“…[56][57][58] As depicted in Figure 3, the earlier demonstrations that leptin can act directly on skeletal muscle, specifically via the long form of the leptin receptor (ObRb), to stimulate glucose utilization in a PI3K-dependent manner 59,60 and lipid oxidation via the activation of AMP-activated protein kinase (AMPK) leading to inhibition of ACCs 58,61 prompted us to investigate whether leptin could also exert direct control on thermogenesis in skeletal muscle. Using a method that involves repeated measurements of O 2 consumption in intact muscle perifused ex vivo with Krebs-Ringer buffer, we found that leptin could directly stimulate thermogenesis in skeletal muscle via ObRb, 62 and that this thermogenic effect of leptin, which requires PI3K activity (since it is inhibited by wortmannin), is potentiated by insulin, a potent activator of PI3K.…”

Section: Substrate Cycling Between De Novo Lipogenesis and Lipid Oxidmentioning

confidence: 99%

“…A requirement for AMPK activation and for entry of fatty acids through the mitochondrial b-oxidation pathway was also suggested by the fact that leptin-induced thermogenesis was inhibited either in the presence of araA (an inhibitor of AMPK) or by addition of etomoxir, an inhibitor of CPT-1. 63 In other experiments that involved interference with key control points of intermediary metabolism in order to investigate the nature of an 'apparent' link between leptin's direct effects on skeletal muscle to stimulate glucose metabolism, 58-60 lipid oxidation [57][58][59][60][61] and thermogenesis, 62 evidence emerged of a requirement for de novo lipogenesis in the mechanism by which leptin stimulates muscle thermogenesis. 63 Specifically, the direct thermogenic effect of leptin on skeletal muscle O 2 consumption was found to be completely inhibited by the addition of any one of the following compounds that would inhibit the synthesis of lipids from glucose, namely (a) 2-deoxyglucose, which interferes with glucose metabolism, (b) hydroxy-citrate, which inhibits citrate lyase and hence the conversion of citrate to acetyl-CoA and (c) cerulenin, which inhibits fatty acid synthase and hence the conversion of malonyl-CoA to fatty acids.…”

Section: Substrate Cycling Between De Novo Lipogenesis and Lipid Oxidmentioning

confidence: 99%

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Substrate cycling between de novo lipogenesis and lipid oxidation: a thermogenic mechanism against skeletal muscle lipotoxicity and glucolipotoxicity

et al. 2004

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Life is a combustion, but how the major fuel substrates that sustain human life compete and interact with each other for combustion has been at the epicenter of research into the pathogenesis of insulin resistance ever since Randle proposed a 'glucose-fatty acid cycle' in 1963. Since then, several features of a mutual interaction that is characterized by both reciprocality and dependency between glucose and lipid metabolism have been unravelled, namely:(i) the inhibitory effects of elevated concentrations of fatty acids on glucose oxidation (via inactivation of mitochondrial pyruvate dehydrogenase or via desensitization of insulin-mediated glucose transport), (ii) the inhibitory effects of elevated concentrations of glucose on fatty acid oxidation (via malonyl-CoA regulation of fatty acid entry into the mitochondria), and more recently (iii) the stimulatory effects of elevated concentrations of glucose on de novo lipogenesis, that is, synthesis of lipids from glucose (via SREBP1c regulation of glycolytic and lipogenic enzymes).This paper first revisits the physiological significance of these mutual interactions between glucose and lipids in skeletal muscle pertaining to both blood glucose and intramyocellular lipid homeostasis. It then concentrates upon emerging evidence, from calorimetric studies investigating the direct effect of leptin on thermogenesis in intact skeletal muscle, of yet another feature of the mutual interaction between glucose and lipid oxidation: that of substrate cycling between de novo lipogenesis and lipid oxidation. It is proposed that this energy-dissipating substrate cycling that links glucose and lipid metabolism to thermogenesis could function as a 'fine-tuning' mechanism that regulates intramyocellular lipid homeostasis, and hence contributes to the protection of skeletal muscle against lipotoxicity.

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Section: Substrate Cycling Between De Novo Lipogenesis and Lipid Oxidmentioning

confidence: 99%

Section: Substrate Cycling Between De Novo Lipogenesis and Lipid Oxidmentioning

confidence: 99%

Substrate cycling between de novo lipogenesis and lipid oxidation: a thermogenic mechanism against skeletal muscle lipotoxicity and glucolipotoxicity

et al. 2004

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“…11 CPT-1 mRNA expression can be affected by nutritional states, and both fasting and fat feeding increase its expression. 12 Many circulating hormones secreted by white adipose tissue (WAT) including adiponectin 13,14 and leptin 15,16 can stimulate fatty-acid oxidation and glucose uptake. Undernutrition in early life may have long-lasting effects on the regulation of these hormones.…”

Section: Introductionmentioning

confidence: 99%

Undernutrition during suckling in rats elevates plasma adiponectin and its receptor in skeletal muscle regardless of diet composition: a protective effect?

et al. 2008

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Objective: Nutrition during critical periods in early life may increase the subsequent risk of obesity, hypertension and metabolic diseases in adulthood. Few studies have focused on the long-term consequences of poor nutrition during the suckling period on the susceptibility to developing obesity when exposed to a palatable cafeteria-style high-fat diet (CD) after weaning. Design: This study examined the impact of early undernutrition, followed by CD exposure, on blood pressure, hormones and genes important for insulin sensitivity and metabolism and skeletal muscle mRNA expression of adiponectin receptor 1 (AdipoR1), carnitine palmitoyl-transferase I (CPT-1), cytochrome c oxidase 4 (COX4) and peroxisome proliferator-activated receptor a (PPARa). Following normal gestation, Sprague-Dawley rat litters were adjusted to 18 (undernourished) or 12 (control) pups. Rats were weaned (day 21) onto either palatable CD or standard chow. Results: Early undernourished rats were significantly lighter than control by 17 days, persisting into adulthood only when animals were fed chow after weaning. Regardless of litter size, rats fed CD had doubled fat mass at 15 weeks of age, and significant elevations in plasma leptin, insulin and adiponectin. Importantly, undernutrition confined to the suckling period, elevated circulating adiponectin regardless of post-weaning diet. Blood pressure was reduced in early undernourished rats fed chow, and increased by CD. Early undernutrition was associated with long-term elevations in the expression of AdipoR1, CPT-1, COX4 and PPARa in skeletal muscle. Conclusion: This study demonstrates the important role of early nutrition on body weight and metabolism, suggesting early undernourishment enhances insulin sensitivity and fatty-acid oxidation. The long-term potential benefit of limiting nutrition in the early postnatal period warrants further investigation.

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“…Additionally, the importance of leptin to reproduction has been highlighted by the lack of sexual maturation in people who are genetically deficient in leptin [5] or the leptin receptor [6]. Although many of leptin's effects are centrally mediated, there is growing evidence that peripheral leptin receptors mediate leptin's proliferative effects on haemopoietic cells [7] and its anti-lipogenic effects on muscle and pancreatic islets [8,9].Because leptin has a critical role in regulating energy metabolism, adipose stores and body weight, questions have been raised concerning the control of leptin synthesis and secretion and the function of leptin in controlling satiety and food intake. Basal or fasting leptin values are higher in women than men, increase during the course of pregnancy and, in both healthy adults and those with Type II (non-insulindependent) diabetes mellitus, are strongly correlated with per cent body fat or BMI [10,11] and adipose tissue mass [12±15].…”

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confidence: 99%

Nutritional regulation of leptin in humans

Coleman

Herrmann

1999

Diabetologia

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OverviewPositional cloning of the defective gene in genetically obese ob/ob mice identified leptin as the long-sought hormone that communicates information about adipocyte metabolism to the brain [1]. Supplying leptin to genetically deficient ob/ob mice increases metabolic rate, body temperature and general activity and decreases food intake, body weight and adiposity [1±4]. Additionally, the importance of leptin to reproduction has been highlighted by the lack of sexual maturation in people who are genetically deficient in leptin [5] or the leptin receptor [6]. Although many of leptin's effects are centrally mediated, there is growing evidence that peripheral leptin receptors mediate leptin's proliferative effects on haemopoietic cells [7] and its anti-lipogenic effects on muscle and pancreatic islets [8,9].Because leptin has a critical role in regulating energy metabolism, adipose stores and body weight, questions have been raised concerning the control of leptin synthesis and secretion and the function of leptin in controlling satiety and food intake. Basal or fasting leptin values are higher in women than men, increase during the course of pregnancy and, in both healthy adults and those with Type II (non-insulindependent) diabetes mellitus, are strongly correlated with per cent body fat or BMI [10,11] and adipose tissue mass [12±15]. Despite these strong correlations, people with similar degrees of adiposity have circulating leptin concentrations that vary considerably. Thus, factors other than adipocyte size and fat content must influence leptin production. Further, the regulation of leptin's diurnal pattern of secretion is still to be explained.In this review we summarize current data, primarily from human studies, that address the nutritional controls on leptin synthesis and secretion and point out fruitful areas for future study. Excellent recent reviews should be consulted for information on the leptin receptor, other aspects of leptin's effects, and the relation of leptin to other hormones that regulate food intake and energy expenditure [16±22]. Leptin regulation by fasting, refeeding and overfeedingFasting and refeeding. During short-term energy restriction, plasma leptin concentrations decrease much more than the amount of weight or adipose tissue lost. For example, lean and obese adults who fasted for 52 to 96 h lost less than 4 % of body weight but the leptin concentrations decreased 54 to 72 % [23±25]. In careful long-term studies of lean and obese people who were either losing weight or maintaining a defined weight loss, leptin concentrations were lower during the period of loss than the period of weight maintenance at the same body composition [26]. After a 4 day fast followed by an additional 6 days of fasting during which an intravenous infusion of 5 % glucose was given, leptin increased 80 % within the first 24 h, even though glucose provided only 338 kcal/day [25]. Although it is possible that the previous 4 day fast confounded these results [27], taken together, these studies suggest that ...

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Leptin Directly Alters Lipid Partitioning in Skeletal Muscle

Cited by 341 publications

References 21 publications

Substrate cycling between de novo lipogenesis and lipid oxidation: a thermogenic mechanism against skeletal muscle lipotoxicity and glucolipotoxicity

Substrate cycling between de novo lipogenesis and lipid oxidation: a thermogenic mechanism against skeletal muscle lipotoxicity and glucolipotoxicity

Undernutrition during suckling in rats elevates plasma adiponectin and its receptor in skeletal muscle regardless of diet composition: a protective effect?

Nutritional regulation of leptin in humans

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