Proton nuclear magnetic resonance study of the electronic and molecular structure of the heme crevice in horseradish peroxidase

Assignment of the 1H NMR resonances of protein residues in close proximity to the heme of the nitrophorins: similarities and differences among the four proteins from the saliva of the adult blood-sucking insect Rhodnius prolixus

The nuclear Overhauser effects (NOEs) observed between heme substituent protons and a small number of nearby protein side chain protons in the water-elimination Fourier transform NOE spectroscopy (WEFT-NOESY) spectra of high- and low-spin wild-type nitrophorin (NP) 2 and its ligand complexes have been analyzed and compared with those observed for the same complexes of wild-type NP3. These assignments were made on naturally abundant isotope samples, with the most useful protein side chains being those of Ile120, Leu122, and Leu132 for NP2 and NP3, and Thr121, Leu123, and Leu133 for NP1 and NP4. It is found that the NOEs observed are identical, with extremely similar protein side chain proton chemical shifts. This is strong evidence that the structure of NP3, for which no X-ray crystal structures are available, is essentially identical to that of NP2, at least near the heme binding pocket. Similarly, the NOEs observed between heme substituents and protein side chains for NP1 and NP4 also indicate that the structures of the protein having both A and B heme orientations are very similar to each other, as well as to the proteins with major B heme orientation of NP2 and NP3. These A and B connectivities can be seen, even though the two heme orientations have similar populations in NP1 and NP4, which complicates the analysis of the NOESY spectra. The histamine complex of wild-type NP2 shows significant shifts of the Leu132 side chain protons relative to all other ligand complexes of NP1-NP4 because of the perturbation of the structure near Leu132 caused by the histamine's side chain ammonium hydrogen bond to the Asp29 side chain carboxylate.

Variation and analysis of second-sphere interactions and axial histidinate character in c-type cytochromes

The electron-donating properties of the axial His ligand to heme iron in cytochromes c (cyts c) are found to be correlated with the midpoint reduction potential (E(m)) in variants of Hydrogenobacter thermophilus cytochrome c(552) (Ht cyt c(552)) in which mutations have been made in and near the Cys-X-X-Cys-His (CXXCH) heme-binding motif. To probe the strength of the His-Fe(III) interaction, we have measured (13)C nuclear magnetic resonance (NMR) chemical shifts for (13)CN(-) bound to heme iron trans to the axial His in Ht Fe(III) cyt c(552) variants. We observe a linear relationship between these (13)C chemical shifts and E(m), indicating that the His-Fe(III) bond strength correlates with E(m). To probe a conserved hydrogen bonding interaction between the axial His Hdelta1 and the backbone carbonyl of a Pro residue, we measured the pK(a) of the axial His Hdelta1 proton (pK(a(2))), which we propose to relate to the His-Fe(III) interaction, reduction potential, and local electrostatic effects. The observed linear relationship between the axial His (13)Cbeta chemical shift and E(m) is proposed to reflect histidinate (anionic) character of the ligand. A linear relationship also is seen between the average heme methyl (1)H chemical shift and E(m) which may reflect variation in axial His electron-donating properties or in the ruffling distortion of the heme plane. In summary, chemical shifts of the axial His and exogenous CN(-) bound trans to His are shown to be sensitive probes of the His-Fe(III) interaction in variants of Ht cyt c(552) and display trends that correlate with E(m).

The endogenous calcium ions of horseradish peroxidase C are required to maintain the functional nonplanarity of the heme

Horseradish peroxidase C (HRPC) binds 2 mol calcium per mol of enzyme with binding sites located distal and proximal to the heme group. The effect of calcium depletion on the conformation of the heme was investigated by combining polarized resonance Raman dispersion spectroscopy with normal coordinate structural decomposition analysis of the hemes extracted from models of Ca(2+)-bound and Ca(2+)-depleted HRPC generated and equilibrated using molecular dynamics simulations. Results show that calcium removal causes reorientation of heme pocket residues. We propose that these rearrangements significantly affect both the in-plane and out-of-plane deformations of the heme. Analysis of the experimental depolarization ratios are clearly consistent with increased B(1g)- and B(2g)-type distortions in the Ca(2+)-depleted species while the normal coordinate structural decomposition results are indicative of increased planarity for the heme of Ca(2+)-depleted HRPC and of significant changes in the relative contributions of three of the six lowest frequency deformations. Most noteworthy is the decrease of the strong saddling deformation that is typical of all peroxidases, and an increase in ruffling. Our results confirm previous work proposing that calcium is required to maintain the structural integrity of the heme in that we show that the preferred geometry for catalysis is lost upon calcium depletion.

Detection of a tryptophan radical as an intermediate species in the reaction of horseradish peroxidase mutant (Phe-221 --> Trp) and hydrogen peroxide

The crucial reaction intermediate in the reaction of peroxidase with hydrogen peroxide (H2O2), compound I, contains a porphyrin pi-cation radical in horseradish peroxidase (HRP), which catalyzes oxidation of small organic and inorganic compounds, whereas cytochrome c peroxidase (CcP) has a radical center on the tryptophan residue (Trp-191) and oxidizes the redox partner, cytochrome c. To investigate the roles of the amino acid residue near the heme active center in discriminating the function of the peroxidases in these two enzymes, we prepared a CcP-like HRP mutant, F221W (Phe-221 --> Trp). Although the rapid spectral scanning and stopped-flow experiments confirmed that the F221W mutant reacts with H2O2 to form the porphyrin pi-cation radical at the same rate as for the wild-type enzyme, the characteristic spectral features of the porphyrin pi-cation radical disappeared rapidly, and were converted to the compound II-type spectrum. The EPR spectrum of the resultant species produced by reduction of the porphyrin pi-cation radical, however, was quite different from that of compound II in HRP, showing typical signals from a Trp radical as found for CcP. The sequential radical formation from the porphyrin ring to the Trp residue implies that the proximal Trp is a key residue in the process of the radical transfer from the porphyrin ring, which differentiates the function of peroxidases.

Binding of iodide to Arthromyces ramosus peroxidase investigated with X-ray crystallographic analysis, 1H and 127I NMR spectroscopy, and steady-state kinetics

The site and characteristics of iodide binding to Arthromyces ramosus peroxidase were examined by x-ray crystallographic analysis, 1H and 127I NMR, and kinetic studies. X-ray analysis of an A. ramosus peroxidase crystal soaked in a KI solution at pH 5.5 showed that a single iodide ion is located at the entrance of the access channel to the distal side of the heme and lies between the two peptide segments, Phe90-Pro91-Ala92 and Ser151-Leu152-Ile153, 12.8 A from the heme iron. The distances between the iodide ion and heme peripheral methyl groups were all more than 10 A. The findings agree with the results obtained with 1H NMR in which the chemical shift and intensity of the methyl groups in the hyperfine shift region of A. ramosus peroxidase were hardly affected by the addition of iodide, unlike the case of horseradish peroxidase. Moreover, 127I NMR and steady-state kinetics showed that the binding of iodide depends on protonation of an amino acid residue with a pKa of about 5.3, which presumably is the distal histidine (His56), 7.8 A away from the iodide ion. The mechanism of electron transfer from the iodide ion to the heme iron is discussed on the basis of these findings.

Catalytic roles of the distal site asparagine-histidine couple in peroxidases

There are highly conserved hydrogen bonds between the distal His and the adjacent Asn in many peroxidases. Although the crystal structure of horseradish peroxidase C (HRP) is not available, comparison of the amino acid sequence with cytochrome c peroxidase indicates that Asn70 is making the hydrogen bond with the distal His in the active site of HRP. To investigate the catalytic roles of the hydrogen bond, Asn70 in HRP was replaced with Val (N70V) or Asp (N70D). Though UV-vis, CD, and 1H-NMR spectra of native (plant enzyme), wild-type (recombinant enzyme), and mutant HRPs suggest that the active site and secondary structure are very similar even after mutation, the mutants exhibit low Vmax values for the hydroquinone oxidation (native, 281; wild-type, 283; and N70V, 18; and N70D, 33 microM.min-1). The rates of compound I formation were decreased to less than 10% of that of the native enzyme. The reduction rates of compounds I and II by guaiacol also were reduced to less than 10% of that of the native enzyme. Substituent effects of various phenol derivatives on the reduction of native, wild-type, and mutant compound I were examined. Large negative Hammett rho values (rho N70V:fast = -4.0, rho N70V:slow = -3.6, rho N70D = -3.8, rho native = -6.9, and rho wild-type = -6.8) are an indication of electron transfer being the rate-determining step in the phenol oxidation. However, these results also indicate the participation of the deprotonation step in the compound I reduction process. The proton abstraction from phenol must be harder for the mutants due to the decrease of basicity of the distal His upon mutation. Contrary to phenol oxidation, ABTS [2,2'-azinobis(3-ethybenzothiazoline-6-sulfonic acid)] oxidation activity was substantially increased by the mutations (native, 73; wild-type, 71; N70V, 217; and N70D, 234 microM.s-1). The redox potentials of N70V and N70D compounds II are 957 and 970 mV (vs NHE), which are 95 and 108 mV higher than that of native compound II (862 mV), respectively. Therefore, the high ABTS oxidation activities of mutants are attributed to these high redox potentials of compound II.

Baculovirus expression and characterization of catalytically active horseradish peroxidase

Studies of horseradish peroxidase (HRP), a prototypical enzyme, have provided much of the information that is available on the mechanisms and functions of hemoprotein peroxidases. HRP itself is widely used in biotechnological applications. Further progress in defining the structure and function of the enzyme, however, requires its expression in a heterologous system. We report here baculovirus-mediated, high yield expression of a synthetic gene for HRP in Spodoptera frugiperda cell culture. Expression of the soluble, glycosylated protein requires the 5'-leader sequence of the native gene. Recombinant horseradish peroxidase reacts with H2O2 to give compound I, II, and III spectra and a guaiacol oxidation activity, identical to those of the native enzyme. The integrity of the recombinant active site is confirmed by NMR spectroscopy and by catalytic reaction with ethylhydrazine to give a stabilized isoporphyrin that decays exclusively to delta-meso-ethylheme. Furthermore, thioanisoles are oxidized by recombinant and native HRP with the same enantiomeric specificity. HRP expressed in a baculovirus system, despite probable differences in glycosylation, is essentially identical to the native enzyme.

1H NMR studies of Chromatium vinosum cytochrome c'

The cytochrome c' from Chromatium vinosum has been studied through 1H NMR in the pH range 4-11 in both the oxidized and the reduced forms. The 1H NMR spectra are similar to those of the other cytochrome c' systems. Three pKa values of 5.1, 7.0, and 9.2 have been observed for the oxidized species and tentatively assigned to the two carboxylate propionic residues of the heme moiety and to the iron-coordinated histidine 125, respectively. The spectra are consistent with an essentially S = 5/2 state in all the pH ranges investigated. Some evidence is provided for conformational flexibilities. Among the oxidized cytochromes c' the present one is capable of binding cyanide, giving rise to a low spin state. The reduced species is a typical high spin iron(II) system.

Two-dimensional 1H-NMR studies of horseradish peroxidase C and its interaction with indole-3-propionic acid

The binding of aromatic donor molecules to plant peroxidases has been investigated by examining the complex formed between horseradish peroxidase isoenzyme C and indole-3-propionic acid using two-dimensional 1H-NMR spectroscopy. Despite the relatively high molecular mass and paramagnetism of the protein, this technique can be successfully applied to provide new information on the structure of the complex. A number of relatively well-resolved resonances in certain regions of the one-dimensional spectrum are assigned to amino acid type on the basis of the two-dimensional experiments. Two phenylalanine side chains are found to interact at positions close to the haem group as shown by nuclear Overhauser effect spectroscopy (NOESY). Furthermore, the NOESY spectrum of the complex reveals distinct interactions between these phenylalanine residues and the indole ring of the donor molecule. The binding site is found to comprise of these phenylalanine side chains and also the methyl group of a leucine or valine residue. On the basis of the model structure of horseradish peroxidase isoenzyme C proposed by Welinder and Nørskov-Lauritsen and information from previous studies of the related turnip peroxidases, possible locations for this binding site are discussed. The NMR methods adopted here may be generally applicable to the study of peroxidase--aromatic-donor interactions.

Magnetic resonance spectral characterization of the heme active site of Coprinus cinereus peroxidase

Examination of the peroxidase isolated from the inkcap Basidiomycete Coprinus cinereus shows that the 42,000-dalton enzyme contains a protoheme IX prosthetic group. Reactivity assays and the electronic absorption spectra of native Coprinus peroxidase and several of its ligand complexes indicate that this enzyme has characteristics similar to those reported for horseradish peroxidase. In this paper, we characterize the H2O2-oxidized forms of Coprinus peroxidase compounds I, II, and III by electronic absorption and magnetic resonance spectroscopies. Electron paramagnetic resonance (EPR) and nuclear magnetic resonance (NMR) studies of this Coprinus peroxidase indicate the presence of high-spin Fe(III) in the native protein and a number of differences between the heme site of Coprinus peroxidase and horseradish peroxidase. Carbon-13 (of the ferrous CO adduct) and nitrogen-15 (of the cyanide complex) NMR studies together with proton NMR studies of the native and cyanide-complexed Coprinus peroxidase are consistent with coordination of a proximal histidine ligand. The EPR spectrum of the ferrous NO complex is also reported. Protein reconstitution with deuterated hemin has facilitated the assignment of the heme methyl resonances in the proton NMR spectrum.

Solvent isotope effects on NMR spectral parameters in high-spin ferric hemoproteins: an indirect probe for distal hydrogen bonding

The influence of solvent isotope composition on 1H-NMR resonance position and linewidth of heme methyls has been investigated for a variety of high-spin ferric hemoproteins for the purpose of detecting hydrogen-bonding interactions in the heme cavity. Consistently larger hyperfine shifts and paramagnetic linewidths in 2H2O than 1H2O are observed for metmyoglobins and methemoglobin possessing a coordinated water molecule. The analysis of the dynamics of labile proton exchange in sperm whale metmyoglobin, and the absence of any isotope effects in the five-coordinate Aplysia metmyoglobin, indicate that the significant axial modulation of heme electronic structure by solvent isotope is consistent with arising from distal hydrogen-bonding interactions. The presence or absence of similarly large isotope effects on shifts and linewidths in other hemoproteins, depending on the presence of a bound water in the distal heme pocket, suggests that this isotope effect can serve as a probe for the presence of such bound water. The absence of any detectable isotope effect on either shifts or linewidths in resting-state horseradish peroxidase supports a five-coordinate structure with bound water absent from the vicinity of the iron.

A nuclear Overhauser effect study of the heme crevice in the resting state and compound I of horseradish peroxidase: evidence for cation radical delocalization to the proximal histidine

The assignment of resolved hyperfine-shifted resonances in high-spin resting state horseradish peroxidase (HRP) and its double-oxidized reactive form, compound I (HRP-I), has been carried out by using the nuclear Overhauser effect (NOE) starting with the known heme methyl assignments in each species. In spite of the efficient spin-lattice relaxation and very broad resonances, significant NOEs were observed for all neighboring pyrrole substituents, which allowed the assignment of the elusive propionate alpha-methylene protons. In the resting state HRP, this leads directly to the identity of the proximal His-170 H beta peaks. The determination that one of the most strongly contact-shifted single proton resonances in HRP-I does not arise from the porphyrin dictates that the cation radical must be delocalized to some amino acid residue. The relaxation properties of the non-heme contact-shifted signal in HRP-I support the identity of this contributing residue as the proximal His-170. Detailed analysis of changes in both contact shift pattern and NOEs indicates that compound I formation is accompanied by a approximately 5 degree rotation of the 6-propionate group. The implication of a porphyrin cation radical delocalized over the proximal histidine for the proposed location of the solely amino acid centered radical in compound I of related cytochrome c peroxidase is discussed.

Structural characterization of lactoperoxidase in the heme environment by proton NMR spectroscopy

The heme environmental structures of lactoperoxidase (LP) have been studied by the use of hyperfine-shifted proton NMR and optical absorption spectra. The NMR spectra of the enzyme in native and cyanide forms in H2O indicated that the fifth ligand of the heme iron is the histidyl imidazole with an anionic character and that the sixth coordination site is possibly vacant. These structural characteristics are quite similar to those of horseradish peroxidase (HRP), suggesting that these may be prerequisite to peroxidase activity. The pH dependences of the spectra of LP in cyanide and azide forms showed the presence of two ionizable groups with pK values of 6 and 7.4 in the heme vicinity, which is consistent with the kinetic results. The group with pK = 7.4 is associated with azide binding to LP in a slow NMR exchange limit, which is in contrast to the fast entry of azide to HRP.

High resolution proton nuclear magnetic resonance spectroscopy of lactoperoxidase

The first high resolution proton nuclear magnetic resonance spectra are reported for the native ferric and ferric cyano complexes of bovine lactoperoxidase. The spectrum of the native species exhibits broad heme signals in a far downfield region characteristic of the high-spin ferric state. The low-spin cyano complex yields a proton nuclear magnetic resonance spectrum with signals as far as 68.5 ppm downfield and as far as -28 ppm upfield of the tetramethylsilane reference. These peak positions are anomalous with respect to those seen only as far as 35 ppm downfield in other cyano hemoprotein complexes. An extreme asymmetry in the unpaired spin delocalization pattern of the iron porphyrin is suggested. The unusual proton nuclear magnetic resonance properties parallel distinctive optical spectral properties and the exceptional resistance to heme displacement from the enzyme. Lactoperoxidase utilized in these studies was isolated from raw milk and purified by an improved, rapid chromatographic procedure.

High-resolution proton nuclear magnetic resonance spectroscopy of chloride peroxidase: identification of new forms of the enzyme

Chloride peroxidase from the mold Caldariomyces fumago in the native high-spin iron(III) and low-spin cyanoiron (III) states has been subjected to high-field proton nuclear magnetic resonance spectroscopic measurements. Signals shifted well outside the diamagnetic envelope by the paramagnetic iron(III) center are surprisingly insensitive to pH changes over the range from pH 3 to pH 7. The previously identified major form of chloride peroxidase (form A) and the minor form (B) show very similar chemical shift patterns. Of greatest significance, however, is the discovery that each of the separable forms of the enzyme exhibits splitting of porphyrin ring methyl resonances. The appearance of two sets of signals in both native and cyanide-complexed enzyme is best explained by the existence of two additional forms of the A and B isoenzymes. Structural differences for the newly identified forms of chloride peroxidase must be located in the vicinity of the heme prosthetic group.

Axial histidyl imidazole non-exchangeable proton resonances as indicators of imidazole hydrogen bonding in ferric cyanide complexes of heme peroxidases

Proton NMR spectra of a model of low-spin cyanide complexes of ferric hemoproteins indicate that two broad single-protein resonances from the axial imidazole can be resolved outside the diamagnetic spectral region. Upon deprotonation of the imidazole in the model, the upfield resonance shifts dramatically to higher field, suggesting that its position may reflect the degree of hydrogen bonding or proton donation of the imidazole. Met-cyano myoglobin reveals a pair of such broad peaks in the regions expected for an essentially neutral axial imidazole. In the cyano complexes of horseradish peroxidase and cytochrome c peroxidase, a pair of single-proton resonances are located which are assigned to the same imidazole protons on the basis of their linewidth and shift changes upon altering the heme substituents. The upfiled proton, however, is found at much higher field than in metMbCN. The upfield bias of this resonance is taken as evidence for appreciable imidazolate character for the axial ligand in these heme peroxidases.