Nearest-neighbour analysis of myoglobin antigenic sites. Nearest-neighbour residues whose replacement can alter the environment of binding-site residue(s) and thus change their characteristics and binding capability.

By using the known antigenic structure of sperm-whale myoglobin previously determined in this laboratory and the X-ray co-ordinates for the myoglobin molecule, we have calculated the nearest-atom distances between each of the residues of the antigenic sites and all the other amino acids of the myoglobin molecule. These calculations have enabled us to identify the nearest-neighbour residues to each of the residues in the five antigenic sites, and which thus describe the immediate molecular environment of the sites. The influences of chemical changes or replacements in these environmental residues on the binding capacity of an antigenic site, when considered together with replacements directly in the antigenic sites, are expected to account for the major effects and will be extremely useful in explaining the cross-reactions of myoglobins from various species. However, it is stressed that the analysis has limitations due to the qualitative estimates of the effects, the influences of substitutions of once-removed or even at more distant locations (especially when they are cumulative) and finally the influences of any conformational re-adjustments when these occur as a result of the replacement(s).     

Binding with lysozyme of antibodies against surface-simulation peptides representing the lysozyme antigenic sites.

Previously it had been shown that native lysozyme has three discontinuous antigenic sites (comprising spatially adjacent residues that may be distant in sequence) that were mimicked by surface-simulation synthetic peptides that had the capacity to bind the bulk (97-99%) of the antibody response against native lysozyme. In the present work these three surface-simulation synthetic peptides were coupled to succinoylated bovine serum albumin, and the conjugates were injected into rabbits. Antibodies against each peptide reacted, as expected, only with that peptide, but it was also found that the antibodies could bind with lysozyme, and the complete specificity of this binding was rigorously established. The advantages of these findings in conformational and immunological investigations are outlined.     

Amino acid sequence of California quail lysozyme. Effect of evolutionary substitutions on the antigenic structure of lysozyme.

To examine the effect of amino acid substitutions in lysozyme on the binding of antibodies to lysozyme, we purified lysozyme from the egg whites of California quail and Gambel quail. Tryptic peptides were isolated from digests of the reduced and carboxymethylated lysozymes and subjected to quantitative analysis of their amino acid compositions. The two proteins were identical by this criterion. Each peptide from the California quail lysozyme was then sequenced by quantitative Edman degradation, and the peptides were ordered by homology with other bird lysozymes. California quail lysozyme is most similar in amino acid sequence to bobwhite quail lysozyme, from which it differs by two substitutions: arginine for lysine at position 68 and histidine for glutamine at position 121. California and bobwhite quail lysozymes were antigenically distinct from each other in quantitative microcomplement fixation tests, indicating that substitutions at one or both of these positions can alter the antigenic structure of lysozyme. Yet neither of these positions is among those claimed to account for the precise and entire antigenic structure of lysozyme [Atassi, M. Z., & Lee, C.-L. (1978) Biochem. J. 171, 429--434]. Two possible explanations for this discrepancy are discussed.     

Single-amino-acid substitution in an antigenic site of influenza virus hemagglutinin can alter the specificity of binding to cell membrane-associated gangliosides.

Antigenic variants of influenza virus A/Mem/1/71-Bel/42 (H3N1) selected with monoclonal antibodies and having single substitutions in their hemagglutinins were examined for their ability to hemagglutinate and hemolyse erythrocytes coated with different gangliosides. The majority of variants, including one with a substitution near the receptor-binding site (Asn-133----Lys), did not differ from the parent in specificity for receptor molecules. However, a substitution in HA1 at residue 205 (Ser----Tyr), which is distant from the receptor-binding site in antigenic site D, affected hemagglutination and hemolysis of erythrocytes coated with sialyl-paraglobosides. The variant preferentially recognized N-acetylneuraminic acid-alpha 2,6-galactose linkages to sialylparaglobosides, whereas the parent and other variants preferentially recognized N-acetylneuraminic acid-alpha 2,3-galactose linkages. In the trimeric hemagglutinin molecule, residue 205 is located across the subunit interface from the receptor-binding site. The bulky hydrophobic tyrosine in the variant may cause a conformational change in the receptor-binding pocket on the neighboring subunit and influence receptor binding.     

Additional binding sites in lysozyme. X-ray analysis of lysozyme complexes with bromophenol red and bromophenol blue.

The binding sites in hen egg-white lysozyme for neutral bromophenol red (BPR) and ionized bromophenol blue (BPB) have been characterized at 2 A resolution. In either case, the dye-bound enzyme is active against the polysaccharide, but not against the cell wall. Both binding sites are outside, but close to, the hexasaccharide binding cleft in the enzyme. The binding site of BPR made up of Arg5, Lys33, Phe34, Asn37, Phe38, Ala122, Trp123 and possibly Arg125, is close to subsite F while that of BPB made up of Tyr20, Arg21, Asn93, Lys96, Lys97 and Ser100, is close to subsites A and B. The binding sites of the neutral dye and the ionized dye are thus spatially far apart. The peptide component of the bacterial cell wall probably interacts with these cells during enzyme action. Such interactions are perhaps necessary for appropriately positioning the enzyme molecule on the bacterial cell wall.     

Expression of specific binding sites on Candida with functional and antigenic characteristics of human complement receptors

Receptors for C3 degradation fragments (CR1, CR2, and CR3) are present on many human cells including phagocytes and lymphoid cells and may be critical in the attachment of invading microorganisms. In these studies Candida were found to mimic the human CR by binding erythrocytes coated with specific human C3 fragments. Yeast forms of Candida species were adhered to glass slides and were allowed to germinate. Sheep erythrocytes (E) were coated with IgM (EA) and human complement components to prepare EA, EAC14, EAC3b, EAC3bi, and EAC3d. These test cells were then examined for adherence to the organism. Antibodies to human CR1, CR2, and CR3 were used to evaluate their potential for blocking adherence of the test erythrocytes to Candida. Fluorescein-labeled antibodies to human complement receptors were also used to characterize the binding sites. EAC3bi and EAC3d, but not E, EA, or EAC14, bound extensively to the germ tubes and pseudohyphae of Candida albicans and C. stellatoidea. EAC3b bound infrequently. Other Candida species, generally considered less pathogenic, bound significantly fewer specific test erythrocytes than C. albicans. Monoclonal antibodies to human CR1 and CR3 (3D9, 1B4, C511, 2B6, anti-B2, Mo1, and anti-Mac-1), in general, did not block adherence of test erythrocytes. Blocking of adherence of EAC3bi and EAC3d test erythrocytes coated with small quantities of C3 fragments occurred with high concentrations of monoclonal (anti-CR2) HB-5 and polyclonal (anti-CR2) anti-GP 140. Immunofluorescence studies demonstrated binding of Mo-1 to the germinated forms of the organism, whereas binding of the other antibodies was not seen. These studies suggest a surface constituent on the organism similar to CR on human cells. Additional studies are necessary to further define the molecular nature of the binding site. The ability of organisms to mimic human CR may be more generalized than previously known and may serve as a mechanism for modification of the inflammatory and immune response.     

Modeling alpha-helical transmembrane domains: the calculation and use of substitution tables for lipid-facing residues.

Amino acid substitution tables are calculated for residues in membrane proteins where the side chain is accessible to the lipid. The analysis is based upon the knowledge of the three-dimensional structures of two homologous bacterial photosynthetic reaction centers and alignments of their sequences with the sequences of related proteins. The patterns of residue substitutions show that the lipid-accessible residues are less conserved and have distinctly different substitution patterns from the inaccessible residues in water-soluble proteins. The observed substitutions obtained from sequence alignments of transmembrane regions (identified from, e.g., hydrophobicity analysis) can be compared with the patterns derived from the substitution tables to predict the accessibility of residues to the lipid. A Fourier transform method, similar to that used for the calculation of a hydrophobic moment, is used to detect periodicity in the predicted accessibility that is compatible with the presence of an alpha-helix. If the putative transmembrane region is identified as helical, then the buried and exposed faces can be discriminated. The presence of charged residues on the lipid-exposed face can help to identify the regions that are in contact with the polar environment on the borders of the bilayer, and the construction of a meaningful three-dimensional model is then possible. This method is tested on an alignment of bacteriorhodopsin and two related sequences for which there are structural data at near atomic resolution.     

Intestinal trypsin can significantly modify antigenic properties of polioviruses: implications for the use of inactivated poliovirus vaccine.

It was recently reported that the intestinal protease trypsin cleaves in vitro the VP1 protein of type 3 poliovirus at antigenic site 1 (J. P. Icenogle, P. D. Minor, M. Ferguson, and J. M. Hogle, J. Virol. 60:297-301, 1986). We found that incubation of purified or crude type 3 poliovirus preparations with specimens of human intestinal fluid brings about a similar change in the virion structure. Sera from children immunized solely with the regular inactivated poliovirus vaccine (IPV) neutralized trypsin-cleaved Sabin 3 virus poorly, if at all, despite moderate levels of antibodies to the corresponding intact virus. Sera containing very high titers of the intact virus also neutralized the trypsin-cleaved virus but at a relatively weaker capacity. Most sera from older persons who may have been exposed to a natural poliovirus infection before the introduction of the poliovirus vaccines as well as sera from children infected with type 3 poliovirus during the recent outbreak in Finland were able to neutralize the trypsin-cleaved type 3 polioviruses. Serum specimens collected 1 month after a single dose of live poliovirus vaccine from children previously immunized with IPV were able to neutralize the trypsin-cleaved virus as well. During natural infection and after live poliovirus vaccine administration polioviruses are exposed to proteolytic enzymes in the gut. Our results may offer an alternative explanation for the relatively weak mucosal immunity obtained with IPV. Improvement of IPV preparations by incorporation of trypsin-treated type 3 polioviruses in the vaccine should be studied.     

Analysis of the critical sites for protein thermostabilization by proline substitution in oligo-1,6-glucosidase from Bacillus coagulans ATCC 7050 and the evolutionary consideration of proline residues.

To identify the critical sites for protein thermostabilization by proline substitution, the gene for oligo-1,6- glucosidase from a thermophilic Bacillus coagulans strain, ATCC 7050, was cloned as a 2.4-kb DNA fragment and sequenced. In spite of a big difference in their thermostabilities, B. coagulans oligo-1,6-glucosidase had a large number of points in its primary structure identical to respective points in the same enzymes from a mesophilic Bacillus cereus strain, ATCC 7064 (57%), and an obligately thermophilic Bacillus thermoglucosidasius strain, KP1006 (59%). The number of prolines (19 for B. cereus oligo-1,6-glucosidase, 24 for B. coagulans enzyme, and 32 for B. thermoglucosidasius enzyme) was observed to increase with the rise in thermostabilities of the oligo-1,6-glucosidases. Classification of proline residues in light of the amino acid sequence alignment and the protein structure revealed by X-ray crystallographic analysis also supported this tendency. Judging from proline residues occurring in B. coagulans oligo-1,6-glucosidase and the structural requirement for proline substitution (second site of the beta turn and first turn of the alpha helix) (K. Watanabe, T. Masuda, H. Ohashi, H. Mihara, and Y. Suzuki, Eur. J. Biochem. 226:277-283, 1994), the critical sites for thermostabilization were found to be Lys-121, Glu-290, Lys-457, and Glu-487 in B. cereus oligo-1,6-glucosidase. With regard to protein evolution, the oligo-1,6-glucosidases very likely follow the neutral theory. The adaptive mutations of the oligo-1,6-glucosidases that appear to increase thermostability are consistent with the substitution of proline residues for neutrally occurring residues. It is concluded that proline substitution is an important factor for the selection of thermostability in oligo-1,6-glucosidases.     

Distance between the substrate and regulatory reduced coenzyme binding sites of bovine liver glutamate dehydrogenase by resonance energy transfer

Bovine liver glutamate dehydrogenase is known to bind reduced coenzyme at two sites/subunit, one catalytic and one regulatory; ADP competes for the latter site. The enzyme is here shown to be catalytically active with the thionicotinamide analogue of NADPH [( S]NADPH). For native enzyme, ultrafiltration studies revealed that [S]NADPH reversibly occupies about two sites/enzyme subunit in the absence of other ligands; by the addition of ADP, [S]NADPH binding can be limited to one molecule/subunit. The enzyme is irreversibly inactivated by reaction with 4-(iodoacetamido)salicylic acid (ISA) at lysine126 within the 2-oxoglutarate binding site [Holbrook, J.J., Roberts, P.A. & Wallis, R.B. (1973) Biochem. J. 133, 165-171]. ISA-modified enzyme binds 1 molecule [S]NADPH/subunit in the absence of ADP, suggesting that reaction at the substrate site blocks binding at the catalytic, but not at the regulatory site. The fluorescence spectrum of ISA-modified enzyme overlaps the absorption spectrum of [S]NADPH allowing a distance measurement between these sites by resonance energy transfer. [S]NADPH quenches the emission of ISA-modified enzyme, yielding 3.2 nm as the average distance between sites. ADP competes for the [S]NADPH site but does not affect the fluorescence of ISA-modified enzyme, indicating that [S]NADPH quenching is attributable to energy transfer rather than to a conformational change. The 3.2 nm thus represents the distance between the 2-oxoglutarate and reduced coenzyme regulatory sites of glutamate dehydrogenase.     

beta-Endorphin: characteristics of binding sites in the rat brain.

Stereospecific binding of human β-endorphin to rat membrane preparations is described for the first time using $\text{[}{}^3\text{H-Tyr}{}^{27}\text{]-β}{}_{\mathrm{h}}\text{-endorphin}$ as the ligand. The binding is time dependent and saturable with respect to β_h-endorphin with an apparent dissociation constant of 0.3 nM. Sodium ion (100 mM) elevates this value to 2.5 nM but has no effect on the total number of binding sites present in the membrane preparation. The ability of certain β-endorphin analogs, opiate agonists as well as antagonists to inhibit the binding of β_h-endorphin, is presented.     

Enzymic and immunochemical properties of lysozyme. XI. Conformation and immunochemistry of the two-disulfide peptide and the tryptophan and lysine residues in its antigenic reactivity.

The previously described peptide 62-68 (Cys 64-Cys 80) 74-96 (Cys 76-Cys 94) (Atassi, M.Z., Suliman, A.M. and Habeeb, A.F.S.A. (1975) Biochim. Biophys. Acta 405, 452-463), which accounted for about one-third of the total antigenic reactivity of native lysozyme, was isolated here with lysine 97 attached to it. The peptide was subjected to specific modification reactions in order to determine some of the residues which formed part of its antigenic reactive site. ORD measurements showed that the peptide was greatly unfolded in solution relative to its expected mode of folding within the intact lysozyme molecule. Modification of the two tryptophan residues in the peptide by reaction with 2,3-dioxo-5-indolinesulfonic acid provided a derivative which possessed similar conformational parameters to those of the unmodified peptide. However, the derivative retained only about half the immunochemical reactivity of the peptide. Succinylation of the amino groups afforded a derivative whose conformational parameters were identical to those of the unmodified peptide but in which half of the immunochemical reactivity was lost. Modification of the two tryptophan residues followed by succinylation of the amino groups resulted in almost complete loss of the antigenic reactivity, and the loss was not due to conformational differences. The antigenic reactivity of the peptide was also destroyed on removal of tryptophans 62 and 63, of sequence 84-93 from the loop 74-79 and of sequence 74-75 by chymotryptic digestion. From these and previous results it was concluded that the antigenic reactive site in this part of the lysozyme molecule incorporates one or both of tryptophans 62 and 63 as well as one or both lysines 96 and 97. The two disulfides 64-80 and 76-94 bring these two parts of the lysozyme molecule into a single reactive site. The intactness of the disulfides is essential for maintenance and reactivity of the site.     

Mutational substitution of residues implicated by crystal structure in binding the substrate glutathione to human glutathione S-transferase pi.

Site-directed substitution mutations were introduced into a cDNA expression vector (pUC120 pi) that encoded a human glutathione S-transferase pi isozyme to non-conservatively replace four residues (Tyr7, Arg13, Gln62 and Asp96). Our earlier X-ray crystallographic analysis implicated these residues in binding and/or chemically activating the substrate glutathione. Each substitution mutation decreased the specific activity of the enzyme to less than 2% of the wild-type. Glutathione-binding was also reduced; however, the Tyr7----Phe mutant still retained 27% of the wild-type capacity to bind glutathione, underlining the primary role that this residue is likely to play in chemically activating the glutathione molecule during catalysis.     

Human fibronectin and MMP-2 collagen binding domains compete for collagen binding sites and modify cellular activation of MMP-2.

The region of fibronectin (FN) surrounding the two type II modules of FN binds type I collagen. However, little is known about interactions of this collagen binding domain with other collagen types or extracellular matrix molecules. Among several expressed recombinant (r) human FN fragments from the collagen binding region of FN, only rI6-I7, which included the two type II modules and both flanking type I modules, bound any of several tested collagens. The rI6-I7 interacted specifically with both native and denatured forms of types I and III collagen as well as denatured types II, IV, V and X collagen with apparent K(d) values of 0.2-3.7 x 10(-7) M. Reduction with DTT disrupted the binding to gelatin verifying the functional requirement for intact disulfide bonds. The FN fragments showed a weak, but not physiologically important, binding to heparin, and did not bind elastin or laminin. The broad, but selective range of ligand interactions by rI6-I7 mirrored our prior observations for the collagen binding domain (rCBD) from matrix metalloproteinase-2 (MMP-2) [J. Biol. Chem. 270 (1995) 11555]. Subsequent experiments showed competition between rI6-I7 and rCBD for binding to gelatin indicating that their binding sites on this extracellular matrix molecule are identical or closely positioned. Two collagen binding domain fragments supported cell attachment by a beta1-integrin-dependent mechanism although neither protein contains an Arg-Gly-Asp recognition sequence. Furthermore, activation of MMP-2 and MMP-9 was greatly reduced for HT1080 fibrosarcoma cells cultured on either of the fibronectin fragments compared to full-length FN. These observations imply that the biological activities of FN in the extracellular matrix may involve interactions with a broad range of collagen types, and that exposure to pathologically-generated FN fragments may substantially alter cell behavior and regulation.     

Enzymic and immunochemical properties of lysozyme. XVI. A novel synthetic approach to an antigenic reactive site by direct linkage of the relevant conformationally adjacent residues constituting the site.

Previous studies from this laboratory on the immunochemistry of specific chemical derivatives of native lysozyme and of the two disulfide peptide 62-68 (Cys 64-Cys 80) 74-97 (Cys 76-Cys 94) (i.e. (SS)2-peptide), have established an antigenic reactive site to comprise the spatially contiguous surface residues: Trp 72, Lys 97, Lys 96, Asn 93, Thr 89 and Asp 87. In the present work, the identity of the site was verified by an entirely different and novel approach. The aforementioned amino acids were linked directly into a single linear peptide with an intervening spacer where appropriate and substituting phenylalanine for tryptophan (i.e. Phe-Gly-Lys-Asn-Thr-Asp). This peptide (which does not exist in native lysozyme but simulates a surface region of the protein) possessed a remarkable inhibitory activity towards the reaction of lysozyme with its antisera. The immunochemical reactivity of the peptide was equal to the maximum expected reactivity of the site (i.e. a third of the total antigenic reactivity of lysozyme). These findings define quite conclusively and accurately the reactive site which is clearly composed of spatially adjacent residues that are distant in sequence reacting as if in direct linear linkage. The unequivocal establishment of this concept indicates that antigenic sites need not always be composed of residues in direct peptide linkage in the sequence. The nature of the site may depend on the protein. This unorthodox attack at the problem provides a novel and powerful approach for final delineation of the antigenic reactive sites (and perhaps other types of binding sites) in native proteins, following the completion of accurate narrowing down by chemical methods.     

Changes in the state of tryptophan residues in T4 phage lysozyme during binding to a competitive inhibitor

The analysis of the intrinsic fluorescence parameters of T4 phage lysozyme in free state and in complex with inhibitor--disaccharide-tetrapeptide from the E. coli cell wall has been carried out. A comparison of the fluorescence changes with the results obtained by difference spectrophotometry and with the data of Elwell and Schellman on the intrinsic fluorescence of wild type WT and mutant eRI T4 phage lysozymes and a consideration of the three dimensional structure of the protein allows to represent the protein fluorescence parameters as a sum of contributions of the individual tryptophan residues. According to the proposed scheme Trp-126 does not emit neither in the free protein nor in the complex; the fluorescence parameters of Trp-158 (lambda m 332 nm, q = 0.27) are not affected by binding of the inhibitor, but all the fluorescence changes are due to the rise of the quantum yield (from 0.135 to 0.315) and the blue shift (from 332 to 328 nm) of the fluorescence of Trp-138.     

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].     

Studies on the biotin-binding sites of avidin and streptavidin. Tyrosine residues are involved in the binding site.

1. Rat pancreatic islets were isolated and then maintained in culture for 2-4 days before being incubated in groups of 100 in the presence of different glucose (0-20 mM) or CaCl2 (1.2-4.2 mM) concentrations, or with uncoupler. 2. Increases in extracellular glucose concentration resulted in increases in the amount of active, non-phosphorylated, pyruvate dehydrogenase in the islets, with half-maximal effects around 5-6 mM-glucose. Increasing extracellular glucose from 3 to 20 mM resulted in a 4-6-fold activation of pyruvate dehydrogenase within 2 min. 3. The total enzyme activity was unchanged, and averaged 0.4 m-unit/100 islets at 37 degrees C. 4. These changes in active pyruvate dehydrogenase were broadly similar to changes in insulin secretion by the islets. 5. Increasing extracellular Ca2+ or adding uncoupler also activated pyruvate dehydrogenase to a similar degree, but only the former was associated with increased insulin secretion.     

The action of lysozyme on peptidoglycan with N-unsubstituted glucosamine residues. Isolation of glycan fragments and their susceptibility to lysozyme.

1. A peptidoglycan preparation N-acetylated at about 30% of glucosamine residues was obtained by the treatment of the lysozyme-resistant cell wall paptidoglycan of Bacillus cereus with acetic anhydride at pH 7. Fractionation of dialyzable material resulting from lysozyme digestion of the glycan component of this peptidoglycan preparation yielded five oligosaccharides designated as S1 to S5 besides the disaccharide GlcNAc-MurAc. 2. Oligosaccharide S3, which accounted for about 30% of the disaccharide units recovered as disaccharides and oligosaccharides, was identified as GlcN-MurAc-GlcNAc-MurAc. Oligosaccharide S1, accounting for about 20% of the disaccharide units recovered, was characterized as GlcN-MurAc-GlcN-MurAc-GlcNAc-MurAc, while oligosaccharide S2, present in a smaller amount, as GlcNAc-MurAc-GlcN-MurAc-glcNAc-MurAc. Oligosaccharides S4, and S5, present in small amounts, were identified as GlcNAc-MurAc-GlcNAc-MurAc and MurAc-GlcNAc-MurAc, respectively. 3. Oligosaccharides S1, S3 and S5 proved to be completely insusceptible to lysozyme, whereas S2 was digsted by lysozyme to produce GlcNAc-MurAc and S3. S1 was found to act as a more potent inhibitor than S3 in lysozyme-catalyzed digestion of polysaccharides. 4. The results obtained show that the lysozyme-catalyzed hydrolysis of peptidoglycan oligosaccharides had an obligatory requirement for the N-acetyl group on the glucosamine residue located in subsite C in the enzyme-substrate complex.