Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.2.1.36 (hyaluronidase)
 4,606 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Commercial testicular hyaluronidase preparations are contaminated by a small amount of protease activity which is partially inhibited by serine-protease inhibitors or pepstatin. These protease inhibitors can be shown by Sepharose gel column chromatography to abolish or reduce hyaluronidase-induced degradation of bovine nasal cartilage proteoglycan subunit without affecting the ability of the enzyme to degrade chondroitin sulfate. In addition, immunodiffusion studies indicate that pretreatment of hyaluronidase with these protease inhibitors reduces or abolishes the ability of the enzyme to produce a second "link-related" immunoprecipitin line upon digestion of link protein-containing proteoglycan fractions. Thus, the enhancement of immune reactivity and the unmasking of an additional antigen noted after digestion of cartilage proteoglycan with testicular hyaluronidase are most likely due to the exposure of additional antigenic sites or the the release of more highly immunoreactive fragments by the contaminant proteases rather than to the action of hyaluronidase itself.
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PMID:The effect of contaminant proteases in testicular hyaluronidase preparations on the immunological properties of bovine nasal cartilage proteoglycan. 15 47

A high performance liquid chromatography (HPLC) procedure suitable for the simultaneous determination of the molecular size and concentration of macromolecular hyaluronate and proteoglycans in synovial fluid has been developed. Irrigation of the equine tarsocrural joint with 20 ml physiological saline (PSS) caused a mild inflammation with an increase of proteoglycans in the synovial fluid over the baseline arthrocentesis control sample. Proteoglycan and hyaluronate in the synovial fluid did not interact to form hyaluronate-proteoglycan aggregates, but separated as distinct chromatographic peaks. This suggests that the cartilage derived proteoglycans in synovial fluid in the inflamed joint have been proteolytically cleaved from the non-covalent aggregates containing link protein and hyaluronate. Hyaluronidase digestion completely abolished the hyaluronate peak without affecting the proteoglycans. This seems to indicate that proteoglycan in synovial fluid is unable to interact with hyaluronate in synovial fluid to form cartilage type aggregates. Proteolytic degradation and the time dependent release into the synovial fluid of such digested proteoglycan also resulted from the intra-articular injection of methylprednisolone acetate into normal tarsocrural joints and joints irrigated with PSS. These proteoglycans were insensitive to hyaluronidase but may consist of a protein moiety with attached glycosaminoglycans, as suggested by their sensitivity to proteinase and keratanase/chondroitinase digestion. These observations with cartilage treated with methylprednisolone acetate and mildly stimulated articular cartilage are inconsistent with earlier work on osteoarthritic and rheumatoid articular cartilage and have interesting implications for the pathogenesis and for the therapeutic action of intraarticular corticosteroids. A rapid HPLC procedure applicable to unprocessed small volume samples of synovial fluid gives information simultaneously on hyaluronate and proteoglycan in synovial fluid which is not attainable with immunoradiometric or isotope tracer techniques. It therefore appears to be useful for the analysis of cartilage turnover and destruction in health and disease.
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PMID:Methylprednisolone acetate induced release of cartilage proteoglycans: determination by high performance liquid chromatography. 155 Apr 6

Vitreous humor from human, bovine, and chicken eyes was analyzed by rotary shadowing to characterize further the supramolecular organization of the gel-like matrix which forms this tissue. Extensive filamentous networks, distinct from collagen fibrils, were found in both human and bovine vitreous but not in chicken vitreous. The networks consisted of branching structures of various diameters, due to variable numbers of hyaluronan molecules being laterally associated with each other and apparently giving rise to a three-dimensional lattice. These networks could be decorated in a specific and regular manner by the hyaluronan-binding region called G1 purified from bovine nasal septum cartilage. The extent of decoration of hyaluronan was dependent on the relative concentration of G1. In the presence of an excess of G1 the networks were destabilized giving rise to individual unbranched hyaluronan chains of varying length that were saturated with G1. One or more globular proteins, as yet uncharacterized, were seen interacting with the hyaluronan networks, often at branch points. These proteins may serve to stabilize the three-dimensional structure of the matrix although highly ordered networks were also observed without globular proteins. Link protein, which also binds to hyaluronan, bound to the networks in a fashion clearly distinct from G1. Neither G1 nor link protein bound directly to human or bovine vitreous collagen fibrils. However, link protein did bind extensively to the glycosaminoglycan coat of chicken vitreous collagen fibrils described previously (D. W. Wright, and R. Mayne J. Ultrastruct. Mol. Struct. Res. 100, 224-234, 1988), while G1 did not. Digestion of the chicken vitreous collagen fibrils with Streptomyces hyaluronidase did not result in the removal of the glycosaminoglycan coat of the collagen fibrils nor did it affect the binding of G1 or link protein to the fibrils, indicating that hyaluronan is not a component of this structure. These studies demonstrate that proteins with specific binding properties can be used as probes to investigate the structure of the native vitreous humor gel from several species and suggest that this method potentially can be used for structural studies of other connective tissue matrices.
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PMID:Mammalian vitreous humor contains networks of hyaluronan molecules: electron microscopic analysis using the hyaluronan-binding region (G1) of aggrecan and link protein. 172 32

Matrix vesicles (MV) are microstructures localized to the extracellular matrix of developing hard tissues that induce mineral formation. MV proteins are not well characterized, and little is known of how they interact with the surrounding matrix. However, recent electron microscopic studies indicate that MV interact with matrix proteins in growth plate cartilage. In the studies now reported, procedures developed for dissecting various components from isolated MV led to the discovery that two major vesicle proteins (38 and 46 kDa) are readily released from MV by low ionic strength solutions. These low ionic strength-soluble proteins (LISSP) were shown to be major fragments of the link protein (LP) and hyaluronic acid-binding region (HABR) of matrix proteoglycans: they react immunologically with highly specific monoclonal antibodies to LP and HABR, and the NH2-terminal sequence of the 38-kDa LISSP is essentially identical to residues 40-78 of chicken cartilage LP and that the 46-kDa LISSP represents HABR. Release of both LISSP is enhanced by hyaluronidase treatment, indicating anchorage by a hyaluronate-mediated mechanism. Both LP and HABR are firmly attached to MV in either isotonic or hypertonic solutions. In contrast, our other studies show that dissociation of type II collagen from MV occurs only with hypertonic salts which do not release the LISSP. Thus, strong interactions occur under physiological conditions between MV and both the proteoglycans and collagens, but these take place by different mechanisms.
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PMID:Association between proteoglycans and matrix vesicles in the extracellular matrix of growth plate cartilage. 198 42

The association of hyaluronate with the surface of chondrocytes was examined by several approaches using primary cultures of chondrocytes derived from the Swarm rat chondrosarcoma. In culture, chondrosarcoma chondrocytes produced large pericellular coats, which can be visualized by particle exclusion, and which can be removed by Streptomyces hyaluronidase. Exposure of chondrocytes, which had been metabolically labelled with 3H-acetate, to exogenous hyaluronate or to Streptomyces hyaluronidase resulted in the release of 36-38% of the endogenous, labelled chondroitin sulfate from the cell layer into the incubation solution. These results imply that at least 37% of the cell layer chondroitin sulfate proteoglycan is retained there by an interaction with hyaluronate. Thus membranes were prepared from cultured chondrocytes and examined for sites which bind 3H-hyaluronate. Binding was observed and found to be saturable, specific for hyaluronate, of high affinity (Kd = approximately 10(-10) M), and destroyed by treating the membranes with trypsin. The 3H-hyaluronate-binding activity was inhibited competitively by hyaluronate decasaccharides but not by hexasaccharides or octasaccharides, indicating that the binding sites recognize a sequence of hyaluronate composed of five disaccharide repeats. The binding activity was partially purified from a detergent extract of chondrocyte membranes by ion exchange chromatography on DEAE-cellulose, followed by affinity chromatography on wheat germ agglutinin-agarose. Analysis of the partially purified binding activity by SDS-PAGE revealed five protein bands of 48,000-66,000 daltons in silver-stained gels. SDS-PAGE followed by Western blotting and exposure to monoclonal antibodies which recognize epitopes present in link protein and in the hyaluronate-binding region of cartilage proteoglycan revealed no immunoreactive protein bands in the partially purified material. We conclude that one mechanism by which hyaluronate associates with the chondrocyte surface may be via interaction with a membrane-bound hyaluronate-binding protein which is distinct from link protein and proteoglycan.
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PMID:Membrane-associated hyaluronate-binding activity of chondrosarcoma chondrocytes. 247 51

The hyaluronic acid binding region was prepared by clostripain digestion of chondroitin sulfate proteoglycan isolated from the Swarm rat chondrosarcoma, and biotinylated in the presence of associated hyaluronic acid and link protein. After removal of hyaluronic acid by gel filtration in 4 M guanidine HCl, the biotinylated binding region-link protein complex was used as a specific histochemical probe in conjunction with avidin-peroxidase. Its utility was initially evaluated by comparison with Alcian blue staining of the axial region of 2 to 5 day chick embryos, where staining was seen in the dorsolateral area between the neural tube and the ectoderm, in the perichordal mesenchyme, and in developing limb buds. Light and electron microscopic studies of early postnatal rat cerebellum indicate that hyaluronic acid is primarily localized in the extracellular space of immature brain. Staining specificity was demonstrated by the ability of hyaluronic acid oligosaccharides of appropriate size to block the staining reaction, and by the absence of staining after treatment of tissue sections with protease-free Streptomyces hyaluronidase, which degrades only this glycosaminoglycan.
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PMID:The hyaluronic acid binding region as a specific probe for the localization of hyaluronic acid in tissue sections. Application to chick embryo and rat brain. 404 84

Monospecific antibodies to bovine cartilage proteoglycan monomer (PG) and link protein (LP) have been used with immunoperoxidase electron microscopy to study the distribution and organization of these molecules in bovine articular cartilage. The following observations were made: (a) The interterritorial matrix of the deep zone contained discrete interfibrillar particulate staining for PG and LP. This particulate staining, which was linked by faint bands of staining (for PG) or filaments (for LP), was spaced at 75- to 80-nm intervals. On collagen fibrils PG was also detected as particulate staining spaced at regular intervals (72 nm), corresponding to the periodicity of collagen cross-banding. The interfibrillar PG staining was often linked to the fibrillar PG staining by the same bands or filaments. The latter were cleaved by a proteinase-free Streptomyces hyaluronidase with the removal of much of the interfibrillar lattice. Since this enzyme has a specificity for hyaluronic acid, the observations indicate that the lattice contains a backbone of hyaluronic acid (which appeared as banded or filamentous staining) to which is attached LP and PG, the latter collapsing when the tissue is fixed, reacted with antibodies, and prepared for electron microscopy. Thishyaluronic acid is anchored to collagen fibrils at regular intervals where PG is detected on collagen. PG and LP detected by antibody in the interterritorial zones are essentially fully extractible with 4 M guanidine hydrochloride. These observations indicated that interfibrillar PG and LP is aggregated with HA in this zone. (b) The remainder of the cartilage matrix had a completely different organization of PG and LP. There was no evidence of a similar latticework based on hyaluronic acid. Instead, smaller more closely packed particulate staining for PG was seen everywhere irregularly distributed over and close to collagen fibrils. LP was almost undetectable in the territorial matrix of the deep zone, as observed previously. In the middle and superficial zones, stronger semiparticulate staining for LP was distributed over collagen fibrils. (c) In the superficial zone, reaction product for PG was distributed evenly on collagen fibrils as diffuse staining and also irregularly as particulate staining. LP was observed as semiparticulate staining over collagen fibrils. The diffuse staining for PG remained after extraction with 4 M guanidine hydrochloride. (d) In pericellular matrix, most clearly identified in middle and deep zones, the nature and organization of reaction product for PG and LP were similar to those observed in the territorial matrix, except that LP and PG were more strongly stained and amorphous staining for both components was also observed. (e) This study demonstrates striking regional variations of ultrastructural organization of PG and LP in articular cartilage...
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PMID:An immunoelectron microscope study of the organization of proteoglycan monomer, link protein, and collagen in the matrix of articular cartilage. 711 5

Monoclonal antibodies (mAbs) against the major constituents of cartilage extracellular matrix, aggrecan and link protein, were screened by indirect immunofluorescence on frozen sections of bovine spinal cord. Antibodies against aggrecan and link protein gave rise to very similar perineuronal labeling in spinal cord gray matter. Aggrecan and link protein reactivities were seen in other regions of the central nervous system (CNS), although their distributions were not always coincident. Pretreatment of the tissue section with Streptomyces hyaluronidase, which is hyaluronate-specific, led to the loss of both reactivities. On Western blots, anti-aggrecan mAbs reacted with a large chondroitin sulfate proteoglycan. The chondroitinase-treated CNS proteoglycan co-migrated with the chondroitinase- and keratanase-treated cartilage proteoglycan. In CNS tissue homogenates, the addition of Streptomyces hyaluronidase brought about the release of the proteoglycan from the tissue. Anti-link protein mAbs were reactive with two species in the bovine CNS, the mobilities of which were very similar to those of the cartilage link proteins. The release of these species from the tissue required hyaluronidase. A rabbit antiserum against aggrecan was used to identify a similar proteoglycan in the rat CNS. In spinal cord-derived cell cultures, the labeled material was associated with astrocytes. An aggrecan cDNA hybridized to a 9.5 kb mRNA in the rat CNS. We conclude that the perineuronal matrix consists, in part, of a hyaluronate-bound aggrecan-like proteoglycan and link proteins, and that the former is produced by astrocytes.
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PMID:On the existence of a cartilage-like proteoglycan and link proteins in the central nervous system. 761 38

In the preovulatory follicle, the oocyte is surrounded by approximately 1000 closely associated cumulus cells forming the compact form of the cumulus cell-oocyte complex (COC). In response to the gonadotropin surge, the COC in a follicle destined for ovulation undergoes expansion when the cumulus cells synthesize and organize an extensive extracellular matrix enriched in hyaluronan. Successful expansion of the COC appears to be essential for ovulation and ultimately for fertilization. We studied this process in vitro by isolating compact COCs from preovulatory mouse follicles and incubating them under conditions which promote COC expansion by retention of newly synthesized hyaluronan (HA in the extracellular matrix around the cells. [3H]-Leucine and [35S]sulfate were used as precursors to label macromolecules synthesized by the cells that may be necessary for organizing the HA in this matrix. After labeling, expanded COCs were washed to remove medium and any labeled molecules that were not associated with the matrix. Macromolecules selectively associated with the matrix were then solubilized by digesting the expanded COCs briefly with Streptomyces hyaluronidase, an enzyme that specifically cleaves HA. Cells were removed by centrifugation, and the digest supernate was analyzed by molecular sieve chromatography and SDS-PAGE. A dermatan sulfate proteoglycan of large hydrodynamic size ( > 1 million Da) and a approximately 46-kDa protein were the predominant labeled species identified. The proteoglycan has properties similar to proteoglycans such as aggrecan and versican which interact specifically with HA. The approximately 46-kDa protein has the same molecular size as the link protein which interacts with HA and HA-binding proteoglycans to form stable ternary complexes in a variety of extracellular matrices. We propose that the dermatan sulfate proteoglycan and the approximately 46-kDa protein synthesized by the cumulus cells form similar ternary complexes that are necessary for retaining HA in the COC matrix and hence are required for successful COC expansion.
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PMID:Proteoglycans and proteins in the extracellular matrix of mouse cumulus cell-oocyte complexes. 856 97

Cartilage is a hypocellular tissue in which a balance of matrix molecules, especially aggrecan and link protein, play a critical role in maintaining structural integrity. To study the role of aggrecan and link protein in mediating cell activities, we have stably expressed them in NIH/3T3 fibroblasts and observed the effect on cell-substratum interactions. Overexpression of either protein destabilized the cell-substratum interaction. However, when both were co-expressed, the interaction between cell and substratum was less impaired. Similar results were obtained on type II collagen-coated plates. The addition of exogenous gene products into fibroblast cell lines and chondrocyte culture had the same effect as expression of the genes. The addition of exogenous hyaluronan to the growth medium or treatment of cells with hyaluronidase also decreased cell adhesion, indicating that hyaluronan also plays a role in the cell-substratum adhesion. The presence of aggrecan seems to increase the amount of link protein on the cell surface. Chondrocytes expressing high concentrations of aggrecan and link protein were maintained within a matrix network and were able to survive in suspended culture. Imbalances in aggrecan or link protein concentrations, or degradation of hyaluronan, disrupted the network and caused the chondrocytes to aggregate or adhere to the plates.
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PMID:Aggrecan and link protein affect cell adhesion to culture plates and to type II collagen. 956 23


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