Binding of N-acetyl-chitotriose to Asp 52-esterified hen lysozyme

The pH dependence of the binding constant of (GlcNAc)3 to Asp 52-esterified lysozyme was determined by the fluorescence technique. The pK values of Asp 101 in the modified lysozyme and its complex with (GlcNAc)3 were determined to be 4.5 and 3.6, respectively, at 25 degrees C and 0.1 ionic strength. This result is different from that obtained by Parsons and Raftery ((1972) Biochemistry 11, 1633--1638), who observed no pK shift of Asp 101. The macroscopic pK value of Asp 52 in intact lysozyme determined by them using the pH difference titration data of Asp 52-esterified lysozyme relative to intact lysozyme ((1972) Biochemistry 11, 1623--1629) was 4.5, which is higher by about one pH unit than the pK value determined by our group (Kuramitsu et al. (1974) J. Biochem. 76, 671--683; (1977) ibid. 82, 585--597; (1978) ibid. 83, 159--170. We found that their pH difference titration data in the absence and presence of saccharides can be consistently interpreted in terms of our pK values of Asp 52, Glu 35, and Asp 101, if we assume that the pK value of another ionizable group (probably Asp 48) is perturbed on esterification of Asp 52.     

Binding of substrate analogs to hen egg-white lysozyme with an ester linkage between Glu 35 and Trp 108.

The interactions of the substrate analogs beta-methyl-GlcNAc, (GlcNAc)2, and (GlcNAc)3 with hen egg-white lysozyme [EC 3.2.1.17] in which an ester linkage had been formed between Glu 35 and Trp 108 (108 ester lysozyme), were studied by the circular dichroic and fluorescence techniques, and were compared with those for intact lysozyme. The binding constants of beta-methyl-GlcNAc and (GlcNAc)2 to 108 ester lysozyme were essentially the same as those for intact lysozyme in the pH range of 1 to 5. Above pH 5, the binding constants of these saccharides to 108 ester lysozyme did not change with pH, while the binding constants to intact lysozyme decreased. This indicates that Glu 35 (pK 6.0 in intact lysozyme) participates in the binding of these saccharides. The extent and direction of the pK shifts of Asp 52 (pK 3.5), Asp 48 (pK 4.4), and Asp 66 (pK 1.3) observed when beta-methyl-GlcNAc is bound to 108 ester lysozyme were the same as those for intact lysozyme. The participation of Asp 101 and Asp 66 in the binding of (GlcNAc)2 to 108 ester lysozyme was also the same as that for intact lysozyme. These findings indicate that the conformations of subsites B and C are not changed by the formation of the ester linkage. On the other hand, the binding constants of (GlcNAc)3 to 108 ester lysozyme were higher than those for intact lysozyme at all pH values studied. This result is interpreted in terms of an increase in the affinity for a GlcNAc residue of subsite D, which is situated near the esterified Glu 35.     

Binding of substrate analogues to subsites D, E, and F of hen egg-white lysozyme.

The pH dependence of the binding of dye, Beibrich Scarlet, to hen egg-white lysozyme[EC 3.2.1.17] was studied at ionic strength 0.3 and 25 degrees by following circular dichroic (CD)bands originating from the bound dye. This binding involved one of the catalytic groups, Glu 35. The effect of the binding of N-acetylglucosamine (GlcNAc), its dimer or trimer on the binding of this dye was also studied at pH 7.5 by measuring changes in the CD bands of the dye bound to lysozyme. It was shown that there are two sites for simultaneous binding of these saccharides in the lysozyme molecule. The stronger binding of the saccharide was noncompetitive and the weaker binding was competitive with dye binding. The binding constants for the stronger binding site (the upper portion of lysozyme cleft) were in good agreement with those previously determined by following changes in the tryptophyl CD bands of lysozyme. The binding constants to the weaker site were about 1.1 x 10(-4), 5 x 10(2), and 5M(-1) for the trimer, dimer, and monomer of GlcNAc, respectively. Assuming that the trimer, dimer, and monomer occupy subsites D, E, and F; E and F; and E, respectively, the unitary free energies of saccharide binding were estimated to be about --1.9, --3.3, and --2.7 kcal/mole for D, E, and F, respectively.     

Effects on tryptophyl absorption of the ionization of the catalytic carboxyls in hen and turkey lysozymes.

The difference spectra of hen and turkey egg-white lysozymes [EC 3.2.1.17] produced by acidification were measured. The difference spectra of both lysozymes had peaks at 295 and 301 nm which are characteristic of tryptophyl residues. The pH dependence curves of the extinction differences (delta eplision) at 301 nm and 295 nm for hen lysozyme were identical with the corresponding curves for turkey lysozyme. The pH dependence of delta eplision at 301 nm was analyzed assuming that the extinction at 301 nm is due to Trp 108 only, which interacts with the catalytic carboxyls, Glu 35 and Asp 52. The macroscopic pK values of Glu 35 and Asp 52 in both lysozymes thus determined were 6.0 and 3.3, respectively. These values were in excellent agreement with those determined by measuring the pH dependence of the circular dichroic band at 305 nm (Kuramitsu et al. (1974) J. Biochem, 76, 671-683; (1975) ibid. 77, 291-301). The pH dependence of delta eplision at 295 nm could not be completely explained in terms of the electrostatic effects of the catalytic groups on Trp 108.     

Importance of van der Waals contact between Glu 35 and Trp 109 to the catalytic action of human lysozyme.

The importance of van der Waals contact between Glu 35 and Trp 109 to the active-site structure and the catalytic properties of human lysozyme (HL) has been investigated by site-directed mutagenesis. The X-ray analysis of mutant HLs revealed that both the replacement of Glu 35 by Asp or Ala, and the replacement of Trp 109 by Phe or Ala resulted in a significant but localized change in the active-site cleft geometry. A prominent movement of the backbone structure was detected in the region of residues 110 to 120 and in the region of residues 100 to 115 for the mutations concerning Glu 35 and Trp 109, respectively. Accompanied by the displacement of the main-chain atoms with a maximal deviation of C alpha atom position ranging from 0.7 A to 1.0 A, the mutant HLs showed a remarkable change in the catalytic properties against Micrococcus luteus cell substrate as compared with native HL. Although the replacement of Glu 35 by Ala completely abolished the lytic activity, HL-Asp 35 mutant retained a weak but a certain lytic activity, showing the possible involvement of the side-chain carboxylate group of Asp 35 in the catalytic action. The kinetic consequence derived from the replacement of Trp 109 by Phe or Ala together with the result of the structural change suggested that the structural detail of the cleft lobe composed of the residues 100 to 115 centered at Ala 108 was responsible for the turnover in the reaction of HL against the bacterial cell wall substrate. The results revealed that the van der Waals contact between Glu 35 and Trp 109 was an essential determinant in the catalytic action of HL.     

Ser475, Glu272, Asp276, Asp327, and Asp360 are involved in catalytic activity of human tripeptidyl-peptidase I

Tripeptidyl-peptidase I (TPP I) is a lysosomal aminopeptidase that sequentially removes tripeptides from small polypeptides and also shows a minor endoprotease activity. Mutations in TPP I are associated with a fatal lysosomal storage disorder--the classic late-infantile form of neuronal ceroid lipofuscinoses. In the present study, we analyzed the catalytic mechanism of the human enzyme by using a site-directed mutagenesis. We demonstrate that apart from previously identified Ser475 and Asp360, also Glu272, Asp276, and Asp327 are important for catalytic activity of the enzyme. Involvement of serine, glutamic acid, and aspartic acid in the catalytic reaction validates the idea, formulated on the basis of significant amino acid sequence homology and inhibition studies, that TPP I is the first mammalian representative of a growing family of serine-carboxyl peptidases.     

Left-sided substrate binding of lysozyme: evidence for the involvement of asparagine-46 in the initial binding of substrate to chicken lysozyme.

The "right-sided" and "left-sided" substrate binding modes at the lower saccharide binding subsites (D-F sites) of chicken lysozyme were investigated by utilizing mutant lysozymes secreted from yeast. We constructed the following mutant lysozymes; "left-sided" substitution of Asn46 to Asp, deletion of Thr47, and insertion of Gly between Thr47 and Asp48 and "right-sided" substitution of Asn37 to Gly. Analyses of their activities and substrate binding abilities showed that Asn46 and Thr47 are involved in the initial enzyme-substrate complex and Asn37 is involved in the transition state. These results support an earlier proposal that interactions between substrate and residues at the left side of lysozyme stabilize a catalytically inactive enzyme-substrate complex, while interactions between substrate and residues at the right side stabilize the catalytically active complex [Pincus, M. R., & Scheraga, H. A. (1979) Macromolecules 12, 633-644]. These results are also consistent with the proposed kinetic mechanism for lysozyme reaction that the rearrangement of an initial enzyme-substrate complex (beta-complex) to another complex (gamma-complex) is required for catalytic hydrolysis [Banerjee S. K., Holler, E., Hess, G. P., & Rupley, J. A. (1975) J. Biol. Chem. 250, 4355-4367].     

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.     

Binding of divalent copper ions to aspartic acid residue 52 in hen egg-white lysozyme

Divalent copper was found to inhibit non-competitively the lysis of Micrococcus lysodeikticus cells by hen egg-white lysozyme, with an inhibition constant K_a= 3.8 × 10²m^?1. The association constants of Cu²⁺ for lysozyme and for a derivative of lysozyme in which tryptophan residue 108 was selectively modified, were measured spectrofluorimetrieally and found to be 1.8 × 10²m^?1 and 1.0 × 10³m^?1, respectively. The electron spin resonance spectrum of Cu²⁺ was not affected by the addition of lysozyme, whereas many new lines appeared on addition of the modified protein. This was interpreted as evidence for the binding of Cu²⁺ in the neighbourhood of tryptophan 108. To unequivocally establish the site of ligation of Cu²⁺, crystals of lysozyme soaked in Cu²⁺ were examined by X-ray crystallography and the results compared to those obtained from crystals of native lysozyme. Cu²⁺ was found to be located 2 to 3 Å from the carboxyl side-chain of aspartic acid 52, 5 Å from the carboxyl of glutamic acid 35 and about 7 Å from tryptophan 108.The addition of a saccharide inhibitor to lysozyme was found to increase the association constant of Cu²⁺ for lysozyme from a value of 1.8 × 10²m^?1 to 6.0 × 10²m^?1. This finding was interpreted as indicative of a change in conformation around tryptophan 108 and glutamic acid 35 induced by the interaction of saccharides with the enzyme, which affects the metal binding properties of aspartic acid 52.     

Thermodynamics and stoicheiometry of the binding of substrate analogues to uricase.

The subunit composition, metal content, substrate-analogue binding and thermal stability of Aspergillus flavus uricase were determined. A. flavus uricase is a tetramer and contains no copper, iron or any other common prosthetic group. Analytical-gel-filtration and equilibrium-dialysis experiments showed one binding site per subunit for urate analogues. The free energy of xanthine binding was -30.5 kJ (-7.3 kcal)/mol of subunit by equilibrium dialysis and -30.1 kJ (-7.2 kcal)/mol of subunit by microcalorimetry. The enthalpy change for xanthine binding was -15.9 kJ (-3.8 kcal)/mol of subunit when determined from the temperature-dependence of the equilibrium constant and -18.0 kJ (-4.3 kcal)/mol of subunit when measured microcalorimetrically. The thermal inactivation rate of A. flavus uricase increases as protein concentration is decreased. This concentration-dependent instability is not due to subunit dissociation.     

Analysis of a catalytic pathway via a covalent adduct of D52E hen egg white mutant lysozyme by further mutation.

We previously demonstrated by X-ray crystallography and electrospray mass spectrometry that D52E mutant hen lysozyme formed a covalent enzyme-substrate adduct on reaction with N-acetylglucosamine oligomer. This observation indicates that D52E lysozyme may acquire a catalytic pathway via a covalent adduct. To explain this pathway, the formation and hydrolysis reactions of the covalent adduct were investigated. Kinetic analysis indicated that the hydrolysis step was the rate-limiting step, 60-fold slower than the formation reaction. In the formation reaction, the pH dependence was bell-shaped, which was plausibly explained by the functions of the two catalytic pKas of Glu35 and Glu52. On the other hand, the pH dependence in the hydrolysis was sigmoidal with a transition at pH 4. 5, which was identical with the experimentally determined pKa of Glu35 in the covalent adduct, indicating that Glu35 functions as a general base to hydrolyze the adduct. To improve the turnover rate of D52E lysozyme, the mutation of N46D was designed and introduced to D52E lysozyme. This mutation reduced the activation energy in the hydrolysis reaction of the covalent adduct by 1.8 kcal/mol at pH 5.0 and 40 degrees C but did not affect the formation reaction. Our data may provide a useful approach to understanding the precise mechanism of the function of natural glycosidases, which catalyze via a covalent adduct.     

Difference in substrate binding processes between intact and iodine-inactivated lysozyme.

The binding of glycol chitin to intact and iodine-inactivated lysozyme was studied by measuring the absorbance of the complex with N-methylnicotinamide chloride, which binds to the subsite C in lysozyme as a competitive inhibitor. The association constant of glycol chitin to inactivated lysozyme was determined from static experiments to be 1.7 × 10⁴M^?1. The kinetics of the substrate binding to intact and iodine-inactivated lysozyme were measured by the stopped-flow method at 23°C and pH 5.6. The binding to inactivated lysozyme was clearly monophasic, whereas in intact lysozyme it consisted of multiple phases. In the substrate binding to intact lysozyme, a fast bimolecular process and two subsequent slow unimolecular processes were observed besides the hydrolysis process of polymer substrate. These slow phases were missing completely in inactivated lysozyme. It results from the alteration in the local structure occurring at the subsite D in inactivated lysozyme. These results mean that the slow phases are important for catalytic action of lysozyme. The rate constants of association and dissociation in the fast bimolecular process were determined in this paper. Furthermore, the association constant of the substrate to intact lysozyme was also determined kinetically to be 6.5 × 10³M^?1.     

Triple point mutation Asp10-->His, Asn101-->Asp, Arg148-->Ser in T4 phage lysozyme leads to the molten globule.

The triple amino acid replacement (Asp10-->His, Asn101-->Asp, Arg148-->Ser) in T4 phage lysozyme was carried out by site-directed mutagenesis. At acid pH (2.7) the mutant is in a conformational state with the properties of the molten globule: (i) the mutant protein molecule is essentially compact; (ii) its CD spectrum in the near UV region is drastically reduced in intensity as compared with the wild type protein spectrum; (iii) the CD spectrum in the far UV region indicates the presence of pronounced secondary structure in the mutant; (iv) unlike the wild type protein the mutant protein can bind the hydrophobic fluorescent probe, ANS.     

Functional consequences of alterations to Glu309, Glu771, and Asp800 in the Ca(2+)-ATPase of sarcoplasmic reticulum.

Site-specific mutagenesis was used to replace Glu309, Glu771, and Asp800 in the Ca(2+)-ATPase of rabbit fast twitch muscle sarcoplasmic reticulum with their corresponding amides. These residues are predicted to lie in the transmembrane domain and have been suggested as oxygen ligands for Ca2+ binding at high affinity sites (Clarke, D. M., Loo, T. W., Inesi, G., and MacLennan, D. H. (1989) Nature 339, 476-478). The Glu309----Gln and Asp800----Asn mutants were unable to form a phosphoenzyme from ATP at the Ca2+ concentrations examined (up to 12.5 mM), whereas the Glu771----Gln mutant phosphorylated from ATP at 2.5 mM Ca2+. In all three mutants, Ca2+ at concentrations well below 12.5 mM prevented or inhibited phosphorylation with Pi, suggesting that at least one calcium-binding site was functioning in each mutant. In the mutants Glu309----Gln and Glu771----Gln, the ADP-insensitive phosphoenzyme intermediate was unusually stable, as indicated by a very low rate of dephosphorylation observed in kinetic experiments and by an increased apparent affinity for Pi determined in equilibrium phosphorylation experiments. These data indicate a central role of Glu309 and Glu771 in the energy-transducing conformational changes and/or in the activation of phosphoenzyme hydrolysis.