Purification, amino acid sequence, and some properties of rabbit kidney lysozyme

The lysozyme (rabbit kidney lysozyme) from the homogenate of rabbit kidney (Japanese white) was purified by repeated cation-exchange chromatography on Bio-Rex 70. The amino acid sequence was determined by automated gas-phase Edman degradation of the peptides obtained from the digestion of reduced and S-carboxymethylated rabbit lysozyme with Achromobacter protease I (lysyl endopeptidase). The sequence thus determined was KIYERCELARTLKKLGLDGYKGVSLANWMCLAKWESSYNTRATNYNPGDKSTDYGIFQ INSRYWCNDGKTPRAVNACHIPCSDLLKDDITQAVACAKRVVSDPQGIRAWVAWRNHCQ NQDLTPYIRGCGV, indicating 25 amino acid substitutions from human lysozyme. The lytic activity of rabbit lysozyme against Micrococcus lysodeikticus at pH 7, ionic strength of 0.1, and 30 degrees C was found to be 190 and 60% of those of hen and human lysozymes, respectively. The lytic activity-pH profile of rabbit lysozyme was slightly different from those of hen and human lysozymes. While hen and human lysozymes had wide optimum activities at around pH 5.5-8.5, the optimum activity of rabbit lysozyme was at around pH 5.5-7.0. The high proline content (five residues per molecule compared with two prolines per molecule in hen or human lysozyme) is one of the interesting features of rabbit lysozyme. The transition temperatures for the unfolding of rabbit, human, and hen lysozymes in 3 M guanidine hydrochloride at pH 5.5 were 51.2, 45.5, and 45.4 degrees C, respectively, indicating that rabbit lysozyme is stabler than the other two lysozymes. The high proline content may be responsible for the increased stability of rabbit lysozyme.     

Changes in Lysozyme due to Interaction with Vaporized Hexanal

In order to elucidate the mechanism of the alteration of proteins induced by vaporized aldehydes, unmodified and chemically-modified lysozymes were exposed in the solid state to vaporized hexanal at 50°C and 5.8 or 75% relative humidity (RH). On exposure at 75%RH, the unmodified lysozyme exhibited polymerization, browning, loss of solubility, fluorescence production and impairment of lysine, tryptophan and methionine residues. Methionine residues seemed to be oxidized to methionine sulfoxide residues. The polymerization did not proceed at 5.8RH. All the above alterations were almost completely prevented by the removal of oxygen from the reaction cells. Acetylation of lysozyme retarded these alterations fairly well except that the impairment of tryptophan residues was unaffected.

On the basis of all the results it is suggested that at the first step the concerned reaction essentially requires hexanal derivatives such as peroxyhexanoic acid and/or related radicals induced through the reaction with oxygen. The second step seems to consist at least of two routes which are independent of each other and require water. One route is assumed to be an amino-carbonyl reaction involving lysine residues. The other route seems responsible for the attack on tryptophan and methionine residues through oxidation involving the radicals.     

Purification and characterization of goose type lysozyme from cassowary (Casuarius casuarius) egg white

A novel goose-type lysozyme was purified from egg white of cassowary bird (Casuarius casuarius). The purification step was composed of two fractionation steps: pH treatment steps followed by a cation exchange column chromatography. The molecular mass of the purified enzyme was estimated to be 20.8 kDa by SDS-PAGE. This enzyme was composed of 186 amino acid residues and showed similar amino acid composition to reported goose-type lysozymes. The N-terminal amino acid sequencing from transblotted protein found that this protein had no N-terminal. This enzyme showed either lytic or chitinase activities and had some different properties from those reported for goose lysozyme. The optimum pH and temperature on lytic activity of this lysozyme were pH 5 and 30 degrees C at ionic strength of 0.1, respectively. This lysozyme was stable up to 30 degrees C for lytic activity and the activity was completely abolished at 80 degrees C. The chitinase activity against glycol chitin showed dual optimum pH around 4.5 and 11. The optimum temperature for chitinase activity was at 50 degrees C and the enzyme was stable up to 40 degrees C.     

Modification of arginine and lysine in proteins with 2,4-pentanedione.

Primary amines react with 2,4-pentanedione at pH 6-9 to form enamines, N-alkyl-4-amino-3-penten-2-ones. The latter compounds readily regenerate the primary amine at low pH or on treatment with hydroxylamine. Guanidine and substituted guanidines react with 2,4-pentanedione to form N-substituted 2-amino-4,6-dimethylpyrimidines at a rate which is lower by at least a factor of 20 than the rate of reaction of 2,4-pentanedione with primary amines. Selective modification of lysine and arginine side chains in proteins can readily be achieved with 2,4-pentanedione. Modification of lysine is favored by reaction at pH 7 or for short reaction times at pH 9. Selective modification of arginine is achieved by reaction with 2,4-pentanedione for long times at pH 9, followed by treatment of the protein with hydroxylamine. The extent of modification of lysine and arginine side chains can readily be measured spectrophotometrically. Modification of lysozyme with 2,4-pentanedione at pH 7 results in modification of 3.8 lysine residues and less than 0.4 arginine residue in 24 hr. Modification of lysozyme with 2,4-pentanedione at pH 9 results in modification of 4 lysine residues and 4.5 arginine residues in 100 hr. Treatment of this modified protein with hydroxylamine regenerated the modified lysine residues but caused no change in the modified arginine residues. One arginine residue seems to be essential for the catalytic activity of the enzyme.     

The role of epsilon-amino groups of lysine of human serum albumin in heat-induced protein denaturation. Increased stability of glycosylated and alkylated albumin in aggregation during heating

Human serum albumin was glycosidated by prolonged protein incubation in phosphate buffer, pH 6.8-7.0, with excess glucose at 37 degrees C. epsilon-amino groups of lysine residues of the albumin molecule were alkylated by pyridoxal-5-phosphate in the presence of NaBH4. The solutions of glycosidated and alkylated serum albumin were incubated at different temperature values in the range of 20 to 80 degrees C in phosphate buffer, pH 7.0, over 30 min. The nondenatured monomer and the resulting aggregated were isolated by TSK-HW-55-gel column chromatography and polyacrylamide gel electrophoresis. The stability of modified proteins elevated in parallel to the increase in the number of the ligand molecules covalently bound to albumin amino groups. The 1-3% aqueous solutions of glycosidated serum albumin containing 3-4 glucose residues and those of alkylated albumin containing 6-7 residues of pyridoxal-5-phosphate were stable on heating up to 80 degrees C and did not form aggregates. Under these conditions the initial serum albumin completely aggregated. Preincubation of the aggregated albumin with glucose at 37 degrees C resulted in protein "renaturation" to the monomeric form with a small number of dimers and trimers.     

Multiple role of hydrophobicity of tryptophan-108 in chicken lysozyme: structural stability, saccharide binding ability, and abnormal pKa of glutamic acid-35.

Trp108 of chicken lysozyme is in van der Waals contact with Glu35, one of two catalytic carboxyl groups. The role of Trp108 in lysozyme function and stability was investigated by using mutant lysozymes secreted from yeast. By the replacement of Trp108 with less hydrophobic residues, Tyr (W108Y lysozyme) and Gln (W108Q lysozyme), the activity, saccharide binding ability, stability, and pKa of Glu35 were all decreased with a decrease in the hydrophobicity of residue 108. Namely, at pH 5.5 and 40 degrees C, the activities of W108Y and W108Q lysozymes against glycol chitin were 17.3 and 1.6% of that of wild-type lysozyme, and their dissociation constants for the binding of a trimer of N-acetyl-D-glucosamine were 7.4 and 309 times larger than that of wild-type lysozyme, respectively. For the reversible unfolding at pH 3.5 and 30 degrees C, W108Y and W108Q lysozymes were less stable than wild-type lysozyme by 1.4 and 3.6 kcal/mol, respectively. As for the pKa of Glu35, the values for W108Y and W108Q lysozymes were found to be lower than that for wild-type lysozyme by 0.2 and by 0.6 pKa unit, respectively. The pKa of Glu35 in lysozyme was also decreased from 6.1 to 5.4 by the presence of 1-3 M guanidine hydrochloride, or to 5.5 by the substitution of Asn for Asp52, another catalytic carboxyl group. Thus, both the hydrophobicity of Trp108 and the electrostatic interaction with Asp52 are equally responsible for the abnormally high pKa (6.1) of Glu35, compared with that (4.4) of a normal glutamic acid residue.(ABSTRACT TRUNCATED AT 250 WORDS)     

Polymerization of Lysozyme and Impairment of Its Amino Acid Residues Caused by Reaction with Glucose

In order to reveal the mechanism of the Maillard reaction between proteins and reducing sugars, unmodified and chemically modified lysozymes were incubated with and without glucose at 50°C and 75% relative humidity in the solid state. Incubation of unmodified lysozyme with glucose resulted in browning and polymerization of the protein, and noticeable losses of arginine, lysine, and tryptophan residues. Those changes were little affected by the presence of an oxygen adsorber. Acetylation of lysozyme almost completely prevented those changes, indicating that the reaction of free amino groups of the protein with glucose is essential at the initial stage of these changes.

Incubation of lysozyme the arginine residues of which were masked with 1,2-cyclohexane-dione (CHD) resulted in almost the same changes as above even in the absence of glucose. Those changes could be explained as caused by the action of CHD released from the arginine residues. This similarity in the effects on protein of CHD and glucose implies that dicarbonyl compounds are key components at the secondary stage of the Maillard reaction between proteins and reducing sugars.     

Effect of chemical modifications of tryptophan residues on the folding of reduced hen egg-white lysozyme

The effects of chemical modifications of Trp62 and Trp108 on the folding of hen egg-white lysozyme from the reduced form were investigated by means of the sulfhydryl-disulfide interchange reaction at pH 8 and 40 degrees C. The folding of reduced lysozyme was monitored by following the recovery of the original activity. Under the conditions employed, the apparent first-order rate constant for the folding of reduced lysozyme was not changed by the modifications of both Trp62 and Trp108 and the folding was completed within 30 min. However, the extent of the correct folding was changed by the modification of Trp62 but not by that of Trp108. Native and oxindolealanine108 lysozymes recovered 80 and 81% of their original activities after 30-min refolding, respectively, but Trp62-modified lysozymes recovered their activities to a lesser extent than native and oxindolealanine108 lysozymes. The recovered activities of Trp62-modified lysozymes after 30-min refolding were 63% for oxindolealanine62 lysozyme, 65% for delta 1-carboxamidomethylthiotryptophan62 lysozyme, and 52% for delta 1-carboxymethylthiotryptophan62 lysozyme. These results suggest that Trp62 is important for preventing the misfolding of reduced lysozyme, but that neither Trp62 nor Trp108 is involved in the rate-determining step (the slowest step) in the folding pathway. A decrease in the hydrophobic nature of Trp62 seems to increase the misfolding and thus to decrease the extent of the correct folding of reduced lysozyme. A mechanism for the involvement of Trp62 in the folding pathway of reduced lysozyme is proposed.     

Difference absorption spectra, circular dichroism, and disulfide cleavage of hen and turkey lysozymes in the alkaline pH region.

The difference absorption spectra of hen and turkey lysozymes in the alkaline pH region had three maxima at around 245, 292, and 300 nm and had no isosbestic points. The ratio of the extinction difference at 245 nm to that at 295 nm changed with pH. These spectral features are quite different from those observed when only tyrosyl residues are ionized, and it was impossible to determine precisely the pK values of the tyrosyl residues in lysozyme by spectrophotometric titration. A time-dependent spectral change was observed above about pH 12. This is not due to exposure of a buried tyrosyl residue on alkali denaturation. The disulfide bonds and the peptide bonds in the lysozyme molecule were cleaved by alkali above about pH 11. The intrinsic pK value of Tyr 23 of hen lysozyme was determined to be 10.24 (apparent pK 9.8) at 0.1 ionic strength and 25 degrees C from the CD titration data. Comparison of the CD titration of turkey lysozyme with that of hen lysozyme suggested that Tyr 3 and Tyr 23 in turkey lysozyme have apparent pK values of 11.9 and 9.8, respectively.     

The pH dependence of binding of alpha,alpha'-dibromo-p-xylenesulfonic acid to lysozyme.

The chemical modification of lysozyme (I) has been accomplished with alpha, alpha'-dibromo-p-xylenesulfonic acid (DBX) at five different pH values. I was alkylated by DBX at room temperature (28 degrees C) with decrease in enzyme activity. The rate of inactivation depended upon the pH at which alkylation was carried out. The highest rate was seen at alkaline pH values; the lowest at more acidic pH values. Amino acid analyses showed that-two lysines and two tryptophan residues had been modified at pH 9; two lysines, one tryptophan and one methionine had reacted at pH 8. A histidine residue was bound at pH 6.5 together with a tryptophan residue. At the lower pH values (2.7, 4.5, 6.5), alkylation occurred with a single tryptophan residue each. Fluorescence and CD data both ruled out the participation of tryptophans 62 or 108. Labeling experiments showed that two residues of DBX-35S were bound per molecule of I at both pH9 and pH8; one residue of DBX was bound per molecule of I at the other pH values. Sedimentation coefficients were characteristic of native lysozyme. The stoichiometry of binding and residue modification indicated that intra-molecular cross links were established. The pH dependence of the cross-linking provides means to measure several allowed intra-molecular distances. The results presented here are consistent with the existence of side chain motion in lysozyme.     

Correlation of structural differences in several bird lysozymes and their loop regions with immunological cross-reactivity

Goat antibodies that were specific, respectively, to hen egg white lysozyme, its loop region (residues 60 to 83) and to regions other than the loop, were reacted with the intact lysozyme or its loop region. The interference with this reaction by several bird lysozymes was tested. Bobwhite quail lysozyme was as efficient as hen lysozyme in the lysozyme-anti-lysozyme system, but much less reactive with anti-loop antibodies. Turkey lysozyme, on the other hand, was similar to hen lysozyme in its behaviour with anti-loop antibodies but different in its reactivity with anti-lysozyme. It is thus concluded that the loop region of hen lysozyme is far more reactive than that of bobwhite quail lysozyme with loop-specific goat antibodies. The large antigenic difference results from replacement of an arginine residue (at position 68) in the hen loop by a lysine residue in the quail loop. By contrast, the loop region of turkey lysozyme is antigenically similar to that of hen lysozyme. Yet the turkey loop also differs from the hen loop by a single lysine-for-arginine replacement (at position 73). To explain why the lysine substitution has a greater antigenic effect at position 68 than at position 73, two hypotheses are considered. First, as arginine 68 is the i + 2 residue of a β-bend (encompassing residues 66 to 69) and as the frequency of occurrence of lysine at the i + 2 position in β-bends is lower than that of arginine, the presence of lysine at position 68 may lower the stability of the β-bend and thereby cause a conformational change in the β-bend region of the loop. Alternatively, arginine 68 may be more exposed than is arginine 73 in hen lysozyme, and hence goat antibodies may more easily recognize the side-chain difference produced by the lysine substitution at position 68.     

Purification, characterization and comparison of reptile lysozymes

Cation exchange column chromatography and gel filtration chromatography were used to purify four reptile lysozymes from egg white: SSTL A and SSTL B from soft shelled turtle (Trionyx sinensis), ASTL from Asiatic soft shelled turtle (Amyda cartilagenea) and GSTL from green sea turtle (Chelonia mydas). The molecular masses of the purified reptile lysozymes were estimated to be 14 kDa by SDS-PAGE. Enzyme activity of the four lysozymes could be confirmed by gel zymograms and showed charge differences on native-PAGE. SSTL A, SSTL B and ASTL had sharp pH optima of about pH 6.0, which contrasts with that of GSTL, which showed dual pH optima at about pH 6.0 and pH 8.0. The activities of the reptile lysozymes rapidly decreased within 30 min of incubation at 90 degrees C except for ASTL, which was more stable. Partial N-terminal amino acid sequencing and peptide mapping strongly suggested that the enzymes were C-type lysozymes. Interestingly, the mature SSTL lysozymes show an extra Gly residue at the N-terminus, which was previously found in soft-shelled turtle lysozyme. The reptile lysozymes showed lytic activity against several species of bacteria, such as Micrococcus luteus and Vibrio cholerae, but showed only weak activity to Pseudomonas aeruginosa and lacked activity towards Aeromonas hydrophila.     

Interactions of alpha- and beta-N-acetyl-D-glucosamines with hen and turkey lysozymes.

The binding constants of alpha- and beta-GlcNAc to hen and turkey lysozymes [EC 3.2.1.17] were determined at various pH's using the method proposed by Ikeda and Hamaguchi (1975) J. Biochem. 77, 1-16). The pH dependence of the binding of beta-GlcNAc to hen lysozyme was essentially the same as that for turkey lysozyme. The pH dependence curves of the binding constants of beta-GlcNAc to hen and turkey lysozymes were interpreted in terms of the participation of Glu 35 (pK 6.0), Asp 52 (pK 3.5), Asp 48 (pK 4.5), and Asp 66 (pK 1.5). The binding constants of alpha-GlcNAc to hen and turkey lysozymes were the same below pH 3.5 but were different above this pH. The main participant residues in the binding of alpha-GlcNAc were Glu 35, Asp 48, and Asp 66 for hen lysozyme and Glu 35 and Asp 66 for turkey lysozyme. The results obtained here were well explained by the following assumptions: (1) above about pH 4, alpha-GlcNAc binds to hen lysozyme in both alpha- and beta-modes, which correspond to the binding orientation of alpha-GlcNAc and that of beta-GlcNAc, respectively, as determined by X-ray crystallographic studies, but it binds predominantly in the beta-mode below about pH 4, (2) beta-GlcNAc binds to hen and turkey lysozymes predominantly in the beta-mode above about pH 4 and in both alpha- and beta-modes below pH 4, and (3) alpha-GlcNAc binds to turkey lysozyme predominantly in the beta-mode over the whole pH range studied.     

Effects of chemical modification of lysine residues on the sweetness of lysozyme

Lysozyme is a sweet-tasting protein with a sweetness threshold value of around 7 microM. To clarify the effect of basicity at the side chain of lysine residues on the threshold values of sweetness, charge-specific chemical modifications such as guanidination, acetylation and phosphopyridoxylation of lysine residues were performed. Sensory analysis showed that the sweetness threshold value of lysozyme was not changed by guanidination, whereas it was increased markedly by acetylation and phosphopyridoxylation. To confirm the importance of the basicity in the lysine residues in detail, purification of acetylated (Ac-) and phosphopyridoxylated (PLP-) lysozymes using SP-ion exchange column chromatography was performed. The threshold values were not changed by modification with fewer than two residues (approximately 7 microM), whereas the threshold values significantly increased to 15 and 34 microM when tetra-Ac and tri-PLP, respectively. Furthermore, sweetness was not detected at 30 microM (hexa-, penta-Ac and tetra-PLP). It should be noted that removal of the negative charges of the phosphate groups in the tri-PLP lysozyme by acid phosphatase resulted in the recovery of sweetness (6.4 microM), indicating that basicity at the position of the lysine residues is responsible for lysozyme sweetness and that strict charge complementarities might be required for interaction to its putative receptor.     

Substituent effects in alkylated liver alcohol dehydrogenases

Alcohol dehydrogenase from horse liver was reductively alkylated with aldehydes having varied alkyl substituents. Kinetic studies of alkylated liver alcohol dehydrogenases which were modified in the absence and in the presence of NADH indicate that the alkylation of the specific lysine residues generally activates the enzyme by increasing Michaelis and inhibition constants for substrates and maximum velocities for the reactions. These kinetic parameters were analyzed in terms of electronic, steric, and hydrophobic effects of alkyl substituents. The hydrophilic character of the lysine residues is the most important factor which affects all kinetic parameters, particularly K_ia and V₂. In addition, the nucleophilic character of the lysine residues enhances the enzyme activity by increasing the maximum velocity of ethanol oxidation and the affinity of alcohol dehydrogenase for NADH and acetaldehyde. The steric interaction at the lysine residues favors the affinity of the enzyme for NADH and ethanol.     

Remarkable thermal stability of doubly intramolecularly cross-linked hen lysozyme

In order to examine how a protein can be effectively stabilized, two intramolecular cross-links, Glu35-Trp108 and Lys1-His15, which have few unfavorable interactions in the folded state, were simultaneously introduced into hen lysozyme. Both of the intramolecularly cross-linked lysozymes, 35-108 CL and 1-15 CL, containing cross-links Glu35-Trp108 and Lys1-His15, respectively, showed increases in thermal stability of 13.9 and 5.2 degrees C, respectively, over that of wild type, at pH 2.7. On the other hand, a doubly cross-linked lysozyme showed an increase in thermal stability of 20.8 degrees C over that of wild type, under identical conditions. Since the sum of the differences in denaturation temperature between wild type and each of the cross-linked lysozymes was nearly equal to that between wild type and the doubly cross-linked lysozyme, we suggest that the efficient stabilization of the lysozyme molecule was the direct result of the double intramolecular cross-links.     

Structure of the pigeon lysozyme and its relationship with other type c lysozymes

1. The secondary structure of the pigeon egg-white lysozyme shows important differences when compared to other type c lysozymes. These differences are mainly located at the region comprising residues 77-84. This segment contains one alpha-helix in the lysozymes c studied by means of an X-ray analysis, while the residues at such positions in pigeon lysozyme would form two beta-bends. 2. Analysis of the tertiary structure of the pigeon lysozyme by means of hydropathy profiles reveals that the above segment seems to be more hydrophilic in the pigeon enzyme than in other type c lysozymes. 3. Though a certain similarity to the calcium-binding loop of alpha-lactalbumins is detected in pigeon lysozyme, the circular dichroism spectra of the protein at neutral pH do not change in the presence of Ca2+ ions. 4. The presented structural analysis is discussed in terms of function-structure and antigenicity relationships between the type c lysozymes.     

Purification of several bacteriolytic enzymes by affinity chromatography on lysozyme-lysate of Micrococcus lysodeikticus cell wall coupled with sepharose.

Using lysozyme-lysate of Micrococcus lysodeikticus cell wall coupled with Sepharose, several bacteriolytic enzymes were purified from crude preparations of animal and microbial origin. Quail egg-white, human milk and salivary lysozymes [EC 3.2.1.17] were adsorbed onto the adsorbent at pH 5-7 and eluted with 2M NaCl at pH 10. By means of these treatments, lysozymes were purified 20-250 fold with activity recoveries of 60-80%, and the quail lysozyme thus purified was shown to be discelectrophoretically homogeneous. Some bacteriolytic enzymes of microbial origin were also highly purified by using this affinity adsorbent. A bacterial lysozyme from Bacillus sp. ML-208 showed high affinity for the ligand and was not eluted under the conditions mentioned above, but was recovered by elution with 2M guanidine-HCl at pH 5.8, resulting in a 500-fold increase in the specific activity. A Pseudomonas-lytic enzyme from Streptomyces sp. P-51 was easily released from the adsorbent by elution with 0.5M NaCl at pH 5.0. A staphylolytic F2 enzyme from S. griseus S-35 and a chitinase [EC 3.2.1.14] from yam, both of which were completely inert toward M. lysodeikticus cell wall, passed through the adsorbent column. A modified ligand, in which muramic acid and glucosamine residues were N,O-acetylated, failed to adsorb any of these animal and bacterial lysozymes. Some of the enzymatic properties and bacteriolytic action spectra of these purified enzymes are also described in this paper in comparison with those of hen egg-white lysozyme.     

Reversible modification of arginine residues. Application to sequence studies by restriction of tryptic hydrolysis to lysine residues.

1, 2-Cyclohexanedione reacts specifically with the guanidino group of arginine or arginine residues at pH 8 to 9 in sodium borate buffer in the temperature range of 25-40 degrees. The single product, N-7, N-8-(1,2-dihydroxycyclohex-1,2-ylene)-L-arginine (DHCH-arginine) is stable in acidic solutions and in borate buffers (pH 8 to 9). DHCH-Arginine is converted to N-7-adipyl-L-arginine by periodate oxidation. The structures of the two compounds were elucidated by chemical and physicochemical means. Arginine or arginyl residues can be regenerated quantitatively from DHCH-arginine by incubation at 37 degrees in hydroxylamine buffer at pH 7.0 FOR 7 TO 8 hours. Analysis of native egg white lysozyme and native as well as oxidized bovine pancreatic RNase, which were treated with cyclohexanedione, showed that only arginine residues were modified. The utility of the method in sequence studies was shown on oxidized bovine pancreatic ribonuclease A. Arginine modification was complete in 2 hours at 35 degrees in borate buffer at pH 9.0 with a 15-fold molar excess of the reagent. The derived peptides showed that tryptic hydrolysis was entirely limited to peptide bonds involving lysine residues, as shown both by two-dimensional peptide patterns and by isolation of the resulting peptides. The stability of DHCH-arginyl residues permits isolation of labeled peptides.     

Binding of N-acetyl-chitotriose to human lysozyme.

The interaction of N-acetyl-chitotriose ((GlcNAc)3) with human lysozyme [EC 3.2.1.17] was studied at various pH values by measuring changes in the circular dichroic (CD) band at 294 or 255 nm and the data were compared with the results for hen and turkey lysozymes reported previously (Kuramitsu et al. (1974) J. Biochem.76, 671-683; Kuramitsu et al. (1975) J. Biochem. 77, 291-301). The pH dependence of the binding constant of (GlcNAc)3 to human lysozyme was different from those for hen and turkey lysozymes. The catalytic carboxyls of human lysozyme, Asp 52 and Glu 35, were not perturbed on binding of (GlcNAc)3. This is consistent with the previous findings that the macroscopic pK values of Asp 52 and Glu 35 of human lysozyme are 3.4 and 6.8 at 0.1 ionic strength and 25 degrees and were unchanged on complexing with (GlcNAc)3. An ionizable group with pK 4.5, which participates in the binding of (GlcNAc)3 to hen lysozyme and was assigned as Asp 101, did not participate in the binding of the saccharide to human lysozyme. Between pH 9 and 11, the binding constants of (GlcNAc)3 to hen lysozyme remained unchanged, whereas perturbation of an ionizable group with pK 10.5 to 10.0 was observed for human lysozyme. This group may be Tyr 62 in the active-site cleft. The binding constants of (GlcNAc)3 to human lysozyme molecules having different microscopic protonation forms, with respect to the catalytic carboxyls, were estimated using the binding constants obtained in the present experiments and the microscopic ionization constants of the catalytic carboxyls obtained previously. All four species of human lysozyme had similar binding constants to (GlcNAc)3. This result is different from those for hen and turkey lysozymes.