EC:3.1.1.34 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.1.1.34 (lipoprotein lipase)
7,025 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The VLDL receptor has been described as a new member of the LDL receptor supergene family that specifically binds VLDL in vitro via apolipoprotein E and lipoprotein lipase. Both apolipoprotein E and lipoprotein lipase are constituents of chylomicron remnants, another triglyceride-rich lipoprotein which has been proposed as a physiological ligand for the VLDL receptor. We used human chylomicron remnants to study their uptake into LDL, receptor-deficient Chinese hamster ovary cells overexpressing the human VLDL receptor. The uptake into these cells was compared to that into cells transfected with an empty transfection vector. Human chylomicron remnants were produced in vitro by hydrolysis with lipoprotein lipase, and were labeled with 125I. The uptake of these remnants into the cells overexpressing the VLDL receptor was found to be about 3-fold higher than the uptake into the control cells. The addition of a surplus of either apolipoprotein E or inactivated lipoprotein lipase to the remnants led to an increase in particle uptake. The chylomicron remnant uptake was inhibited by addition of the 39 kDa receptor associated protein These in vitro experiments strongly support the idea that the VLDL receptor is a physiological receptor for chylomicron remnants. The increase of receptor-mediated uptake induced by the addition of apoE or lipoprotein lipase underlines the role of these two proteins in this process.
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PMID:VLDL receptor mediates the uptake of human chylomicron remnants in vitro. 886 57

In eight patients with familial hypercholesterolemia the effects of two lipid reducing drugs on subpopulations of high density lipoproteins (HDL) were examined. After a 14-week period of diet and diet/placebo a 12-week therapy followed with either bezafibrate (CAS 41859-67-0) or fluvastatin (CAS 93957-55-2). Throughout both treatments a significant decrease of total and low density lipoprotein (LDL)-cholesterol, apolipoprotein B and triglycerides during both therapies were noted as well as an insignificant increase of HDL-cholesterol during bezafibrate. The nondenaturating gradient gel electrophoresis is a valid method for the investigation of the behaviour of HDL and was therefore chosen for this investigation. The individual HDL pattern and HDL diameters did not change in these subjects. The effect on the amounts of HDL 3b and HDL 3c was significantly more extensive during fluvastatin (+2.4% resp. + 2.9%) as compared to during bezafibrate therapy (+1.7% resp. + 2.9%). The changes noted in the HDL subclasses are probably due to a variable lipoprotein metabolism, for example increased activity of lipoprotein lipase, hepatic triglyceride lipase, lecithin-cholesterol acyltransferase and cholesterol ester transfer protein.
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PMID:Effect of fluvastatin or bezafibrate on the distribution of high density lipoprotein subpopulations in patients with familial hypercholesterolemia. 887 36

To study the role of apoC1 in lipoprotein metabolism, we have generated transgenic mice expressing the human APOC1 gene. On a sucrose-rich diet, male transgenic mice with high APOC1 expression in the liver showed elevated levels of serum cholesterol and triglyceride compared with control mice (5.7+/-0.7 and 3.3+/-2.1 vs. 2.7+/-0.1 and 0.4+/-0.1 mmol/liter, respectively). These elevated levels were mainly confined to the VLDL fraction. Female APOC1 transgenic mice showed less pronounced elevated serum lipid levels. In vivo VLDL turnover studies revealed that, in hyperlipidemic APOC1 transgenic mice, VLDL particles are cleared less efficiently from the circulation as compared with control mice. No differences were observed in the hepatic production and extrahepatic lipolysis of VLDL-triglyceride. Also, VLDL isolated from control and APOC1 transgenic mice were found to be equally good substrates for bovine lipoprotein lipase in vitro. These data indicate that the hyperlipidemia in APOC1 transgenic mice results primarily from impaired hepatic VLDL particle clearance, rather than a defect in the hydrolysis of VLDL-triglyceride. To investigate which hepatic receptor is involved in the apoC1-mediated inhibition of VLDL clearance, APOC1 transgenic mice were bred with an LDL receptor-deficient (LDLR(-/-)) background. In addition, control, LDLR(-/-), and LDLR(-/-)/APOC1 mice were transfected with adenovirus carrying the gene for the receptor-associated protein (Ad-RAP). Both serum cholesterol and triglyceride levels were strongly elevated in LDLR(-/-)/APOC1 mice compared with LDLR(-/-) mice (52+/-19 and 36+/-19 vs. 8.4+/-0.9 and 0.5+/-0.2 mmol/liter, respectively), indicating that apoC1 inhibits the alternative VLDL clearance pathway via the remnant receptor. Transfection of LDLR(-/-) mice with Ad-RAP strongly increased serum cholesterol and triglyceride levels, but to a lesser extent than those found in LDLR(-/-)/APOC1 mice (39+/-8 and 17+/-8 vs. 52+/-19 and 36+/-19 mmol/liter, respectively). However, in LDLR(-/-)/APOC1 mice the transfection with Ad-RAP did not further increase serum cholesterol and triglyceride levels (52+/-19 and 36+/-19 vs. 60+/-10 and 38+/-7 mmol/liter, respectively). From these studies we conclude that, in the absence of the LDLR, apoC1 inhibits the hepatic uptake of VLDL via a RAP-sensitive pathway.
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PMID:In the absence of the low density lipoprotein receptor, human apolipoprotein C1 overexpression in transgenic mice inhibits the hepatic uptake of very low density lipoproteins via a receptor-associated protein-sensitive pathway. 894 42

White Carneau pigeons develop atherosclerosis naturally, and at an accelerated rate with cholesterol feeding. Macrophages play a central role in the pathogenesis of atherosclerosis in pigeons, as they do in man. The purpose of this study was to determine whether pigeon macrophages express the alpha 2-macroglobulin receptor/low density lipoprotein receptor-related protein (alpha 2 MR/LRP) and whether this receptor would recognize beta-VLDL, the major cholesterol-transporting lipoprotein in cholesterol-fed pigeons. The binding of 125I-methylamine-treated alpha 2M (125I-alpha 2 M+) at 4 degrees C was saturable (> 10 nM), specific, Ca2+ dependent, was competed for by the receptor-associated protein (RAP), and had a Kd of binding of 1-5.6 nM, similar to mouse peritoneal macrophages studied simultaneously. At 37 degrees C the bound 125I-alpha 2 M+ was rapidly internalized and degraded in lysosomes. The binding of alpha 2 M+ was not down-regulated with cholesterol loading, as is the LDL receptor on pigeon macrophages. At 4 degrees C there was no competition for binding of 125I-alpha 2 M+ by either pigeon or rabbit beta-VLDL, nor was binding of 125I-pigeon or rabbit beta-VLDL competed for by alpha 2 M+. Stimulation of cholesterol esterification by rabbit or pigeon beta-VLDL was unaffected by RAP, lactoferrin, or alpha 2 M+. Metabolism of 125I-pigeon or rabbit beta-VLDL was not competed by RAP, lactoferrin, or alpha 2 M+ even in the presence of lipoprotein lipase. Pigeon macrophages, and a 500 kDa membrane protein isolated from them, were recognized by several antihuman alpha 2 MR/LRP monoclonal antibodies. The 500 kDa membrane protein also bound 45Ca. These data suggest considerable sequence homology with the human alpha 2 MR/LRP. This is the first study to characterize a functional alpha 2 MR/LRP on peritoneal macrophages from an avian species. There was no evidence, however, that the alpha 2 MR/LRP mediates uptake of beta-VLDL by pigeon macrophages.
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PMID:Characterization of alpha 2-macroglobulin receptor low density lipoprotein receptor-related protein (alpha 2 MR/LRP) in White Carneau pigeon peritoneal macrophages: its role in lipoprotein metabolism. 903 Jan 94

We have shown previously that the activity of lipoprotein lipase (LPL), the major enzyme responsible for hydrolysis of triglyceride contained in circulating lipoproteins, is associated with lipoproteins in postheparin plasma. In other studies, microtiter plate assays showed that LPL interaction with low density lipoprotein (LDL) and very low density lipoprotein (VLDL) was decreased by antibodies to apolipoprotein (apo)B. To test whether antibodies to apoB affected LPL-LDL association in solution, two types of assays were performed, gel filtration and coprecipitation. First we showed that LPL activity and immunoreactive mass co-eluted during gel filtration of normal postheparin plasma, approximately with the peak of low density lipoproteins. Then LPL was used for gel filtration studies in the presence and absence of LDL and anti-apoB monoclonal antibodies. LPL association with LDL was diminished by antibodies to the amino-terminal region of apoB; antibodies to the carboxyl-terminal LDL receptor binding region of apoB were less effective. LDL binding to LPL containing heparin-agarose was also disrupted by the amino-terminal antibodies to apoB. To determine the LPL-lipoprotein association in situations in which the distribution of plasma lipoproteins was altered, we studied plasma from two types of subjects with dyslipidemias. The addition of 125I-labeled LPL to type 1 postheparin plasma produced two peaks of radioactivity, one peak eluted in the void volume of the column (with the chylomicrons) and a second peak eluted just prior to the normal elution of low density lipoproteins. In postheparin plasma from an abetalipoproteinemic subject, LPL eluted with HDL. We conclude that LPL associates primarily with apoB-containing lipoproteins. The reason for this appears to be that LPL interacts with the apoB.
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PMID:Dissociation of LPL and LDL: effects of lipoproteins and anti-apoB antibodies. 903 2

VLDL receptor (VLDL-R) is a novel member of the LDL receptor gene family with distinct tissue distribution and function. It binds and internalizes VLDL particles and is primarily expressed in skeletal muscle, heart, brain and adipose tissue, which use fatty acids for energy production or storage. CRF is associated with elevated serum triglyceride and VLDL concentrations and depressed VLDL and chylomicron clearance. We have recently shown marked down-regulation of lipoprotein lipase expression in CRF. This study was conducted to test the hypothesis that VLDL-R expression may be similarly depressed in CRF. To this end, VLDL-R mRNA (Northern blot) and protein mass (Western blot) of skeletal muscle (soleus) and heart were measured in male Sprague-Dawley rats six weeks after 5/6 nephrectomy (CRF group) or sham operation (NL group). A group of erythropoietin (EPO)-treated (150 U/kg twice weekly) CRF animals was included to determine the possible effect of EPO-deficiency anemia (EPO-CRF group). Subgroups of animals were studied at weeks 1, 3 and 6. The CRF group showed a fivefold increase in plasma triglyceride concentration. This was associated with an impressive fourfold reduction in heart and skeletal muscle VLDL-R mRNA and protein mass. VLDL-R mRNA levels in the heart and skeletal muscle were directly related to creatinine clearance and inversely related to serum triglyceride and VLDL concentrations. EPO therapy led to a mild improvement in CRF hypertriglyceridemia but failed to improve VLDL-R expression. Thus, the rise in plasma triglyceride and VLDL concentrations in CRF animals was associated with marked down-regulation of VLDL-R expression. Down-regulation of VLDL-R expression, shown here for the first time, reveals another facet of disturbed lipid metabolism in CRF.
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PMID:Down-regulation of VLDL receptor expression in chronic experimental renal failure. 906 30

Apolipoprotein (apo) E-deficient mice display marked accumulation in the plasma of VLDL deficient in both apoE and apoB100 but containing apoB48, apoA-I, apoCs, and apoA-IV. Since apoE-deficient mice develop severe atherosclerotic lesions with lipid-laden macrophages, we reasoned that the uptake of lipoproteins by intimal macrophages can take place in the absence of both apoE and apoB100. To get more insight into the mechanism of foam cell formation in apoE-deficient mice, we measured the interaction of VLDL from apoE-deficient mice (apoEnull VLDL) with the murine macrophage cell line J774. Scatchard analysis revealed that apoEnull VLDL is bound to J774 cells with a Kd value comparable to that of control VLDL (8.1 versus 4.7 micrograms/mL) and with a Bmax value about half that of control VLDL (40 versus 70 ng/mg cell protein, respectively). ApoEnull VLDL is also taken up and degraded by J774 macrophages via a high-affinity process less efficiently than control mouse VLDL (6-fold and 50-fold less efficiently, respectively). In line with this observation, incubation of J774 cells with 50 micrograms/mL apoEnull VLDL for 24 hours resulted in an increase in intracellular cholesteryl ester (CE) content, although 5-fold less pronounced than after incubation with 50 micrograms/mL control mouse VLDL. Under the conditions applied, simultaneous addition of 5 micrograms/mL lipoprotein lipase (LPL) stimulated the cellular uptake and degradation of apoEnull VLDL about 10-fold and resulted in a 5-fold stimulation of the intracellular CE accumulation, from 9 +/- 2 to 46 +/- 5 micrograms CE per milligram cell protein. In contrast to control mouse VLDL, apoEnull VLDL could not compete with 125I-labeled LDL for binding to the LDL receptor of J774 cells. Furthermore, neither LDL nor acetylated LDL could compete with 125I-labeled apoEnull VLDL for binding to these cells, whereas control mouse VLDL, VLDL from a hypertriglyceridemic patient, and apoEnull VLDL itself were efficient competitors. Thus, VLDL from apoE-deficient mice is taken up by J774 macrophages through recognition by a distinct receptor, which could be the triglyceride-rich lipoprotein receptor. We conclude that in apoE-deficient mice, foam cell formation occurs via a receptor-mediated uptake of apoEnull VLDL, which can be stimulated by the presence of LPL.
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PMID:Uptake by J774 macrophages of very-low-density lipoproteins isolated from apoE-deficient mice is mediated by a distinct receptor and stimulated by lipoprotein lipase. 910 68

If dietary therapy and other lifestyle changes do not adequately normalise blood lipid levels, lipid-regulating drugs, as single-drug or combination-drug therapy, may be prescribed to supplement lifestyle changes. Evaluation of the individual patient's health and risk status, determination of the dyslipidaemia, definition of treatment goals and a clear understanding of the mechanisms and effects of lipid-regulating agents are necessary for optimisation of treatment. Although all the available lipid-regulating agents lower low density lipoprotein (LDL) cholesterol, the agents with the greatest LDL cholesterol-lowering effect are the bile acid sequestrants, which up-regulate the LDL receptor by the decrease in intrahepatic cholesterol caused by the interruption of enterohepatic circulation of cholesterol-rich bile acids, and the HMG-CoA reductase inhibitors, which partially inhibit HMG-CoA reductase. The agents with the greatest triglyceride-lowering effect are nicotinic acid, which decreases the production of very low density lipoprotein (VLDL) cholesterol and reduces the availability of free fatty acids in the circulation, and the fibric acid derivatives, which increase lipoprotein lipase activity and may also decrease the release of free fatty acids. Although the safety profile of the available lipid-regulating drugs has been established, patients should be monitored for potential adverse effects and interactions with concomitantly administered agents. When used correctly, lipid-regulating drug therapy is highly effective in the treatment of a variety of dyslipidaemias.
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PMID:Choosing the right lipid-regulating agent. A guide to selection. 911 15

1. We examined common polymorphisms in the genes encoding the LDL receptor, lipoprotein lipase, apoAI, apoB, apoAIV and cholesteryl ester transfer protein and related them to changes in LDL and HDL cholesterol after high fat/high cholesterol diets. 2. The only significant association was seen with the apoIV polymorphism, which leads to a structural change in the protein. The response to fat and cholesterol in subjects with at least one apoAIV 2 allele was only 30% of that seen in subjects with the common apoIV 1 allele (P < 0.01), accounting for 6-7% of the variance in response. This confirms the results of two previous studies in which dietary cholesterol intake was changed. 3. No association were seen with polymorphisms of the other five genes examined.
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PMID:Response to dietary fat and cholesterol and genetic polymorphisms. 914 92

Pigeon and rabbit beta-migrating very low density lipoprotein (beta-VLDL) are similar in size and composition, yet rabbit beta-VLDL consistently stimulates greater cholesteryl ester accumulation in pigeon peritoneal macrophages than does pigeon beta-VLDL. The purpose of this study was to determine the mechanism of this difference. Pigeon beta-VLDL bound to both a high and low affinity site while rabbit beta-VLDL bound primarily to a low affinity site. The high affinity site had the characteristics of the LDL receptor. Most rabbit beta-VLDL and some pigeon beta-VLDL bound to the low affinity site that was not down-regulated by cholesterol loading. beta-VLDL binding to the low affinity site and subsequent internalization and degradation were mediated by cell surface heparan sulfate proteoglycans (HSPG). Evidence for this includes inhibition of binding and uptake by chlorate, which prevents sulfation of proteoglycans, and by treatment with heparinase but not chondroitinase ABC. beta-VLDL uptake was stimulated by lipoprotein lipase (LpL) and apolipoprotein E (apoE), both known to bind HSPGs. Uptake and degradation of beta-VLDL were not mediated by the LDL receptor or the alpha(2)MR/LRP. Thus, binding of beta-VLDL to low affinity, high capacity HSPG binding sites on pigeon macrophages appears to directly promote internalization and degradation and is largely responsible for the greater ability of rabbit beta-VLDL to stimulate cholesterol accumulation.
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PMID:Heparan sulfate proteoglycans mediate internalization and degradation of beta-VLDL and promote cholesterol accumulation by pigeon macrophages. 914 91

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