A novel goose-type lysozyme gene with chitinolytic activity from the moderately thermophilic bacterium <Emphasis Type="Italic">Ralstonia</Emphasis> sp. A-471: cloning,sequencing, and expression

In this study, we cloned the gene encoding goose-type (G-type) lysozyme with chitinase (Ra-ChiC) activity from Ralstonia sp. A-471 genomic DNA library. This is the first report of another type of chitinase after the previously reported chitinases ChiA (Ra-ChiA) and ChiB (Ra-ChiB) in the chitinase system of the moderately thermophilic bacterium, Ralstonia sp. A-471 and also the first such data in Ralstonia sp. G-type lysozyme gene. It consisted of 753 bp nucleotides, which encodes 251 amino acids including a putative signal peptide. This ORF was modular enzyme composed of a signal sequence, chitin-binding domain, linker, and catalytic domain. The catalytic domain of Ra-ChiC showed homologies to those of G-type lysozyme (glycoside hydrolases (GH) family 23, 16.8%) and lysozyme-like enzyme from Clostridium beijerincki (76.1%). Ra-ChiC had activities against ethylene glycol chitin, carboxyl methyl chitin, and soluble chitin but not against the cell wall of Micrococcus lysodeikticus. The enzyme produced α-anomer by hydrolyzing β-1,4-glycosidic linkage of the substrate, indicating that the enzyme catalyzes the hydrolysis through an inverting mechanism. When N-acetylglucosamine hexasaccharide [(GlcNAc)6] was hydrolyzed by the enzyme, the second and third glycosidic linkage from the non-reducing end were split producing (GlcNAc)2 + (GlcNAc)4 and (GlcNAc)3 + (GlcNAc)3 of almost the same concentration in the early stage of the reaction. The G-type lysozyme hydrolyzed (GlcNAc)6 in an endo-splitting manner, which produced (GlcNAc)3 + (GlcNAc)3 predominating over that to (GlcNAc)2 + (GlcNAc)4. Thus, Ra-ChiC was found to be a novel enzyme in its structural and functional properties. The sequence data reported in the present paper have been submitted to the DDBJ, EMBL, and NCBI databases under the accession number AB45458.     

Peptidoglycan N-acetylglucosamine deacetylases from Bacillus cereus, highly conserved proteins in Bacillus anthracis

The genomes of Bacillus cereus and its closest relative Bacillus anthracis contain 10 polysaccharide deacetylase homologues. Six of these homologues have been proposed to be peptidoglycan N-acetylglucosamine deacetylases. Two of these genes, namely bc1960 and bc3618, have been cloned and expressed in Escherichia coli, and the recombinant enzymes have been purified to homogeneity and further characterized. Both enzymes were effective in deacetylating cell wall peptidoglycan from the Gram(+) Bacillus cereus and Bacillus subtilis and the Gram(-) Helicobacter pylori as well as soluble chitin substrates and N-acetylchitooligomers. However, the enzymes were not active on acetylated xylan. These results provide insight into the substrate specificity of carbohydrate esterase family 4 enzymes. It was revealed that both enzymes deacetylated only the GlcNAc residue of the synthetic muropeptide N-acetyl-D-glucosamine-(beta-1,4)-N-acetylmuramyl-L-alanine-D-isoglutamine. Analysis of the constituent muropeptides of peptidoglycan from B. subtilis and H. pylori resulting from incubation of the enzymes BC1960 and BC3618 with these polymers and subsequent hydrolysis by Cellosyl and mutanolysin, respectively, similarly revealed that both enzymes deacetylate GlcNAc residues of peptidoglycan. Kinetic analysis toward GlcNAc(2-6) revealed that GlcNAc4 was the favorable substrate for both enzymes. Identification of the sequence of N-acetychitooligosaccharides (GlcNAc(2-4)) following enzymatic deacetylation by using 1H NMR revealed that both enzymes deacetylate all GlcNAc residues of the oligomers except the reducing end ones. Enzymatic deacetylation of chemically acetylated vegetative peptidoglycan from B. cereus by BC1960 and BC3618 resulted in increased resistance to lysozyme digestion. This is the first biochemical study of bacterial peptidoglycan N-acetylglucosamine deacetylases.     

Further studies on endo-beta-N-acetylglucosaminidase D1.

The purification procedure for endo-beta-N-acetylglucosaminidase D was improved to yield an enzyme preparation which was homogeneous upon gel electrophoresis. The molecular weight of the enzyme as estimated by Sephadex G-200 column chromatography was 280,000, while SDS-gel electrophoresis after reduction with 2-mercaptoethanol gave a value of 150,000. The purified enzyme did not show any chitinase, hyaluronidase or lysozyme activity. In the presence of exoglycosidases removing peripheral sugars, the endoglycosidase acted on serum glycoproteins such as transferrin and fetuin. The enzyme also hydrolyzed an oligosaccharide, (Man)5(GlcNAc)2, indicating that the peptide portion of substrates does not have much effect on susceptibility to the enzyme.     

Enzymatic polymerization to novel polysaccharides having a glucose-N-acetylglucosamine repeating unit, a cellulose-chitin hybrid polysaccharide

A cellulose-chitin hybrid polysaccharide having alternatingly beta(1-->4)-linked D-glucose (Glc) and N-acetyl-d-glucosamine (GlcNAc) was synthesized via two modes of enzymatic polymerization. First, a sugar oxazoline monomer of Glcbeta(1-->4)GlcNAc (1) was designed as a transition-state analogue substrate (TSAS) monomer for chitinase catalysis. Monomer 1 was recognized by chitinase from Bacillus sp., giving rise to a cellulose-chitin hybrid polysaccharide (2) via ring-opening polyaddition with perfect regioselectivity and stereochemistry. Molecular weight (M(n)) of 2 reached 4030, which corresponds to 22 saccharide units. Second, a sugar fluoride monomer of GlcNAcbeta(1-->4)Glc (3) was synthesized for the catalysis of cellulase from Trichoderma viride. The enzyme catalyzed polycondensation of 3, providing a cellulose-chitin hybrid polysaccharide (4) in regio- and stereoselective manner. M(n) of 4 reached 2840, which corresponds to 16 saccharide units. X-ray diffraction measurements revealed that these hybrid polysaccharides did not form any characteristic crystalline structures. Furthermore, these unnatural hybrids of 2 and 4 were successfully digested by lysozyme from human neutrophils.     

Functional Analysis of the Carbohydrate-Binding Domains of Erwinia chrysanthemi Cel5 (Endoglucanase Z) and an Escherichia coli Putative Chitinase

The Cel5 cellulase (formerly known as endoglucanase Z) from Erwinia chrysanthemi is a multidomain enzyme consisting of a catalytic domain, a linker region, and a cellulose binding domain (CBD). A three-dimensional structure of the CBD(Cel5) has previously been obtained by nuclear magnetic resonance. In order to define the role of individual residues in cellulose binding, site-directed mutagenesis was performed. The role of three aromatic residues (Trp18, Trp43, and Tyr44) in cellulose binding was demonstrated. The exposed potential hydrogen bond donors, residues Gln22 and Glu27, appeared not to play a role in cellulose binding, whereas residue Asp17 was found to be important for the stability of Cel5. A deletion mutant lacking the residues Asp17 to Pro23 bound only weakly to cellulose. The sequence of CBD(Cel5) exhibits homology to a series of five repeating domains of a putative large protein, referred to as Yheb, from Escherichia coli. One of the repeating domains (Yheb1), consisting of 67 amino acids, was cloned from the E. coli chromosome and purified by metal chelating chromatography. While CBD(Cel5) bound to both cellulose and chitin, Yheb1 bound well to chitin, but only very poorly to cellulose. The Yheb protein contains a region that exhibits sequence homology with the catalytic domain of a chitinase, which is consistent with the hypothesis that the Yheb protein is a chitinase.     

Characterization of seven basic endochitinases isolated from cell cultures of Citrus sinensis (L.)

Seven endochitinases (EC 3.2.1.14) (relative molecular masses 23000–28000 and isoelectric points 10.3–10.4) were purified from nonembryogenic Citrus sinensis L. Osbeck cv. Valencia callus tissue. The basic chitinase/lysozyme from this tissue (BCLVC) exhibited lysozyme, chitinase and chitosanase activities and was determined to be a class III chitinase. While BCLVC acted as a lysozyme at pH 4.5 and low ionic strength (0.03) it acted as a chitinase/chitosanase at high ionic strengths (0.2) with a pH optimum of ca. 5. The lysozyme activity of BCLVC was inhibited by histamine, imidazole, histidine and the N-acetyl-d-glucosamine oligosaccharide (GlcNAc)₃. The basic chitinase from cv. Valencia callus, BCVC-2, had an N-terminal amino acid sequence similar to tomato and tobacco AP24 proteins. The sequences of the other five chitinases were N-terminal blocked. Whereas BCLVC was capable of hydrolyzing 13.8–100% acetylated chitosans and (GlcNAc)_4–6 oligosaccharides, BCVC-2 hydrolyzed only 100% acetylated chitosan, and the remaining enzymes expressed varying degrees of hydrolytic capabilities. Experiments with (GlcNAc)_2–6 suggest that BCLVC hydrolysis occurs in largely tetrasaccharide units whereas hydrolysis by the other chitinases occurs in disaccharide units. Cross-reactivities of the purified proteins with antibodies for a potato leaf chitinase (Ab_PLC), BCLVC, BCVC-3, and tomato AP24 indicate that these are separate and distinct proteins.Mention of a trademark, warranty, propriety, or vendor does not constitute a guarantee by the U.S. Department of Agriculture and does not imply its approval to the exclusion of other products or vendors that may also be suitable.Abbreviations Ab antibody - BCLVC basic chitinase/lysozyme cv. Valencia callus - BCVC basic chitinase cv. Valencia callus - CE capillary electrophoresis - CM-chitin-RBV carboxymethyl-chitin-remazol brilliant violet - GlcNAc N-acetyl-d-glucosamine - HEWL hen egg-white lysozyme - M_r relativemolecular mass - pI isoelectric point - PLC potato leaf chitinase - PR pathogenesis-related - SEC size exclusion chromatography We thank Mr. M. Burkhart, Ms. T.-T. Ho, and Ms. M. Doherty for their valuable technical assistance. A portion of the funding for this work was made available from the Citrus Production Research Marketing Order by the Division of Marketing and Development, Florida Department of Agriculture and Consumer Services, Bob Crawford, Commissioner.     

Lysozyme Effect on Oleic Acid/Oleate Vesicles

We have analysed by means of turbidimetric, dynamic light scattering (DLS), and fluorimetric techniques the effect of lysozyme on negatively charged oleic acid/oleate vesicles. The addition of lysozyme brings about a decrease in optical density of the vesicle population, which finally results in a size distribution of oleate vesicles shifted toward smaller mean diameters. On the contrary, (a) when phosphatidylserine vesicles were used, lysozyme induces an increase of turbidity and a shift toward larger vesicle sizes; and (b) the addition of histone H1 or poly-L-lysine produces an aggregative behavior both in oleate and in phosphatidylserine vesicles. Experiments carried out with calcein-containing vesicles indicate that the observed changes in the lysozyme/oleate system occur with partial leakage of the vesicle content. All this is taken to suggest that the interaction between lysozyme and oleate vesicles is of quite specific nature, and certainly not just due to electrostatic interactions.     

Human serum contains a chitinase: identification of an enzyme, formerly described as 4-methylumbelliferyl-tetra-N-acetylchitotetraoside hydrolase (MU-TACT hydrolase)

Since 1988 an endoglucosaminidase, provisionally named MU-TACThydrolase, has been known that hydrolyses the artificial substrate4-methylumbelliferyl-tetra-N-acetyl-chitotetraoside (MU-[GlcNAc]₄,where GlcNAc is N-acetyl-glucosamine). The biological functionof the enzyme was unknown. In this paper evidence is presentedshowing that this endoglucosaminidase from human serum is infact a chitinase that is different from lysozyme. The factssustaining this finding are: (i) the identification of the productsformed from MU-[GlcNAc]₃ as [GlcNAc]₂ and [GlcNAc]₃; (ii) chitinand ethylene glycolchitin can be degraded by the enzyme; (iii)the chitinase inhibitor allosamidin also inhibits the actionof MU-TACT hydrolase from human serum; (iv) no hydrolysis ofthe lysozyme substrate Micrococcus lysodeikticus. The enzymealso occurs in rat liver. It was demonstrated that upon Percolldensity gradient centrifugation the enzyme from this tissuedistributed parallel to the lysosomal marker enzymes ß-N-acetylhexosaminidaseand ß-galactosidase, indicating a lysosomal localizationfor this enzyme. It is proposed that the enzyme functions inthe hydrolysis of chitin, to which mammals are frequently exposedduring infection by pathogens. allosamidin chitinase human serum lysozyme MUTACT hydrolase     

Bacterial cellulose synthesized with apple pomace enhanced by ionic liquid pretreatment

Abstract

Apple pomace was explored as alternative feedstock for producing bacterial cellulose (BC) by Gluconacetobacter xylinus following a cellulase saccharification performed after pretreatment of 1-allyl-3-methylimidazolium chloride ([AMIM]Cl). The dissolving process of apple pomace cellulose was observed by polarized light microscopy (PLM). As FT-IR and XRD results demonstrated, the IL pretreatment proved to be a physical process and no changes in the crystalline structure occurred during the pretreatment. However, the SEM result showed that more fissures and breakages appeared on the surface of pomace microfibers after IL-pretreating, which increased the contact area with cellulase and improved the enzymatic hydrolysis efficiency. An enhancing effect on the BC yield has been observed, 27% higher yield of BC obtained from hydrolysate as compared to sucrose-based medium indicates efficiency of IL-treated apple pomace to serve as high quality feedstock in BC production.     

Localization of chitinolytic enzymes in blood of turbot, Scophthalmus maximus, and their possible roles in defence

The intracellular localizations ofchitinase and β-N-acetylglucosaminidase were detected in turbot blood smears, using a novel method employing fluorogenic substrates. The two enzymes showed different distributions, with chitinase being more generally distributed and N-acetylglucosaminidase being strongly associated with distinct intracellular bodies, probably lysosomes. The fluorogenic substrates were used to analyse soluble and membrane fractions of homogenates of red and white blood cells prepared on Percoll gradients. In the leucocytes, the chitinase and N-acetylglucosaminidase activities were mostly in the soluble fraction. In the erythrocytes the activities were lower, at about one-hundredth and one-tenth specific activities, respectively, and were distributed between soluble and membrane-bound fractions at about 2 : 1 and 3 : 1, respectively. In contrast, lysozyme had a soluble distribution in leucocytes and was not detected in erythrocytes. Plasma was rich in chitinase and lysozyme activities but had no detectable N-acetylglucosaminidase. Two possible roles for the chitinolytic enzymes are discussed: defence against pathogens and processing of glycoproteins or glucosaminoglycans. Evidence for a defence role for the chitinase and lysozyme is provided by demonstrating that they had inhibitory activity against the chitinous fungus Mucor mucedo .     

海参i型溶菌酶基因及其编码产物的结构特点

通过RT-PCR 和 RACE PCR技术,从海参(Stichopus japonicus)体壁中克隆得到一种溶菌酶基因(GenBank：EF036468).生物信息软件分析表明,其中全长cDNA为 713 bp,5′非编码区（UTR）246 bp,3′UTR 29 bp,开放阅读框438 bp,编码145个氨基酸,包括溶菌酶成熟肽124个氨基酸和信号肽21个氨基酸.对海参溶菌酶与多种无脊椎动物的c、g和i型溶菌酶进行分析比较,发现它与i型溶菌酶有较高的同源性,并具有i型溶菌酶高度保守的2个活性位点,即Glu34和Ser50.活性位点附近具有i型溶菌酶的一段特有的氨基酸保守序列MDVGSLSCG(P/Y)(Y/F)QIK,所以推断克隆的海参溶菌酶为i型.另外,通过搜索蛋白保守结构域数据库,发现海参溶菌酶与医用水蛭失稳酶相似性最高,并且这2个酶的三级结构模型也极其相似.因此推测,海参i型溶菌酶具有双功能特性,既能作用于细菌细胞壁的糖苷键使细胞裂解,又具有失稳酶的一些生化功能,能够水解纤维蛋白,这些特点在海参自溶过程中发挥重要的作用.     

Induction of chitinase and β-1,3-glucanase in Parthenocissus quinquefolia cells cultured in vitro

Chitin, chitosan and peptidoglycan induced chitinase (EC 3. 2. 1. 14) activity in Parthenocissus quinquefolia cells cultured in vitro, while cellulose did not. The real inducers seemed to be oligomers released from the large size polymers by hydrolytic enzymes secreted into the medium during the cell growth and division. This effect was mimicked by the addition to the medium of a partially purified Parthenocissus chitinase/lysozyme (EC 3. 2. 1. 17), which was also able to hydrolyse chitosan. Oligomers of chitin and of chitosan induced the activity to the same level and with the same time course, while peptidoglycan oligomers induced less activity. Oligomers also induced β-1,3-glucanase (EC 3. 2. 1. 6) activities. The changes with time of both activities and the relative effects of the three kinds of polymers suggested that the induction of both enzymes involves a common element early in the signal pathway.     

Biosynthesis of a novel polysaccharide by Acetobacter xylinum

An Acetobacter xylinum adapted to a medium containing N-acetylglucosamine (GlcNAc) has been used to prepare a novel polysaccharide containing residual GlcNAc in cellulose. The maximum amount of incorporation was found to be 4 mol% in cellulose, when a mixed medium containing 1.4% glucose (Glc) and 0.6% GlcNAc was used for the culture of A. xylinum. The resulting polysaccharide was lysozyme-susceptible. The aminosugar residue incorporated into bacterial cellulose was found to be only GlcNAc, even if galactosamine (GalN) and glucosamine (GlcN) were applied, whereas there was little effect by mannosamine (ManN). As the major component of the resulting polysaccharide was Glc residues, even if the only carbon source in the culture medium was GlcNAc, it was suggested that there must be several enzyme systems to convert GlcNAc into Glc in the bacteria. Several ammonium salts were also found to be effective for the incorporation of GlcNAc residues when the incubation system was converted to rotatory and aerobic incubation from static incubation. The amount of residual GlcNAc was remarkably increased by the addition of lysozyme-susceptible phosphoryl-chitin (P-chitin) and increased slightly with addition of P-chitin that was less lysozyme-susceptible. However, little effect was found on addition of highly substituted P-chitin.     

Brittle culm15 encodes a membrane-associated chitinase-like protein required for cellulose biosynthesis in rice

Plant chitinases, a class of glycosyl hydrolases, participate in various aspects of normal plant growth and development, including cell wall metabolism and disease resistance. The rice (Oryza sativa) genome encodes 37 putative chitinases and chitinase-like proteins. However, none of them has been characterized at the genetic level. In this study, we report the isolation of a brittle culm mutant, bc15, and the map-based cloning of the BC15/OsCTL1 (for chitinase-like1) gene affected in the mutant. The gene encodes the rice chitinase-like protein BC15/OsCTL1. Mutation of BC15/OsCTL1 causes reduced cellulose content and mechanical strength without obvious alterations in plant growth. Bioinformatic analyses indicated that BC15/OsCTL1 is a class II chitinase-like protein that is devoid of both an amino-terminal cysteine-rich domain and the chitinase activity motif H-E-T-T but possesses an amino-terminal transmembrane domain. Biochemical assays demonstrated that BC15/OsCTL1 is a Golgi-localized type II membrane protein that lacks classical chitinase activity. Quantitative real-time polymerase chain reaction and β-glucuronidase activity analyses indicated that BC15/OsCTL1 is ubiquitously expressed. Investigation of the global expression profile of wild-type and bc15 plants, using Illumina RNA sequencing, further suggested a possible mechanism by which BC15/OsCTL1 mediates cellulose biosynthesis and cell wall remodeling. Our findings provide genetic evidence of a role for plant chitinases in cellulose biosynthesis in rice, which appears to differ from their roles as revealed by analysis of Arabidopsis (Arabidopsis thaliana).     

The Cellulases Endoglucanase I and Cellobiohydrolase II of Trichoderma reesei Act Synergistically To Solubilize Native Cotton Cellulose but Not To Decrease Its Molecular Size

Degradation of cotton cellulose by Trichoderma reesei endoglucanase I (EGI) and cellobiohydrolase II (CBHII) was investigated by analyzing the insoluble cellulose fragments remaining after enzymatic hydrolysis. Changes in the molecular-size distribution of cellulose after attack by EGI, alone and in combination with CBHII, were determined by size exclusion chromatography of the tricarbanilate derivatives. Cotton cellulose incubated with EGI exhibited a single major peak, which with time shifted to progressively lower degrees of polymerization (DP; number of glucosyl residues per cellulose chain). In the later stages of degradation (8 days), this peak was eventually centered over a DP of 200 to 300 and was accompanied by a second peak (DP, (apprx=)15); a final weight loss of 34% was observed. Although CBHII solubilized approximately 40% of bacterial microcrystalline cellulose, the cellobiohydrolase did not depolymerize or significantly hydrolyze native cotton cellulose. Furthermore, molecular-size distributions of cellulose incubated with EGI together with CBHII did not differ from those attacked solely by EGI. However, a synergistic effect was observed in the reducing-sugar production by the cellulase mixture. From these results we conclude that EGI of T. reesei degrades cotton cellulose by selectively cleaving through the microfibrils at the amorphous sites, whereas CBHII releases soluble sugars from the EGI-degraded cotton cellulose and from the more crystalline bacterial microcrystalline cellulose.     

Lysozyme-catalyzed reaction in continuous flow system

The lysozyme-catalyzed reaction of chitooligosaccharide was carried out in a continuous flow system in which the solution of substrate, chitooligosaccharide [(GlcNAc)n], flowed into the lysozyme solution in an ultrafiltration apparatus and the products were filtered off. The filtrate was continuously collected in test tubes with the aid of a fraction collector. The product distribution in each fraction was analyzed by high performance gel filtration. Using (GlcNAc)5 as the substrate, the concentrations of products, (GlcNAc)1----4, increased gradually and came to the steady state when the volume of the outflow amounted to sixfold of the inside volume. Before reaching the steady state, the product distribution was quite different from that observed in the closed reaction system, in which the reaction species are not exchangeable through the boundary of the system. The outflows of (GlcNAc)3-5 were delayed in comparison with those of GlcNAc and (GlcNAc)2. The delay period increased with the decrease in substrate concentration, and was shortened by using the [Asp 101 or Trp 62]-modified lysozyme instead of the native lysozyme. These results suggest that the delay in the (GlcNAc)3-5 outflows is caused by the nonproductive binding of the oligosaccharide to the lysozyme molecule. The profile of the flow reaction yields information not only on the catalytic efficiency but also on the substrate binding efficiency of the lysozyme.     

The Presence of Cellulose in Heterocyst Envelopes of Blue-Green Algae and its Role in Relation to Nitrogen Fixation

The present study gives evidence for the presence of cellulose in the heterocyst envelope of blue-green algae by means of electron microscopy, cellulase treatments and specific staining and demonstrates the role of this cellulose for the protection of the heterocyst nitrogenase during acetylene reduction. Experiments with lysozyme and cellulase suggest that nitrogen fixation in heterocystous blue-green algae under aerobic conditions is functionally effective only when an intimate relationship exists between vegetative cells and heterocysts and both cell types have intact wall structures.     

Delineation of an evolutionary salvage pathway by compensatory mutations of a defective lysozyme.

Model-free approaches (random mutagenesis, DNA shuffling) in combination with more "rational," three-dimensional information-guided randomization have been used for directed evolution of lysozyme activity in a defective T4 lysozyme mutant. A specialized lysozyme cloning vector phage, derived from phage lambda, depends upon T4 lysozyme function for its ability to form plaques. The substitution W138P in T4 lysozyme totally abolishes its plaque-forming ability. Compensating mutations in W138P T4 lysozyme after sequential random mutagenesis of the whole gene as well as after targeted randomization of residues in the vicinity of Trp138 were selected. In a second stage, these mutations were randomly recombined by the recombinatorial PCR method of DNA shuffling. Shuffled and selected W138P T4 lysozyme variants provide the hybrid lambda phage with sufficient lysozyme activity to produce normal-size plaques, even at elevated temperature (42 degrees C). The individual mutations with the highest compensatory information for W138P repair are the substitutions A146F and A146M, selected after targeted randomization of three residues in the neighborhood of Trp138 by combinatorial mutagenesis. The best evolved W138P T4 lysozymes, however, accumulated mutations originating from both randomly mutagenized as well as target-randomized variants.     

1H-NMR study on the chitotrisaccharide binding to hen egg white lysozyme.

Interaction between hen egg white lysozyme and chitotrisaccharide was investigated by 1H-NMR spectroscopy using partially acetylated chitotrisaccharides and chemically modified lysozyme. Monoacetyl (GlcN-GlcN-GlcNAc), diacetyl (GlcN-GlcNAc-GlcNAc), or triacetyl chitotrisaccharide [(GlcNAc)3] was added to the lysozyme solution, and the changes in the 1H-NMR signals of the lysozyme were analyzed. Although many of the resonances were affected by addition of the saccharide, the most remarkable effect was seen on the signal of Trp28 C5H which is in a hydrophobic box adjacent to the saccharide-binding site. The signal shifted upfield by 0.2 ppm upon (GlcNAc)3 binding, whereas the chemical shift change of the signal resulting from binding of GlcN-GlcNAc-GlcNAc or GlcN-GlcN-GlcNAc was smaller than that resulting from (GlcNAc)3 binding. When the Asp101-modified lysozyme was used instead of the native lysozyme, the chemical shift change of the Trp28 C5H signal resulting from (GlcNAc)3 binding was also smaller than that for the native lysozyme. The chemical shift change of the signal reflects the conformational change of the hydrophobic box region which should synchronize with the movement of the binding site resulting from the saccharide binding. Therefore, the conformational change resulting from the saccharide binding might be reduced when the sugar residues located at binding subsites A and B of the lysozyme are deacetylated, as well as when Asp101 interacting with the sugar residues at the same subsites is modified.