Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:4.2.2.7 (heparinase)
 1,270 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Lipoprotein lipase (LPL) binds to the low density lipoprotein receptor-related protein (LRP)/alpha 2-macroglobulin receptor and induces catabolism of normal human very low density lipoproteins (VLDL) via LRP in vitro. Recent studies showed that the C-terminal domain of LPL can bind LRP in solid phase assays and inhibit cellular catabolism of two LRP ligands, activated alpha 2-macroglobulin and the 39-kDa receptor-associated protein (Williams, S.E., Inoue, I., Tran, H., Fry, G. L., Pladet, M.W., Iverius, P.-H., Lalouel, J.-M., Chappell, D.A., and Strickland, D.K. (1994) J. Biol. Chem. 269, 8653-8658). The current study investigated the potential for this region of LPL to promote cellular catabolism of VLDL via LRP. A fragment comprising the C-terminal domain of LPL (designated LPLC) was expressed in bacteria and found to promote cellular binding, uptake, and degradation of normal human VLDL in a dose-dependent manner. These effects were present whether LPLC was added simultaneously with 125I-VLDL or was prebound to cell surfaces prior to the assay. Mutations involving Lys407, Trp393, Trp394, or deletion of the C-terminal 14 residues reduced the effects of LPLC. Three LRP-binding proteins, the receptor-associated protein, lactoferrin, and a polyclonal antibody against LRP, competed for 125I-VLDL degradation induced by LPLC. Heparin or heparinase treatment of cells prevented LPLC-induced 125I-VLDL catabolism. Thus, cell-surface proteoglycans play an important role in this pathway. Interestingly, either LPLC or LPL when added in excess could block LPL-induced 125I-VLDL degradation presumably by interacting directly with LRP. However, unlabeled VLDL could not prevent catabolism of 125I-labeled LPLC or LPL. These data show that cellular fates for VLDL versus LPLC or LPL are divergent. This is probably due to independent catabolism of the latter via cell-surface proteoglycans. In summary, these in vitro studies indicate that a fragment of LPL corresponding to the C-terminal domain mimics the native enzyme with respect to induction of VLDL catabolism via LRP. Because LPLC lacks the catalytic site of native LPL, these studies establish that lipase activity is not required for LRP-mediated lipoprotein catabolism.
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PMID:Cellular catabolism of normal very low density lipoproteins via the low density lipoprotein receptor-related protein/alpha 2-macroglobulin receptor is induced by the C-terminal domain of lipoprotein lipase. 751 36

The fibroblast growth factors (FGFs) act through high affinity tyrosine kinase receptors and, in addition, interact with lower affinity receptors that represent cell- or matrix-associated heparan sulfate proteoglycans. These lower affinity receptors modulate the biological activities of FGFs, but the mechanism by which they exert these effects is rather controversial. We have previously shown (Ron, D., Bottaro, D. P., Finch, P. W., Morris, D., Rubin, J. S., and Aaronson, S. A. (1993) J. Biol. Chem. 268, 2984-2988) that heparin potentiates the mitogenic activity of acidic FGF (aFGF) but inhibits that of the keratinocyte growth factor (KGF) in cells that express the KGF receptor (KGFR). Both growth factors bind the KGFR with high affinity. To gain an insight into the mechanism by which heparin modulates the biological activity of aFGF and KGF, we studied the effect of heparin and cell-associated heparan sulfates on the binding of these two growth factors to the KGFR. To work in a well defined system, we expressed functional KGFR in L6E9 myoblasts that lack detectable high affinity binding sites for FGFs. Low concentrations of heparin inhibited the binding of KGF to the KGFR. By contrast, similar concentrations of heparin enhanced the binding of aFGF to this receptor. The effect of heparin was not unique to L6E9 cells expressing the KGFR; it was also observed in Balb/MK cells that naturally express KGFR. Treatment of cells with sodium chlorate, which blocks sulfation of proteoglycans, reduced the binding of aFGF to its low and high affinity binding sites by 95 and 80%, respectively. In contrast, the binding of KGF to its high affinity binding sites was enhanced about 2-fold. Similar results were obtained after degradation of cell-associated heparan sulfates by heparinase and heparitinase. Heparin restored the high affinity binding of aFGF to chlorate-treated cells and completely abolished the high affinity binding of KGF. Binding competition experiments suggest that aFGF and KGF bind to the same population of cell-associated heparan sulfates. In addition, KGF is apparently interacting with an as yet unidentified type of low affinity binding site that is not affected by chlorate or heparan sulfate-degrading enzymes. An important property of the FGF high affinity receptors is their ability to bind more than one ligand with high affinity. Based on the differential effect of cell-associated heparan sulfates on the binding of KGF and aFGF to the KGFR, we propose a regulatory role for cell-associated heparan sulfates as coordinators of the interaction of aFGF and KGF with the KGFR.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Differential effect of cell-associated heparan sulfates on the binding of keratinocyte growth factor (KGF) and acidic fibroblast growth factor to the KGF receptor. 752 11

Heparin and heparan sulfate proteoglycans (HSPGs) stabilize FGFs which belong to heparin-binding growth factors (HBGFs) on active conformation. They also strongly potentiate their mitogenic activity on many cell types, and protect them against thermal denaturation and enzymatic degradation. In the present work we have tested two heparin-like substances named mesoglycan and sulodexide obtained from bovine intestinal mucosal extracts. These products are used as heparin, in various of therapeutic fields such as atherosclerosis or antithrombotic therapy. The compositions of mesoglycan and sulodexide are partially known and include chondroitin, dermatan and heparan sulfate. We have shown that mesoglycan and sulodexide potentiated the mitogenic activity of FGF1 and FGF2. The magnitude of this effect was identical with that of heparin used as a control substance but at double concentration. Mesoglycan and sulodexide also exerted stabilizing and protective effects on FGFs for heat denaturation and enzymatic degradation. The suppression of the protective properties after heparinase treatment of mesoglycan and sulodexide indirectly demonstrated the presence of heparan sulfate which was shown to represent about 60% of the commercial products.
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PMID:Mesoglycan and sulodexide act as stabilizers and protectors of fibroblast growth factors (FGFs). 754 22

Heparin inhibited the hemagglutinin activity of Akabane and Aino viruses. The minimal inhibitory concentration of heparin required to inhibit 8 hemagglutination (HA) U of Akabane and Aino viruses was 10 U/ml. Goose erythrocytes failed to combine with the HA inhibitory factor of heparin. On the other hand, goose erythrocytes treated with heparinase had greatly reduced agglutinability by Akabane virus. Virus-heparin complex formation was observed by sedimenting heparin with the virus particles.
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PMID:Effect of heparin on hemagglutination by Akabane and Aino viruses belonging to the Simbu group of bunyaviruses. 757 76

A whole blood hemostasis system (Hepcon) provides both activated clotting time and accurate whole blood heparin concentration measurements via an automated protamine titration method. This study was designed to prospectively evaluate the impact of heparin and protamine administration using this system on the incidence and treatment of bleeding after cardiopulmonary bypass. Two hundred fifty-four patients requiring cardiopulmonary bypass were enrolled in this prospective study over a 7-month period. Patients treated with antifibrinolytic agents (aprotinin, epsilon-aminocaproic or tranexamic acid) were excluded. Patients were randomly assigned to either a control (n = 127) or intervention (n = 127) group. For control patients, the anticoagulation protocol consisted of an initial fixed dose of 250 U/kg of heparin, and additional 5000 U heparin doses were administered if the activated clotting time was less than 480 seconds. Heparin was neutralized with an initial fixed dose of protamine (0.8 mg protamine per milligram total heparin). For the intervention group, an initial dose of heparin was based on an automated heparin dose-response assay. Additional heparin doses were administered if the heparin concentration was less than the reference concentration or for an activated clotting time less than 480 seconds. The protamine dose was based on the residual heparin concentration. Treatment of excessive bleeding after cardiopulmonary bypass was based on an algorithm using point-of-care testing with whole blood prothrombin time, activated partial thromboplastin time, heparinase activated clotting time, and platelet count. No differences between the two treatment groups were identified in reference to demographic factors, preoperative anticoagulant medications, preoperative coagulation data, number of reoperations, or combined procedures and duration of cardiopulmonary bypass. Indirect evidence for coagulation factor consumption was demonstrated in control patients by more prolonged whole blood prothrombin time and activated partial thromboplastin time values after cardiopulmonary bypass when compared with values obtained in the intervention group. Patients in the intervention cohort received greater doses of heparin (intervention: 612 +/- 147, control: 462 +/- 114 U/kg, p < 0.0001) and had lower protamine to heparin ratios (intervention: 0.70 +/- 0.64, control: 0.94 +/- 0.21, p = 0.0001) compared with control patients. Patients in the intervention cohort received significantly fewer platelet (intervention: 1.7 +/- 3.6 U, control: 3.7 +/- 6.7 U, p = 0.003), plasma (intervention: 0.4 +/- 1.3 U, control: 1.4 +/- 2.5 U, p = 0.0001), and cryoprecipitate units (intervention: 0.0 +/- 0.0 U, control: 0.2 +/- 1.2 U, p = 0.04) during the perioperative interval than control patients.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:The impact of heparin concentration and activated clotting time monitoring on blood conservation. A prospective, randomized evaluation in patients undergoing cardiac operation. 858 30

Heparan sulfate (HS) secreted into the medium of bovine aortic endothelial cell (BAEC) cultures was subjected to chemical and enzymatic degradation followed by analysis using gel-filtration and ion-exchange chromatography. Treatment with HNO2 showed that 41% of the disaccharides were N-sulfated. Degradation by Heparin lyases I (Hep I) showed that 8-9% of the disaccharides contained IdoA(2S) residues. Heparin lyase III (Hep III) degradation produced mainly disaccharides with 67% of the molecules glycosidic linkages susceptible to cleavage. Further degradation of Hep III-resistant fragments with Hep I showed that IdoA(2S) residues were predominantly positioned centrally within the repeating GlcNSO3(+/- 6S)alpha 1-4IdoA containing domains. Digestion with a mixture of Heparin lyases I, II and III degraded the molecule almost entirely to disaccharides, with small amounts of tetrasaccharides containing resistant linkages, suggesting the presence of 3-O sulfated GlcNSO3. Further analysis of the disaccharide products by ion-exchange chromatography and comparison with the data from single enzymatic digestion, allowed an estimate of the disaccharide composition to be made. The results suggest an ordered arrangement of structural domains; however, variations in the structure of these domains results in a heterogeneous population of HS chains. It is suggested that biosynthetic differences in HS structure may act as a regulator of bFGF induced cellular responses.
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PMID:Molecular attributes of bovine aortic endothelial cell heparan sulfate. 776 9

1. The ability of heparins (bovine heparin sm 1026, Av. mol. wt. 36.9 kDa and bovine heparin EP 756, Av. mol. wt. 12.9 kDa) and heparin fractions of different molecular weights (low molecular weight heparin, LMW 2123/OP, Av. mol. wt. 4.5 kDa and oligo-heparin, Av. mol. wt. 2 kDa) to inhibit the proliferation and signalling of Balb/c 3T3 fibroblasts was investigated. 2. Heparin and heparin fractions of 4.5 and 2 kDa significantly inhibited DNA synthesis as monitored by [2H]-thymidine incorporation. 3. 3H-labelled heparin fractions of 4.5 and 2 kDa were prepared by gel-chromatography fractionation on Sephadex G-75 of an 3H-labelled commercial heparin after treatment with heparinase. 4. The binding of unfractionated and oligo-heparin of 2 kDa to Balb/c 3T3 fibroblasts was studied; we determined the specificity of heparin and oligo-heparin binding to the cells by means of displacement of bound 3H-labelled compound in response to increasing concentrations of unlabelled compounds. Scatchard analysis of binding data obtained using [3H]-heparin as ligand revealed the presence of a single class of high affinity binding sites (Kd = 28 nM) for heparin. Scatchard analysis of binding data obtained using [3H]-oligo-heparin as ligand revealed the presence of a single class of low affinity binding sites (Kd = 3.2 microM) for oligo-heparin. 5. In addition heparin displaced [3H]-oligo-heparin at a concentration of approximately 100 fold of the Kd determined in displacement studies. Furthermore, oligo-heparin significantly displaced [3H]-heparin at a concentration of approximately 10 fold of the Kd determined by displacement studies. 6. Both heparin and oligo-heparin exert their inhibitory effects on Balb/c 3T3 DNA synthesis stimulated by PDGF or serum. However these molecules did not affect the inositol lipid turnover triggered by PDGF at a concentration which did not produce maximal response. The increase of inositol phosphate metabolism produced by 20% serum was also unaffected by heparin. This concentration of serum elicited a response comparable to that induced by a submaximal concentration of PDGF.
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PMID:Binding and growth-inhibitory effect of heparin and oligo-heparin (2kDa) in Balb/c 3T3 cells: lack of effect on PDGF- or serum-induced inositol lipid turnover. 781 18

Heparin, NAcHep, DS, and CS were labeled with deuterium by N-reacetylating, with the deuterated acetic anhydride (CD3CO)2O, GAGs previously N-deacetylated (by hydrazinolysis) to the desired extent. Degrees of deuteration of the present preparations, as determined by 2H- and 1H-NMR were 15%, 51%, 49%, and 79% for heparin, NAcHep, DS, and CS, respectively. The NMR analysis (including the 13C spectra) of the labeled products indicated that deuterium labeling did not involve any substantial modification of the GAG structures. Also NMR signals associated with specific sequences of heparin for antithrombin and of DS for heparin cofactor II were essentially the same in the unlabeled and in the deuterated GAGs. The substantial retention of the original structure was confirmed by data on the degree of sulfation (by conductimetry) and on the electrophoretic mobility in acid buffer. On the other hand, HPLC/SEC data indicated some depolymerization of heparin and DS in the N-deacetylation step of the labeling reactions. HPLC/MS spectrometry permitted a clear identification of disaccharide and tetrasaccharide fragments obtained from deuterated GAGs by enzymic (heparinase, chondroitinase ABC) or chemical depolymerization (deaminative cleavage, Smith degradation), opening new prospects for studies of human pharmacokinetics, with differentiation of exogenous from endogenous GAGs.
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PMID:Preparation and characterization of deuterium-labeled glycosaminoglycans. 799 88

Heparin is a potent inhibitor of the proliferation and migration of vascular smooth muscle cells. This agent selectively inhibits the transcription of tissue-type plasminogen activator and interstitial collagenase, probably by decreasing the binding of activator protein-1 (AP-1) to phorbol ester-responsive elements in the promoters of these genes. Decreased AP-1 binding is not due to a direct inhibition by heparin, since heparinase digestion of nuclear extracts prepared from heparin-treated smooth muscle cells does not restore AP-1 binding activity. Treatment of cells with heparin suppresses the expression of Jun B, one of the components of AP-1. The major effect of heparin is at the level of posttranslational modification of Jun B. Results from pulse-chase labeling experiments show that the newly synthesized Jun B is rapidly converted to a higher-molecular-weight form and that conversion is suppressed by heparin. Evidence is presented suggesting that the heparin-inhibited event is phosphorylation of Jun B.
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PMID:Heparin decreases activator protein-1 binding to DNA in part by posttranslational modification of Jun B. 801 74

Borrelia burgdorferi adhere to mammalian cells in vitro but neither the ligand(s) nor the receptor(s) has (have) been clearly established. Using an in vitro attachment-inhibition assay, a B. burgdorferi attachment mechanism has been identified. Heparin, heparan sulfate, and dermatan sulfate reduced the attachment of virulent B. burgdorferi strain 297 to HeLa cells by approximately 60%. In addition, virulent, but not avirulent, B. burgdorferi strains B31, N40, and HB19 demonstrated heparin attachment-inhibition. Attachment to Chinese hamster ovary cells deficient in heparan sulfate proteoglycans was reduced by 68% compared to attachment to wild-type cells and was identical to attachment at maximum heparin inhibition to the wild-type cells. Pretreatment of HeLa cell monolayers with heparitinase, heparinase, and chondroitinase ABC, but not with chondroitinase AC, reduced borrelial attachment by approximately 50%. A moderately high affinity, low copy number, promiscuous B. burgdorferi glycosaminoglycan receptor was demonstrated by equilibrium binding studies. A 39-kD polypeptide, purified by heparin affinity chromatography from Triton X-100 extracts derived from virulent borrelia, was a candidate for this receptor. These studies indicate that one mode of B. burgdorferi attachment to eukaryotic cells is mediated by a borrelial glycosaminoglycan receptor attaching to surface-exposed proteoglycans on mammalian cells.
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PMID:Borrelia burgdorferi bind to epithelial cell proteoglycans. 811 83


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