EC:3.1.1.34 - FACTA Search

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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)

Triglycerides in circulating plasma lipoproteins are hydrolyzed by lipoprotein lipase (LPL) which is thought to bind to proteoglycans on the luminal endothelial cell surface. Previous studies from this laboratory using LPL-Sepharose affinity chromatography identified a 220-kDa LPL binding proteoglycan. Using ligand blotting with 125I-LPL, we now report a 116-kDa LPL binding protein in plasma membrane preparations of endothelial cells. 125I-LPL binding to this protein was abolished by addition of unlabeled LPL. When the cell surface of endothelial cells was labeled with biotin, a 116-kDa protein was biotinylated. Furthermore, the biotinylated 116-kDa protein bound to LPL-Sepharose and eluted with 0.4 M NaCl suggesting that the 116-kDa LPL binding protein is present on the cell surface. When detergent extracts of endothelial cells were applied to LPL-Sepharose in the presence of 0.15 M NaCl, the 116-kDa, but not the 220-kDa, protein still bound to LPL-Sepharose. The 116-kDa protein was not labeled with 35SO4 and eluted from DEAE-cellulose prior to proteoglycans, suggesting that it is not a proteoglycan. However, a 116-kDa endothelial cell surface protein was metabolically labeled with [35S]methionine. This protein was dissociated from the cell surface by incubating cells with heparin (50 units/ml)-containing buffer. After heparin treatment of endothelial cells, LPL binding to and internalization by the cells decreased greater than 70% compared to control cells. These results suggest that endothelial cells synthesize a heparin-releasable, high affinity 116-kDa LPL binding protein. We postulate that this protein is associated with proteoglycans on luminal endothelial surfaces and mediates LPL binding, internalization, and recycling. We name this protein hrp (heparin-releasable protein)-116.
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PMID:Identification of a heparin-releasable lipoprotein lipase binding protein from endothelial cells. 164 32

The hydrolysis of triglycerides in plasma lipoproteins is mediated by lipoprotein lipase (LPL) that is bound to vascular endothelial cells. The specific endothelial cell surface protein(s) with which LPL associates has not been characterized. To identify this LPL binding protein(s), radioiodinated cell surface proteins from cultured bovine aortic endothelial cells were chromatographed using bovine LPL-Sepharose. A single radioiodinated protein of apparent molecular mass 220 kDa was specifically retained by the gel and eluted with 0.4 M NaCl. A LPL-binding protein of similar size was obtained after metabolic labeling of the cellular proteoglycans with 35SO4, indicating that the 220-kDa protein is a proteoglycan. After heparitinase or nitrous acid treatments the molecular mass of the LPL-binding protein decreased to approximately 50 kDa, suggesting that it contains heparin sulfate chains. A 220-kDa protein from the basal cell surface was also identified using LPL-Sepharose chromatography. 125I-LPL was cross-linked to the endothelial cell surface using ethylene glycobis (succinimidylsuccinate). A single ligand-receptor complex, approximately 350 kDa, was obtained. Heparin and unlabeled LPL decreased the cross-linking of radioiodinated LPL to the cell surface receptor. To examine whether the receptor mediates the internalization of cross-linked 125I-LPL, cells containing 125I-LPL complexed to the surface were incubated at either 37 or at 4 degrees C. The amount of 125I-LPL internalized by the cells was 74% greater at 37 degrees C than at 4 degrees C. This suggested that LPL cross-linked to the receptor was internalized in a temperature-dependent manner. Thus, a 220-kDa heparan sulfate proteoglycan functions as an endothelial cell surface receptor for LPL.
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PMID:Identification and characterization of the endothelial cell surface lipoprotein lipase receptor. 165 30

The domain structure of heparan sulphate chains from an endothelial low-density proteoglycan was examined using specific degradations of the chains while attached to the intact proteoglycan. 'Inner' chain fragments, remaining on the protein core, were separated from 'outer' fragments by gel chromatography, and were subsequently released from the protein core by alkaline cleavage. The structure of 'inner' and 'outer' chain fragments was then examined and compared. Using deaminative cleavage we obtained evidence that the first N-sulphated glucosamine residue is variably positioned some 10-17 disaccharides from the xylose-serine linkage of the proteoglycan. Digestion with heparinase yielded 'inner' and 'outer' fragments covering a broad range of different sizes, indicating a scarce and variable distribution of sulphated iduronic acid in the native chains. N-sulphated glucosamine occurred more frequently in the 'outer' fragments. We also studied the affinity of the endothelial heparan sulphate chains towards two presumptive biological ligands, namely antithrombin III and lipoprotein lipase. A major part of the endothelial heparan sulphate chains showed a weak affinity for antithrombin III and the affinity was essentially lost on heparinase digestion. On lipoprotein lipase-agarose the endothelial heparan sulphate chains were eluted at the same salt concentration as heparin, and the binding persisted, although with decreased strength, after digestion with heparinase.
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PMID:Domain structure of endothelial heparan sulphate. 195 77

The heparan sulfate proteoglycans present in a deoxycholate extract of rat brain were purified by ion exchange chromatography, affinity chromatography on lipoprotein lipase agarose, and gel filtration. Heparitinase treatment of the heparan sulfate proteoglycan fraction (containing 86% heparan sulfate and 10% chondroitin sulfate) that was eluted from the lipoprotein lipase affinity column with 1 M NaCl led to the appearance of a major protein core with a molecular size of 55,000 daltons, as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Comparison of the effects of heparinase and heparitinase treatment revealed that the heparan sulfate proteoglycans of brain contain a significant proportion of relatively short N-sulfoglucosaminyl 6-O-sulfate [or N-sulfoglucosaminyl](alpha 1-4)iduronosyl 2-O-sulfate(alpha 1-4) repeating units and that the portions of the heparan sulfate chains in the vicinity of the carbohydrate-protein linkage region are characterized by the presence of D-glucuronic acid rather than L-iduronic acid. After chondroitinase treatment of a proteoglycan fraction that contained 62% chondroitin sulfate and 21% heparan sulfate (eluted from lipoprotein lipase with 0.4 M NaCl), the charge and density of a portion of the heparan sulfate-containing proteoglycans decreased significantly. These results indicate that a population of "hybrid" brain proteoglycans exists that contain both chondroitin sulfate and heparan sulfate chains covalently linked to a common protein core.
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PMID:Structural properties of the heparan sulfate proteoglycans of brain. 252 92

The effect of phosphatidylinositol-specific phospholipase C (PI-PLC) on the release of lipoprotein lipase was studied in F1 heart cell cultures. Exposure of the cultures for 10 min to PI-PLC resulted in a 2-fold increase in the release of lipoprotein lipase (LPL) into the culture medium. PI-PLC released LPL from the heparin-releasable pool and PI-PLC was not effective in cultures pretreated with heparin. Insulin had no influence on the release of LPL from the heart cell cultures, even though it enhanced the uptake of 2-deoxy[3H]glucose by these cells. In cultures labeled with 35S, treatment with PI-PLC resulted in an increase in the release of 35S-labeled proteoglycan. PI-PLC was also effective in enhancing the release of bovine LPL exogenously bound to cultured aortic smooth muscle cells. The findings that PI-PLC was not effective after heparin, that it did release exogenously added LPL to cell cultures and that it released 35S-labeled proteoglycan, were interpreted to indicate that PI-PLC apparently acts on the release of LPL in an indirect manner, releasing heparan sulphate to which LPL is bound. As there is a previously described correlation between circulating LPL and the heparin-releasable LPL, we hypothesize that the activity of PI-PLC in the endothelial cell membrane or plasma phosphatidyl-specific phospholipase D regulates the plasma LPL levels.
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PMID:Phosphatidylinositol-specific phospholipase C releases lipoprotein lipase from the heparin releasable pool in rat heart cell cultures. 255 75

For over 100 years heparin has attracted interest because of its anticoagulant powers. Commercial heparin has now been shown to be a mixture of over 100 different closely related sulfated polysaccharides of which only 10% activate antithrombin-III. Fifty years ago the original research teams in Toronto and Stockholm in demonstrating the clinical uses of heparin observed that antithrombotic activity did not correspond to levels of anticoagulation. It has been shown that: (a) Heparin accumulates rapidly and specifically in the endothelium against a concentration gradient of hundreds- to thousands-fold. (b) Experimental thrombosis, however produced, is accompanied by a marked decrease in the electronegative charge of the vessel wall and the charge is restored in all cases by heparin. (c) The normal electronegative charge is due to glycosaminoglycans. Heparin possesses the strongest electronegative charge of these substances and is present in the vessel wall as a component of a larger heparitin (sulfate) proteoglycan molecule. (d) Maintenance of the normal electronegative charge depends on adequate supply of oxygen (adequate blood flow). (e) Commercial heparin releases enzymes from the endothelium, lipoprotein lipase and histaminase (D.A.O.). Lipoprotein lipase changes the composition of plasma lipids and lipoproteins and histaminase provides a check for fat absorption. The release of these enzymes decrease and prevent atherosclerotic changes. (f) After administration of commercial heparin, heparin isolated from the plasma has higher antithrombin activity than that injected. The heparin taken up by the endothelium is returned with greater activity. The anticoagulant effect of administered heparin does not produce hemorrhage since this requires simultaneous occurrence of defects in the vascular factor of hemostasis (the result of stress or pituitary-adrenal imbalance) or platelet defect. Thus, clinical effectiveness of heparin is an expression of its close relationship to the vessel wall.
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PMID:The close relationship of heparin and the vessel wall. 273 Mar 47

1. Artery wall proteoglycans-lipoprotein lipase binding characteristics were studied using bovine milk 125I-labelled lipoprotein lipase (LPL) and chondroitin sulphate-dermatan sulphate proteoglycans (PGs) purified from pig aorta. 2. The binding process was studied either by a soluble assay (gel filtration) or by an immobilized proteoglycan assay (ELISA). 3. The binding process was reversible, saturable and occurred at a stoichiometry 1:1. 4. The binding process involved ionic interactions between the positively charged groups of LPL and the negatively charged groups of PG carbohydrate chains. 5. The complex PG-LPL may lead to the production of remnant lipoproteins and, thereby, contribute to cholesteryl ester accumulation in the arterial wall.
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PMID:Evidence for an interaction of lipoprotein lipase with artery wall proteoglycans. 275 34

Heparan sulfate proteoglycans were extracted from rat brain microsomal membranes or whole forebrain with deoxycholate and purified from accompanying chondroitin sulfate proteoglycans and membrane glycoproteins by ion-exchange chromatography, affinity chromatography on lipoprotein lipase-Sepharose, and gel filtration. The proteoglycan has a molecular size of approximately 220,000, containing glycosaminoglycan chains of Mr = 14,000-15,000. In [3H]glucosamine-labeled heparan sulfate proteoglycans, approximately 22% of the radioactivity is present in glycoprotein oligosaccharides, consisting predominantly of N-glycosidically linked tri- and tetraantennary complex oligosaccharides (60%, some of which are sulfated) and O-glycosidic oligosaccharides (33%). Small amounts of chondroitin sulfate (4-6% of the total glycosaminoglycans) copurified with the heparan sulfate proteoglycan through a variety of fractionation procedures. Incubation of [35S]sulfate-labeled microsomes with heparin or 2 M NaCl released approximately 21 and 13%, respectively, of the total heparan sulfate, as compared to the 8-9% released by buffered saline or chondroitin sulfate and the 82% which is extracted by 0.2% deoxycholate. It therefore appears that there are at least two distinct types of association of heparan sulfate proteoglycans with brain membranes.
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PMID:Isolation and characterization of the heparan sulfate proteoglycans of brain. Use of affinity chromatography on lipoprotein lipase-agarose. 315 51

To study the interaction between low-density lipoprotein (LDL) and granules from rat serosal mast cells in vitro, mast cells were stimulated with the degranulating agent 48/80 to induce exocytosis of the secretory granules. Subsequent incubation of the exocytosed granules with 125I-LDL resulted in binding of the labelled LDL to the granules. When increasing amounts of agent 48/80 were added to mast-cell suspensions, a dose-dependent release of granules was observed and a parallel increase in the amount of 125I-LDL bound to granules resulted. 125I-LDL bound to a single class of high-affinity binding sites on the granules. At saturation, 105 ng of LDL were bound per microgram of granule protein. The lipoprotein binding to mast-cell granules was apolipoprotein(apo)-B + E-specific. Thus 125I-LDL binding to the granules was effectively compared for by LDL (apo-B) or by dimyristoyl phosphatidylcholine vesicles containing apo-E, but not by high-density lipoprotein (HDL3) containing apo-AI as their major protein component. Neutralization by acetylation of the positively charged amino groups of apo-B of LDL or presence of a high ionic strength in the incubation medium prevented LDL from binding to the granules, indicating the presence of ionic interactions between the positively charged amino acids of LDL and negatively charged groups of the granules. It could be demonstrated that LDL bound to the negatively charged heparin proteoglycan of the granules. Thus treatment of granules with heparinase resulted in loss of their ability to bind LDL, and substances known to bind to heparin, such as Toluidine Blue, avidin, lipoprotein lipase, fibronectin and protamine, all effectively competed with LDL for binding to the granules. The results show that LDL is efficiently bound to the heparin proteoglycan component of mast-cell granules once the mast cells are stimulated to release their granules into the extracellular space.
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PMID:Low-density-lipoprotein binding by mast-cell granules. Demonstration of binding of apolipoprotein B to heparin proteoglycan of exocytosed granules. 359 8

Rabbit thoracic aorta segments were treated with either proteoglycan-degrading enzymes or with glycosaminoglycan-binding proteins to examine the nature of the endothelial and subendothelial binding sites of 125I-thrombin. Treatment (5-30 min) with enzymes (heparitinase, chondroitinases AC or ABC) caused a decrease in 125I-thrombin binding by the endothelium (30-70%) and by the subendothelial (intima-media) layer (20-50%); a low-specificity protease destroyed endothelial binding almost entirely and reduced binding to the subendothelium by approximately 60% over a similar period. Of the glycosaminoglycan-binding proteins, pretreatment of the aorta wall with protamine caused a 30% decrease in thrombin binding to the endothelium whereas lipoprotein lipase (present during 125I-thrombin uptake) decreased binding by up to 40%. Pretreatment with antithrombin III did not significantly affect binding of either 125I-thrombin or 125I-FPR-inactivated thrombin. In contrast to thrombin, 125I-antithrombin III was not readily uptaken by the aorta segments. These observations indicate that, whereas the minimal binding by 125I-antithrombin III probably does not involve endothelial proteoglycan, a strong case can be made for endothelial and subendothelial proteoglycan binding sites for thrombin.
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PMID:A role for pericellular proteoglycan in the binding of thrombin or antithrombin III by the blood vessel endothelium? The effects of proteoglycan-degrading enzymes and glycosaminoglycan-binding proteins on 125I-thrombin binding by the rabbit thoracic aorta in vitro. 402 34

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