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)

Lipoprotein metabolism is the result of a complex network of many individual components. Abnormal lipoprotein concentrations can result from changes in the production, conversion, or catabolism of lipoprotein particles. Studies in hypolipoproteinemia and hyperlipoproteinemia have elucidated the processes that control VLDL secretion as well as VLDL and LDL catabolism. Here, we review the current knowledge regarding apolipoprotein B (apoB) metabolism, focusing on selected clinically relevant conditions. In hypobetalipoproteinemia attributable to truncations in apoB, the rate of secretion is closely linked to the length of apoB. On the other hand, in patients with the metabolic syndrome, it appears that substrate, in the form of free fatty acids, coupled to the state of insulin resistance can induce hypersecretion of VLDL-apoB. Studies in patients with familial hypercholesterolemia, familial defective apoB, and mutant forms of proprotein convertase subtilisin/kexin type 9 show that mutations in the LDL receptor, the ligand for the receptor, or an intracellular chaperone for the receptor are the most important determinants in regulating LDL catabolism. This review also demonstrates the variance of results within similar, or even the same, phenotypic conditions. This underscores the sensitivity of metabolic studies to methodological aspects and thus the importance of the inclusion of adequate controls in studies.
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PMID:Thematic review series: patient-oriented research. What we have learned about VLDL and LDL metabolism from human kinetics studies. 1672 Aug 94

There is a paucity of data concerning the metabolic syndrome (MetS) in families with familial combined hyperlipidemia (FCHL), familial hypertriglyceridemia (FHTG), familial hypercholesterolemia (FH) and normolipidemic families in China. This study investigated the prevalence of MetS in these families and explored potential factors relevant to MetS. We recruited 70 families with 560 individuals > or = 20 years of age, including 43 FCHL families with 379 individuals, 3 FHTG families with 30 individuals, 16 FH families with 102 individuals and 8 normolipidemic families with 49 individuals. The definition of MetS is determined using modified criteria of National Cholesterol Education Program substituting body mass index for waist circumference. MetS is identified in 60.7% of FCHL patients and 71.4% of FHTG patients. The prevalence of MetS in family members is 36.7% for FCHL, 33.3% for FHTG, 17.6% for FH and 16.3% for normolipidemic families, with an odds ratio (OR) of 2.97 (95% CI 1.29-7.07, P=0.007) in FCHL families compared with normolipidemic families. Apolipoprotein B (apoB) is associated with MetS by multiple logistic analysis with an OR of 1.05 (1.03-1.07, P<0.001) in FCHL families, OR of 1.26 (1.03-1.55, P=0.026) in FHTG and OR of 1.07 (1.01-1.12, P=0.014) in FH families, independent of variables including age, gender, apolipoprotein A1, and low density lipoprotein cholesterol. Apolipoprotein A1 provided an OR of 0.95 (0.94-0.97, P<0.001) in FCHL families and OR of 0.94 (0.90-0.97, P=0.011) in FH families, but neither in FHTG nor in normolipidemic families (both P>0.05). Thus, apoB may be regarded as a relevant factor in the assessment of MetS in FCHL, FHTG and FH families. However, this finding needs to be verified by prospective studies in diverse ethnicities and warrants additional studies to elucidate possible mechanisms linking apoB to MetS.
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PMID:Apolipoprotein B is associated with metabolic syndrome in Chinese families with familial combined hyperlipidemia, familial hypertriglyceridemia and familial hypercholesterolemia. 1682 5

The 3-hydroxy-3-methylglutaryl coenzyme A reductase inhibitors or statins are the most successful cardiovascular drugs of all time. By interrupting cholesterol synthesis in the liver, they activate hepatocyte low-density lipoprotein (LDL) receptors and produce consistent and predictable reductions in circulating LDL cholesterol with resulting reproducible improvements in cardiovascular risk by retarding or even regressing the march of atherosclerosis in all major arterial trees (coronary, cerebral and peripheral). Clinical trials have demonstrated their capacity not only to extend life, but also to improve its quality by retarding the progression of diabetes mellitus and chronic renal disease and by enhancing central and peripheral blood flow. They are amongst the most extensively investigated pharmaceutical agents in current clinical use. In cardiovascular end-point trials they have proven ability to help prevent that first and all important myocardial infarction and to reduce the likelihood of a recurrence in those who do succumb. They are equally effective in men and women of all ages and at all levels of cardiovascular risk, whether caused by hypercholesterolaemia, hypertension, cigarette smoking, diabetes mellitus or the metabolic syndrome. In addition, they improve the outlook of patients with familial hypercholesterolaemia whose LDL receptor function is deficient or defective; and all of this comes at minimal risk to the recipient. Their most important potential side effect is myopathy, which on very rare occasions may lead to rhabdomyolysis. Clinical experience shows that myopathic symptoms with creatine kinase levels raised to more than 10 times the upper limit of normal is seen in <0.01% of recipients and progression to fatal rhabdomyolysis because of renal failure has been recorded in only 0.15 cases per million prescriptions. Liver function abnormalities are also, rarely, seen. Again, the frequency of raised aspartate or alanine aminotransferase to more than three times the normal limit is encountered in no more than 1-2% of all treated patients and is completely reversible upon withdrawal of treatment. Progression to hepatitis or liver failure does not occur. This constellation of benefits with little side effect penalty has resulted in the comparison of statins with antibiotics in the global battle against cardiovascular disease.
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PMID:Who should receive a statin these days? Lessons from recent clinical trials. 1696 68

Obesity, hyperlipidemia, and insulin resistance are cardinal features of the metabolic syndrome and individually increase the risk for developing diabetes and cardiovascular disease, a risk that is amplified when they are simultaneously present. It is becoming increasingly clear that macrophages can infiltrate white adipose tissue (WAT) in the obese state, and their presence is associated with pathophysiological consequences of obesity, such as inflammation and insulin resistance. To determine whether hyperlipidemia could potentiate macrophage infiltration into WAT in the presence of obesity, obesity-prone agouti yellow mice (A(y)/a) on a hyperlipidemia-prone LDL receptor (LDLR)-deficient (LDLR(-/-)) background were placed on chow or Western diet. In addition, A(y)/a mice that were LDLR sufficient were also placed on Western diet. Both genetics and diet increased the degree of adiposity; however, plasma lipids were elevated only in the Western diet-fed LDLR(-/-) mice. The extent of macrophage accumulation in WAT correlated with the degree of adiposity. However, hyperlipidemia did not impact macrophage recruitment to WAT or the downstream metabolic consequences of macrophage accumulation in WAT, such as inflammation and insulin resistance. These data have important implications for the pathogenesis of diet-induced obesity in humans, even when plasma lipid abnormalities are not present.
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PMID:Diet-induced increases in adiposity, but not plasma lipids, promote macrophage infiltration into white adipose tissue. 1732 23

Glucocorticoids, which are well established to regulate body fat mass distribution, adipocyte lipolysis, hepatic gluconeogenesis, and hepatocyte VLDL secretion, are speculated to play a role in the pathology of metabolic syndrome. Recent focus has been on the activity of 11beta-hydroxysteroid dehydrogenase type 1 (11beta-HSD1), which is capable of regenerating, and thus amplifying, glucocorticoids in key metabolic tissues such as liver and adipose tissue. To determine the effects of global 11beta-HSD1 inhibition on metabolic syndrome risk factors, we subcutaneously injected "Western"-type diet-fed hyperlipidemic mice displaying moderate or severe obesity [LDL receptor (LDLR)-deficient (LDLR(-/-)) mice and mice derived from heterozygous agouti (A(y)/a) and homozygous LDLR(-/-) breeding pairs (A(y)/a;LDLR(-/-) mice)] with the nonselective 11beta-HSD inhibitor carbenoxolone for 4 wk. Body composition throughout the study, end-point fasting plasma, and extent of hepatic steatosis and atherosclerosis were assessed. This route of treatment led to detection of high levels of carbenoxolone in liver and fat and resulted in decreased weight gain due to reduced body fat mass in both mouse models. However, only A(y)/a;LDLR(-/-) mice showed an effect of 11beta-HSD1 inhibition on fasting insulin and plasma lipids, coincident with a reduction in VLDL due to mildly increased VLDL clearance and dramatically decreased hepatic triglyceride production. A(y)/a;LDLR(-/-) mice also showed a greater effect of the drug on reducing atherosclerotic lesion formation. These findings indicate that subcutaneous injection of an 11beta-HSD1 inhibitor allows for the targeting of the enzyme in not only liver, but also adipose tissue, and attenuates many metabolic syndrome risk factors, with more pronounced effects in cases of severe obesity and hyperlipidemia.
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PMID:Carbenoxolone treatment attenuates symptoms of metabolic syndrome and atherogenesis in obese, hyperlipidemic mice. 1787 20

Insulin resistance plays a central role in the development of the metabolic syndrome, but how it relates to cardiovascular disease remains controversial. Liver insulin receptor knockout (LIRKO) mice have pure hepatic insulin resistance. On a standard chow diet, LIRKO mice have a proatherogenic lipoprotein profile with reduced high-density lipoprotein (HDL) cholesterol and very low-density lipoprotein (VLDL) particles that are markedly enriched in cholesterol. This is due to increased secretion and decreased clearance of apolipoprotein B-containing lipoproteins, coupled with decreased triglyceride secretion secondary to increased expression of Pgc-1 beta (Ppargc-1b), which promotes VLDL secretion, but decreased expression of Srebp-1c (Srebf1), Srebp-2 (Srebf2), and their targets, the lipogenic enzymes and the LDL receptor. Within 12 weeks on an atherogenic diet, LIRKO mice show marked hypercholesterolemia, and 100% of LIRKO mice, but 0% of controls, develop severe atherosclerosis. Thus, insulin resistance at the level of the liver is sufficient to produce the dyslipidemia and increased risk of atherosclerosis associated with the metabolic syndrome.
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PMID:Hepatic insulin resistance is sufficient to produce dyslipidemia and susceptibility to atherosclerosis. 1824 66

In the circulation, cholesterol and triglycerides are enveloped in apolipoproteins and phospholipids, and transported as complex particles called lipoproteins. Abnormal levels of lipoproteins occur in children either because of a genetic defect in lipid metabolism pathways (primary lipid disorders, e.g. familial hypercholesterolemia [FH]) or secondary to other diseases or conditions (e.g. insulin resistance) and can be clinically significant; for example, elevated low-density lipoprotein cholesterol levels are a major risk factor for future cardiovascular disease. Patients with primary lipid disorders in childhood such as FH can exhibit early atherosclerotic lesions in childhood. Other risk factors for cardiovascular disease, such as obesity and type 2 diabetes mellitus, are increasingly common in the pediatric population, and are often associated with dyslipidemia. Thus, pediatricians should be aware of how to screen, diagnose and treat dyslipidemia. The majority of lipid disorders in children can be managed with diet and lifestyle modification. Pharmacologic therapy (e.g. statins) may be added if target lipoprotein levels are not achieved. Clinicians may be guided in patient management by recent scientific statements from the American Heart Association; however, existing National Cholesterol Education Program treatment guidelines should be urgently updated to incorporate new evidence regarding atherosclerosis pathophysiology, obesity and the metabolic syndrome, emerging cardiovascular risk factors, and pharmacologic therapy in pediatric patients.
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PMID:Primary and secondary disorders of lipid metabolism in pediatrics. 1831 44

The metabolic syndrome is a common and complex disorder combining obesity, dyslipidemia, hypertension, and insulin resistance. It is a primary risk factor for diabetes and cardiovascular disease. We showed for the first time that the metabolic syndrome is associated with a higher fraction of oxidized LDL and thus with higher levels of circulating oxidized LDL. Hyperinsulinemia and impaired glycaemic control, independent of lipid levels, were associated with increased in vivo LDL oxidation, as reflected by the higher prevalence of high oxidized LDL. High levels of oxidized LDL were associated with increased risk of future myocardial infarction, even after adjustment for LDL-cholesterol and other established cardiovascular risk factors. This association is in agreement with the finding that accumulation of oxidized LDL, which activates/induces subsets of smooth muscle cells and macrophages to gelatinase production, was associated with upstream localization of a vulnerable plaque phenotype. Dyslipidemia and insulin resistance in obese LDL receptor-deficient mice were associated with increased oxidative stress and impaired HDL-associated antioxidant defence associated with accelerated atherosclerosis due to increased macrophage infiltration and accumulation of oxidized LDL in the aorta. The accumulation of oxidized LDL was partly due to an impaired HDL-associated antioxidant defence due to a decrease in PON. Our data in this experimental model are thus the more relevant because a decrease in PON activity was found to be associated with a defective metabolism of oxidized phospholipids by HDL from patients with type 2 diabetes. Weight loss in leptin-deficient, obese, and insulin-resistant mice was associated with expressional changes of key genes regulating adipocyte differentiation, glucose transport and insulin sensitivity, lipid metabolism, oxidative stress and inflammation, most of which are under the transcriptional control of PPARs. We established an important relationship between PPAR-gamma and SOD1 for the prevention of the oxidation of LDL in the arterial wall. For example we showed that rosuvastatin decreased the oxidized LDL accumulation by increasing the expression of PPAR-gamma and SOD1. In addition, we established a relation between increased PPAR-alpha expression in the adipose tissue and a change in the gene expression pattern, which explains the decrease of free fatty acids, triglycerides and the increase in insulin sensitivity. We demonstrated that plaque oxidized LDL correlated with coronary plaque complexity in a swine atherosclerosis model. Oxidized LDL correlated positively with the expression of IRF1 and TLR2 suggesting a relation between oxidative stress and inflammation in coronary atherosclerotic plaques. Oxidized LDL induced further the expression of TLR2 and IRF1 in macrophages in vitro suggesting a causative link. As in the mouse model described above, plaque oxidized LDL correlated negatively with SOD1 expression and ox-LDL inhibited the expression of SOD1 in macrophages in vitro. We showed that TLR2, CXCR4 and MYC are overexpressed in monocytes of obese women at high cardiovascular risk and that weight loss was associated with a concomitant decrease of their expression. This suggests that the transcription factor cMYC has an atherogenic effect by inducing pro-inflammatory genes. The increased expression of TLR2 and CXCR4 were observed in the absence of an increase in ox-LDL but in the presence of an increase in SOD1. Interestingly, the expression of SOD1 correlated also with that of MYC, suggesting that it has an atherogenic effect by inducing the expression of an anti-oxidant enzyme. How ox-LDL prevents this increase remains to be determined. How we plan to do this is explained in the next part. In aggregate, our studies contributed to a better understanding of the relationships between metabolic syndrome, insulin signalling, oxidative stress and inflammation and atherosclerosis. We identified paraoxonase, interferon regulatory factor-1, toll-like receptors, CXCR4 and SOD1 as possible targets for intervention.
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PMID:Relations between metabolic syndrome, oxidative stress and inflammation and cardiovascular disease. 1866 60

Poor quality of nutrition during fetal development is associated with adverse health outcomes in adult life. Epidemiological studies suggest that markers of fetal undernutrition are predictive of risk of the metabolic syndrome and CHD. Here we show that feeding a low-protein diet during pregnancy programmed the development of atherosclerosis in ApoE*3-Leiden mice. ApoE*3-Leiden mice carry a mutation of human ApoE*3 rendering them prone to atherosclerosis when fed a diet rich in cholesterol. It was noted that fetal exposure to protein restriction led to a greater degree of dyslipidaemia in mice when fed an atherogenic diet, with low-protein-exposed ApoE*3 mice having elevated total plasma cholesterol (34 % higher; P < 0.001) and TAG (39 % higher; P < 0.001) relative to offspring exposed to a control diet in utero. The low-protein group developed more severe atherosclerotic lesions within the aortic arch (2.61-fold greater lesion area; P < 0.001). Analysis of a targeted gene array suggested a potential role for members of the LDL receptor superfamily, along with similar programmed suppression of the mRNA expression of hepatic sterol regulatory element-binding protein-1c. This indicates that disordered lipid metabolism may play a role in the fetal programming of atherosclerosis in this model. Whereas earlier studies have shown early programming of cardiovascular risk factors, these results demonstrate for the first time that the interaction of prenatal undernutrition with a postnatal atherogenic diet increases the extent of atherosclerotic disease.
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PMID:Maternal undernutrition programmes atherosclerosis in the ApoE*3-Leiden mouse. 1878 62

Despite successes in identifying genetic contributors to common metabolic phenotypes, only part of the heritable component of these traits has thus far been explained. Copy number variation (CNV) is likely to be responsible for some of the unexplained variation. As observed with single nucleotide changes, it is probable that both rare and common CNVs will contribute to susceptibility to metabolic disease. For instance, CNVs in the LDLR gene underlie a substantial portion of disease in patients with heterozygous familial hypercholesterolemia. As well, a common CNV in LPA encoding apolipoprotein(a) is the primary determinant of plasma lipoprotein(a) concentrations, a risk factor for atherosclerosis. Recent efforts to map CNVs in control populations have defined their size, frequency and distribution. Many of the identified CNVs overlap genes with important functions in metabolic pathways. The overlap of CNVs that were found in control datasets with functional candidate genes or genes with previous evidence of association with metabolic syndrome presents an important subset for future CNV association studies. Finally, we describe an approach to search for CNVs in a rare high-penetrance metabolic disorder, namely lipodystrophy. As methods to identify CNVs increase in precision and accuracy, the prospect of identifying their role in both rare Mendelian and common complex metabolic phenotypes will become a reality.
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PMID:Copy number variation in metabolic phenotypes. 1928 52

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