UMLS:C0948265 - FACTA Search

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Query: UMLS:C0948265 (metabolic syndrome)
24,271 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The triglyceride (TG) level is one of several lipid parameters that can aid prediction of coronary heart disease (CHD) risk. An elevated plasma TG level is strongly associated with an increased risk of CHD. Hypertriglyceridemia, the second most common dyslipidemic abnormality in hypertensive subjects after increased low-density lipoprotein cholesterol (LDL-C), is defined by the National Cholesterol Education Programme (NCEP) as a fasting TG level of > 2.26 mmol/l (> 200 mg/dl) and is recognised as a primary indicator for treatment in type IIb dyslipidemia. Raised TG levels can be present in individuals at risk for CHD when the total cholesterol is normal. However, not all individuals with raised TG levels have increased risk of CHD. Factors such as: diet, age, lifestyle, and a range of medical conditions, drug therapy and metabolic disorders, can all affect the TG level. In some of these circumstances, other factors protect against the risk of CHD, and can minimise or negate the effect of the risk factors present. Although TG reducing therapy has been shown to be associated with an improved clinical outcome, more research is needed to determine whether this is an independent effect of TG reduction or an effect of normalising the overall lipid profile in hypertriglyceridemic patients. Further trials are required to quantify the clinical benefits of lowering TG to 'target' levels and to confirm targets defined by NCEP-II (shown in Table 1). The role of TG in CHD pathogenesis is thought to involve several direct and indirect mechanisms, such as effects on the metabolism of other lipoproteins, transport proteins, enzymes, and on coagulation and endothelial dysfunction. More research is required to fully elucidate the role of TG, the ways in which it can influence other risk factors and the mechanism of its own more direct role in the atherogenic process. Patients with hypertriglyceridemia have been shown to respond well to dietary control and to the use of lipid lowering drugs such as 3-hydroxy-3-methylglutaryl-Coenzyme A (HMG CoA) reductase inhibitors (known as statins), fibrates and nicotinic acids. However, recent retrospective real-life clinical studies show that only 38% of patients receiving some form of lipid-lowering therapy achieved NCEP-defined LDL-C target levels, demonstrating the need for the use of more aggressive treatment. In hypertriglyceridemic patients, the newer statins, cerivastatin and atorvastatin, have shown comparable efficacy in reducing TG compared with the older statins. Achieving NCEP target lipid levels has been shown to reduce the risk of cardiovascular disease in dyslipidemic individuals, including high-risk patient groups such as those with additional risk factors, existing heart disease, diabetes mellitus and metabolic syndrome. Although the latest clinical studies investigating combination therapies, i.e. dual therapy with both a statin and a fibrate, have demonstrated them to be effective for overall control of lipid parameters and reducing coronary events, it is not yet clear whether this offers any significant advantage over monotherapy. Results from ongoing longer-term end-point clinical studies may provide further information in this area and consequent reviews of primary care management policies for dyslipidemia. Statin monotherapy may be a reliable option for primary care treatment of dyslipidemia (including hypertriglyceridemia).
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PMID:Hypertriglyceridemia: a review of clinical relevance and treatment options: focus on cerivastatin. 1146 48

Insulin resistance is an important issue in the understanding of the metabolic syndrome. Clinical insulin resistance is usually defined by reduced insulin-mediated uptake of glucose in skeletal muscle. However, new studies have shown that liver and fat cells may also develop insulin resistance in subjects with the metabolic syndrome, specifically when these subjects are hyperglycaemic. New investigations also indicate that the endothelial cell itself can be insulin-resistant, reduced blood flow and increased peripheral resistance as the outcome. Insulin resistance may not only induce hyperglycaemia, but also dyslipidaemia (increased plasma levels of free fatty acids and triglyceride, and reduced plasma HDL levels) and arterial hypertension. All these variables may provoke arteriosclerosis and ischaemic heart disease. Specifically, abdominal adiposity seems to be responsible for insulin resistance in subjects with the metabolic syndrome. The mechanism could be intracellular accumulation of acyl CoA and triglyceride. However, an increased production of peptides from the adipose tissue, such as TNF alpha and reduced production of adiponectine may also play a role. The mechanism by which FFA and triglyceride, together with the peptides mentioned, may induce insulin resistance at a cellular level, resulting in reduced glucose transport and intracellular glucose processing, is still being discussed. A change in the insulin signalling cascade is one possibility, but the results so far have been contradictory. Another possibility is, of course, that the cellular accumulation of acyl CoA itself intervenes with gene expression and with phosphorylation of proteins.
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PMID:[Insulin resistance: organ manifestations and cellular mechanisms]. 1198 54

Insulin resistance and hyperinsulinemia are the critical characteristics of the metabolic syndrome that is associated with abdominal obesity and are the early manifestations of its progression to type 2 diabetes. These metabolic abnormalities are becoming recognized as a major contributor to cardiovascular disease. The experimental studies required to elucidate the underlying mechanisms and to develop effective preventative strategies will require the use of appropriate animal models and these are available. The evidence from such research indicates that a wide range of interventions (including peroxisome proliferator activator receptor agonists, insulin-sensitizing agents, statins, fibrates, angiotensin-converting enzyme inhibitors, estrogen receptor modulators, lipid-based nutriceuticals, and ethanol) can markedly reduce or prevent vasculopathy and ischemic cardiac lesions in animal models. Overall, the results suggest that early damage to the vascular wall, both in function and presenting as atherosclerotic lesions, is secondary to long-term hyperinsulinemia and, especially, to postprandial peaks in plasma insulin levels, and is exacerbated by the accompanying hyperlipidemia. Effective treatment will, of necessity, be preventative and will necessitate diagnostic approaches that can identify asymptomatic individuals at high risk for vascular damage and eventual progression to type 2 diabetes. Therapeutic targets in this population include insulin sensitivity and the associated signal transduction pathways, the peroxisome proliferator activator receptor-alpha and -gamma systems, and the complex pathways leading from acetyl CoA and the citric acid cycle to the synthesis of fatty acid and the storage of triglyceride. These pharmacological approaches offer the prospect of preventing a significant proportion of cardiovascular disease.
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PMID:Reduction and prevention of the cardiovascular sequelae of the insulin resistance syndrome. 1276 60

Insulin has a major anabolic function leading to storage of lipidic and glucidic substrates. All its effects result from insulin binding to a specific membrane receptor which is expressed at a high level on the 3 insulin target tissues: liver, adipose tissue and muscles. The insulin receptor exhibits a tyrosine-kinase activity which leads, first, to receptor autophosphorylation and then to tyrosine phosphorylation of substrates proteins, IRS proteins in priority. This leads to the formation of macromolecular complexes close to the receptor. The two main transduction pathways are the phosphatidylinositol 3 kinase pathway activating protein kinase B which is involved in priority in metabolic effects, and the MAP kinase pathway involved in nuclear effects, proliferation and differentiation. However, in most cases, a specific effect of insulin requires the participation of the two pathways in a complex interplay which could explain the pleiotropy and the specificity of the insulin signal. The negative control of the insulin signal can result from hormone degradation or receptor dephosphorylation. However, the major negative control results from phosphorylation of serine/threonine residues on the receptor and/or IRS proteins. This phosphorylation is activated in response to different signals involved in insulin resistance, hyperinsulinism, TNFalpha or increased free fatty acids from adipose tissue, which are transformed inside the cell in acyl-CoA. A deleterious role for molecules issued from the adipose tissue is postulated in the resistance to insulin of the liver and muscles present in type 2 diabetes, obesity and metabolic syndrome.
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PMID:[Insulin signaling: mechanisms altered in insulin resistance]. 1459 14

Obesity and insulin resistance have been recognised as leading causes of major health issues, particularly diabetes type 2 and metabolic syndrome. Although obesity, defined as excess body fat, is frequently accompanied by insulin resistance, diabetes, metabolic syndrome and cardiovascular diseases, the molecular basis for the link between obesity and those diseases has not yet been clarified. Adipose tissue expresses various secretory proteins, including leptin, tumour necrosis factor-alpha and adiponectin, which may be involved in the regulation of energy expenditure, lipid metabolism and insulin resistance. The aim of this study is to provide an overview of the metabolic alterations occurring in insulin resistance as well as to review the biological roles of adiponectin, particularly in the regulation of fatty acid oxidation and insulin action. Adiponectin is the most abundant gene product in adipose tissue and accounts for 0.01% of total plasma protein. Plasma adiponectin level is decreased in obesity, both in children and adults, and it is negatively associated to plasma insulin and positively associated to plasma triglycerides. Low levels of adiponectin decreases fatty acid oxidation in muscle. Recent data have demonstrated that adiponectin effects are mediated by the interaction with muscle and hepatic receptors through activation of AMP kinase, the cellular "fuel gauge", which in turn inhibits acetyl CoA carboxylase and increases fatty acid beta-oxidation. Since there is no available recombinant adiponectin for human use, its direct effects on human metabolism remain unknown, but this hormone appears to be promising in the treatment of obesity an related metabolic disorders.
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PMID:Adiponectin, the missing link in insulin resistance and obesity. 1538 Aug 84

Effective therapies for the treatment of obesity, a key element of metabolic syndrome, are urgently needed but currently lacking. Stearoyl-CoA desaturase-1 (SCD1) is the rate-limiting enzyme catalyzing the conversion of saturated long-chain fatty acids into monounsaturated fatty acids, which are major components of triglycerides. In the current study, we tested the efficacy of pharmacological inhibition of SCD1 in controlling lipogenesis and body weight in mice. SCD1-specific antisense oligonucleotide inhibitors (ASOs) reduced SCD1 expression, reduced fatty acid synthesis and secretion, and increased fatty acid oxidization in primary mouse hepatocytes. Treatment of mice with SCD1 ASOs resulted in prevention of diet-induced obesity with concomitant reductions in SCD1 expression and the ratio of oleate to stearoyl-CoA in tissues and plasma. These changes correlated with reduced body adiposity, hepatomegaly and steatosis, and postprandial plasma insulin and glucose levels. Furthermore, SCD1 ASOs reduced de novo fatty acid synthesis, decreased expression of lipogenic genes, and increased expression of genes promoting energy expenditure in liver and adipose tissues. Thus, SCD1 inhibition represents a new target for the treatment of obesity and related metabolic disorders.
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PMID:Prevention of obesity in mice by antisense oligonucleotide inhibitors of stearoyl-CoA desaturase-1. 1674 73

Insulin resistance, the impaired action of insulin, has been linked to many important consequences, including Type 2 diabetes, hypertension, dyslipidemia, acanthosis nigricans and polycystic ovarian syndrome. Although there are some genetic causes for insulin resistance, the most common cause is an excess of nutrition a condition called "Nutrient Toxicity". Both excess glucose and excess fat can cause insulin resistance in muscle and fat tissues and excess fat can cause insulin resistance in the liver. High fat feeding and fat infusion rapidly lead to the development of insulin resistance caused by impairment in glucose transport. Other studies have shown defects in insulin signaling possibly secondary to activation of Protein Kinase C resulting from the accumulation of active fatty acyl CoA's. Glucose toxicity has been studied both in vivo and in vitro. In vivo it has been shown that rats over-expressing the gluconeogenic enzyme Phosphoenol Pyruvate Carboxykinase (PEPCK) develop insulin resistance in fat and muscle tissues and some features of the metabolic syndrome including mild obesity and dyslipidemia. Excess glucose entry in fat cells results in increased flux through the hexosamine biosynthesis pathway leading to activation of protein kinase C and impairment of glucose transport. Obesity resulting from excess nutrient intake can also cause insulin resistance by an increase in the production of agents that impair insulin action such as TNFalpha and resistin and a decrease in the production of an insulin sensitizing compound adiponectin. Both glucose and free fatty acids acutely stimulate insulin secretion but chronic exposure to high levels of either nutrient leads to impairment of beta cell function. The combination of insulin resistance and beta cell failure leads to diabetes. Nutrient toxicity is thus the driving cause of the diabetes epidemic that is being recorded around the world.
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PMID:Mechanisms of insulin resistance caused by nutrient toxicity. 1620 73

The transcription factor farnesoid X receptor (FXR) has recently been implicated in the control of hepatic triglyceride production. Activation of FXR may ameliorate hypertriglyceridemia, a cardinal feature of the metabolic syndrome. Because hamsters share many characteristic features of human lipid metabolism, we used a high-fructose-fed hamster model to study the impact of FXR activation with chenodeoxycholic acid (CDCA) on plasma lipoprotein metabolism. Male Syrian hamsters fed a diet containing 60% kcal from fructose for 2 wk developed hypertriglyceridemia and hypercholesterolemia (+120 and +60%, P = 0.005 and 0.0004 vs. controls) due to increased hepatic lipoprotein production. This could be largely attributed to enhanced hepatic de novo lipogenesis, as indicated by increased expression of sterol regulatory element-binding protein-1, fatty acid synthase, and steaoryl-CoA desaturase-1. Lipoprotein analysis demonstrated that the increase in plasma triglycerides occurred in the VLDL density range, whereas increases in VLDL, IDL/LDL, and HDL cholesterol accounted for the elevated plasma cholesterol concentrations. Addition of 0.1% CDCA to the high-fructose diet decreased hepatic de novo lipogenesis and consequently triglyceride production and prevented the increases in plasma triglycerides and cholesterol (-40 and -18%, P = 0.03 and 0.03 vs. high fructose-fed animals). CDCA-treated animals had lower VLDL triglycerides and decreased VLDL and IDL/LDL cholesterol plasma concentrations. These data demonstrate that activation of FXR with CDCA effectively lowers plasma triglyceride and cholesterol concentrations, mainly by decreasing de novo lipogenesis and hepatic secretion of triglyceride-rich lipoproteins. Our studies identify activators of FXR as promising new tools in the therapy of hypertriglyceridemic states, including the insulin resistance syndrome and type 2 diabetes.
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PMID:Activation of the farnesoid X receptor improves lipid metabolism in combined hyperlipidemic hamsters. 1629 72

Enzymes of the medium-chain acyl-CoA synthetase (MACS) family catalyze the ligation of medium chain fatty acids with CoA to produce medium-chain-acyl-CoA. At least four members of the MACS gene family are clustered on human chromosome 16p12. Association studies in the Japanese Suita cohort of MACS polymorphisms and various phenotypes revealed the contribution of the Leu513Ser polymorphism in MACS2 to multiple risk factors of the metabolic syndrome. Here, we investigated the association between this polymorphism and different risk factors in the Caucasian Metabolic Intervention Cohort Kiel. Seven hundred and sixteen male subjects aged 45-65 years were recruited for a standard oral glucose tolerance test and the postprandial assessment of metabolic parameters after an oral metabolic tolerance test (oMTT; 1017 kcal, 51.6% fat, 29.6% carbohydrates, 11.9% protein). The MACS2 Leu513Ser polymorphism was determined by TaqMan-Assay in 705 subjects. Postprandial triglyceride levels following oMTT [area under the curve (AUC)] were significantly higher in subjects carrying the Ser allele compared to subjects homozygous for the Leu allele (1690 +/- 100 mg x h/dL versus 1514 +/- 39 mg x h/dL, p = 0.04). Significant differences between genotype groups were also found for fasting (108 +/- 1.9 mg/dL versus 104 +/- 0.66 mg/dL, p = 0.04) and postprandial (AUC 535 +/- 11 versus 512 +/- 4.0, p = 0.02) glucose levels as well as for high-density-lipoprotein, body mass index, waist circumference, systolic and diastolic blood pressure. Carriers of the Ser allele also show an increased risk of impaired glucose metabolism (OR: 1.48, 95% confidence interval: 0.98-2.27, p = 0.07), adiposity (1.8, 1.16-2.81, p = 0.01) and hypertension (1.5, 0.99-2.17, p = 0.06). In conclusion, our results suggest an involvement of the MACS2 Leu513Ser polymorphism in the development of the metabolic syndrome in Caucasian population. Additionally, the higher triglyceride and glucose levels after an oMTT support a possible functional impact of the polymorphism in vivo.
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PMID:The L513S polymorphism in medium-chain acyl-CoA synthetase 2 (MACS2) is associated with risk factors of the metabolic syndrome in a Caucasian study population. 1652 Nov 60

Insulin has a major anabolic function leading to storage of lipidic and glucidic substrates. All its effects result from insulin binding to a specific membrane receptor which is expressed at a high level on the 3 insulin target tissues: liver, adipose tissue and muscles. The insulin receptor exhibits a tyrosine-kinase activity which leads, first, to receptor autophosphorylation and then to tyrosine phosphorylation of substrates proteins, IRS proteins in priority. This leads to the formation of macromolecular complexes close to the receptor. The two main transduction pathways are the phosphatidylinositol 3 kinase pathway activating protein kinase B which is involved in priority in metabolic effects, and the MAP kinase pathway involved in nuclear effects, proliferation and differentiation. However, in most cases, a specific effect of insulin requires the participation of the two pathways in a complex interplay which could explain the pleiotropy and the specificity of the insulin signal. The negative control of the insulin signal can result from hormone degradation or receptor dephosphorylation. However, the major negative control results from phosphorylation of serine/threonine residues on the receptor and/or IRS proteins. This phosphorylation is activated in response to different signals involved in insulin resistance, hyperinsulinism, TNFalpha or increased free fatty acids from adipose tissue, which are transformed inside the cell in acyl-CoA. A deleterious role for molecules issued from the adipose tissue is postulated in the resistance to insulin of the liver and muscles present in type 2 diabetes, obesity and metabolic syndrome.
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PMID:[Insulin signaling: mechanisms altered in insulin resistance]. 1659 3

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