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)

Recent epidemiological evidence suggests that although lowering low-density lipoprotein (LDL) cholesterol is important in decreasing cardiovascular disease morbidity and mortality, it accounts only for part of the coronary artery disease (CAD) improvement with lipid-lowering therapy. In the last decade, it has become evident that the atherogenicity of LDL particles is associated not only with their plasma levels, but also with their size and density. The presence of small, dense LDL particles is associated with a three fold increase in CAD risk. Hepatic lipase (HL), a key enzyme in the formation of small, dense LDL particles, modulates their phospholipid and triglyceride contents. The higher the HL activity, the smaller, denser, and more atherogenic the resulting lipoprotein particle. It is, therefore, plausible to hypothesize that at least part of the CAD benefits observed in the recent CAD-prevention pharmacological trials, which are not accounted for by the decrease in LDL-C (LDL-cholesterol), might be explained by a pharmacological effect on LDL size and density, possibly mediated by changes in hepatic lipase activity. By studying patients with dyslipidemia and CAD, we have been able to provide strong evidence that regression of coronary atherosclerosis results from at least two independent effects of lipid-lowering therapy on lipoprotein metabolism: the well known one that leads to changes in LDL-C and apo B levels, and a new pathway of HL-mediated improvement in LDL buoyancy. Finally, HL activity and LDL density appear to be significantly affected by the presence of a common C-->T substitution at position -514 with respect to the transcription start site of the HL gene, raising the possibility that the -514 C-->T polymorphism may significantly contribute to differences in individual CAD response to lipid-lowering treatment, as seen in the recent major primary and secondary CAD-prevention clinical trials.
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PMID:Hepatic lipase as a focal point for the development and treatment of coronary artery disease. 1121 40

Qualitative and quantitative anomalies of low-density lipoproteins (LDL) play a key role in the pathophysiology of atherosclerosis. Such anomalies are characteristics of the atherogenic dyslipidemias which occur most frequently, i.e. primary hypercholesterolemia of phenotype IIA (including familial hypercholesterolemia), combined hyperlipidemias (Type IIB) and hypertriglyceridemia (Type IV). An elevated concentration of circulating LDL occurs either as a result of hepatic overproduction of VLDL particles, the major precursors of LDL, or as a result of delayed catabolism, as occurs when there is a deficit of cellular LDL receptors (e.g. familial hypercholesterolemia), or as a combination of both. The major qualitative anomaly of LDL which results in elevated atherogenicity involves a predominance of small dense LDL, as seen in patients with premature coronary heart disease and equally in combined hyperlipidemia and in hypertriglyceridemia. The mechanism of the formation of these particles is complex and involves the concerted intravascular action of cholesteryl ester transfer protein (CETP), lipoprotein lipase (LPL) and hepatic lipase (HL) on triglyceride-rich precursors of dense LDL Lipid-lowering agents, such as fibrates and statins, act to reduce the atherogenicity of dense LDL by distinct mechanisms, which lead to normalisation of circulating LDL levels and/or to targeted reduction in dense particles of elevated atherogenicity. Indeed, such pharmacological probes have facilitated new insight into the molecular and cellular mechanisms which underlie each of the major forms of atherogenic dyslipidemia.
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PMID:[Role of anomalies of low density lipoproteins (LDL) in atherogenicity]. 1147 67

A mouse model of insulin resistance and its associated dyslipidemia was generated by crossing mice expressing human apolipoprotein B (apoB) with mice lacking only brown adipose tissue (BATless). On a high fat diet, male apoB/BATless mice became obese, hypercholesterolemic, hypertriglyceridemic, and hyperinsulinemic compared with control apoB mice. Fast performance liquid chromatography revealed increased triglyceride concentrations in intermediate density lipoprotein/low density lipoprotein (LDL) and reduced high density lipoprotein cholesterol concentrations. Inhibition of lipolysis by the drug, tetrahydrolipostatin, demonstrated that very low density lipoprotein-sized particles were initially secreted. Metabolic studies employing Triton WR-1339 and either [(3)H]glycerol or [(3)H]palmitate showed that the hypertriglyceridemia in apoB/BATless mice was due to the increased synthesis and secretion of triglyceride. Furthermore, lipoprotein lipase and hepatic lipase activities were not defective. ApoB was also secreted at increased rates in the apoB/BATless mice. Similar levels of apoB mRNA in apoB and apoB/BATless mice indicated that apoB secretion was regulated post-transcriptionally. LDL receptor mRNA was increased in the apoB/BATless mice, indicating that the observed increase in apoB-lipoprotein secretion was not due to their decreased reuptake. Finally, mRNA levels of the large subunit of microsomal triglyceride transfer protein, a required component for very low density protein assembly, were not different between apoB and apoB/BATless mice. This rodent model should prove useful in exploring mechanisms underlying the regulation of apoB secretion in the context of insulin resistance.
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PMID:Post-transcriptional stimulation of the assembly and secretion of triglyceride-rich apolipoprotein B lipoproteins in a mouse with selective deficiency of brown adipose tissue, obesity, and insulin resistance. 1159 38

Hepatic lipase (HL) and cholesteryl ester transfer protein (CETP) have been independently associated with low density lipoprotein (LDL) and high density lipoprotein (HDL) size in different cohorts. These studies have been conducted mainly in men and in subjects with dyslipidemia. Ours is a comprehensive study of the proposed biochemical determinants (lipoprotein lipase, HL, CETP, and triglycerides) and genetic determinants (HL gene [LIPC] and Taq1B) of small dense LDL (sdLDL) and HDL subspecies in a large cohort of 120 normolipidemic, nondiabetic, premenopausal women. HL (P<0.001) and lipoprotein lipase activities (P=0.006) were independently associated with LDL buoyancy, whereas CETP (P=0.76) and triglycerides (P=0.06) were not. The women with more sdLDL had higher HL activity (P=0.007), lower HDL2 cholesterol (P<0.001), and lower frequency of the HL (LIPC) T allele (P=0.034) than did the women with buoyant LDL. The LIPC variant was associated with HL activity (P<0.001), HDL2 cholesterol (P=0.034), and LDL buoyancy (P=0.03), whereas the Taq1B polymorphism in the CETP gene was associated with CETP mass (P=0.002) and HDL3 cholesterol (P=0.039). These results suggest that HL activity and HL gene promoter polymorphism play a significant role in determining LDL and HDL heterogeneity in healthy women without hypertriglyceridemia. Thus, HL is an important determinant of sdLDL and HDL2 cholesterol in normal physiological states as well as in the pathogenesis of various disease processes.
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PMID:Contribution of hepatic lipase, lipoprotein lipase, and cholesteryl ester transfer protein to LDL and HDL heterogeneity in healthy women. 1195 Jul 8

The composition and the transport of lipoproteins are seriously disturbed in thyroid diseases. Overt hypothyroidism is characterized by hypercholesterolaemia and a marked increase in low-density lipoproteins (LDL) and apolipoprotein B (apo A) because of a decreased fractional clearance of LDL by a reduced number of LDL receptors in the liver. The high-density lipoprotein (HDL) levels are normal or even elevated in severe hypothyroidism because of decreased activity of cholesteryl-ester transfer protein (CETP) and hepatic lipase (HL), which are enzymes regulated by thyroid hormones. The low activity of CETP, and more specifically of HL, results in reduced transport of cholesteryl esters from HDL(2) to very low-density lipoproteins (VLDL) and intermediate low-density lipoprotein (IDL), and reduced transport of HDL(2) to HDL(3). Moreover, hypothyroidism increases the oxidation of plasma cholesterol mainly because of an altered pattern of binding and to the increased levels of cholesterol, which presents a substrate for the oxidative stress. Cardiac oxygen consumption is reduced in hypothyroidism. This reduction is associated with increased peripheral resistance and reduced contractility. Hypothyroidism is often accompanied by diastolic hypertension that, in conjunction with the dyslipidemia, may promote atherosclerosis. However, thyroxine therapy, in a thyrotropin (TSH)-suppressive dose, usually leads to a considerable improvement of the lipid profile. The changes in lipoproteins are correlated with changes in free thyroxine (FT(4)) levels. Hyperthyroidism exhibits an enhanced excretion of cholesterol and an increased turnover of LDL resulting in a decrease of total and LDL cholesterol, whereas HDL are decreased or not affected. The action of thyroid hormone on Lp(a) lipoprotein is still debated, because both decrease or no changes have been reported. The discrepancies are mostly because of genetic polymorphism of apo(a) and to the differences between the various study groups. Subclinical hypothyroidism (SH) is associated with lipid disorders that are characterized by normal or slightly elevated total cholesterol levels, increased LDL, and lower HDL. Moreover, SH has been associated with endothelium dysfunction, aortic atherosclerosis, and myocardial infarction. Lipid disorders exhibit great individual variability. Nevertheless, they might be a link, although it has not been proved, between SH and atherosclerosis.
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PMID:Thyroid disease and lipids. 1203 52

Traditional risk factors for coronary artery disease (CAD) predict about 50% of the risk of developing CAD. The Adult Treatment Panel (ATP) III has defined emerging risk factors for CAD, including small, dense low-density lipoprotein (LDL). Small, dense LDL is often accompanied by increased triglycerides (TGs) and low high-density lipoprotein (HDL). An increased number of small, dense LDL particles is often missed when the LDL cholesterol level is normal or borderline elevated. Small, dense LDL particles are present in families with premature CAD and hyperapobetalipoproteinemia, familial combined hyperlipidemia, LDL subclass pattern B, familial dyslipidemic hypertension, and syndrome X. The metabolic syndrome, as defined by ATP III, incorporates a number of the components of these syndromes, including insulin resistance and intra-abdominal fat. Subclinical inflammation and elevated procoagulants also appear to be part of this atherogenic syndrome. Overproduction of very low-density lipoproteins (VLDLs) by the liver and increased secretion of large, apolipoprotein (apo) B-100-containing VLDL is the primary metabolic characteristic of most of these patients. The TG in VLDL is hydrolyzed by lipoprotein lipase (LPL) which produces intermediate-density lipoprotein. The TG in intermediate-density lipoprotein is hydrolyzed further, resulting in the generation of LDL. The cholesterol esters in LDL are exchanged for TG in VLDL by the cholesterol ester tranfer proteins, followed by hydrolysis of TG in LDL by hepatic lipase which produces small, dense LDL. Cholesterol ester transfer protein mediates a similar lipid exchange between VLDL and HDL, producing a cholesterol ester-poor HDL. In adipocytes, reduced fatty acid trapping and retention by adipose tissue may result from a primary defect in the incorporation of free fatty acids into TGs. Alternatively, insulin resistance may promote reduced retention of free fatty acids by adipocytes. Both these abnormalities lead to increased levels of free fatty acids in plasma, increased flux of free fatty acids back to the liver, enhanced production of TGs, decreased proteolysis of apo B-100, and increased VLDL production. Decreased removal of postprandial TGs often accompanies these metabolic abnormalities. Genes regulating the expression of the major players in this metabolic cascade, such as LPL, cholesterol ester transfer protein, and hepatic lipase, can modulate the expression of small, dense LDL but these are not the major defects. New candidates for major gene effects have been identified on chromosome 1. Regardless of their fundamental causes, small, dense LDL (compared with normal LDL) particles have a prolonged residence time in plasma, are more susceptible to oxidation because of decreased interaction with the LDL receptor, and enter the arterial wall more easily, where they are retained more readily. Small, dense LDL promotes endothelial dysfunction and enhanced production of procoagulants by endothelial cells. Both in animal models of atherosclerosis and in most human epidemiologic studies and clinical trials, small, dense LDL (particularly when present in increased numbers) appears more atherogenic than normal LDL. Treatment of patients with small, dense LDL particles (particularly when accompanied by low HDL and hypertriglyceridemia) often requires the use of combined lipid-altering drugs to decrease the number of particles and to convert them to larger, more buoyant LDL. The next critical step in further reduction of CAD will be the correct diagnosis and treatment of patients with small, dense LDL and the dyslipidemia that accompanies it.
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PMID:Clinical relevance of the biochemical, metabolic, and genetic factors that influence low-density lipoprotein heterogeneity. 1241 79

Hepatic lipase (HL) plays a central role in LDL and HDL remodeling. High HL activity is associated with small, dense LDL particles and with reduced HDL2 cholesterol levels. HL activity is determined by an HL gene promoter polymorphism, by gender (lower in premenopausal women), and by visceral obesity with insulin resistance. The activity is affected by dietary fat intake and selected medications. There is evidence for an interaction of the HL promoter polymorphism with visceral obesity, dietary fat intake, and with lipid-lowering medications in determining the level of HL activity. The dyslipidemia with high HL activity is a potentially proatherogenic lipoprotein profile in the metabolic syndrome, in Type 2 diabetes, and in familial combined hyperlipidemia.
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PMID:Hepatic lipase and dyslipidemia: interactions among genetic variants, obesity, gender, and diet. 1263 74

Protease inhibitor-based highly active antiretroviral therapy (PI-HAART) has been implicated in dyslipidemia, peripheral insulin resistance, and abnormal adipose tissue deposition in human immunodeficiency virus (HIV) and acquired immunodeficiency syndrome, or AIDS. In vitro evidence indicates that some PIs reduce adipocyte lipoprotein (LPL) and hepatic lipase (HL) expression and activities. We examined whether LPL and HL activities are reduced in HIV-infected patients with dyslipidemia. Fasting serum lipids, glucoregulatory hormones, and postheparin LPL and HL activities, as well as whole body and regional adiposity, were measured in 19 HIV-seronegative controls, 9 HIV+ patients naive to all anti-HIV medications, 9 HIV+ patients naive to PIs, 9 HIV+ patients with prior PI experience but not currently receiving PIs, and 47 HIV+ patients receiving PI-HAART. The PI-HAART group had low LPL and HL activities. However, multiple linear regression analysis indicated that low postheparin LPL activity contributed only partially to HIV-dyslipidemia. Central adiposity and high C-peptide levels (an indicator of high insulin secretion) were stronger predictors of HIV-dyslipidemia. Low LPL and HL activities, by themselves, were insufficient to explain HIV-dyslipidemia because the PI-naive group had low LPL and HL activities but had normal adiposity, C-peptide levels, and serum lipid and lipoprotein levels. HDL-cholesterol was lower in PI-HAART and PI-naive groups than seronegative controls and was directly associated with LPL activity. These findings suggest that HIV-dyslipidemia is mediated primarily by factors that influence triglyceride and lipoprotein synthesis (e.g., central adiposity and hyperinsulinemia) and mediated only partially by factors that influence triglyceride clearance (e.g., lipase activity).
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PMID:Visceral adiposity, C-peptide levels, and low lipase activities predict HIV-dyslipidemia. 1283 64

Excessive weight gain in a subset of intensively treated Diabetes Control and Complications Trial (DCCT) subjects was associated with higher waist to hip ratio; higher triglyceride (TG), low-density lipoprotein (LDL) cholesterol, and apolipoprotein B (ApoB) in the presence of small-dense LDL; and decreased high-density lipoprotein 2 cholesterol (HDL2-C), suggesting that weight gain in these subjects resulted in higher intraabdominal fat (IAF), and an atherosclerotic dyslipidemia mediated through hepatic lipase activity (HL). Objectives were to investigate relationships between IAF, HL, and dyslipidemia and to relate IAF to previous body mass index change during the DCCT. Sixty-one subjects were studied approximately 4 yr after DCCT closeout. IAF was positively related to HL (P < 0.001). IAF positively correlated with logTG (P < 0.001) and ApoB (P < 0.001), and negatively with LDL relative flotation rate (P < 0.001) and logHDL2-C (P = 0.001). HL accounted for most of the relationship between IAF with logHDL2-C and LDL relative flotation rate, and none of the relationship between IAF and logTG or ApoB. DCCT-related body mass index change accounted for a significant portion of logIAF variance measured 4 yr later (P < 0.001). Elevated IAF in subjects with type 1 diabetes was related to an atherosclerotic dyslipidemia similar to that seen in individuals without diabetes who have metabolic syndrome. DCCT-related weight gain positively correlated with subsequent IAF.
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PMID:Visceral obesity, hepatic lipase activity, and dyslipidemia in type 1 diabetes. 1284 91

Hypertriglyceridemia, low plasma concentrations of high density lipoproteins (HDL) and qualitative changes in low density lipoproteins (LDL) comprise the typical dyslipidemia of insulin resistant states and type 2 diabetes. Although isolated low plasma HDL-cholesterol (HDL-c) and apolipoprotein A-I (apo A-I, the major apolipoprotein component of HDL) can occur in the absence of hypertriglyceridemia or any other features of insulin resistance, the majority of cases in which HDL-c is low are closely linked with other clinical features of insulin resistance and hypertriglyceridemia. We and others have postulated that triglyceride enrichment of HDL particles secondary to enhanced CETP-mediated exchange of triglycerides and cholesteryl ester between HDL and triglyceride-rich lipoproteins, combined with the lipolytic action of hepatic lipase (HL), are driving forces in the reduction of plasma HDL-c and apoA-I plasma concentrations. The present review focuses on these metabolic alterations in insulin resistant states and their important contributions to the reduction of HDL-c and HDL-apoA-I plasma concentrations.
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PMID:Mechanisms of HDL lowering in insulin resistant, hypertriglyceridemic states: the combined effect of HDL triglyceride enrichment and elevated hepatic lipase activity. 1295 Nov 68


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