Evidence for involvement of tryptophan residue in the low-affinity saccharide binding site of ricin D

The nature of the saccharide-binding site of ricin D, which is a galactose- and N-acetylgalactosamine-specific lectin, was studied by chemical modification and spectroscopy. With excitation at 290 nm, ricin D displayed a fluorescence spectrum with a maximum at 335 nm. Upon binding of the specific saccharides, the spectrum shifted to shorter wavelength by 3 nm. However, binding of galactosamine and N-acetylgalactosamine failed to induce such a change in the fluorescence spectrum. The interaction of ricin D with its specific saccharides was analyzed in terms of the variation of the intensity at 320 nm as a function of saccharide concentration. The results indicate that the change in the fluorescence spectrum induced by saccharide binding is attributable to the binding of saccharide to the low-affinity (LA-) binding site of ricin D. The cytoagglutinating activity of ricin D decreased to 2% upon modification of two tryptophan residues/mol with N-bromosuccinimide at pH 4.0, but in the presence of galactose or lactose one tryptophan residue/mol remained unmodified, and a fairly high cytoagglutinating activity was retained. Galactosamine and N-acetylgalactosamine did not show such a protective effect. Spectroscopic analyses indicate that the decrease in the cytoagglutinating activity of ricin D upon tryptophan modification is principally due to the loss of the saccharide binding activity of the LA-binding site. The results suggest that one tryptophan residue is essential for saccharide binding at the LA-binding site, which can bind galactose and lactose but lacks the ability to bind N-acetylgalactosamine and galactosamine.     

Identification of the tryptophan residue located in the calcium binding site of Trimeresurus flavoviridis phospholipase A2

When phospholipase A2 from the venom of Trimeresurus flavoviridis (the Habu snake) was oxidized with N-bromosuccinimide at pH 4.0, its activity decreased linearly with increase in the extent of oxidation of tryptophan residues. Oxidation of two of the four tryptophan residues caused an apparent loss of activity. The accessibilities of the tryptophan residues were analyzed with differently oxidized phospholipase A2 preparations and were determined to be in the following order: Trp-3 approximately Trp-30 greater than Trp-68 greater than Trp-108. The magnitude of the difference spectrum with a negative peak at 292 nm which is produced upon the binding of Ca2+ in the vicinity of tryptophan residue(s) decreased in a concave manner with increase in the extent of oxidation of tryptophan residues and was greatly diminished when 2 mol of tryptophan residues were oxidized. The activity and Ca2+-induced difference spectrum are thus related to either Trp-3 or Trp-30 or both. Des-octapeptide(1-8)-phospholipase A2 (L-fragment) is 14% as active as phospholipase A2 and is able to give a Ca2+-induced difference spectrum which is smaller than, but similar to, that of phospholipase A2. Its activity and the magnitude of the Ca2+-induced difference spectrum decreased along similar paths with increase in the amount of tryptophan residues oxidized, but in a manner indicating that two tryptophan residues are apparently responsible for the activity and the Ca2+-induced difference spectrum. The order of accessibility of the tryptophan residues of L-fragment was Trp-30 approximately Trp-108 greater than Trp-68. Trp-108, however, could be excluded from the residues located in the active site by reference to the tertiary structure of homologous Crotalus atrox phospholipase A2. Thus, Trp-30 is located in the Ca2+ binding site and is responsible for the activity of L-fragment. It is thus concluded that in phospholipase A2 Trp-30 is located in the Ca2+ binding site. From the concave decrease of relative magnitude of the Ca2+-induced difference spectrum and the linear decrease of relative activity upon oxidation of phospholipase A2, it may be assumed that both Trp-3 and Trp-30 are required to produce the Ca2+-induced difference spectrum, while only Trp-30 need be intact for activity. Anomalous binding of Ca2+ was observed for oxidized phospholipase A2.     

Chemical modification of dipeptidyl peptidase iv: involvement of an essential tryptophan residue at the substrate binding site

Inactivation of pig kidney dipeptidyl peptidase IV (EC 3.4.14.5) by photosensitization in the presence of methylene blue at pH 7.5 was observed to have pseudo-first-order kinetics. During the process, until over 95% inactivation was achieved, the histidine and tryptophan residues were decreased from 14.0 to 2.7 and 12.6 to 7.1, respectively, per 94,000-Da subunit, without any detectable changes in other photosensitive amino acids. Modification of four histidine residues per subunit using diethylpyrocarbonate resulted in only 30% inactivation of the enzyme, while N-bromosuccinimide almost completely inactivated the enzyme with the modification of only one tryptophan residue per subunit, as determined by absorption spectrophotometry at 280 nm. The protective action of the substrate and inhibitors such as Ala-Pro-Ala and Pro-Pro against the modification of tryptophan residues with N-bromosuccinimide was observed both fluorometrically and by measurement of activity. On the basis of these results it is suggested that one of the tryptophan residues in the enzyme subunit is essential for the functioning of the substrate binding site of pig kidney dipeptidyl peptidase IV.     

Evidence for one essential tryptophan residue at the active site of relaxin.

The hormone relaxin, which is responsible for the rapid widening of the birth channel in mammals prior to parturition, was purified from hog ovarian extracts and shown to be homogeneous by exclusion chromatography in 6 M guanidine hydrochloride and SDS gel electrophoresis. Of the two disulfide-linked chains that comprise relaxin, the larger chain was shown to contain two tryptophan residues, one of which could be completely oxidized in native relaxin without measurable effect on its biological activity. Oxidation of the second residue completely inactivated the hormone. Modifications of lysine side chains or carboxymethylation of a single methionine residue at low pH did not impair the effectiveness of relaxin.     

Tryptophan residue at the heparin binding site in antithrombin III

Chemical modifications have demonstrated that the ultraviolet difference spectrum produced when heparin interacts with antithrombin III is due primarily to changes in the tryptophan environment. This is based on the observation that this spectrum could be abolished by treatment of antithrombin III with dimethyl (2-hydroxy-5-nitrobenzyl) sulfonium bromide but not with tetranitromethane. The tryptophan-modified antithrombin III is still capable of binding to thrombin even when it has lost 85% of heparin cofactor activity. A marked decrease in reactivity of tryptophan residues is observed when modification is carried out in the presence of heparin. Evidence is presented that tryptophan is in the heparin binding site.     

Myelin basic protein binds heme at a specific site near the tryptophan residue

Fluorescence of the single tryptophan residue in myelin basic protein (MBP) was excited directly at 295 nm (red-edge excitation) or at 278 nm which allows, in addition, indirect excitation by resonance energy transfer (RET) from any nearby tyrosine residues. Both red-edge excitation and the RET pathway were collisionally quenched by I- and acrylamide, but not by Cs+ or Co2+, implying that the fluorophore is in an exposed, positively charged environment. The quenching coefficients (K) for I- are 12-15 M-1 at both excitation wavelengths while coefficients for acrylamide are 15 M-1 at 278-nm and 8 M-1 at 295-nm excitation. Chloroheme, cyanoheme, and protoporphyrin IX also quench both red-edge excitation and the RET pathway with apparent quenching coefficients which are (2-5) X 10(4)-fold higher. This suggests that the mechanism of quenching now includes static in addition to collisional processes and thus that heme has a relatively high affinity for MBP. Scatchard analysis of the quenching suggests that chloroheme binds to MBP at two sites with dissociation constants (Kd) of 1.6 X 10(-8) and 2.0 X 10(-7) M and stoichiometries of 0.04:1 and 0.16:1, respectively. The hydrophobic fluorescent probe 4,4'-bis[1-(phenylamino)-8-naphthalenesulfonate] [bis(ANS)] binds to MBP less avidly (Kd = 10(-7) M) and is rapidly displaced by chloroheme (Ki = 2 X 10(-8) M). The affinities of bis(ANS) and heme for MBP, along with the fluorescent amino acid quenching data, demonstrate that a subfraction of MBP molecules contain considerable structural specificity, implying stable long-range interactions in the molecule.(ABSTRACT TRUNCATED AT 250 WORDS)     

Identification of a cysteine residue as the binding site for the dipyrromethane cofactor at the active site of Escherichia coli porphobilinogen deaminase

The dipyrromethane cofactor of Escherichia coli porphobilinogen deaminase was specifically labelled with 13C by growth of the bacteria in the presence of 5-amino[5-13C]levulinic acid. Using 13C-NMR spectroscopy, the structure of the cofactor was confirmed as a dipyrromethane made up of two linked pyrrole rings each derived from porphobilinogen. The chemical shift data indicate that one of the pyrrole rings of the cofactor is covalently linked to the deaminase enzyme through a cysteine residue. Evidence from protein chemistry studies suggest that cysteine-242 is the covalent binding site for the cofactor.     

Studies on the tryptophan residues of soybean agglutinin. Involvement in saccharide binding

Modification of tryptophan side chains of soybean agglutinin (SBA) with N-bromosuccinimide results in a loss of the hemagglutinating and carbohydrate binding activities of the protein. One residue/subunit is probably essential for the binding activity. Modification leads to a large decrease in the fluorescene of the protein accompained by a blue shift. Iodide ion quenching of the protein fluorescence shows that saccharide binding results in a decreased accessibility of some of the tryptophan side chains. These results strongly point towards the involvement of tryptophan residues in the active site of SBA.Abbreviations SBA soybean agglutinin - NBS N-bromosuccinimide - dansyl N-dimethyl 5-amino-naphthalene 1-sulphonyl - GalNAc N-acetyl D-galactosamine     

A lysyl residue at the NADP binding site of ferredoxin-NADP reductase.

Dansyl chloride, at low molar ratio, inactivates ferredoxin-NADP reductase (NADPH:ferredoxin oxidoreductase, EC 1.6.7.1). The complete protection afforded either by NADP or NADPH suggests a direct involvement of the active site. Experiments with [Me-14C] dansyl chloride showed that about 1.5 residues per flavin were dansylated: by differential labelling experiments using NADP, it has been proved that enzyme inactivation is due to dansylation of one residue. The group modified has been identified as the epsilon-amino group of a lysine. The pH-inactivation profile indicates that this essential group has an apparent pKa of 8.7. The dansylated flavoprotein seems to maintain its native conformation; it shows a fluorescent chromophore with a peak at 335 nm. The modified enzyme has lost the capacity to form a complex with NADP, nevertheless it interacts normally with ferredoxin. It is concluded that the loss of catalytic activity which parallels the dansylation of a lysyl residue occurs because this residue is essential for the binding of the pyridine nucleotide substrate. Protection experiments with a series of coenzyme analogs further indicate that this lysyl residue interacts, most likely, with the 2'-phosphate moiety of NADP(H).     

Critical lysine residue at the chloride binding site of angiotensin converting enzyme

Pulmonary angiotensin converting enzyme has been reductively methylated by using formaldehyde and sodium cyanoborohydride. This modification virtually eliminates enzyme activity toward some substrates (e.g., furanacryloyl-Phe-Gly-Gly) while less drastically affecting activity toward others (e.g., furanacryloyl-Phe-Phe-Arg). Affinity chromatography and analysis of radiolabeled reaction products reveal that this effect is due to methylation of a single critical lysine residue. Loss of activity primarily represents an increase in Km values, indicating that the critical lysine plays a role in substrate binding. This lysine can be protected by a competitive inhibitor, suggesting that it is at or near the active site. Addition of chloride at pH 6.1 specifically protects against methylation of this lysine. These findings support the idea that the critical lysine is part of the binding site for chloride and other monovalent anions which are strong activators of the enzyme.     

Identification of the ricin lipase site and implication in cytotoxicity

Ricin is a heterodimeric plant toxin and the prototype of type II ribosome-inactivating proteins. Its B-chain is a lectin that enables cell binding. After endocytosis, the A-chain translocates through the membrane of intracellular compartments to reach the cytosol where its N-glycosidase activity inactivates ribosomes, thereby arresting protein synthesis. We here show that ricin possesses a functional lipase active site at the interface between the two subunits. It involves residues from both chains. Mutation to alanine of catalytic serine 221 on the A-chain abolished ricin lipase activity. Moreover, this mutation slowed down the A-chain translocation rate and inhibited toxicity by 35%. Lipase activity is therefore required for efficient ricin A-chain translocation and cytotoxicity. This conclusion was further supported by structural examination of type II ribosome-inactivating proteins that showed that this lipase site is present in toxic (ricin and abrin) but is altered in nontoxic (ebulin 1 and mistletoe lectin I) members of this family.     

An essential arginine residue at the substrate binding site of 4-hydroxyisophthalate hydroxylase

4-Hydroxyisophthalate hydroxylase was inactivated by treatment with phenylglyoxal by a process obeying pseudo-first order kinetics indicating the presence of an essential arginine located presumably in the active site. Addition of saturating amounts of 4-hydroxyisophthalate during the treatment resulted in complete protection of the enzyme from the inactivation, but addition of NADPH was totally ineffective. Analysis of the effect of various substrate analogs on the protection of the enzyme showed that carboxyl and hydroxyl groups at para positions on the aromatic ring are essential for substrate binding to the active site. It was also observed that analogs which protect the enzyme against phenylglyoxal inactivation are themselves effective inhibitors of the enzyme activity.     

An essential arginyl residue at the nucleotide binding site of creatine kinase.

Treatment of rabbit muscle creatine kinase (EC 2.4.3.2) with either butanedione in borate buffer or phenylglyoxal in Veronal buffer decreases enzymatic activity correlating with the modification of a single arginyl residue per subunit of the dimeric enzyme. Very little activity is lost when modification is performed in the presence of MgATP or MgADP. Nucleotide binding to the modified enzyme is virtually abolished as determined by ultraviolet difference spectroscopy. The data suggest that an arginyl residue plays an essential role in the enzymatic mechanism of creatine kinase, probably as a recognition site for the negatively charged oligophosphate moiety of the nucleotide.     

Extended binding site of ricin B lectin for oligosaccharide recognition

The plant lectin ricin B chain binds oligosaccharide with more affinity than the mono- or disaccharide ligands. The experiments indicated that a biantennary oligosaccharide could bind itself to any of the crystallographically established 1st or 2nd binding sites. After manual docking of either terminal galactose residues of the oligosaccharide in the 1st and 2nd binding sites of Ricin B and simulating the systems over nanosecond trajectories in implicit solvent, it was observed that the protein bound the oligosaccharide strongly through both its 1st and 2nd binding sites. Not only were the terminal galactose residues, several other residues of the oligosaccharide were involved in the binding scheme. Average gas phase energies were calculated molecular mechanically, solvation energies were calculated by Generalized Born model and the normal mode analysis was used to calculate the entropic contribution of binding. The entropy/enthalpy compensation has been observed for the protein-oligosaccharide interactions. The binding was found to be enthalpically favorable and compensating for the unfavorable entropic contribution. Comparison of the calculated free energy with the experimental data clearly suggests that binding is mono-dentate rather than bi-dentate through a single Gal-containing antenna.     

Assessing the role of tryptophan residues in the binding site

Instead of looking at the interfacial area as a measure of the extent of a protein--protein recognition site, a new procedure has been developed to identify the importance of a specific residue, namely tryptophan, in the binding process. Trp residues which contribute more towards the free energy of binding have their accessible surface area reduced, on complex formation, for both the main-chain and side-chain atoms, whereas for the less important residues the reduction is restricted only to the aromatic ring of the side chain. The two categories of residues are also distinguished by the presence or absence of hydrogen bonds involving the Trp residue in the complex. A comparison of the observed change in the accessible surface area with the value calculated using an analytical expression provides another way of characterizing the Trp residues critical for binding and this has been used to identify such residues involved in binding non-proteinaceous molecules in protein structures.     

Identification of three oligosaccharide binding sites in ricin.

The galactoside-binding sites of ricin B chain can be blocked by affinity-directed chemical modification using a reactive ligand derived from asialoglycopeptides containing triantennary N-linked oligosaccharides. The terminal galactosyl residue of one branch of the triantennary oligosaccharide is modified to contain a reactive dichlorotriazine moiety. Two separate galactoside-binding sites have been clearly established in the ricin B chain by X-ray crystallography [Rutenber, E., and Robertus, J. D. (1991) Proteins 10, 260-269], and it is necessary to covalently attach two such reactive ligands to the B chain to block its binding to galactoside affinity matrixes. A method was developed using thiol-specific labeling of the ligand combined with subsequent immunoaffinity chromatography which allowed the isolation of ricin B chain peptides covalently linked to the ligand from proteolytic digests of purified blocked ricin. The sites of covalent attachment of the two ligands in blocked ricin were inferred from sequence analysis to be Lys 62 in domain 1 of the B chain and Tyr 148 in domain 2. A minor species of blocked ricin contains a third covalently attached ligand. From the analysis of peptides derived from blocked ricin enriched in this species, it is inferred that Tyr 67 in domain 1 is the specific site on the ricin B chain where a third reactive ligand becomes covalently linked to the protein. These results are interpreted as providing support for the notion that the ricin B chain has three oligosaccharide binding sites.     

An essential arginine residue at the binding site of pig kidney 3,4-dihydroxyphenylalanine decarboxylase

Pig kidney 3,4-dihydroxyphenylalanine (Dopa) decarboxylase is inactivated by the arginine-specific reagent phenylglyoxal. Under these experimental conditions, the reaction follows pseudo-first-order kinetics with a second-order rate constant of 25 m-1 min-1. Holo- and apo-enzyme were inactivated at the same rate. However, inactivation seems to be related to modification of 1 and 2 arginyl residues per mol of holo- and apo-enzyme, respectively. Only one of these two residues was essential to decarboxylase activity of the enzyme. Phenylglyoxal-modified apo-Dopa decarboxylase retained the capacity to bind pyridoxal-P. Neither this reconstituted species nor the phenylglyoxal-modified holoenzyme were able to form Schiff base intermediates with aromatic amino acids in L and D forms. These data together with protection experiments suggest that the susceptible arginine residue in holoenzyme may somehow perturb the substrate binding site. However, unlike in other pyridoxal-P enzymes, this critical arginine in Dopa decarboxylase does not seem to behave as an anionic recognition site for the phosphate group of the coenzyme or the carboxy group of the substrate. It is speculated that this guanidyl group could function in hydrogen bonding of substrate side chain.