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:C0020473 (hyperlipidemia)
15,891 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Human hepatic lipase (HL) is a 477 residue glycoprotein that hydrolyzes triglycerides from plasma lipoproteins. Familial HL deficiency is a rare recessive disorder that is characterized by premature atherosclerosis and abnormal circulating lipoproteins. While studying the HL gene from the world's index family with HL deficiency, we identified four coding sequence variants of HL, one in each of exons 4, 5, 6, and 8. In this report we present the genetic basis for two new HL gene variants, one in each of exons 3 and 5. All six HL DNA variants are single base pair changes. Two variants (at codons 133 and 202) are diallelic DNA polymorphisms that are silent at the amino acid level. One variant (V73M) is an allele that defines an uncommon HL isoprotein. One variant (N193S) has two alleles of approximately equal frequency in the population that specify two common HL isoproteins. Two variants (S267F and T383M) are rare mutations found to date only in HL deficient subjects and their relatives. Of the six HL variants described to date, only S267F and T383M are associated with hyperlipidemia.
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PMID:Human hepatic lipase mutations and polymorphisms. 130 39

Serum concentrations of apolipoprotein(a) [apo(a)], the unique glycoprotein of lipoprotein(a), are increased in patients with end-stage renal failure. We prospectively studied serum apo(a) and other lipoproteins in 20 consecutive patients, ages 46 +/- 11 years, before and for six months after successful renal transplantation. All patients received cyclosporine, and no patient was treated for hyperlipidemia. The mean creatinine clearance increased from 7.5 mL/min before transplant surgery to 40.9 mL/min six months afterwards (P less than 0.001). Apo(a) decreased from a median of 403 units/L before transplantation to 184 units/L at one week (P less than 0.001) and was 170 units/L (P less than 0.001) at six months. For the assay used, 1 unit of apo(a) is equivalent to 1 mg of lipoprotein(a). In contrast, from baseline to six months, increases were found for low-density lipoprotein (LDL) cholesterol (P = 0.03), high-density lipoprotein cholesterol (P = 0.06), apo B (P = 0.07), and apo A-I (P = 0.01). The decrease in apo(a) in individual patients was significantly correlated with the increase in creatinine clearance (r = -0.48, P less than 0.001). The single patient who developed nephrotic syndrome after renal transplantation had marked increases in apo(a) (693-1595 units/L), apo B, and LDL cholesterol, which paralleled the degree of proteinuria. These findings suggest that abnormal renal function affects the regulation of lipoprotein(a) metabolism.
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PMID:Decreases in apolipoprotein(a) after renal transplantation: implications for lipoprotein(a) metabolism. 154 51

Genetic polymorphism and rare mutants of apolipoproteins occur in humans. The polymorphism of apolipoprotein E (apoE) is controlled by three common alleles, epsilon 2, epsilon 3, and epsilon 4, which code for proteins that differ in lipoprotein receptor binding activity, or in their catabolism in vivo, or both. This may explain the observed significant effects of the apoE alleles on the phenotypic variance of plasma lipoprotein concentrations in different ethnic groups and, moreover, the involvement of apoE alleles in the pathogenesis of multifactorial forms of hyperlipidaemia, for example, hypertriglyceridaemia, familial type III hyperlipidaemia (apoE-2 Arg-158----Cys) and polygenic hypercholesterolaemia (apoE-4 Cys-112----Arg). A further polymorphic gene locus controls the concentrations of the Lp(a) lipoprotein complex in plasma, which may vary from less than 1 mg/dl to greater than 200 mg/dl between different individuals. This lipoprotein contains two different polypeptides, apoB-100 and the Lp(a) glycoprotein. The Lp(a) glycoprotein exhibits genetic polymorphism which is controlled by a series of autosomal alleles at a single locus and which is associated with lipoprotein concentrations in plasma. This suggests that the same gene locus is involved in determining Lp(a) glycoprotein phenotypes and Lp(a) lipoprotein concentrations in plasma. Thus, there is evidence that variability in apolipoprotein genes relates to the normal variance of lipoprotein concentrations in the population and that this variability is a major genetic factor in multifactorial forms of hyperlipidaemia.
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PMID:Apolipoproteins, quantitative lipoprotein traits and multifactorial hyperlipidaemia. 296

Apolipoproteins AIV, B, E, and the Lp(a) glycoprotein are genetically polymorphic in humans. Three common alleles epsilon 2, epsilon 3 and epsilon 4 control the polymorphism of apolipoprotein E. These code for proteins which differ in functional properties, e.g. receptor binding activity and in vivo catabolism. This explains the significant effect of the apoE gene locus on the variability of plasma lipoprotein concentrations and moreover the implication of apoE alleles in the aetiology of multifactorial forms of hyperlipidaemia e.g. familial type III hyperlipidaemia (apoE2; arg158----cys) and polygenic hypercholesterolaemia (apoE4; cys112----arg). A further gene locus controls the concentrations in plasma of the Lp(a) lipoprotein that is composed of an LDL-like particle containing apoB-100 and the disulphide-bonded Lp(a) glycoprotein. The latter exhibits a genetic size polymorphism (MW approximately 400 kD-700 kD) that is controlled by at least seven autosomal alleles. These alleles at the same time are involved in determining the plasma concentrations of the lipoprotein that range from less than 1 mg/dl to greater than 200 mg/dl. Thus there is evidence that genetic variability in apolipoproteins relates to the variability of lipoprotein concentrations in the population and is implicated in the aetiology of multifactorial hyperlipidaemias.
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PMID:Apolipoprotein polymorphism and multifactorial hyperlipidaemia. 314 88

The free (unbound) concentration of drug in plasma is often an important determinant of pharmacological and toxicological effects. Unfortunately, studies examining the factors influencing the free fraction of quinidine in plasma have yielded inconsistent results. It is probable that differences in the type of blood collection tubes utilized and the analytical procedure employed biased some of these estimates of quinidine binding. The present study was executed in a manner free of factors now known to introduce artifacts into estimates of the free fraction of quinidine. In healthy volunteers, the free fraction of quinidine (1.0 microgram/mL) was 0.129 +/- 0.019 (mean +/- SD) and was constant throughout the therapeutic range. A high-affinity, low-capacity binding site (K = 1.17 X 10(5) M-1; nP = 3.49 X 10(-5) M) and a low-affinity, high-capacity binding site (K = 1.33 X 10(3) M-1; nP = 3.14 X 10(-3) M) were identified. The characteristics of quinidine binding in a 4.5-g/dL solution of human serum albumin (K = 3.05 X 10(3) M-1; nP = 1.36 X 10(-3) M) suggested that the low-affinity, high-capacity binding site was on this quinidine free fraction increased from 0.114 to 0.231. A lidocaine concentration of 250 micrograms/mL caused a similar increase. Patients suffering traumatic injury had a significant increase in alpha 1-acid glycoprotein concentration (197 mg/dL) and a decreased quinidine free fraction (0.075 +/- 0.019). Patients with hyperlipidemia had free fractions similar to those observed in healthy individuals (0.118 +/- 0.019).(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Factors affecting quinidine protein binding in humans. 649 48

The alpha 1-acid glycoprotein (orosomucoid) concentration in the serum of 34 uremic patients on chronic hemodialysis was measured twice at intervals of 3 months. In 80% of the cases the concentrations are above normal. Furthermore, the examination showed a correlation between the concentrations at the first and at the second measurement. No change in se-orosomucoid concentration was observed during hemodialysis. We therefore conclude that orosomucoid cannot be used as an acute phase reactant among uremic patients in chronic hemodialysis neither is it very likely that the hyperlipidemia and accelerated atherosclerosis in hemodialysis patients are due to lack of orosomucoid.
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PMID:Serum alpha-1-acid glycoprotein (orosomucoid) in uremic patients on hemodialysis. 711 Apr 72

In order to determine whether elevated levels of beta 2 glycoprotein-I (beta 2GPI) are associated with increased plasma lipids, we measured plasma beta 2GPI antigen levels in 47 patients with primary hyperlipidaemia (20 severe hypercholesterolaemia, nine severe hypertriglyceridaemia, and 18 mixed hyperlipidaemia) and 34 normal healthy subjects. Mean beta 2GPI levels were significantly increased in each patient group (302.3, 272.9 and 299.1 mg/l, respectively) compared to controls (199.6 mg/l) (P < 0.01). Significant correlations were demonstrated between beta 2GPI levels and triglyceride and total cholesterol levels in the control group (r = 0.387, r = 0.559; P < 0.05), but were not observed in all patient groups. These results indicate that beta 2GPI is increased in hyperlipidaemia and that its distribution between plasma lipid fractions is perturbed. Plasma lipid levels should therefore be considered when interpreting results of beta 2GPI antigen assays.
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PMID:Beta 2 glycoprotein-I antigen is increased in primary hyperlipidaemia. 780 98

Glycogen storage disease type 1 (GSD-1), also known as von Gierke disease, is a group of autosomal recessive metabolic disorders caused by deficiencies in the activity of the glucose-6-phosphatase (G6Pase) system that consists of at least two membrane proteins, glucose-6-phosphate transporter (G6PT) and G6Pase. G6PT translocates glucose-6-phosphate (G6P) from cytoplasm to the lumen of the endoplasmic reticulum (ER) and G6Pase catalyzes the hydrolysis of G6P to produce glucose and phosphate. Therefore, G6PT and G6Pase work in concert to maintain glucose homeostasis. Deficiencies in G6Pase and G6PT cause GSD-1a and GSD-1b, respectively. Both manifest functional G6Pase deficiency characterized by growth retardation, hypoglycemia, hepatomegaly, kidney enlargement, hyperlipidemia, hyperuricemia, and lactic acidemia. GSD-1b patients also suffer from chronic neutropenia and functional deficiencies of neutrophils and monocytes, resulting in recurrent bacterial infections as well as ulceration of the oral and intestinal mucosa. The G6Pase gene maps to chromosome 17q21 and encodes a 36-kDa glycoprotein that is anchored to the ER by 9 transmembrane helices with its active site facing the lumen. Animal models of GSD-1a have been developed and are being exploited to delineate the disease more precisely and to develop new therapies. The G6PT gene maps to chromosome 11q23 and encodes a 37-kDa protein that is anchored to the ER by 10 transmembrane helices. A functional assay for the recombinant G6PT protein has been established, which showed that G6PT functions as a G6P transporter in the absence of G6Pase. However, microsomal G6P uptake activity was markedly enhanced in the simultaneous presence of G6PT and G6Pase. The cloning of the G6PT gene now permits animal models of GSD-1b to be generated. These recent developments are increasing our understanding of the GSD-l disorders and the G6Pase system, knowledge that will facilitate the development of novel therapeutic approaches for these disorders.
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PMID:The molecular basis of type 1 glycogen storage diseases. 1189 41

We compared the levels of microparticles, platelet activation markers, soluble cell adhesion molecules, soluble selectins, and antioxidized low-density lipoprotein (anti-Ox LDL) antibody between patients with hyperlipidemia and control subjects. Binding of anti-glycoprotein (GP) IIb/IIIa and anti-GPIb monoclonal antibodies to platelets did not differ significantly between the hyperlipidemic patients and controls. However, expression of activation markers (CD62P, CD63, PAC-1, and annexin V) by platelets was higher in the hyperlipidemic patients with Type 2 diabetes. The levels of platelet-derived microparticles (PDMPs) and monocyte-derived microparticles (MDMPs) were significantly different in hyperlipidemic patients with Type 2 diabetes and controls. Soluble P-selectin (sP-selectin), soluble E-selectin (sE-selectin), and anti-Ox LDL antibody also showed higher levels in the hyperlipidemic patients with Type 2 diabetes. After treatment with eicosapentaenoic acid (EPA), the levels of CD62P, CD63, annexin V, PDMPs, and MDMPs, sE-selectin, and oxidized LDL antibody were reduced significantly. Triglyceride (TG) and total cholesterol levels were also decreased. Anti-Ox LDL antibodies and MDMPs were correlated positively with platelet CD62P (plt-CD62P) levels. These findings suggest that in hyperlipidemic patients with Type 2 diabetes, EPA may prevent complications caused by oxidized LDL, E-selectin, and activated platelets or monocytes.
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PMID:Effects of eicosapentaenoic acid on platelet activation markers and cell adhesion molecules in hyperlipidemic patients with Type 2 diabetes mellitus. 1273

Kidney transplant recipients are not only prone to dyslipidemia but also have a high risk of cardiovascular death. Impairment of the fibrinolytic system is thought to be one factor playing a role in development of thrombotic complications. Thrombin-activatable fibrinolysis inhibitor (TAFI) is a glycoprotein, linking coagulation and fibrinolysis. The purpose of this study was to assess TAFI concentrations and activities in renal transplant recipients stratified based upon serum cholesterol values above 220 mg/dL or below 200 mg/dL. The groups did not differ regarding age, creatinine clearance, BMI, time after transplantation, albumin, fibrinogen, thrombomodulin, or PAP. Additionally, we evaluated thrombin activity (thrombin-antithrombin complex TAT, prothrombin fragments 1 + 2); TAFI activator; thrombomodulin (TM), catalyzer of TAFI activation; and the degree of plasmin generation (plasmin-antiplasmin complex PAP) using commercially available kits. In patients with hyperlipidemia significantly higher TAFI concentrations and activities may contribute to prolonged ECLT and lowered fibrinolytic activity index (FAI). Increased levels of F1 + 2 and TAT were observed in hypercholesterolemic patients, indicating enhanced thrombin generation. Elevated TAFI concentration, and activities and enhanced thrombin generation observed in hypercholesterolemic kidney transplant recipients may contribute to hypofibrinolysis and progression of atherosclerosis in this group of patients.
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PMID:Thrombin-activatable fibrinolysis inhibitor in kidney transplant recipient with dyslipidemia. 1452 94


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