EC:3.2.1.36 - FACTA Search

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)

Snake venoms are a rich source of enzymes including many hydrolytic enzymes. Some enzymes such as phospholipase A2, proteolytic enzymes, and phosphodiesterases are well characterized. However many enzymes, such as the glycosidase, hyaluronidase, have not been studied extensively. Here we describe the characterization of snake venom hyaluronidase. In order to determine which venom was the best source for isolation of the enzyme, the hyaluronidase activity of 19 venoms from Elapidae, Viperidae, and Crotalidae snakes was determined. Since Agkistrodon contortrix contortrix venom showed the highest activity, this venom was used for purification of hyaluronidase. Molecular weight was determined by matrix-assisted laser desorption ionization mass spectroscopy and was found to be 59,290 Da. The molecular weight value as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis was 61,000 Da. Substrate specificity studies indicated that the snake venom enzyme was specific only for hyaluronan and did not hydrolyze similar polysaccharides of chondroitin, chondroitin sulfate A (chondroitin 4-sulfate), chondroitin sulfate B (dermatan sulfate), chondroitin sulfate C (chondroitin 6-sulfate), chondroitin sulfate D, chondroitin sulfate E, or heparin. The enzyme is an endo-glycosidase without exo-glycosidase activity, as it did not hydrolyze p-nitrophenyl-beta-D-glucuronide or p-nitrophenyl-N-acetyl-beta-D-glucosaminide. The main hydrolysis products from hyaluronan were hexa- and tetrasaccharides with N-acetylglucosamine at the reducing terminal. The cleavage point is at the beta1,4-glycosidic linkage and not at the beta1,3-glycosidic linkage. Thus, snake venom hyaluronidase is an endo-beta-N-acetylhexosaminidase specific for hyaluronan.
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PMID:Characterization of hyaluronidase isolated from Agkistrodon contortrix contortrix (Southern Copperhead) venom. 1136 37

Specific hyaladherin-based assays have been set up to measure the concentration of hyaluronan in biological fluids. Hyaluronectin (HN; a hyaladherin extracted from ovine brain) binds to hyaluronan (HA) that must be 10 units (HA10) or more long. It was therefore of interest to determine whether HN would continue to bind to HA10 in full-length HA since conformational changes might mask potential binding sites. We used the enzyme-linked sorbent assay (ELSA) to assay HA and hyaluronan-derived oligosaccharides, with different standard HAs, and the results were compared to results obtained with the carbazole technique. Oligosaccharide length was calculated from the ratio glucuronic acid/reducing N-acetylglucosamine in fractions of hyaluronidase-digested macromolecular hyaluronan prepared by chromatography; the size of the HA12 oligosaccharide was confirmed by matrix-assisted laser desorption ionization mass spectrometry. During the digestion of macromolecular HA with hyaluronidase, the binding of HN to HA first increased and then decreased as shown using the ELSA. The concentration of HA fragments of HA60 and below was overestimated when intact macromolecular HA was used as the reference for the ELSA, while the concentration of HA100 and above was underestimated when HA10 was used as the reference. The binding of HN to HA20, HA40, and HA60 saccharides was consistent with binding to multiples of HA10 sites. In conclusion, the level of HN binding is determined by the conformation of HA, which may mask binding sites. Hence, calibration HA used in the ELSA must be adapted to the size of HA to assay.
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PMID:Importance of hyaluronan length in a hyaladherin-based assay for hyaluronan. 1187 9

The action of hyaluronidase on oligosaccharides from hyaluronan is complicated due to branched reaction paths containing hydrolysis, transglycosylation and condensation. The unit component of hyaluronan is a disaccharide, namely GlcA-(beta 1-->3)-GlcNAc where GlcA and GlcNAc are d-glucuronic acid and d-N-acetylglucosamine respectively. Hyaluronan is the linear polymer formed by these disaccharide units, linked together with beta 1-->4 glycosidic bonds. Bovine testicular hyaluronidase acts only at beta 1-->4 glycosidic bonds of hyaluronan. The progress of product distribution from short oligosaccharides was simulated with the Monte Carlo method using the probabilistic model. The model consists only of a single enzyme molecule and a finite number of substrate and water molecules. The simulation is based on a simple reaction scheme and proceeds via an algorithm with minimum adjustable parameters generating random numbers and probabilities. The experimental data for bovine testicular hyaluronidase using [GlcA-(beta 1-->3)-GlcNAc](4) as the starting substrate were quantitatively simulated with only three adjustable parameters. The simulated data for [GlcA-(beta 1-->3)-GlcNAc](3) and [GlcA-(beta 1-->3)-GlcNAc](5) as the starting substrates agreed semi-quantitatively with experimental data using the same parameters. The mechanism of the hyaluronidase reaction is a combination of branched probabilistic cycles. The condensation reaction is much weaker than the transglycosylation reaction but contributes to product distribution at the final stage of the reaction, preventing complete hydrolysis of the substrates.
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PMID:Monte Carlo simulation of hyaluronidase reaction involving hydrolysis, transglycosylation and condensation. 1196 43

Hyaluronic acid (HA) is a linear polysaccharide formed from disaccharide units containing N-acetylglucosamine and glucuronic acid. When HA was digested with the enzyme hyaluronidase, a double bond is formed. It is known that this double bond forms a complex (radical scavenger) with the radicals (ROO, HO) during UV irradiation, and reduced the toxicity of the radicals before they are absorbed in the human skin. Therefore, the characterization of the double bond formed after the enzymatic digestion of HA is very important. In this study, 1H NMR, 13C NMR, Raman, infrared (IR), and UV-Vis spectroscopies were used for characterization of the double bond of HA after enzymatic digestion. HA derivatives in shape of films were tested using Raman and infrared (IR) spectroscopies and the wavenumber of the double bond and some other assignment were determined. The 1H and 13C NMR spectra were measured for HA derivatives in D(2)O solutions. The chemical shifts and coupling constant of 1H and 13C were assigned to the CH=C fragment. The relative amount of olefinic proportion in the mixture was obtained from 1H and 13C NMR spectra. The spectroscopy measurement showed an increase in the double bond amount with increasing enzymatic digestion time.
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PMID:Characterization of enzymatically digested hyaluronic acid using NMR, Raman, IR, and UV-Vis spectroscopies. 1261 42

Hyaluronan is a megadalton glycosaminoglycan composed of repeating units of D-N-acetylglucosamine-beta-D-Glucuronic acid. It is known to form a highly hydrated pericellular coat around chondrocytes, fibrosarcoma, and smooth muscle cells. Using environmental scanning electron microscopy we detected fully hydrated hyaluronan pericellular coats around rat chondrocytes (RCJ-P) and epithelial cells (A6). Hyaluronan mediates early adhesion of both chondrocytes and A6 cells to glass surfaces. We show that chondrocytes in suspension establish early "soft contacts" with the substrate through a thick, hyaluronidase-sensitive coat (4.4 +/- 0.7 microm). Freshly-attached cells drift under shear stress, leaving hyaluronan "footprints" on the surface. This suggests that chondrocytes are surrounded by a multilayer of entangled hyaluronan molecules. In contrast, A6 cells have a 2.2 +/- 0.4- microm-thick hyaluronidase-sensitive coat, do not drift under shear stress, and remain firmly anchored to the surface. We consider the possibility that in A6 cells single hyaluronan molecules, spanning the whole thickness of the pericellular coat, mediate these tight contacts.
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PMID:Organization and adhesive properties of the hyaluronan pericellular coat of chondrocytes and epithelial cells. 1294 12

The glycosaminoglycan microenvironment of testicular hyaluronidase was simulated by multipoint covalent attachment of the enzyme to glycans as a result of benzoquinone activation. The efficiency of their binding was assessed using gel chromatography, ultrafiltration, titration of surface amino groups of the enzyme, electrophoresis, as well as judging by the value of residual endoglycosidase activity and its inhibition with heparin. Copolymer glycosaminoglycans, such as dermatan sulfate and heparin, inactivated the endoglycosidase activity as a result the C-5 epimerization of hexuronic acid. It was shown that glucuronic acid and, to a lesser extent, N-acetylglucosamine determine the specificity of hyaluronidase. The chondroitin-sulfate microenvironment made the enzyme resistant to heparin inhibition because the equatorial orientation of the OH groups is similar to that in hyaluronic acid. Model experiments with dextran and dextran sulfate showed that sulfation of the glycan chain increased its rigidity, thus hampering the stabilizing effect on hyaluronidase. The effect of chondroitin sulfate on the endoglycosidase activity of hyaluronidase had additive character and did not directly affect the small fragment of the active site of the enzyme located at the bottom of a groove. The glycosaminoglycan microenvironment of hyaluronidase, containing an iduronic acid residue, the alpha1-3 and alpha1-4 glycosidic bond, inactivated the hyaluronidase activity of the enzyme, whereas simple polymers (such as gluco- and galactoaminoglycans) potentiated it due to a similar way of linking--beta(1e-4e) and beta(1e-3e). To understand the nature of these interactions in detail, the effect of oligomeric glycosaminoglycan fragments and their derivatives on hyaluronidase should be studied.
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PMID:Role of the glycosaminoglycan microenvironment of hyaluronidase in regulation of its endoglycosidase activity. 1294 86

Chesbro, William R. (University of New Hampshire, Durham), Fred P. Heydrick, Roland Martineau, and Gail N. Perkins. Purification of staphylococcal beta-hemolysin and its action on staphylococcal and streptococcal cell walls. J. Bacteriol. 89:378-389. 1965.-After growth of bovine-derived strains of Staphylococcus aureus in a completely dialyzable medium, the beta-hemolysin in the culture supernatant fluids was purified by gradient-elution chromatography on cellulose phosphate. The purified hemolysin contained two components, demonstrable by immunodiffusion or electrophoresis, but was free from alpha-hemolysin, coagulase, Delta-hemolysin, enterotoxins A and B, glucuronidase, hyaluronidase, lipase, muramidase, Panton-Valentine leukocidin, phosphatase, and protease. The hemolysin was heat-labile and sulfhydryl-dependent, and the preparation was leukocidal for guinea pig macrophages. When rabbit red blood cell (RBC) stroma and staphylococcal or enterococcal cell walls were treated with the purified hemolysin, it liberated mucopolysaccharides from the rabbit RBC stroma, polysaccharides and mucopolysaccharides (or mucopeptides) from the staphyloccoal cell walls, and rhamnose, glucose, an unidentified monosaccharide, N-acetylglucosamine, and at least two polysaccharides from the enterococcal cell walls. The hemolytic and cell-wall degradative activities had similar thermal inactivation kinetics, pH optima, sedimentation coefficients, and chromatographic and electrophoretic mobilities; both required Mg and were inhibited by thiol-inactivating agents. Consequently, it seems likely that both activities are expressions of the same enzyme.
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PMID:PURIFICATION OF STAPHYLOCOCCAL BETA-HEMOLYSIN AND ITS ACTION ON STAPHYLOCOCCAL AND STREPTOCOCCAL CELL WALLS. 1425 4

This paper reports the synthesis of hyaluronan (HA) and its derivatives via the hyaluronidase-catalyzed polymerization of 2-substituted oxazoline derivative monomers designed as "transition-state analogue substrates". Polymerization of 2-methyl oxazoline monomer from N-acetylhyalobiuronate (GlcAbeta(1-->3)GlcNAc) effectively proceeded at pH 7.5 and 30 degrees C, giving rise to synthetic HA (natural type) in an optimal yield of 78% via ring-opening polyaddition under total control of regioselectivity and stereochemistry. Hyaluronidase catalysis enabled the polymerization of 2-ethyl, 2-n-propyl, and 2-vinyl monomers, affording the corresponding HA derivatives (unnatural type) with N-propionyl, N-butyryl, and N-acryloyl functional groups, respectively, at the C2 position of all glucosamine units in good yields. The 2-isopropyl oxazoline derivative provided the N-isobutyryl derivative of HA in low yields. Monomers of 2-phenyl and 2-isopropenyl oxazoline derivatives were not polymerized. The mechanism of the polymerization is discussed.
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PMID:Bottom-up synthesis of hyaluronan and its derivatives via enzymatic polymerization: direct incorporation of an amido functional group. 1576 80

A beta-N-acetylglucosaminidase gene (nag84A) was cloned from Clostridium paraputrificum M-21 in Escherichia coli. The nag84A gene consists of an open reading frame of 4647 by encoding 1549 amino acids, with a deduced molecular weight of 174,311, which have a catalytic domain belonging to family 84 of the glycoside hydrolases. Nag84A was purified from a recombinant E. coli and characterized. Although Nag84A exhibited high homology to the hyaluronidase from Clostridium perfringens, it did not degrade hyluronic acid. The enzyme hydrolyzed chitooligomers such as di-, tri-, tetra-, penta- and hexa-N-acetylchitohexaose, and synthetic substrates such as 4-methylumbelliferyl N-acetyl beta-D-glucosaminide [4-MU-(G1cNAc)], but did not hydrolyze 4-MU-beta-D-glucoside, 4-MU-alpha-D-glycoside, 4-MU-alpha-D-GlcNAc, 4-MU-alpha-D-galactoside, 4-MU-beta-D-xyloside, PNP-beta-D-galactoside, and PNP-alpha-D-xyloside. The enzyme was optimally active at 50 degrees C and pH 6.5, and the apparent K(m) and V(max) values for 4-MU-(GlcNAc) were 8.5 microM and 1.39 micromol/min/mg of protein, respectively. SDS-PAGE, zymogram, and immunological analyses suggested that Nag84A was inducible by ball-milled chitin. Since Nag84A has a high molecular weight with a family 84 catalytic domain with high homology to hyaluronidases but no hyaluronidase activity, the enzyme is a novel beta-N-acetylglucosaminidase different from others reported having low molecular weights and belonging to family 3 and family 18.
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PMID:A new type of beta-N-Acetylglucosaminidase from hydrogen-producing Clostridium paraputrificum M-21. 1623 20

Group A streptococcus (GAS) depends on a hyaluronic acid (HA) capsule to evade phagocytosis and to interact with epithelial cells. Paradoxically, GAS also produces hyaluronidase (Hyl), an enzyme that cleaves HA. A common assumption is that Hyl digests structurally identical HA in human tissue to promote bacterial spread. We inactivated the gene encoding extracellular hyaluronidase, hylA, in a clinical Hyl(+) isolate. Hyl(+) and an isogenic Hyl(-) mutant were injected subcutaneously into mice with or without high-molecular-weight dextran blue. The Hyl(-) strain produced small lesions with dye concentrated in close proximity. The Hyl(+) strain produced identical lesions, but the dye diffused subcutaneously. However, Hyl(+) bacteria were not isolated from unaffected skin stained by dye diffusion. Thus, Hyl digests tissue HA and facilitates spread of large molecules but is not sufficient to cause subcutaneous diffusion of bacteria or to affect lesion size. GAS capsule expression was assayed periodically during broth culture and was reduced in Hyl(+) strains relative to Hyl(-) strains at the onset and the end of active capsule synthesis but not during peak synthesis in mid-exponential phase. Thus, Hyl is not sufficiently active to remove capsule during peak synthesis. To demonstrate a possible nutritional role for Hyl, GAS was shown to grow with N-acetylglucosamine but not d-glucuronic acid (both components of HA) as a sole carbon source. However, only Hyl(+) strains could grow utilizing HA as a sole carbon source, suggesting that Hyl may permit the organism to utilize host HA or its own capsule as an energy source.
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PMID:Role of hyaluronidase in subcutaneous spread and growth of group A streptococcus. 1636 55

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