The simultaneous binding of lanthanide and N-acetylglucosamine inhibitors to hen egg-white lysozyme in solution by 1H and 13C nuclear magnetic resonance.

Lanthanide ions and the N-acetylglucosamine (GlcNAc) sugars are able to bind simultaneously to hen egg-white lysozyme (EC 3.2.1.17). The present study characterizes the properties of the ternary complexes with lysozyme, which involve up to seven paramagnetic lanthanides and two diamagnetic lanthanides, together with alpha GlcNAc, beta GlcNAc, alpha MeGlcNAc and beta MeGlcNAc. pH titrations and binding titrations of the GlcNAc sugars with lysozyme-La(III) complexes show that the GlcNAc sugars bind to at least two independent sites and that one of them competes with La(III) for binding to lysozyme. Given the known binding site of lanthanides at Asp-52 and Glu-35, the competitive binding site of GlcNAc is identified as subsite E. A simple analysis of the paramagnetic-lanthanide-induced shifts shows that the GlcNAc sugar binds in subsite C, in accordance with crystallographic results [Perkins, Johnson, Machin & Phillips (1979) Biochem. J. 181, 21-36]. This finding was refined by several computer analyses of the lanthanide-induced shifts of 17 proton and carbon resonances of beta MeGlcNAc. Good fits were obtained for all the signals, except for two that were affected by exchange broadening phenomena. No distinction could be made between a fit for a two-position model of Ln(III) binding with axial symmetry to lysozyme, according to the crystallographic result, or a one-position model with axial symmetry where the Ln(III) is positioned mid-way between Asp-52 and Glu-35. Although this work establishes the feasibility of lanthanide shift reagents for study of protein-ligand complexes, further work is required to establish the manner in which lanthanides bind to lysozyme in solution.     

Interactions on 3-deoxy and 6-deoxy derivatives of N-acetyl-D-glucosamine with hen lysozyme.

The interactions of deoxy derivatives of GlcNAc, 6-deoxy-GlcNAc, and 3-deoxy-GlcNAc with hen egg-white lysozyme [EC 3.2.1.17] were studied at various pH's by measuring the changes in the circular dichroic (CD) band at 295 nm. It was shown that 6-deoxy-GlcNAc and 3-deoxy-GlcNAc bind at subsite C of lysozyme and compete with GlcNAc. The pH dependence of the binding constant of 6-deoxy-GlcNAc was the same as that of GlcNAc. On the other hand, the binding constants of 3-deoxy-GlcNAc were 3--10 times smaller than those of GlcNAc in the pH range from 3 to 9. X-ray crystallographic studies show that O(6) and O(3) of GlcNAc at subsite C are hydrogen-bonded to the indole NH's of Trp 62 and Trp 63, respectively, but the above results indicate that Trp 63, not Trp 62, is important for the interaction of GlcNAc with lysozyme.     

Topography of the combining region of a Thomsen-Friedenreich-antigen-specific lectin jacalin (Artocarpus integrifolia agglutinin). A thermodynamic and circular-dichroism spectroscopic study.

Thermodynamic analysis of carbohydrate binding by Artocarpus integrifolia (jackfruit) agglutinin (jacalin) shows that, among monosaccharides, Me alpha GalNAc (methyl-alpha-N-acetylgalactosamine) is the strongest binding ligand. Despite its strong affinity for Me alpha GalNAc and Me alpha Gal, the lectin binds very poorly when Gal and GalNAc are in alpha-linkage with other sugars such as in A- and B-blood-group trisaccharides, Gal alpha 1-3Gal and Gal alpha 1-4Gal. These binding properties are explained by considering the thermodynamic parameters in conjunction with the minimum energy conformations of these sugars. It binds to Gal beta 1-3GalNAc alpha Me with 2800-fold stronger affinity over Gal beta 1-3GalNAc beta Me. It does not bind to asialo-GM1 (monosialoganglioside) oligosaccharide. Moreover, it binds to Gal beta 1-3GalNAc alpha Ser, the authentic T (Thomsen-Friedenreich)-antigen, with about 2.5-fold greater affinity as compared with Gal beta 1-3GalNAc. Asialoglycophorin A was found to be about 169,333 times stronger an inhibitor than Gal beta 1-3GalNAc. The present study thus reveals the exquisite specificity of A. integrifolia lectin for the T-antigen. Appreciable binding of disaccharides Glc beta 1-3GalNAc and GlcNAc beta 1-3Gal and the very poor binding of beta-linked disaccharides, which instead of Gal and GalNAc contain other sugars at the reducing end, underscore the important contribution made by Gal and GalNAc at the reducing end for recognition by the lectin. The ligand-structure-dependent alterations of the c.d. spectrum in the tertiary structural region of the protein allows the placement of various sugar units in the combining region of the lectin. These studies suggest that the primary subsite (subsite A) can accommodate only Gal or GalNAc or alpha-linked Gal or GalNAc, whereas the secondary subsite (subsite B) can associate either with GalNAc beta Me or Gal beta Me. Considering these factors a likely arrangement for various disaccharides in the binding site of the lectin is proposed. Its exquisite specificity for the authentic T-antigen, Gal beta 1-3GalNAc alpha Ser, together with its virtual non-binding to A- and B-blood-group antigens, Gal beta 1-3GalNAc beta Me and asialo-GM1 should make A. integrifolia lectin a valuable probe for monitoring the expression of T-antigen on cell surfaces.     

Mechanism of lysozyme catalysis: role of ground-state strain in subsite D in hen egg-white and human lysozymes.

The association constants for the binding of various saccharides to hen egg-white lysozyme and human lysozyme have been measured by fluorescence titration. Among these are the oligosaccharides GlcNAc-beta(1 leads to 4)-MurNAc-beta(1 leads to 4)-GlcNAc-beta(1 leads to 4)-GlcNAc, GlcNAc-beta(1 leads to 4)-MurNAc-beta(1 leads to 4)-GlcNAc-beta(1 leads to 4)-N-acetyl-D-xylosamine, and GlcNAc-beta(1 leads to 4-GlcNAc-beta(1 leads to 4)-MurNAc, prepared here for the first time. The binding constants for saccharides which must have N-acetylmuramic acid, N-acetyl-D-glucosamine, or N-acetyl-D-xylosamine bound in subsite D indicate that there is no strain involved in the binding of N-acetyl-D-glycosamine in this site, and that the lactyl group of N-acetylmuramic acid (rather than the hydroxymethyl group) is responsible for the apparent strain previously reported for binding at this subsite. For hen egg-white lysozyme, the dependence of saccharide binding on pH or on a saturating concentration of Gd(III) suggests that the conformation of several of the complexes are different from one another and from that proposed for a productive complex. This is supported by fluorescence difference spectra of the various hen egg-white lysozyme-saccharide complexes. Human lysozyme binds most saccharides studied more weakly than the hen egg-white enzyme, but binds GlcNAc-beta(1 leads to 4)-MurNAc-beta(1leads to 4)-GlcNAc-beta(1 leads to 4)-MurNAc more strongly. It is suggested that subsite C of the human enzyme is "looser" than the equivalent site in the hen egg enzyme, so that the rearrangement of a saccharide in this subsite in response to introduction of an N-acetylmuramic acid residue into subsite D destabilizes the saccharide complexes of human lysozyme less than it does the corresponding hen egg-white lysozyme complexes. This difference and the differences in the fluorescence difference spectra of hen egg-white lysozyme and human lysozyme are ascribed mainly to the replacement of Trp-62 in hen egg-white lysozyme by Tyr-63 in the human enzyme. The implications of our findings for the assumption of superposition and additivity of energies of binding in individual subsites, and for the estimation of the role of strain in lysozyme catalysis, are discussed.     

Structural basis for the recognition of complex-type biantennary oligosaccharides by Pterocarpus angolensis lectin

The crystal structure of Pterocarpus angolensis lectin is determined in its ligand-free state, in complex with the fucosylated biantennary complex type decasaccharide NA2F, and in complex with a series of smaller oligosaccharide constituents of NA2F. These results together with thermodynamic binding data indicate that the complete oligosaccharide binding site of the lectin consists of five subsites allowing the specific recognition of the pentasaccharide GlcNAc beta(1-2)Man alpha(1-3)[GlcNAc beta(1-2)Man alpha(1-6)]Man. The mannose on the 1-6 arm occupies the monosaccharide binding site while the GlcNAc residue on this arm occupies a subsite that is almost identical to that of concanavalin A (con A). The core mannose and the GlcNAc beta(1-2)Man moiety on the 1-3 arm on the other hand occupy a series of subsites distinct from those of con A.     

Structural basis of carbohydrate recognition by lectin II from Ulex europaeus, a protein with a promiscuous carbohydrate-binding site

Protein-carbohydrate interactions are the language of choice for inter- cellular communication. The legume lectins form a large family of homologous proteins that exhibit a wide variety of carbohydrate specificities. The legume lectin family is therefore highly suitable as a model system to study the structural principles of protein-carbohydrate recognition. Until now, structural data are only available for two specificity families: Man/Glc and Gal/GalNAc. No structural data are available for any of the fucose or chitobiose specific lectins.The crystal structure of Ulex europaeus (UEA-II) is the first of a legume lectin belonging to the chitobiose specificity group. The complexes with N-acetylglucosamine, galactose and fucosylgalactose show a promiscuous primary binding site capable of accommodating both N-acetylglucos amine or galactose in the primary binding site. The hydrogen bonding network in these complexes can be considered suboptimal, in agreement with the low affinities of these sugars. In the complexes with chitobiose, lactose and fucosyllactose this suboptimal hydrogen bonding network is compensated by extensive hydrophobic interactions in a Glc/GlcNAc binding subsite. UEA-II thus forms the first example of a legume lectin with a promiscuous binding site and illustrates the importance of hydrophobic interactions in protein-carbohydrate complexes. Together with other known legume lectin crystal structures, it shows how different specificities can be grafted upon a conserved structural framework.     

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.     

Crystal structure of mannanase 26A from Pseudomonas cellulosa and analysis of residues involved in substrate binding

The crystal structure of Pseudomonas cellulosa mannanase 26A has been solved by multiple isomorphous replacement and refined at 1.85 A resolution to an R-factor of 0.182 (R-free = 0.211). The enzyme comprises (beta/alpha)(8)-barrel architecture with two catalytic glutamates at the ends of beta-strands 4 and 7 in precisely the same location as the corresponding glutamates in other 4/7-superfamily glycoside hydrolase enzymes (clan GH-A glycoside hydrolases). The family 26 glycoside hydrolases are therefore members of clan GH-A. Functional analyses of mannanase 26A, informed by the crystal structure of the enzyme, provided important insights into the role of residues close to the catalytic glutamates. These data showed that Trp-360 played a critical role in binding substrate at the -1 subsite, whereas Tyr-285 was important to the function of the nucleophile catalyst. His-211 in mannanase 26A does not have the same function as the equivalent asparagine in the other GH-A enzymes. The data also suggest that Trp-217 and Trp-162 are important for the activity of mannanase 26A against mannooligosaccharides but are less important for activity against polysaccharides.     

A structural basis for the interaction of urea with lysozyme.

The effect of urea on the crystal structure of hen egg-white lysozyme has been investigated using X-ray crystallography. High resolution structures have been determined from crystals grown in the presence of 0, 0.7, 2, 3, 4, and 5 M urea and from crystals soaked in 9 M urea. All the forms are essentially isomorphous with the native type II crystals, and the derived structures exhibit excellent geometry and RMS differences from ideality in bond distances and angles. Comparison of the urea complex structures with the native enzyme (type II form, at 1.5 A resolution) indicates that the effect of urea is minimal over the concentration range studied. The mean difference in backbone conformation between the native enzyme and its urea complexes varies from 0.18 to 0.49 A. Conformational changes are limited to flexible surface loops (Thr 69-Asn 74, Ser 100-Asn 103), the active site loop (Asn 59-Cys 80), and the C-terminus (Cys 127-Leu 129). Urea molecules are bound to distinct sites on the surface of the protein. One molecule is bound to the active site cleft's C subsite, at all concentrations, in a fashion analogous to that of the N-acetyl substituent of substrate and inhibitor sugars normally bound to this site. Occupation of this subsite by urea alone does not appear to induce the conformational changes associated with inhibitor binding.     

The oligosaccharides of the glycoprotein pheromone of Volvox carteri f. nagariensis Iyengar (Chlorophyceae)

The sexuality-inducing glycoprotein of Volvox carteri f. nagariensis was purified from supernatants of disintegrated sperm packets of the male strain IPS-22 and separated by reverse-phase HPLC into several isoforms which differ in the degree of O-glycosylation. Total chemical deglycosylation with trifluoromethanesulphonic acid yields the biologically inactive core protein of 22.5 kDa. This core protein possesses three putative binding sites for N-glycans which are clustered in the middle of the polypeptide chain. The N-glycosidically bound oligosaccharides were obtained by glycopeptidase F digestion and were shown by a combination of exoglycosidase digestion, gaschromatographic sugar analysis and two-dimensional HPLC separation to possess the following definite structures: (A) Man beta 1-4GlcNAc beta 1-4GlcNAc; (B) (Man alpha)3 Man beta 1-4GlcNAc beta 1-4GlcNAc Xyl beta; (C) (Man alpha)2 Man beta 1-4GlcNAc beta 1-4GlcNAc; (D) (Man)2Xyl(GlcNAc)2. Xyl beta Two of the three N-glycosidic binding sites carry one B and one D glycan. The A and C glycans are shared by the third N-glycosylation site. The O-glycosidic sugars, which make up 50% of the total carbohydrate, are short (up to three sugar residues) chains composed of Ara, Gal and Xyl and are exclusively bound to Thr residues.     

Conformational changes and subunit communication in tryptophan synthase: effect of substrates and substrate analogs.

The transmission of regulatory signals between the alpha- and beta-subunits of the tryptophan synthase alpha 2 beta 2 complex from Salmonella typhimurium has been investigated by monitoring the luminescence properties of the enzyme in the presence and in the absence of the alpha-subunit ligand DL-alpha-glycerol 3-phosphate, the alpha- and beta-subunit substrate indole, and the beta-subunit substrate analog L-histidine. The beta-subunit contains as intrinsic probes Trp-177 and pyridoxal 5'-phosphate, whereas the alpha-subunit has been mutagenized by replacing Ala-129 with a Trp residue. In contrast to the inertness of L-histidine, DL-alpha-glycerol 3-phosphate was found (i) to alter the phosphorescence spectrum of Trp-129, (ii) to shift the fluorescence thermal quenching profile of both Trp-177 and coenzyme to higher temperature, (iii) to slow down the triplet decay kinetics of Trp-177 in fluid solution, and (iv) to affect the equilibrium between different conformations of the enzyme. These findings provide direct evidence that DL-alpha-glycerol 3-phosphate binding affects the structure of the alpha-subunit and, in the presence of coenzyme, induces a conformational change in the beta-subunit that leads to a considerably more rigid structure. As opposed to DL-alpha-glycerol 3-phosphate, the shortening of the phosphorescence lifetime upon indole binding suggests that this substrate increases structural fluctuations in the beta-subunit. Implications for the mechanism of the allosteric regulation between alpha- and beta-subunits are discussed.     

Mapping of nucleotide-depleted mitochondrial F1-ATPase with 2-azido-[alpha-32P]adenosine diphosphate. Evidence for two nucleotide binding sites in the beta subunit

Photolabeling of nucleotide binding sites in nucleotide-depleted mitochondrial F1 has been explored with 2-azido [alpha-32P]adenosine diphosphate (2-N3[alpha-32P] ADP). Control experiments carried out in the absence of photoirradiation in a Mg2+-supplemented medium indicated the presence of one high affinity binding site and five lower affinity binding sites per F1. Similar titration curves were obtained with [3H]ADP and the photoprobe 3'-arylazido-[3H]butyryl ADP [( 3H]NAP4-ADP). Photolabeling of nucleotide-depleted F1 with 2-N3[alpha-32P]ADP resulted in ATPase inactivation, half inactivation corresponding to 0.6-0.7 mol of photoprobe covalently bound per mol F1. Only the beta subunit was photolabeled, even under conditions of high loading with 2-N3[alpha-32P]ADP. The identification of the sequences labeled with the photoprobe was achieved by chemical cleavage with cyanogen bromide and enzymatic cleavage by trypsin. Under conditions of low loading with 2-N3[alpha-32P]ADP, resulting in photolabeling of only one vacant site in F1, covalently bound radioactivity was located in a peptide fragment of the beta subunit spanning Pro-320-Met-358 identical to the fragment photolabeled in native F1 (Garin, J., Boulay, F., Issartel, J.-P., Lunardi, J., and Vignais, P. V. (1986) Biochemistry 25, 4431-4437). With a heavier load of photoprobe, leading to nearly 4 mol of photoprobe covalently bound per mol F1, an additional region of the beta subunit was specifically labeled, corresponding to a sequence extending from Gly-72 to Arg-83. The isolated beta subunit also displayed two binding sites for 2-N3-[alpha-32P]ADP. When F1 was first photolabeled with a low concentration of NAP4-ADP, leading to the covalent binding of 1.5 mol of NAP4-ADP/mol F1, with the bound NAP4-ADP distributed equally between the alpha and beta subunits, a subsequent photoirradiation in the presence of 2-N3[alpha-32P]ADP resulted in covalent binding of the 2-N3[alpha-32P]ADP to both alpha and beta subunits. It is concluded that each beta subunit in mitochondrial F1 contains two nucleotide binding regions, one of which belongs to the beta subunit per se, and the other to a subsite shared with a subsite located on a juxtaposed alpha subunit. Depending on the experimental conditions, the subsite located on the alpha subunit is either accessible or masked. Unmasking of the subsite in the three alpha subunits of mitochondrial F1 appears to proceed by a concerted mechanism.     

Catalytic reaction mechanism of goose egg-white lysozyme by molecular modelling of enzyme-substrate complex

Despite the low similarity between their amino acid sequences, the core structures of the fold between chicken-type and goose-type lysozymes are conserved. However, their enzymatic activities are quite different. Both of them exhibit hydrolytic activities, but the goose-type lysozyme does not exhibit transglycosylation activity. The chicken-type lysozyme has a retaining-type reaction mechanism, while the reaction mechanism of the goose-type lysozyme has not been clarified. To clarify the latter mechanism, goose egg-white lysozyme (GEL)-N-acetyl-D-glucosamine (GlcNAc)6 complexes were modelled and compared with hen egg-white lysozyme (HEL)-(GlcNAc)6 complexes. By systematic conformational search, 48 GEL-(GlcNAc)6 complexes were modelled. The right and left side, and the amino acid residues in subsites E-G were identified in GEL. The GlcNAc residue D could bind towards the right side without distortion and there was enough room for a water molecule to attack the C1 carbon of GlcNAc residue D from alpha-side in the right side and not for acceptor molecule. The result of molecular dynamics simulation suggests that GEL would be an inverting enzyme, and Asp97 would act as a second carboxylate and that the narrow space of the binding cleft at subsites E-G in GEL may prohibit the sugar chain to bind alternative site that might be essential for transglycosylation.     

Interactions of wheat-germ agglutinin with GlcNAc beta 1,6Gal sequence

The interactions of wheat-germ agglutinin (WGA) with the GlcNAc beta 1,6Gal sequence, a characteristic component of branched poly-N-acetyllactosaminoglycans, were investigated using isothermal titration calorimetry and X-ray crystallography. GlcNAc beta 1,6Gal exhibited an affinity greater than GlcNAc beta 1,4GlcNAc to all WGA isolectins, whereas Gal beta 1,6GlcNAc showed much less affinity than GlcNAc beta 1,4GlcNAc. X-ray structural analyses of the glutaraldehyde-crosslinked WGA isolectin 3 crystals in complex with GlcNAc beta 1,6Gal, GlcNAc beta 1,4GlcNAc and GlcNAc beta 1,6Gal beta 1,4Glc were performed at 2.4, 2.2 and 2.2 A resolution, respectively. In spite of different glycosidic linkages, GlcNAc beta 1,6Gal and GlcNAc beta 1,4GlcNAc exhibited basically similar binding modes to each other, in contact with side chains of two aromatic residues, Tyr64 and His66. However, the conformations of the ligands in the two primary binding sites were not always identical. GlcNAc beta 1,6Gal showed more extensive variation in the parameters defining the glycosidic linkage structure compared to GlcNAc beta 1,4GlcNAc, demonstrating large conformational flexibility of the former ligand in the interaction with WGA. The difference in the ligand binding conformation was accompanied by alterations of the side chain conformation of the amino acid residues involved in the interactions. The hydrogen bond between Ser62 and the non-reducing end GlcNAc was always observed regardless of the ligand type, indicating the key role of this interaction. In addition to the hydrogen bonding and van der Waals interactions, CH--pi interactions involving Tyr64, His66 and Tyr73 are suggested to play an essential role in determining the ligand binding conformation in all complexes. One of the GlcNAc beta 1,6Gal ligands had no crystal packing contact with another WGA molecule, therefore the conformation might be more relevant to the interaction mode in solution.     

Enzyme-inhibitor complexes of lysozyme with glucosamine inhibitors. A molecular dynamics study through 2H-NMR

2H relaxation measurements coupled with multiple specific 2H labeling have provided insight into the molecular dynamics of N-acetyl-D-glucosamine (GlcNAc) inhibitors bound to lysozyme. Deuteron T1 and T2 data for the bound state of methyl alpha- and -beta-GlcNAc 2H-labeled in the glycosidic methyl and C2 positions have been derived from measurements at different enzyme/inhibitor ratios. Rotational correlation times calculated therefrom for the labeled sites indicate, in both cases, tight binding for the sugar ring (tau(b) = 3.0 x 10(-9) s) accompanied by fast internal rotation, about one axis, of the glycosidic methyl groups (tau(r) = 5.5-7.6 x 10(-11) s). The small but consistent difference in the rates of internal rotation for the alpha- and beta-anomeric inhibitors may be indicative of different solution structures of the enzyme-inhibitor complexes.     

Synthesis of nucleotide-activated oligosaccharides by beta-galactosidase from Bacillus circulans

The enzymatic access to nucleotide-activated oligosaccharides by a glycosidase-catalyzed transglycosylation reaction was explored. The nucleotide sugars UDP-GlcNAc and UDP-Glc were tested as acceptor substrates for beta-galactosidase from Bacillus circulans using lactose as donor substrate. The UDP-disaccharides Gal(beta1-4)GlcNAc(alpha1-UDP) (UDP-LacNAc) and Gal(beta1-4)Glc(alpha1-UDP) (UDP-Lac) and the UDP-trisaccharides Gal(beta1-4)Gal(beta1-4)GlcNAc(alpha1-UDP and Gal(beta1-4)Gal(beta1-4)Glc(alpha1-UDP) were formed stereo- and regioselectively. Their chemical structures were characterized by 1H and 13C NMR spectroscopy and fast atom bombardment mass spectrometry. The synthesis in frozen solution at -5 degrees C instead of 30 degrees C gave significantly higher product yields with respect to the acceptor substrates. This was due to a remarkably higher product stability in the small liquid phase of the frozen reaction mixture. Under optimized conditions, at -5 degrees C and pH 4.5 with 500 mM lactose and 100 mM UDP-GlcNAc, an overall yield of 8.2% (81.8 micromol, 62.8 mg with 100% purity) for Gal(beta1-4)GlcNAc(alpha1-UDP) and 3.6% (36.1 micromol, 35 mg with 96% purity) for Gal(beta1-4)Gal(beta1-4)GlcNAc(alpha1-UDP) was obtained. UDP-Glc as acceptor gave an overall yield of 5.0% (41.3 micromol, 32.3 mg with 93% purity) for Gal(beta1-4)Glc(alpha1-UDP) and 1.6% (13.0 micromol, 12.2 mg with 95% purity) for Gal(beta1-4)Gal(beta1-4)Glc(alpha1-UDP). The analysis of other nucleotide sugars revealed UDP-Gal, UDP-GalNAc, UDP-Xyl and dTDP-, CDP-, ADP- and GDP-Glc as further acceptor substrates for beta-galactosidase from Bacillus circulans.     

Crystal structures of egg-white lysozyme of hen in acetate-free medium and of lysozyme complexes with N-acetylglucosamine and beta-methyl N-acetylglucosaminide.

The binding of beta-methyl N-acetylglucosaminide (betaMeGlcNAc) to egg-white lysozyme of hen in the tetragonal crystal form was studied by X-ray diffraction techniques to a resolution of 0.25 nm. The binding of the beta-methyl glycoside is almost identical with the binding of beta-N-acetylglucosamine (betaGlcNAc). Real-space refinement of the lysozyme-alpha/beta GlcNAc and lysozyme-betaMeGlcNAc complexes allowed preliminary analysis of the conformational changes observed on binding monosaccharide inhibitors, specially in the region involving tryptophan-62 and residues 70--76. Tetagonal lysozyme crystals, grown in the absence of acetate ions, were examined by X-ray diffraction to 0.25nm resolution. The resulting difference Fourier synthesis shows no firm evidence for bound acetate ions and indicates only minor conformational changes in the side-chain positions of aspartic acid-101 and asparagine-103. The close similarity of the lysozyme structures in the presence and absence of acetate is contrary to expectations from previous n.m.r. studies.     

Enzymatic properties of rhea lysozyme

Rhea lysozyme was analyzed for its enzymatic properties both lytic and oligomer activities to reveal the structural and functional relationships of goose type lysozyme. Rhea lysozyme had the highest lytic activity at pH 6, followed by ostrich and goose at pH 5.5-6, whereas the optimum of cassowary was at pH 5. pH profile was correlated to the net charge of each molecule surface. On the other hand, the pH optimum for oligomer substrate was found to be pH 4, indicating the mechanism of rhea catalysis as a general acid. The time-course of the reaction was studied using beta-1,4-linked oligosaccharide of N-acetylglucosamine (GlcNAc) with a polymerization degree of n ((GlcNAc)n) (n=4, 5, and 6) as the substrate. This enzyme hydrolyzed (GlcNAc)6 in an endo-splitting manner, which produced (GlcNAc)3+(GlcNAc)3 predominating over that to (GlcNAc)2+ (GlcNAc)4. This indicates that the lysozyme hydrolyzed preferentially the third glycosidic linkage from the nonreducing end. Theoretical analysis has shown the highest rate constant value at 1.5 s-1 with (GlcNAc)6. This confirmed six substrate binding subsites as goose lysozyme (Honda, Y., and Fukamizo, T., Biochim. Biophys. Acta, 1388, 53-65 (1998)). The different binding free energy values for subsites B, C, F, and G from goose lysozyme might responsible for the amino acid substitutions, Asn122Ser and Phe123Met, located at the subsite B.     

Substrate specificity of rat liver cytosolic alpha-D-mannosidase. Novel degradative pathway for oligomannosidic type glycans.

The substrate specificity of rat liver cytosolic neutral alpha-D-mannosidase was investigated by in vitro incubation with a crude cytosolic fraction of oligomannosyl oligosaccharides Man9GlcNAc, Man7GlcNAc, Man5GlcNAc I and II isomers and Man4GlcNAc having the following structures: Man9GlcNAc, Man(alpha 1-2)Man(alpha 1-3)[Man(alpha 1-2)Man(alpha 1-6)]Man(alpha 1-6) [Man(alpha 1-2)Man(alpha 1-3)]Man(beta 1-4)GlcNAc; Man5GlcNAc I, Man(alpha 1-3)[Man(alpha 1-6)]-Man(alpha 1-6)Man(alpha 1-3)] Man(beta 1-4)GlcNAc; Man5GlcNAc II, Man(alpha 1-2)Man(alpha 1-2)Man(alpha 1-3) [Man(alpha 1-6)]Man(beta 1-4)GlcNAc; Man4GlcNAc, Man(alpha 1-2)Man(alpha 1-2)Man(alpha 1-3)Man(beta 1-4)GlcNAc. The different oligosaccharide isomers resulting from alpha-D-mannosidase hydrolysis were analyzed by 1H-NMR spectroscopy after HPLC separation. The cytosolic alpha-D-mannosidase activity is able to hydrolyse all types of alpha-mannosidic linkages found in the glycans of the oligomannosidic type, i.e. alpha-1,2, alpha-1,3 and alpha-1,6. Nevertheless the enzyme is highly active on branched Man9GlcNAc or Man5GlcNAc I oligosaccharides and rather inactive towards the linear Man4GlcNAc oligosaccharide. Structural analysis of the reaction products of the soluble alpha-D-mannosidase acting on Man5-GlcNAc I and Man9GlcNAc gives Man3GlcNAc, Man(alpha 1-6)[Man(alpha 1-3)]Man(beta 1-4)GlcNAc, and Man5GlcNAc II oligosaccharides, respectively. This Man5GlcNAc II, Man(alpha 1-2)Man(alpha 1-3)[Man(alpha 1-6)]Man(beta 1-4)GlcNAc, represents the 'construction' Man5 oligosaccharide chain of the dolichol pathway formed in the cytosolic compartment during the biosynthesis of N-glycosylprotein glycans. The cytosolic alpha-D-mannosidase is activated by Co2+, insensitive to 1-deoxymannojirimycin but strongly inhibited by swainsonine in the presence of Co2+ ions. The enzyme shows a highly specific action different from that previously described for the lysosomal alpha-D-mannosidases [Michalski, J.C., Haeuw, J.F., Wieruszeski, J.M., Montreuil, J. and Strecker, G. (1990) Eur. J. Biochem. 189, 369-379]. A possible complementarity between cytosolic and lysosomal alpha-D-mannosidase activities in the catabolism of N-glycosylprotein is proposed.     

Self and foreign peptides interact with intact and disassembled MHC class II antigen HLA-DR via tryptophan pockets

The acid release of endogenous peptides from immunoaffinity-pure human major histocompatibility complex (MHC) class II proteins HLA-DR1 is accompanied by an 18% decrease in intrinsic tryptophan fluorescence. The effect is totally reversible upon readdition of an autologous endogenous peptide fraction. High-performance size-exclusion chromatographic (HPSEC) binding and release studies with a nonfluorescent HLA-DR1-restricted influenza matrix peptide IM(18-29) prove the fact that Trp residues of the HLA protein change their fluorescence intensities. Since the far-UV circular dichroism spectra of HLA molecules before and after peptide release, DR1[NAT] and DR1[REL], show very small differences, we can rule out the breakdown of secondary structural elements under release conditions, although DR[REL] consists of disassembled alpha- and beta-subunits, as evidenced by HPSEC. Quenching of DR1[NAT] and DR1[REL] using the neutral quencher acrylamide results in a 20% increase in total accessibility of the nine-residue Trp population whereas quenching by iodide yields only a 5% increase. Both results taken together tell us that two Trp residues, preferentially ones located in apolar pockets, become accessible upon the release of peptides. The significantly smaller fluorescence enhancement upon binding IM(18-29) of DR3[REL], exclusively lacking Trp-9(beta 1), and the missing tendency to reassemble under the influence of IM(18-29) compared to DR1[REL] suggest an important role for position 9(beta 1). The region around Trp-43(alpha 1) should be responsible for the binding of IM(18-29) to the alpha-subunits of DR1 and DR3, respectively, as verified by fluorometric HPSEC and SDS-PAGE. Obviously, our findings are in total agreement with the hypothetical MHC class II model, whereafter Trp-9(beta 1) and Trp-43(alpha 1) besides Trp-61(beta 1) are constituents of the binding groove of DR1. Extending the homology to MHC class I products, we postulate the existence of three hydrophobic pockets in the binding site of DR1 with the cited Trp residues being juxtaposed to contacting apolar peptide side chains in HLA-peptide complexes. According to the deduced two-residue-contact model the minimal consensus motif for DR1-restricted peptide antigens consists of two hydrophobic residues lying 14-16 A apart in the bound state of the peptide.