Proton magnetic resonance studies of ribonuclease T1. Assignment of histidine-40 peak and analysis of the active site.

Nuclear magnetic resonances of the C-2 protons of the three histidine residues in ribonuclease T₁ have been studied at 360 MHz as a function of pH to discuss the structure of the active site. Comparison of the order of deuterium exchange of the histidine peaks with tritium incorporation rates into individual histidines of the enzyme leads to the unambigous assignment of one of the C-2 proton peaks to histidne-40. It has been concluded that histidine-40 is in the active site, interacting with a charged group of pK 4.1, which is replaced by the phosphate group of guanosine-3′-monophosphate in the enzyme-inhibitor complex. Histidine-92 is most likely a binding site for the complex, where the existence of a hydrogen bond between N-7 of the inhibitor and the ring NH proton of the histidine is suggested on the basis of NMR data.     

Correlation proton magnetic resonance studies at 250 MHz of bovine pancreatic ribonuclease. I. Reinvestigation of the histidine peak assignments.

The deuterium exchange kinetics of the C(2) protons of the four histidine residues of native bovine pancreatic ribonuclease A have been followed at pH 6.5 and 8.0 by proton magnetic resonance spectroscopy (1H NMR). Comparison of the order of exchange of the histidine peaks with tritium exchange rates into individual histidine residues [Ohe, M., Matsuo, H., Sakiyama, F., and Narita, K. (1974), J. Biochem. (Tokyo) 75, 1197] supports the previous assignment of histidine NMR peaks H(1) and H(4) to histidine-105 and histidine-48 but requires reassignment of peaks H(2) and H(3) to histidine-119 and histidine-12, respectively. Ribonuclease A samples having differentially deuterated histidines have been used to verify the existence of crossover points in the histidine proton magnetic resonance titration curves and to observe the discontinuous titration curve of histidine-48. Proton magnetic resonance peaks have been assigned to the C(4) protons of the four histidine residues of ribonuclease A on the basis of their unit proton areas and by matching their titration shifts with the more readily visible C(2)-H peaks of the histidines. The pK' values derived from the C(4)-H data agree, within experimental limits, with those derived from C(2)-H data. The C(4)-H peaks were assigned to histidine-12, -48, -105, and -119 of ribonuclease A on the basis of their pH dependence, pK' values, shifts of their pK' values in the presence of inhibitor cytidine 3'-phosphate, and by comparison with the assignments of the histidine C(2)-H peaks above.     

Nuclear magnetic resonance studies of residual structure in thermally unfolded ribonuclease A.

A proton nuclear magnetic resonance study of the four histidine residues of thermally unfolded ribonuclease A has provided evidence that two of the residues are in regions of residual structure, whereas the other two are freely exposed to solvent. Histidine-48 and, tentatively, histidine-105 occupy an environment at 69 degrees characterized by residual structure and display a pK value of 5.75 and a spin-lattice relaxation time of about 0.8 sec at pH 5.5. Histidine-12 and, tentatively, histidine-119 are in an environment at 69 degrees which is freely accessible to solvent and show a pK value of 5.96 and a spin-lattice relaxation time of about 1.1 sec at pH 5.5.     

Identification of histidine-122alpha in human haemoglobin as one of the unknown alkaline Bohr groups by hydrogen--tritium exchange.

Human carbonmonoxy- and deoxy-haemoglobins were incubated at 37 degrees C in 3H2O at various pH values to measure the pH-dependent hydrogen--tritium exchange at the C-2 position of the imidazole ring of histidine-122alpha. To obtain the pseudo-first-order rate constants for the exchange, k, the two peptides containing histidine-122alpha were isolated and the amounts of tritium incorporated were determined. The rate constants gave pK values for the histidine of 6.1 in carbonmonoxyhaemoglobin and 6.6 in deoxyhaemoglobin, showing that it contributes about 20% to the total alkaline Bohr effect and about 10% at pH7.4.     

Zymogen activation in serine proteinases. Proton magnetic resonance pH titration studies of the two histidines of bovine chymotrypsinogen A and chymotrypsin Aalpha.

Reversible unfolding of bovine chymotrypsinogen A in 2H2O either by heating at low pH or by exposure to 6 M guanidinium chloride results in the exchange of virtually all the nitrogen-bound hydrogens that give rise to low-field 1H NMR peaks, without significant exchange of the histidyl ring Cepsilon1 hydrogens. These preexchange procedures have enabled the resolution of two peaks, using 250-MHz correlation 1H NMR spectroscopy, that are attributed to the two histidyl residues of chymotrypsinogen A. Assignments of the Cepsilon1 hydrogen peaks to histidine-40 and -57 were based on comparison of the NMR titration curves of the native zymogen with those of the diisopropylphosphoryl derivative. Two histidyl Cepsilon1 H peaks were also resolved with solutions of preexchanged chymotrypsin Aalpha. The histidyl peaks of chymotrypsin Aalpha were assigned by comparison of NMR titration curves of the free enzyme with those of its complex with bovine pancreatic trypsin inhibitor (Kunitz). The NMR titration curves of histidine-57 in the zymogen and enzyme and histidine-40 in the zymogen exhibit two inflections; the additional inflections were assigned to interactions with neighboring carboxyl groups: aspartate-102 in the case of histidine-57 and aspartate-194 in the case of histidine-40 of the zymogen. In bovine chymotrypsinogen A in 2H2O at 31 degrees C, histidine-57 has a pK' of 7.3 and aspartate-102 a pK' of 1.4, and the histidine-40-aspartate-194 system exhibits inflections at pH 4.6 and 2.3. In bovine chymotrypsin Aalpha under the same conditions, the histidine-57-aspartate-102 system has pK' values of 6.1 and 2.8, and histidine-40 has a pK' of 7.2. The results suggest that the pK' of histidine-57 is higher than the pK' of aspartate-102 in both zymogen and enzyme. A significant difference exists in the structure and properties of the catalytic center between the zymogen and activated enzyme. In addition to the difference in pK' values, the chemical shift of histidine-57, which is highly abnormal in the zymogen (deshielded by 0.6 ppm), becomes normalized upon activation. These changes may explain part of the increase in the catalytic activity upon activation. The 1H NMR chemical shift of the Cepsilon1 H of histidine-57 in the chymotrypsin Aalpha-pancreatic trypsin inhibitor (Kunitz) complex is constant between pH 3 and 9 at a value similar to that of histidine-57 in the porcine trypsin-pancreatic trypsin inhibitor complex [Markley, J.L., and Porubcan, M. A. (1976), J. Mol. Biol. 102, 487--509], suggesting that the mechanisms of interaction are similar in the two complexes.     

Haem ligands of the ferricytochrome c of Ustilago sphaerogena

The mammalian-type cytochrome c of the basidiomycete Ustilago sphaerogena contains in a single polypeptide chain of 107 residues, two histidine residues located at positions 18 and 33, and one methionine residue situated at position 80 (Bitar et al., 1972). The reaction of Ustilago ferricytochrome c with bromoacetate at neutral pH resulted in the modification of histidine-33, but not of histidine-18 or of the invariant methionine residue. The activities of Ustilago cytochrome c with mitochondrial cytochrome c oxidase and with NADH-cytochrome c reductase were unaltered by the modification. The equilibrium constants for the formation of low-spin complexes of the ferrihaem octapeptide of horse cytochrome c (residues 14-21, including the haem bound covalently to cysteines 14 and 17) with imidazole, N(2)-acetylhistidine and monocarboxymethyl derivatives of N(2)-acetylhistidine were determined spectrophotometrically. Alkylation of the imidazole side-chain group of N(2)-acetylhistidine resulted in a marked decrease in its ability to form low-spin ferrihaem complexes. These results indicate that in Ustilago ferricytochrome c in solution histidine-33 is not involved in the central co-ordination complex. Since side-chain groups of residues other than histidine and methionine do not appear to be involved in the central complexes of other mammalian-type cytochromes c (Hettinger & Harbury, 1964, 1965; Myer & Harbury, 1965) it is likely that in Ustilago ferricytochrome c in solution at neutral pH, the side-chain groups of histidine-18 and methionine-80 are involved in the central co-ordination complex. The latter is stable over the pH range 2.6-8.4.     

Correlation proton magnetic resonance studies at 250 MHz of bovine pancreatic ribonuclease. II. pH and inhibitor-induced conformational transitions affecting histidine-48 and one tyrosine residue of ribonuclease A.

The microenvironment of histidine-48 of bovine pancreatic ribonuclease A was investigated by proton magnetic resonance spectroscopy (1H NMR) using partially deuterated enzyme in which resolution of the C(2)-H resonance of histidine-48 was simplified. The NMR titration curves at 100 and 250 MHz of histidine-48 of ribonuclease A are discontinuous both for the enzyme alone in 0.3 M chloride and for its complex with cytidine 3'-phosphate. This suggests that titration of histidine-48 occurs only as the result of a slow conformational transition. The sum of the peaks corresponding to histidine-48 in the acid-stable and base-stable forms of the enzyme is less than one proton in the transition region, which indicates that there exists at least one intermediate conformational form of the enzyme. The transition from the acid-stable form to an intermediate form has a pHmid of 5.6, and the transition from an intermediate form to the base-stable form has a pHmid of 6.9. In ribonuclease S and in ribonuclease A in the presence of 0.3 M acetate, the titration curve of histidine-48 is continuous, and the area of the peak is uniform throughout the titration. Proton NMR difference spectra at 100 and 250 MHz reveal a pH-induced conformational change with a pHmid of 5.7 that affects the chemical shift of a single tyrosine residue. This conformational transition is absent in ribonuclease S and is altered in ribonuclease A by the presence of either acetate or cytidine 3'-monophosphate. It is postulated that the same conformational transition is responsible for both the tyrosine perturbation and the disappearance of the histidine-48 peak observed in the acid-stable form of the enzyme. It is proposed that the perturbed tyrosine is tyrosine-25. The transition with pHmid 5.6 is attributed to dissociation of aspartic acid-14, and the transition with pHmid 6.9 is assigned to dissociation of histidine-48. A peak in the aromatic region that moves upfield on addition of the competitive inhibitor cytidine 3'-monophosphate is assigned to a tyrosine, and evidence is presented that this tyrosine is tyrosine-25. Inhibitor binding appears to induce a conformational change in the histidine-48/tyrosine-25 region which is remote from the active site.     

Interaction of apocytochrome c and derived polypeptide fragments with sodium dodecyl sulfate micelles monitored by photochemically induced dynamic nuclear polarization 1H NMR and fluorescence spectroscopy.

The topology of apocytochrome c, the heme-free precursor of the mitochondrial protein cytochrome c, was investigated in a lipid-associated form. For this purpose photochemically induced dynamic nuclear polarization 1H nuclear magnetic resonance (CIDNP 1H NMR) spectroscopy and quenching of tryptophan and tyrosine fluorescence by acrylamide were applied to an apocytochrome c-sodium dodecyl sulfate (SDS) micellar system. A pH titration of the chemical shifts of the histidine C2 proton resonances of apocytochrome c, using conventional 1H NMR, yielded pK(a)'s of 5.9 +/- 0.1 and 6.2 +/- 0.1, which were assigned to histidine-18 and -33 and histidine-26, respectively. In the presence of SDS micelles an average pK(a) of 8.1 +/- 0.1 was obtained for all histidine C2 protons. Photo-CIDNP enhancements of the histidine, tryptophan, and tyrosine residues, contained in the intact apocytochrome c and in chemically and enzymatically prepared fragments of the precursor, were reduced in the presence of SDS micelles. Similarly, the quenching of the tryptophan fluorescence of the polypeptides by acrylamide was diminished in the presence of SDS. These results indicate the aromatic residues studied are localized in the interface of the SDS micelle.     

A proton-nuclear-magnetic-resonance study of human somatotropin (growth hormone). Assignment and properties of the histidine residues.

The 1H-n.m.r. spectra of human somatotropin (growth hormone) show perturbed peaks from individual aromatic and aliphatic apolar residues, characteristic of a specifically folded globular structure. The imidazole C-2-H resonances of the histidine residues (at positions 18, 21 and 151 in the somatotropin sequence) were individually resolved, and their titration behaviour in the pH range 1.2-11.5 was investigated. The imidazole C-2-H resonance of histidine-151 is assigned, by comparison of its titration behaviour in human somatotropin and desamido-somatotropin (Asn-152 leads to Asp-152). The C-2-H resonances of all three histidine residues are assigned, by comparison of their relative deuterium-exchange rates (determined by n.m.r.) and the relative tritium-exchange rates of the histidine residues (determined by tryptic digestion of tritiated human somatotropin and reversed-phase high-pressure liquid-chromatographic separation of the histidine-containing tryptic peptides). There is evidence that histidine-18 forms an ion-pair bond with a glutamic acid or aspartic acid residue. The globular structure does not appear to change from pH3 to 11.5, though there is evidence for an unfolding of a region of the structure (involving histidine-21 and a tyrosine residue) below pH3.     

Oxidation of the active site of glutamine synthetase: conversion of arginine-344 to gamma-glutamyl semialdehyde.

Metal-catalyzed oxidative modification of proteins is implicated in a number of physiologic and pathologic processes. The reaction is presumed to proceed via a site-specific free radical mechanism, with the site-specificity conferred by a cation-binding site on the protein. The oxidation of bacterial glutamine synthetase has been studied in detail, providing the opportunity to examine whether the oxidation is consistent with a site-specific radical reaction. Oxidation leads to the appearance of carbonyl groups in amino acid side chains of the protein, and labeling of those carbonyl groups with fluorescein-amine facilitated purification of the oxidized peptide from a tryptic digest. The oxidized residue was arginine-344, which was converted to a gamma-glutamyl semialdehyde residue. Histidine-269 had previously been shown to be converted to asparagine during metal-catalyzed oxidation. Both arginine-344 and histidine-269 are situated at the metal-nucleotide binding pocket of the enzyme's active site, thus establishing the site-specificity of the oxidation.     

Proton-magnetic-resonance studies of the lysine residues of ribonuclease A.

The amino groups of ribonuclease A (RNase-A) have been methylated with formaldehyde and borohydride to provide observable resonances for proton magnetic resonance (PMR) studies. Although enzymatic activity is lost, PMR difference spectroscopy and PMR studies of thermal denaturation show native conformation is largely preserved in methylated RNase-A. Resonances corresponding to the NH2-terminal alpha-amino and 10 xi-amino N-methyl groups are titrated at 220 MHz to obtain pK values. After correction for the effects of methylation, using values previously derived from model compound studies, a pK of 6.6 is found for the alpha-amino group, a pK of 8.6 for the xi-amino group of lysine-41 and pK values ranging from 10.6 to 11.2 for the other lysine xi-amino groups. Interactions between lysine-7 and lysine-41 or between the alpha-amino and xi-amino groups of lysine-1 have been proposed to account for deviations from simple titration behaviour. The correct continuities for the titration curves of the histidine H-2 proton resonances have been confirmed by selective deuteration of the H-2 protons. Titration curves for the H-2 proton resonances of histidine-12 and histidine-119 of methylated RNase-A show deviations from the titration curves for the native enzyme, indicating some alteration of the active-site conformation. In the presence of phosphate, titration curves for the H-2 proton resonances of histidine-12 and histidine-119 of methylated RNase-A indicate binding of phosphate at the active site, but these curves continue to show deviations from the titration behaviour of native RNase-A. The titration curve for the N-methyl resonance of lysine-41 is perturbed considerably by the presence of phosphate, which indicates a possible catalytic role for lysine-41.     

A 13C-n.m.r. investigation of ionizations within a trypsin-inhibitor complex. Evidence that the pKa of histidine-57 is raised by interaction with the hemiketal oxyanion.

The 13C-n.m.r. titration shifts of the alpha-methylene group of N-alkylated imidazoles are shown to be a sensitive probe of the ionization of the imidazolium ion. The 13C-n.m.r. titration shifts of both the intact and denatured/autolysed 2-13C- and 1-13C-enriched trypsin-7-amino-3-benzyloxycarbonylamino-1-chloroheptan-2-one (Z-Lys-CH2Cl) complexes are compared. The titration shift for the denatured/autolysed complex confirms that this ionization is due to deprotonation of the N-alkylated imidazolium ring of histidine-57. In the intact trypsin-inhibitor complex the titration shift due to the 1-13C-enriched carbon is anomalous. We conclude that this titration shift cannot arise solely from the ionization of the imidazolium ion of histidine-57 and that the pKa of the imidazolium ion of histidine-57 is raised in the trypsin-inhibitor complex. The relevance of these studies to the mechanism of action of the serine proteinases is discussed.     

Proton-magnetic-resonance spectroscopic study of the histidine residues of bovine alpha-lactalbumin.

A study of the three histidine residues of bovine alpha-lactalbumin has been made using proton magnetic resonance (PMR) spectroscopy in order to obtain information on their environments in the protein and thereby to test in part the previously proposed structure. PMR titration curves are obtained for the H-4 resonances using difference spectroscopy and for the H-2 resonances and the 1-H-2-H exchange rates of the H-2 protons have been measured. The assignment of resonances to particular histidine residues is achieved by utilising their selective reaction with iodoacetate in conjunction with a PMR study of the carboxymethylation of alpha-N-acetyl-L-histidine. The H-2 and H-4 resonances labelled 1, 2 and 3 starting from the downfield end of the spectrum are assigned to histidine residues 107, 68 and 32 respectively. Their apparent pK values at low ionic strength and 20 degrees C are 5.78, 6.49 and 6.51 respectively. The experimental results on two histidine residues are consistent with the predictions of the proposed structure, which indicate that histidine-68 is an external residue and histidine-32 is partially buried and in the vicinity of aromatic residues. The experimental data on histidine 107 can also be rationalised with less certainty in terms of the proposed structure, which indicates a partially buried residue that may be involved in hydrogen bonding.     

Intramolecular photoredox reactions in iron(III) cytochrome c and its azide derivative

The irradiation of deaerated solutions of horse heart cytochrome c causes the reduction of Fe(III) to Fe(II). The dependence of the photoreaction quantum yield on pH shows that the photoreactive species is a form of cytochrome c which contains methionine-80 and histidine-18 as heme ligands. The primary photochemical event consists of an electron transfer from the sulphur of methionine- 80 to iron. The re-oxidation of the photochemically obtained Fe(II) protein gives a Fe(III) cytochrome which exhibits a typical low-spin absorption spectrum, lacking the 695-nm band and indicating that a strong field ligand, other than methionine-80, coordinates to the sixth binding site of the heme iron. Spectrophotometric titration of the photochemically modified Fe(III) cytochrome shows that histidine- 18 remains bound in the fifth position.The substitution of methionine-80 with the more oxidizable azide ligand increases the efficiency of the intramolecular electron transfer. Azide radicals, detected by spin-trapping ESR technique, are formed in the primary act. Visible-UV spectral data indicate that histidine-18 and methionine-80 occupy the fifth and sixth position, respectively, in the photoreaction product. All the results obtained correlate well with those previously obtained in investigations concerning the photoredox behavior of iron porphyrin complexes.     

(S)-Mandelate dehydrogenase from Pseudomonas putida: mutations of the catalytic base histidine-274 and chemical rescue of activity.

(S)-Mandelate dehydrogenase from Pseudomonas putida, an FMN-dependent alpha-hydroxy acid dehydrogenase, oxidizes (S)-mandelate to benzoylformate. The generally accepted catalytic mechanism for this enzyme involves the formation of a carbanion intermediate. Histidine-274 has been proposed to be the active-site base that abstracts the substrate alpha-proton to generate the carbanion. Histidine-274 was altered to glycine, alanine, and asparagine. All three mutants were completely inactive. The mutants were able to form adducts with sulfite, though with much weaker affinity than the wild-type enzyme. Binding of the inhibitor, (R)-mandelate, was not greatly affected by the mutation, unlike that of the substrate, (S)-mandelate, indicating that H274 plays a role in substrate binding. The activity of H274G and, to a lesser extent, H274A could be partially restored by the addition of exogenous imidazoles. The maximum rescued activity for H274G with imidazole was approximately 0.1% of the wild-type value. Saturation kinetics obtained for rescued activity suggest that formation of a ternary complex of imidazole, enzyme, and substrate is required for catalysis. pH-dependence studies confirm that the free base form of imidazole is the rescue agent. An earlier study of pH profiles of the wild-type enzyme indicated that deprotonation of a residue with a pK(a) of 5.5 in the free enzyme was essential for activity (Lehoux, I. E., and Mitra, B. (1999) Biochemistry 38, 5836-5848). Data obtained in this work confirm that the pK(a) of 5.5 belongs to histidine-274.     

Identification of active-site histidine residues of a self-incompatibility ribonuclease from a wild tomato.

The style component of the self-incompatibility (S) locus of the wild tomato Lycopersicon peruvianum (L.) Mill. is an allelic series of glycoproteins with ribonuclease activity (S-RNases). Treatment of the S3-RNase from L. peruvianum with iodoacetate at pH 6.1 led to a loss of RNase activity. In the presence of a competitive inhibitor, guanosine 3'-monophosphate (3'-GMP), the rate of RNase inactivation by iodoacetate was reduced significantly. Analysis of the tryptic digestion products of the iodoacetate-modified S-RNase by reversed-phase high-performance liquid chromatography and electrospray-ionization mass spectrometry showed that histidine-32 was preferentially modified in the absence of 3'-GMP. Histidine-88 was also modified, but this occurred both in the presence and absence of 3'-GMP, suggesting that this residue is accessible when 3'-GMP is in the active site. Cysteine-150 was modified by iodoacetate in the absence of 3'-GMP and, to a lesser extent, in its presence. The results are discussed with respect to the related fungal RNase T2 family and the mechanism of S-RNase action.     

Reaction of bromoacetazolamide with crystals of human carbonic anhydrase C

Crystals of human carbonic anhydrase C were reacted with [¹⁴C] bromoacetazolamide and an alkylation was found to occur at the 3′-nitrogen of histidine-64, which is known to be located in the active site region. This reaction requires that the bromomethyl group of the reagent move from its initial binding position, phenylalanine-129, within bonding distance of histidine-64 without significantly disturbing the interaction of the sulfonamide moiety with the active site zinc ion. Since the same histidine has been found previously to react with bromoacetazolamide when the enzyme was in solution, it can be concluded that the conformation of the active site histidine is the same in the two states.     

Correlation proton magnetic resonance studies at 250 MHz of bovine pancreatic ribonuclease. III. Mutual electrostatic interaction between histidine residues 12 and 119.

The two adjacent active site histidine residues of bovine pancreatic ribonuclease A (histidine-12 and -119) yield proton magnetic resonance titration curves having Hill coefficients significantly less than unity (0.7 and 0.8, respectively). Three models postulating interactions with other titrating groups in the molecule have been used to approximate these anomalous experimental titration curves. Very good agreement with the data was obtained with models postulating mutual electrostatic interaction between histidine-12 and -119. The additional low pH perturbation of the chemical shift of the C(2)-H peak (but not the C(4)-H peak) of histidine-12 is attributed to a local conformational change with a pHmid of about 3.5.     

Nuclear magnetic resonance titration curves of histidine ring protons. A direct assignment of the resonances of the active site histidine residues of ribonuclease.

One of the four titrating histidine ring C-2 proton resonances of bovine pancreatic ribonuclease has been assigned to histidine residue 12. This was accomplished by a direct comparison of the rate of tritium incorporation into position C-2 of histidine 12 of S-peptide (residues 1 to 20) derived from ribonuclease S, with the rates of deuterium exchange of the four histidine C-2 proton resonances of ribonuclease S under the same experimental conditions. The same assignment was obtained by a comparison of the NMR titration curves of ribonuclease S, the noncovalent complex of S-peptide and S-protein (residues 21 to 124) with the results for the recombined complex in which position C-2 of histidine 12 was fully deuterated. The second active site histidine resonance was assigned to histidine residue 119 by consideration of the NMR titration results fro carboxymethylated histidines and 1-carboxymethylhistidine 119 ribonuclease. This assignment is a reversal of that originally reported, and has important implications for the interpretation of NMR titration data of ribonuclease.     

Protein hydrogen exchange studied by the fragment separation method

The potential of hydrogen-exchange studies for providing detailed information on protein structure and structural dynamics has not yet been realized, largely because of the continuing inability to correlate measured exchange behavior with the parts of a protein that generate that behavior. J. Rosa and F. M. Richards (1979, J. Mol. Biol. 133, 399-416) pioneered a promising approach to this problem in which tritium label at exchangeable proton sites can be located by fragmenting the protein, separating the fragments, and measuring the label carried by each fragment. However, severe losses of tritium label during the fragment separation steps have so far rendered the results ambiguous. This paper describes methods that minimize losses of tritium label during the fragment separation steps and correct for losses that do occur so that the label can be unambiguously located and even quantified. Steps that promote adequate fragment isolation are also described.