Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0242339 (dyslipidemia)
13,927 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The high prevalence of obesity and its well documented association with the cardiovascular risk factors diabetes mellitus, dyslipidemia and hypertension represents a major problem for the general health status of industrialized societies. Although numerous studies have shown that genetic factors have a major influence on the regulation of energy homeostasis and the susceptibility to obesity, the genes and predisposing mutations involved are insufficiently understood. Among several known rodent models of obesity due to single gene mutations, mice homozygous for the obese (ob) gene exhibit massive early-onset obesity, hyperphagia, non-insulin-dependent diabetes mellitus, defective thermoregulation and infertility. Recently the ob gene was identified by positional cloning and shown to be mutated in ob/ob mice. Leptin, the product of the ob gene, is a 167-amino acid secreted protein that is synthesized exclusively in adipose tissue. With the exception of ob/ob mice, circulating plasma leptin is elevated in obesity. Administration of recombinant leptin to ob/ob mice reduces fat mass, food intake, hyperglycemia and hyperinsulinemia. The various effects of the hormone are mediated by leptin receptors expressed at high levels in the hypothalamus, but also in several other non-neuronal tissues. A mutation in the leptin receptor gene is responsible for the obese phenotype of db/db mice. Plasma leptin in humans is positively correlated with body fat mass, suggesting that leptin resistance rather than leptin deficiency is a common feature of human obesity. This review briefly summarizes the current status of the rapidly growing evidence that leptin plays an important role in the regulation of body weight and fat deposition.
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PMID:Regulation of energy balance by leptin. 888 45

Intraabdominal adiposity and insulin resistance are risk factors for diabetes mellitus, dyslipidemia, arteriosclerosis, and mortality. Leptin, a fat-derived protein encoded by the ob gene, has been postulated to be a sensor of energy storage in adipose tissue capable of mediating a feedback signal to sites involved in the regulation of energy homeostasis. Here, we provide evidence for specific effects of leptin on fat distribution and in vivo insulin action. Leptin (LEP) or vehicle (CON) was administered by osmotic minipumps for 8 d to pair-fed adult rats. During the 8 d of the study, body weight and total fat mass decreased similarly in LEP and in CON. However, while moderate calorie restriction (CON) resulted in similar decreases in whole body (by 20%) and visceral (by 21%) fat, leptin administration led to a specific and marked decrease (by 62%) in visceral adiposity. During physiologic hyperinsulinemia (insulin clamp), leptin markedly enhanced insulin action on both inhibition of hepatic glucose production and stimulation of glucose uptake. Finally, leptin exerted complex effects on the hepatic gene expression of key metabolic enzymes and on the intrahepatic partitioning of metabolic fluxes, which are likely to represent a defense against excessive storage of energy in adipose depots. These studies demonstrate novel actions of circulating leptin in the regulation of fat distribution, insulin action, and hepatic gene expression and suggest that it may play a role in the pathophysiology of abdominal obesity and insulin resistance.
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PMID:Leptin selectively decreases visceral adiposity and enhances insulin action. 939 57

It is widely held that although obesity and type 2 diabetes are polygenic in origin, the primary defect causing both conditions is insulin resistance, which in turn gives rise to a constellation of other abnormalities, including hyperinsulinemia, dyslipidemia, glucose intolerance, and (in the genetically predisposed) frank hyperglycemia. Explored here is an alternative, albeit speculative, scenario in which hyperinsulinemia and insulin resistance arise either simultaneously or sequentially from some preexisting defect within the leptin signaling pathway. In either case, a central component of the model is that the breakdown of glucose homeostasis that is characteristic of the condition of obesity with type 2 diabetes is secondary to disturbances in lipid dynamics. The possibility is raised that abnormally high concentrations of malonyl-CoA in liver and skeletal muscle suppress the activity of mitochondrial carnitine palmitoyltransferase I and thus fatty acid oxidation in both sites. It is suggested that the buildup of fat within the muscle cell (caused in part by excessive delivery of VLDLs from the liver) interferes with glucose transport or metabolism or both, producing insulin resistance. Elevated circulating concentrations of fatty acids are also implicated in the etiology of type 2 diabetes by virtue of 1) their powerful acute insulinotropic effect, 2) their ability to exacerbate insulin resistance in muscle, and 3) their long-term detrimental action on pancreatic beta-cell function.
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PMID:Glucose-fatty acid interactions in health and disease. 949 60

While the hyperleptinemia of obesity is likely to be associated with the metabolic complications of obesity/hyperinsulinemia/insulin resistance, it is not associated with diabetes, with the relative hypercortisolism of upper body obesity, with hypertension in women, (it is in men), or with dyslipidemia. Overall, the correlations between leptin and the metabolic diseases associated with obesity are weak. The equivocal results of an association of leptin with components of the metabolic syndrome make it unlikely that leptin affects these directly. (On the other hand, these correlations, when found, preclude any causal relationship between leptin and metabolic diseases.) There are experimental data showing a definite role for insulin and glucocorticoids in the regulation of leptin, and of leptin in the regulation of insulin. More data are required on the effects of leptin, but it is likely that leptin will not be a major link between obesity and the metabolic syndrome. Certainly, however, when leptin is available for clinical use, its effect on different aspects of the metabolic syndrome will be worth studying.
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PMID:Therapeutic controversy: Obesity--a modern-day epidemic. 992 54

There is a high prevalence of type 2 diabetes mellitus and coronary artery disease among urban and migrant Asian Indians despite the absence of traditional risk factors. Evidence exists that Asian Indians are more hyperinsulinemic than Caucasians and that hyperinsulinemia may be important in the development of these diseases. To test whether insulin action was related to total or regional adiposity and to explore the potential role of plasma leptin and lipids, we measured insulin-mediated glucose disposal by the euglycemic insulin clamp, adipose distribution and muscle volume using computed axial tomography, and fasting serum leptin and lipid levels in 20 healthy Asian Indian male volunteers (age, 36 +/- 10 yr). A mean body mass index of 24.5 +/- 2.5 kg/m2 was associated with an unusually high percentage of body fat (33 +/- 7%). The majority of the fat was sc, and 16% was visceral (intraabdominal) adipose tissue. The majority (66%) of these nonobese men were insulin resistant. The mean fasting serum leptin level was 7.6 +/- 3.3 ng/mL. Insulin action was inversely correlated with visceral adipose tissue, not total or abdominal sc adipose tissue. In contrast, leptin levels correlated with sc and total (not visceral) adipose tissue. Serum triglyceride and high density lipoprotein cholesterol levels were inversely correlated with each other and were directly related to insulin resistance and visceral (not subcutaneous) fat. Increased visceral fat in Asian Indians is associated with increased generalized obesity, which is not apparent from their nonobese body mass index. Increased visceral fat is related to dyslipidemia and increased frequency of insulin resistance and may account for the increased prevalence of diabetes mellitus and cardiovascular disease in Asian Indians.
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PMID:Body composition, visceral fat, leptin, and insulin resistance in Asian Indian men. 992 74

Dietary restriction (DR) is the only intervention that has been shown to increase average and median life span in laboratory rodents. The effect of long-term, moderate DR on body composition and fat distribution was evaluated in male rhesus monkeys. Thirty animals (8-14 years of age)fed either 30% less than baseline intake (R, n = 15) or allowed to eat to satiety (C, n = 15), have been assessed semiannually using somatometrics and dual-energy alpha-ray absorptiometry (DXA)for 7.5 years. R subjects have reduced body weight (p <.0001), total body fat (p < .0001), and percentage body fat located in the abdominal region (p < .05). In addition, there has been a sustained reduction in plasma leptin concentrations (p <.001). These findings suggest reduced risk for common morbidities, such as insulin resistance, dyslipidemia, and type 2 diabetes mellitus, that are associated with advancing age and increased levels of bodyfat, especially in the visceral depot.
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PMID:Body fat distribution with long-term dietary restriction in adult male rhesus macaques. 1046 60

Obesity and Type 2 diabetes are now major public health issues in developed nations and have reached epidemic proportions in many developing nations, as well as disadvantaged groups in developed countries, e.g., Mexican-Americans, African-Americans, and Australian Aborigines. These groups all show hyperinsulinemia and insulin resistance, which have been demonstrated to be future predictors of Type 2 diabetes and have also been suggested as key factors in the etiology of the Metabolic Syndrome. It is now increasingly recognized that Type 2 diabetes is part of a cluster of cardiovascular disease (CVD) risk factors comprising the Metabolic Syndrome. This group is at very high risk of atherosclerosis because each of the risk factors in the Metabolic Syndrome cluster in its own right is an important CVD risk factor. They also contribute cumulatively to atherosclerosis. A key strategy in reducing macrovascular disease lies in the better understanding of the Metabolic Syndrome--glucose intolerance, hypertension, hyperlipidemia, and central obesity. Although it has been suggested that hyperinsulinemia/insulin resistance is the central etiological factor for the Metabolic Syndrome, epidemiological data do not support the idea that this can account for all of the cluster abnormalities. We have animal and human data suggesting that hyperleptinemia rather than, or synergistically with, hyperinsulinemia may play a central role in the genesis of the CVD risk factor cluster that constitutes the syndrome. Studies in Psammomys obesus (the Israeli sand rat) suggest hyperinsulinemia/insulin resistance is an early metabolic lesion in the development of obesity and Type 2 diabetes. This animal also develops other features of the Metabolic Syndrome, making it an excellent model to investigate etiology. Psammomys, when placed on an ad libitum laboratory diet, develops hyperinsulinemia, insulin resistance, impaired glucose tolerance, diabetes, and dyslipidemia. It also develops hyperleptinemia and leptin insensitivity, and hyperleptinemia is correlated with insulin resistance independent of changes in body weight. It is likely that a similar sequence occurs in the transition from the prediabetic state to Type 2 diabetes in humans. More recently, other potential players in the etiology of the Metabolic Syndrome have been suggested including endothelial dysfunction and acetylation-stimulating protein (ASP). It has been suggested that endothelial dysfunction may be an antecedent for both Type 2 diabetes and the Metabolic Syndrome. In addition, ASP is a serious new candidate for an important role in insulin resistance. The ASP pathway plays a critical role in fatty acid metabolism and storage, and it has been suggested that ineffective storage of fatty acids by adipocytes due to a defect in the ASP pathway may lead to insulin resistance and Type 2 diabetes.
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PMID:Etiology of the metabolic syndrome: potential role of insulin resistance, leptin resistance, and other players. 1084 50

Recent research has emphasized the importance of the metabolic cluster, which includes glucose intolerance, dyslipidemia, and high blood pressure, as a strong predictor of the obesity-related morbidities and premature mortality. Fundamental to this association, commonly referred to as the metabolic syndrome, is the close interaction between abdominal fat patterning, total body adiposity, and insulin resistance. As the initial step in identifying major genetic loci influencing these phenotypes, we performed a genomewide scan by using a 10-centiMorgan map in 2,209 individuals distributed over 507 nuclear Caucasian families. Pedigree-based analysis using a variance components linkage model demonstrated a quantitative trait locus (QTL) on chromosome 3 (3q27) strongly linked to six traits representing these fundamental phenotypes [logarithm of odds (lod) scores ranged from 2.4 to 3.5]. This QTL exhibited possible epistatic interaction with a second QTL on chromosome 17 (17p12) strongly linked to plasma leptin levels (lod = 5.0). Situated at these epistatic QTLs are candidate genes likely to influence two biologic precursor pathways of the metabolic syndrome.
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PMID:Quantitative trait loci on chromosomes 3 and 17 influence phenotypes of the metabolic syndrome. 1112 Oct 50

The common syndrome of insulin resistance is frequently seen in obese individuals, and is characterized by glucose intolerance, dyslipidemia, high blood pressure, and an increased risk of coronary heart disease. A rare genetic form of insulin resistance is Dunnigan-type familial partial lipodystrophy (FPLD; OMIM #151660), which is characterized by loss of subcutaneous fat from extremities, trunk, and gluteal region, and always by insulin resistance and hyperinsulinemia, often with hypertension, dyslipidemia, type-2 diabetes and early endpoints of atherosclerosis. FPLD was recently discovered to result from mutated LMNA (R482Q; OMIM #150330.0010), which is the gene encoding nuclear lamins A and C. Results from extended pedigrees indicate that dyslipidemia precedes the plasma glucose abnormalities in FPLD subjects with mutant LMNA, and that the hyperinsulinemia is present early in the course of the disease. Plasma leptin is also markedly reduced in subjects with FPLD due to mutant LMNA. Thus, rare mutations in a nuclear structural protein can be associated with markedly abnormal qualitative and quantitative phenotypes, indicating that a defect in the structure and function of the nuclear envelope can result in a phenotype that shares many aspects with the common syndrome of insulin resistance.
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PMID:Insulin resistance in human partial lipodystrophy. 1112 71

Dunnigan-type familial partial lipodystrophy (FPLD; OMIM 151660) is a rare monogenic form of insulin resistance characterized by loss of subcutaneous fat from the extremities, trunk, and gluteal region. FPLD recapitulates the main metabolic attributes of the insulin resistance syndrome, including central obesity, hyperinsulinemia, glucose intolerance and diabetes, dyslipidemia, and hypertension. Through the use of focused DNA sequencing of positional candidate genes on chromosome 1q21, we discovered that FPLD results from mutations in LMNA (R482Q; OMIM 150330.0010), which is the gene that encodes nuclear lamins A and C. By stratifying members of extended FPLD pedigrees according to LMNA genotype, we found that hyperinsulinemia is present early in the course of the disease and that dyslipidemia (characterized by high triglycerides and depressed HDL cholesterol) precedes the development of glucose abnormalities. Plasma leptin is also markedly reduced in subjects with FPLD due to mutant LMNA. The findings in FPLD indicate that defective structure of the nuclear envelope produces a phenotype of insulin resistance. The findings may have relevance for common insulin resistance and for drug-associated lipodystrophies, whose molecular basis is unknown at present.
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PMID:Familial partial lipodystrophy: a monogenic form of the insulin resistance syndrome. 1113 44


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