EC:3.2.1.17 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.2.1.17 (lysozyme)
21,489 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Three cases are presented where modified chitins have been extensively administered to volunteers, as dressings for wounded soft and bone tissues, as anticholesterolemic dietary foods, and in the controlled delivery of anti-inflammatory drugs. The interactions of the modified chitins with human enzymes is critically examined. In the context of drug carrier resorption and wound healing, chitooligomers and monomers, generated by lysozyme, N-acetylglucosaminidase and human chitinase, activate macrophages and stimulate fibroblasts, respectively; the effects are production of smooth, vascularized and physiologically normal tissues. In the dietary food area, lipase, amylase, 3-hydroxy-3-methylglutaryl CoA reductase, glucokinase and the enzymes of prostaglandin synthesis are involved in the oral administration of chitosan: lipid adsorption is depressed mainly because of the physical form of the chitosan-lipid aggregates, which are unsuitable as substrates. When chitosan is used as a drug carrier, chitosan-drug complexes are present. The uniqueness of chitosan among polysaccharides is underlined in terms of susceptibility to enzymatic depolymerization, cationicity, supply of cell-activating oligomers, and supply of N-acetylglucosamine for rebuilding of other biopolymers. Advances in molecular recognition and biocompatibility are also presented.
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PMID:Human enzymatic activities related to the therapeutic administration of chitin derivatives. 911 1

The initial degradation rates (r) in human serum of three chitosans with FA = 0.42, 0.51, and 0.60 were determined by measuring the decrease in viscosity as a function of time. A strong increase in r with increasing FA of the chitosans was observed, with r increasing proportionally to FA4.5. With increasing concentrations of lysozyme added to the reaction mixtures of chitosan and serum, the relative increase in degradation rate of chitosans with increasing FA was almost the same as that without lysozyme added. Addition of the chitinase inhibitor allosamidin (50 microM) did not inhibit the degradation rate of chitosan (FA = 0.60) by human serum. The results suggest that chitosans are actually mainly depolymerized by lysozyme in human serum, and not by other enzymes or other depolymerization mechanisms.
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PMID:In vitro degradation rates of partially N-acetylated chitosans in human serum. 912 98

The method of estimation of lysozyme activity in serum when chitin azure is used as substrate is described. The basis of incubation medium is 0.1 M acetate buffer, pH 5.0. It was judged about activity of lysozyme by fluorescence of azure in incubation medium at the end of three hour incubation at 37 degrees C after separation on non-reacted chitin azure by short time centrifugation. It was shown that development of wound infection is accompanied by increasing of chitinase activity of lysozyme in serum.
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PMID:[Method of estimation of lysozyme activity in serum with chitin azure as substrate]. 927 83

We have further studied some characteristics of human plasma specific chitinase by making use of the fluorescent substrate methylumbelliferyl-tetra-N-acetyl-beta-D-chitotetraoside (MU-TACT). The enzyme is also active towards the substrates MU-di-N-acetyl-beta-D-chitobioside (MU-DACB) and MU-N-acetyl-chitotrioside (MU-TRACT). MU-TACT hydrolase in plasma is very stable. It is inhibited by the substrate and the product of the reaction and by allosamidin and ethyleneglycolchitin. When the activity of plasma MU-TACT hydrolase was compared to Remazol Brilliant Violet carboxymethyl (RBV) chitin hydrolase (RBV chitinase), it appeared that another enzyme--lysozyme--is also active on RBV chitin and this enzyme represents about 50-60% of the total RBV chitinase activity. Highly increased activity of plasma MU-TACT hydrolase in plasma of Gaucher patients was reflected in a similar increase of RBV chitin hydrolase. In these patients, both MU-TACT hydrolase and RBV chitinase are totally inhibited by allosamidin indicating that specific chitinase is the increased enzyme. With the MU-TACT substrate, specific chitinase is measured and with RBV chitin as substrate the measured activity is a combination of specific chitinase (activity inhibited by allosamidin) as well as lysozyme (residual activity after allosamidin inhibition). For measurement of specific chitinase in human plasma and clinical applications, the di-, tri- or tetra-N-acetylglucosamine derivatives of MU are recommended. In order to avoid confusion, recommended names are either the total substrate followed by -ase, or chitinase.
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PMID:Plasma methylumbelliferyl-tetra-N-acetyl-chitotetraoside hydrolase: further study of its characteristics as a chitinase and comparison with its activity on Remazol Brilliant Violet carboxymethyl chitin. 949 75

The sex-inducing pheromone of the multicellular green alga Volvox carteri is a glycoprotein that triggers development of males and females at a concentration <10(-16) M. By differential screening of a cDNA library, two novel genes were identified that are transcribed under the control of this pheromone. Unexpectedly, one gene product was characterized as a lysozyme/chitinase, and the other gene product was shown to encode a polypeptide with a striking modular composition. This polypeptide has a cysteine protease domain separated by an extensin-like module from three repeats of a chitin binding domain. In higher plants, similar protein families are known to play an important role in defense against fungi. Indeed, we found that the same set of genes triggered by the sexual pheromone was also inducible in V. carteri by wounding.
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PMID:The sex-inducing pheromone and wounding trigger the same set of genes in the multicellular green alga Volvox. 959 36

Novel information on the structure and function of chitosanase, which hydrolyzes the beta-1,4-glycosidic linkage of chitosan, has accumulated in recent years. The cloning of the chitosanase gene from Streptomyces sp. strain N174 and the establishment of an efficient expression system using Streptomyces lividans TK24 have contributed to these advances. Amino acid sequence comparisons of the chitosanases that have been sequenced to date revealed a significant homology in the N-terminal module. From energy minimization based on the X-ray crystal structure of Streptomyces sp. strain N174 chitosanase, the substrate binding cleft of this enzyme was estimated to be composed of six monosaccharide binding subsites. The hydrolytic reaction takes place at the center of the binding cleft with an inverting mechanism. Site-directed mutagenesis of the carboxylic amino acid residues that are conserved revealed that Glu-22 and Asp-40 are the catalytic residues. The tryptophan residues in the chitosanase do not participate directly in the substrate binding but stabilize the protein structure by interacting with hydrophobic and carboxylic side chains of the other amino acid residues. Structural and functional similarities were found between chitosanase, barley chitinase, bacteriophage T4 lysozyme, and goose egg white lysozyme, even though these proteins share no sequence similarities. This information can be helpful for the design of new chitinolytic enzymes that can be applied to carbohydrate engineering, biological control of phytopathogens, and other fields including chitinous polysaccharide degradation.
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PMID:Chitosanase from Streptomyces sp. strain N174: a comparative review of its structure and function. 959 57

Based on first principles and molecular mechanics calculations, we conclude that the mechanism of hevamine (a family 18 chitinase) involves an oxazoline ion intermediate stabilized by the neighboring C2' acetamido group. In this intermediate, the acetamido carbonyl oxygen atom forms a covalent bond to C1' of N-acetyl-glucosamine and has a transferred positive charge from the pyranose ring onto the acetamido nitrogen atom, leading to an anchimeric stabilization of 38.1 kcal/mol when docked with hevamine. This double displacement mechanism involving an oxazoline intermediate distinguishes the family 18 chitinase (which have one acidic residue near the active site) from family 19 chitinase and from hen egg-white lysozyme, which have two acidic residues near the active site. The structural and electronic properties of the oxazoline intermediate are similar to the known chitinase inhibitor allosamidin, suggesting that allosamidins act as transition state analogs of an oxazoline intermediate. Structural and electronic features of the oxazoline ion likely to be important in the design of new chitinase inhibitors are discussed.
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PMID:Substrate assistance in the mechanism of family 18 chitinases: theoretical studies of potential intermediates and inhibitors. 967 59

A novel method for the preparation of N-acylchitosan fiber and N-acylchitosan-cellulose fiber is described. Each aqueous solution of sodium N-acetyl and N-propionylchitosan salts in aqueous 14% NaOH was spun through a viscose-type spinneret at 10-15 degrees C into a coagulating bath containing aqueous 10%, H2SO4. 25% Na2SO4 and 1.3% ZnSO4 to afford the corresponding white fiber. By the same method, a clear solution of sodium N-acetyl and N-propionyl chitosan salts were respectively mixed with sodium cellulose xanthate in aqueous 14% NaOH and spun to afford the corresponding white N-acylchitosan-cellulose fiber. Their filament tenacity and elongation values were 0.4-0.7 times as large as cellulose. These fibers were digestible in reactions by chitinase and lysozyme, and the digestibility was controlled by the structure of the N-acyl group.
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PMID:Novel method for the preparation of N-acylchitosan fiber and N-acylchitosan-cellulose fiber. 967 78

A lysozyme (pI 5.5) was purified to homogeneity from heated acid extracts of Drosophila melanogaster larvae, using gel filtration in a Superose column and ion-exchange chromatography in a Mono Q column. The final yield was 67%. The purified lysozyme with Mr 13,700 (determined by SDS-polyacrylamide gel electrophoresis) decreases in activity and has its pH optimum displaced towards acidic values and Km increases as the ionic strength of the medium becomes higher. The lysozyme is resistant to a cathepsin D-like proteinase present in cyclorrhaphous Diptera and displays a chitinase activity which is 11-fold higher than that of chicken lysozyme. Microsequencing of an internal peptide of the purified lysozyme showed that this enzyme is the product of the previously sequenced Lys D gene. The results suggest that the product of the Lys P gene has pI 7.2, a pH optimum around 5 and is not a true digestive enzyme. The most remarkable sequence convergence of D. melanogaster lysozyme D and lysozymes from vertebrate foregut fermenters are serine 104 and a decrease in the number of basic amino acids, suggesting that these features are necessary for digestive function in an acid environment. Adaptive residues putatively conferring stability in an acid proteolytic environment differ between insects and vertebrates, probably because they depend on the overall three-dimensional structure of the lysozymes. A maximum likelihood phylogeny and inferences from insect lysozyme sequences showed that the recruitment of lysozymes as digestive enzymes is an ancestral condition of the flies (Diptera: Cyclorrhapha).
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PMID:Molecular adaptation of Drosophila melanogaster lysozymes to a digestive function. 969 34

Substrate binding subsites of barley chitinase and goose egg white lysozyme were comparatively investigated by kinetic analysis using N-acetylglucosamine oligosaccharide as the substrate. The enzymatic hydrolysis of hexasaccharide was monitored by HPLC, and the reaction time-course was analyzed by the mathematical model, in which six binding subsites (B, C, D, E, F, and G) and bond cleavage between sites D and E are postulated. In this model, all of the possible binding modes of substrate and products are taken into consideration assuming a rapid equilibrium in the oligosaccharide binding processes. To estimate the binding free energy changes of the subsites, time-course calculation was repeated with changing the free energy values of individual subsites, until the calculated time-course was sufficiently fitted to the experimental one. The binding free energy changes of the six binding subsites, B, C, D, E, F and G, which could give a calculated time-course best fitted to the experimental, were 0.0, -5.0, +4.1, -0.5, -3.8, and -2.0 kcal/mol for barley chitinase, and -0.5, -2.2, +4.2, -1.5, -2.6, and -2.8 kcal/mol for goose egg white lysozyme. The binding mode predicted from the p-nitrophenyl-penta-N-acetylchitopentaoside splitting pattern for each enzyme was also analyzed by the identical subsite model. Using the free energy values listed above, the binding mode distribution calculated was fitted to the experimental with a slight modification of free energy value at site G. We concluded that the binding subsite model described above reflects the substantial mechanism of substrate binding for both enzymes. The relatively large disparity in free energy value at site C between these enzymes may be due to the different secondary structures of polypeptide segments interacting with the sugar residue at site C.
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PMID:Substrate binding subsites of chitinase from barley seeds and lysozyme from goose egg white. 977 6

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