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Query: EC:3.1.6.4 (chondroitinase)
 2,039 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Hyaluronate levels change dramatically during morphogenesis of various tissues and organs. Morphological detection of the exact temporal and spatial distribution patterns of hyaluronate may help to elucidate its role in morphogenesis. Since no specific direct method for visualizing hyaluronate with the light or electron microscope is currently available, we have developed a morphological probe by exploiting the high-affinity interaction of cartilage proteoglycan with hyaluronate. The core protein of this proteoglycan consists of a region that binds specifically to hyaluronate with a high association constant, and a region to which the majority of sulfated polysaccharide chains are covalently attached. The polysaccharide chains were removed by treatment with chondroitinase ABC, and the core protein, labeled with rhodamine, was used as the probe. This fluorescent probe binds reversibly and specifically to [3H]hyaluronate in a binding assay using ammonium sulfate precipitation of the core protein. The probe has been used to visualize the cell surface hyaluronate of rat fibrosarcoma cells, 3T3 cells, and SV-40 transformed 3T3 cells, three cell types with significantly different amounts of cell surface-associated hyaluronate.
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PMID:Fluorescent morphological probe for hyaluronate. 258 Aug 46

Murine monocytic leukemic (M1) cells were cultured in the presence of [3H]glucosamine and [35S]sulfate. Labeled proteoglycans were purified by anion exchange chromatography and characterized by gel filtration and sodium dodecyl sulfate-polyacrylamide gel electrophoresis in combination with chemical and enzymatic degradation. M1 cells synthesize a single predominant species of proteoglycan which distributes almost equally between the cell and medium after 17 h labeling. The cell-associated proteoglycan has an overall size of about 135 kDa and contains three to five chondroitin sulfate chains (28-31 kDa each) attached to a chondroitinase-generated core protein of 28 kDa. The synthesis and subsequent secretion of this proteoglycan was enhanced 4-5-fold in cells induced to differentiate into macrophages. This was not a phenomenon of arrest in the G0/G1 stage of the cell cycle, since density inhibited undifferentiated cells arrested at this stage did not increase proteoglycan synthesis. The chondroitin sulfate chains contained exclusively chondroitin 4- and 6-sulfate; however, the ratio of these two disaccharides differed between the medium- and cell-associated proteoglycans, and changed during progression of the cells into a fully differentiated phenotype. Pulse-chase kinetics indicate the presence of two distinct pools of proteoglycan; one that is secreted very rapidly from the cell after a approximately 1-h lag, and a second pool that is turned over in the cell with a half-time of approximately 3.5 h. Subtle differences in the glycosylation patterns of the medium- and cell-associated species are consistent with synthesis of two pools. Papain digestion suggests that the chondroitin sulfate chains are clustered on a small protease resistant peptide. The data suggest that this proteoglycan is similar to the serglycin proteoglycan family.
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PMID:Proteoglycan biosynthesis in murine monocytic leukemic (M1) cells before and after differentiation. 266 17

The major proteoglycan in bovine parietal pericardium is a low molecular weight dermatan-sulfate proteoglycan. It possesses structural and immunologic characteristics similar to those of the small proteoglycan found in tendon. We demonstrate that digestion of purified pericardial proteoglycan with low levels of V8 protease results in the liberation of the glycosaminoglycan chain and of a 40 kDa resistant fragment. A similar 40 kDa fragment can be obtained by V8 protease digestion of the proteoglycan deglycosylated by chondroitinase ABC. Although the protein core size of the pericardial proteoglycan is similar to that of tendon PG II, the size of the glycosaminoglycan chain liberated from the former is smaller. The pericardial proteoglycan and its V8 protease products reacted with an anti-PG II antiserum by immunoblotting. The anti-PG-II antibody localized in the pericardial tissue by the immunoperoxidase technique. The presence of intrachain disulfide bonds in the structure of pericardial proteoglycan core protein and V8 resistant fragment was demonstrated by their decreased electrophoretic mobility after disulfide reduction. Digestion of pericardial proteoglycan with Cathepsin C resulted in a rapid liberation of the glycosaminoglycan chain from the core protein, indicating that its attachment site was very close to the amino terminus. Ultrastructural examination of pericardial tissue utilizing Cuprolinic Blue revealed a periodic association of the proteoglycan with the d/e band on the collagen fibrils. Electron microscopic immunohistochemical studies confirmed the perifibrillar association of pericardial proteoglycan. The present data demonstrate that, although the pericardial proteoglycan possesses some unique structural features, it shares structural and immunological characteristics to place it in the category of the small PG II family.
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PMID:Bovine pericardial proteoglycan: biochemical, immunochemical and ultrastructural studies. 267 26

The low molecular weight proteoglycan fraction extracted from articular discs with 4 M guanidinium chloride was found to consist predominantly of an iduronate-rich dermatan sulphate proteoglycan, together with chondroitin sulphate-containing material. The dermatan sulphate proteoglycan was purified by ion-exchange and gel-filtration chromatography and its core protein isolated after digestion with chondroitinase ABC. The amino acid composition and pattern of cyanogen bromide peptides obtained from this core were closely similar to those of the protein core of bovine skin proteodermatan sulphate. Four monoclonal antibodies raised against bovine skin proteodermatan sulphate also reacted with the disc protein core and its cyanogen bromide peptides. Results of digestion with glycopeptidase F demonstrated the presence of three N-linked oligosaccharides. The combined size of these oligosaccharides appeared to be somewhat less than the size of those on skin proteodermatan sulphate. The glycosaminoglycan chain released by digestion with cathepsin C had a higher molecular weight than that from skin. These differences in glycosylated structures may be responsible for the different effects on collagen fibrillogenesis in vitro; whereas skin proteodermatan sulphate only reduced the rate of fibril growth, disc dermatan sulphate proteoglycan also increased the length of the lag-phase and the final opacity.
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PMID:Proteoglycans of the articular disc of the bovine temporomandibular joint. II. Low molecular weight dermatan sulphate proteoglycan. 279 47

We have isolated cDNA clones that code for a proteoglycan-related polypeptide with unique properties. A lambda gt11 expression library made from human fibroblast mRNA was screened with an antiserum made against a proteoglycan fraction from human fetal membranes. One group of positive clones revealed an open reading frame coding for 685 amino acids from the COOH terminus of a polypeptide. This amino acid sequence contains a domain that is strongly homologous with the COOH-terminal core protein domain of the large aggregating cartilage proteoglycan. This domain also contains sequences that are homologous with vertebrate lectins that bind terminal galactosyl, N-acetyl-glucosaminyl or mannosyl residues. On the NH2-terminal side of the lectin-like domain the cDNA-derived amino acid sequence contains two epidermal growth factor-related segments. The cDNA clones were shown to belong to a chondroitin sulfate proteoglycan by using antisera made against two peptides predicted from the cDNA sequence. These antisera were reactive with a proteoglycan fraction from fibroblasts after chondroitinase treatment of the fraction but not after treatment with heparinase or no treatment. Among the several polypeptides reactive with the anti-peptide antibodies the largest one, corresponding to a molecular weight of about 400,000, is likely to be the intact core protein, whereas the smaller polypeptides may be processing products or products of artifactual proteolysis. These results show that the amino acid sequence belongs to a proteoglycan core protein, and the sequence, therefore, provides a molecular definition to this proteoglycan. The lectin-related and growth factor-like sequences in the core protein of this proteoglycan suggest that it may play a role in intercellular signaling.
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PMID:A fibroblast chondroitin sulfate proteoglycan core protein contains lectin-like and growth factor-like sequences. 282 Sep 64

Human granulation-tissue fibroblasts were cultured from oral chronic inflammatory lesions and compared with fibroblasts of healthy gingival connective tissue with respect to cell-surface sialoglycoproteins, and the synthesis of extracellular matrix components. Granulation-tissue fibroblasts exhibited a slower growth rate and larger size than their controls. Their cell-surface sialoglycoproteins resembled those of the control cells, except that the relative amount of glycoproteins in the 140-kd region was lower. The ratio of mRNAs for pro alpha l (I) and pro alpha l (III) collagen chains was decreased in granulation-tissue fibroblasts, although electrophoretic fractionation of the proteins did not reveal consistent differences in type I/type III collagen ratio. Granulation-tissue fibroblasts secreted into the culture medium a dermatan sulfate proteoglycan with a lower molecular weight. After digestion with chondroitinase ABC, the molecular weight of the core protein appeared to be identical with that of the control fibroblasts, suggesting a difference in the glycosylation of the core protein. These results support the theory that granulation-tissue fibroblasts represent a distinct phenotype of fibroblastic cells.
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PMID:Characterization of one phenotype of human periodontal granulation-tissue fibroblasts. 291 Sep 55

Human promyelocytic cells (HL-60) were labeled with 35S-sulfate and either 3H-glucosamine or 3H-serine as precursors. Accumulation of 35S-labeled macromolecules was approximately linear for up to 96 h, with a mean cell:medium ratio of 5.5:1, although activity/10(5) viable cells reached a plateau level after 24 h. Virtually none of the cell-associated proteoglycan was removed by trypsinization, consistent with a predominantly intracellular localization. Proteoglycan heterogeneity was investigated by DEAE-Sephacel chromatography, isopyknic CsCl gradient centrifugation, and gel filtration chromatography. HL-60 cells appeared to synthesize a single proteoglycan species, Kav = 0.46 on Sepharose CL-4B and Kav = 0.32 on Sepharose CL-6B, recovered primarily from the high-density fractions of a dissociative CsCl gradient (rho greater than 1.40 g/l). Degradation products of lower charge density, lower buoyant density, and lower hydrodynamic size were also present, mainly in the cell pellets. The major proteoglycan was found to contain chondroitin sulfate chains of average Mr = 14.5 kD, yielding virtually 100% 4-sulfated disaccharides on digestion with chondroitinase ABC. The proteoglycan was resistant to trypsin, chymotrypsin, plasmin, and papain, and the core protein Mr was approximately 20 kD by molecular sieve chromatography. Induction of HL-60 cells with 0.15 dimethyl sulfoxide (DMSO) resulted in differentiation to a more mature granulocytic phenotype and was associated with a reduction in 35S-sulfate incorporation to 45% of control values or 32%, expressed as activity/10(5) cells. Proteoglycans synthesized by DMSO-treated cells were identical to those from untreated cells in terms of hydrodynamic size, glycosaminoglycan Mr, and sulfation.
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PMID:Biosynthesis of proteochondroitin sulfate by HL-60 human promyelocytic cells. 291 Oct 20

Proteoglycans of bovine compact bone were purified by chromatography of the formic acid precipitate of an EDTA extract. The sequential chromatographic steps consisted of gel filtration on Sepharose CL-6B in 4-M guanidine HCl, ion-exchange chromatography on DEAE-Sephacel in 4-M urea and rechromatography on Sepharose CL-6B in 4-M guanidine HCl. The preparation consisted of a relatively small proteoglycan (Kav = 0.4 on Sepharose CL-6B) containing about 40% protein, 21% hexuronic acid, 23% galactosamine and lesser amounts of other monosaccharides. The core protein was shown by gradient NaDodSO4 gel electrophoresis, electrotransfer and immunodetection to be monodispersed with an Mr = 45,000. Analysis of glycopeptides obtained after papain digestion of the proteoglycan and separation from glycosaminoglycan chains by gel chromatography, indicated that both N-linked and O-linked oligosaccharides were present. The glycosaminoglycan chains liberated by papain digestion eluted from Sepharose CL-6B as a broad peak with Kav = 0.50, slightly ahead of the position of elution of bovine nasal cartilage glycosaminoglycans (Kav = 0.52); the bone glycosaminoglycans are thus slightly larger than those from cartilage and smaller than the ones attached to fetal bone proteoglycans. These chains were totally susceptible to chondroitinase AC II, a procedure that yielded unsaturated disaccharides corresponding predominantly to chondroitin-4-sulfate, and to a lesser extent chondroitin-6-sulfate. Antisera raised against adult bone proteoglycans cross-reacted with core protein of bone proteoglycan (obtained after chondroitinase digestion) but not with papain digested proteoglycan. In addition, they cross-reacted with core protein and trypsin-liberated, chondroitin sulfate rich region (AlTAl) derived from cartilage proteoglycans and, to a lesser extent, rat bone proteoglycans. No cross-reactivity could be detected to Smith-degraded cartilage proteoglycans, bone acidic glycoproteins or serum proteins.
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PMID:Proteoglycans of adult bovine compact bone. 293 15

Monoclonal antibody-producing cell lines were derived from BALB/c mice immunized with a testicular hyaluronidase digest of tryptic fragments of bovine nasal cartilage proteoglycan. Sera and hybridoma culture supernatants were screened by solid-phase immunoassay for reactivity against a chondroitinase ABC digest of the same proteoglycan fragment fraction. Antibody specificity was determined by competitive inhibition with purified proteoglycan fragment subfractions and their enzymatically modified derivatives. Two monoclonal antibodies were produced which reacted with keratan sulfate-rich fragments from bovine nasal and human articular cartilage proteoglycan. One, monoclonal LC8.13, is directed against keratan sulfate itself, but differs from 5-D-4, a previously described monoclonal antibody to keratan sulfate, in its lesser reactivity with keratanase-treated fragments. The second, monoclonal F1.2, appears to be directed against a conformation-dependent determinant on the core protein of this segment of the cartilage proteoglycan monomer. Monoclonal F1.2 does not react with the keratan sulfate species in human and fetal calf serum and can therefore detect the production of keratan sulfate-bearing proteoglycan by chondrocytes cultured in serum-containing media.
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PMID:Monoclonal antibodies reactive with keratan sulfate-bearing tryptic fragments of bovine nasal cartilage proteoglycan. 295 51

Dermatan sulfate proteoglycans (DS-PGs) isolated from bovine articular cartilage have been examined for their effects on the adhesive responses of BALB/c 3T3 cells and bovine dermal fibroblasts on plasma fibronectin (pFN) and/or type I collagen matrices, and compared to the effects of the chondroitin sulfate/keratan sulfate proteoglycan monomers (CS/KS-PGs) from cartilage. DS-PGs inhibited the attachment and spreading of 3T3 cells on pFN-coated tissue culture substrata much more effectively than the cartilage CS/KS-PGs reported previously; in contrast, dermal fibroblasts were much less sensitive to either proteoglycan class unless they were pretreated with cycloheximide. Both cell types failed to adhere to substrata coated only with the proteoglycans; binding of the proteoglycans to various substrata has also been quantitated. While a strong inhibitory effect was obtained with the native intact DS-PGs, little inhibitory effect was obtained with isolated DS chains (liberated by alkaline-borohydride cleavage) or with core protein preparations (liberated by chondroitinase ABC digestion). In marked contrast, DS-PGs did not inhibit attachment or spreading responses of either 3T3 or dermal fibroblasts on type I collagen-coated substrata when the collagen was absorbed with pFN alone, DS-PGs alone, or the two in combination. These results support evidence for (a) collagen-dependent, fibronectin-independent mechanisms of adhesion of fibroblasts, and (b) different sites on the collagen fibrils where DS-PGs bind and where cell surface "receptors" for collagen bind. Experiments were developed to determine the mechanism(s) of inhibition. All evidence indicated that the mechanism using the intact pFN molecule involved the binding of the DS-PGs to the glycosaminoglycan (GAG)-binding sites of substratum-bound pFN, thereby inhibiting the interaction of the fibronectin with receptors on the cell surface. This was supported by affinity chromatography studies demonstrating that DS-PGs bind completely and effectively to pFN-Sepharose columns whereas only a subset of the cartilage CS/KS-PG binds weakly to these columns. In contrast, when a 120-kD chymotrypsin-generated cell-binding fragment of pFN (CBF which has no detectable GAG-binding activity as a soluble ligand) was tested in adhesion assays, DS-PGs inhibited 3T3 adherence on CBF more effectively than on intact pFN. A variety of experiments indicated that the mechanism of this inhibition also involved the binding of DS-PGs to only substratum-bound CBF due to the presence of a cryptic GAG-binding domain not observed in the soluble CBF.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Fibronectin-mediated adhesion of fibroblasts: inhibition by dermatan sulfate proteoglycan and evidence for a cryptic glycosaminoglycan-binding domain. 295 85


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