Gerd N. La Mar

Heme orientational disorder in reconstituted and native sperm whale myoglobin: Proton nuclear magnetic resonance characterizations by heme methyl deuterium labeling in the met-cyano protein

The solution proton nuclear magnetic resonance spectrum of the Met-cyano form of sperm whale myoglobin reveals the presence of two sets of comparably intense resonances immediately after reacting the apoprotein with hemin, only one of which corresponds to that of the accepted native protein. Isotope labeling of individual methyl groups of hemin reveals that the methyl assignments differ characteristically in that similar resonance positions for the two components arise from the methyl groups related by a 180 degrees rotation about the alpha-gamma-meso axis. This phenomenon, observed earlier only for myoglobin with modified hemin, dictates that the second protein component in solution immediately after reconstitution must have the heme rotated by 180 degrees about the alpha-gamma-meso axis as compared to that found in the single crystal. The two components in the reconstituted protein equilibrate to yield the spectrum of the native Met-cyanomyoglobin for which there still exists approximately 8% of the minor component. Thus native myoglobin in solution is structurally heterogeneous in the heme pocket. Proton nuclear magnetic resonance spectra of deoxymyoglobin produced from both native and freshly reconstituted protein shown that the heterogeneity is also a property of the physiologically relevant reduced protein forms. It is suggested that, contrary to available X-ray data, heme orientational heterogeneity may be the rule rather than the exception in b-type hemoproteins, and that such disorder must be carefully considered in detailed correlations between structure and function even in native hemoproteins.

Assignment of proximal histidine proton nmr peaks in myoglobin and hemoglobin

Summary The proton nmr spectra of model compounds of deoxy myoglobin and hemoglobin have yielded the assignment of the axial imidazole resonances. The information leads directly to an assignment of all three proximal histidyl imidazole proton resonances in sperm whale deoxy myoglobin, and the two non-equivalent proximal histidyl imidazole NH signals of the α and β chains in deoxy hemoglobin A. The NH peaks are expected to serve as valuable probes for the T ⇌ R transition in hemoglobins.

1H-NMR assignments and the dynamics of interconversion of the isomeric forms of cytochrome b5 in solution.

Cytochrome b5 reconstituted with specifically deuterated hemins has led to the assignment of the resolved 6,7 beta-propionate protons and heme meso protons. Freshly reconstituted cytochrome b5 contains a mixture of two isomers in an approx. 1:1 ratio. As time proceeds the minor isomer decreases in intensity until the equilibrium ratio, approx. 8:1, of the two isomers is reached. The rate of the heme disorder kinetics was investigated for cytochrome b5 as a function of pH, oxidation state and 2,4 heme substitutents. Comparison of the kinetic data for cytochrome b5 with that obtained for other b-type heme proteins supports the proposal that the heme disorder arises from a 180 degree rotation of the heme about the alpha, gamma-meso axis. Computer-difference methods allow the spectra of the two individual isomers to be generated. Comparison of the NMR spectral parameters for the two individual isomers indicates small structural differences for amino acid side-chain orientations.

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.

One- and two-dimensional nuclear Overhauser effect studies of the eletronic/molecular structure of the heme cavity of ferricytochrome b5

A nuclear Overhauser effect, NOE, study of solubilized native bovine ferricytochrome b5 has provided the complete assignment of the heme resonances as well as those of the majority of the amino acid side-chains making contact with the prosthetic group. The resonances which could not be identified are those from positions very close to the iron (less than 5 A) for which paramagnetic relaxation is sufficiently strong to significantly decrease the NOEs. The observed 1H-1H dipolar contacts generally confirm a solution structure unchanged from that described in single crystals, except for the detailed orientation of the heme side-chains. The 2-vinyl group is found in both the cis and trans in-plane orientation as opposed to exclusively cis in the crystal, and the 7-propionate group is rotated by 30 degrees in solution towards the 6-propionate group. Identification of resonances for the individual axial histidine residues indicates non-equivalent interaction with the heme iron, and the patterns of meso-H, pyrrole substituent and amino acid dipolar shifts allow the location of the principal magnetic axes in the protein coordinate system. This identifies His-39 as the dominant influence in determining the electronic ground state that orients the molecular orbital for facile electron transfer via the exposed heme edge. The complete two-dimensional NOESY map for ferricytochrome b5 is presented that yields all the cross peaks expected on the basis of the one-dimensional NOE studies, and indicates that such two-dimensional methods should have profitable extension to strongly hyperfine-shifted resonances in paramagnetic proteins.

Assignment of proximal histidyl imidazole exchangeable proton NMR resonances to individual subunits in hemoglobins A, Boston, Iwate and Milwaukee☆

Abstract The proton nmr spectra of the synthetic valency hybrids, α 2 (β + CN) 2 , (α + CN) 2 β 2 of hemoglobin A and the natural valency hybrids of the mutant hemoglobins Boston, Iwate and Milwaukee have led to the unambiguous assignment of the two proximal histidyl imidazole exchangeable proton signals at 64 and 76 ppm to individual α and β subunits, respectively. New single non-exchangeable proton resonances detected in the extreme downfield region of the spectra of Hbs Boston and Iwate are tentatively assigned to the coordinated tyrosine of the mutated α chains.

Acid Bohr effects in myoglobin characterized by proton NMR hyperfine shifts and oxygen binding studies.

Proton NMR studies of sperm whale and horse deoxymyoglobin have revealed that both proteins exhibit a single, well defined, pH-induced structural change. The changes in hyperfine shifts are clearly observed not only at the heme peripheral substituents, but also at the proximal histidyl imidazole, which suggest that heme-apoprotein contacts are looser in the acidic than alkaline conformations. The hyperfine shift changes are modulated by a single titratable group with a pK of approx. 5.7 in both proteins. Oxygen binding studies of sperm whale myoglobin over a range of temperature and pH showed that, while the oxygen affinity was independent of pH at 25 degrees C, it increased below pH 7 at 0 degrees C and decreased below pH 7 at 37 degrees C. Hence, sperm whale myoglobin exhibits a small acid Bohr effect which most likely arises from the characterized structural changes in the deoxy proteins. While horse myoglobin failed to exhibit a resolvable acid Bohr effect between 0 and 37 degrees C, it did show a weak alkaline Bohr effect at 25 degrees C which disappeared at lower temperatures. Since the oxygen affinity changed smoothly over several pH units, this alkaline Bohr effect can not be associated with any well defined conformational change detected by NMR.

Proton NMR study of the thermodynamics and kinetics of the acid ⇌ base transitions in reconstituted metmyoglobins

Abstract Optical and proton NMR pH titrations of sperm whale metmyoglobin (metMb) in its native form and reconstituted with chemically modified hemes reveal that the p K a for the acid ⇌ base transition decreases as the heme 2,4-substituents are made more electron withdrawing. The proton NMR spectra yields resonances which are averaged over the acidic and basic forms of the protein, but still exhibit significant exchange line broadening. Analysis of this exchange contribution to the linewidth is consistent with the simple kinetic scheme metMb ∗ H 2 O + OH − ⇌ k 2 k 1 with k 2 = 1.3 ± 0.5 · 10 10 M −1 · s −1 and k 1 = 1.6 ± 0.6 · 10 5 s −1 for the native protein. The effect of electron-withdrawing substituents on the heme increase k 2 and decrease k 1 .

Proton NMR study of coordinated imidazoles in low-spin ferric heme complexes. Assignment of single proton histidine resonance in hemoproteins

The proton signals for the coordinated axial imidazoles in a series of low-spin ferric bis-imidazole complexes with natural porphyrin derivatives have been located and assigned. The methyl signals of several methyl-substituted imidazoles have also been resolved for the mixed ligand complexes of imidazole and cyanide ion. The imidazole spectra for the bis complexes are essentially the same as those reported earlier for synthetic porphyrins, with the hyperfine shifts exhibiting comparable contributions from the dipolar and contact interactions. The contact contribution reflects spin transfer into a vacant imidazole pi orbital. The spectra of both the mono- and bis-imidazole complex concur in predicting that only the 2-H and 5-CH2 signals of an axial histidine are likely to resonate clearly outside the diamagnetic 0 to --10 ppm from TMS region in hemoproteins. However, both the 2-H and 4-H imidazole peaks are found to be too broad to detect in a hemoprotein. Hence, it is suggested that the pair of non-heme, single-proton resonances in low-spin met-myoglobin cyanides arise from the non-equivalent methylene protons at the 5-position of the histidyl imidazole. Both the resonance positions and relative linewidths in the model compounds are consistent with the data for this pair of protons in myoglobins. The possible interpretations of the average downfield bias of these signals as well as the magnitude of their spacing, are discussed in terms of the conformation of the proximal histidine relative to the heme group.

2D NMR of paramagnetic metalloenzymes: Cyanide-inhibited horseradish peroxidase

SummaryTwo-dimensional (2D) proton NMR correlation spectroscopy, COSY, and nuclear Overhauser spectroscopy, NOESY, have been used to explore the applicability of these methods for the moderately large (42 KDa), paramagnetic cyanide-inhibited derivative of horseradish peroxidase, HRP-CN. The target resonances are those in the active site of HRP-CN which experience substantial hyperfine shifts and paramagnetic relaxation. The magnitude COSY experiment was found to yield cross peaks for all known spin-coupled heme substituents, as well as for the majority of non-heme hyperfine shifted protons, in spite of line widths of the order of ∼100 Hz. Moreover, the rapid relaxation of the hyperfine-shifted resonances allows the extremely rapid collection of useful 2D NMR data sets without the loss of information. For the heme, the combination of COSY cross peaks for the vinyl and propionate substituents, and NOESY cross peaks among these substituent protons and heme methyls, allows assignment of heme resonances without recourse to deuterium labeling of the heme. A seven-proton coupled spin system was identified in the upfield region that is consistent with originating from the proposed catalytic Arg38 residue in the distal heme pocket, with orientation relative to the heme similar to that found in cytochromec peroxidase. The upfield hyperfine-shifted methyl group in the substrate binding pocket previously proposed to arise from Leu237 is shown to arise instead from an as yet unidentified Ile. NOESY spectra collected at very short (3 ms) and intermediate (20 ms) mixing times indicate that build-up curves can be obtained that should yield estimates of distances in the heme cavity. It is concluded that 2D NMR studies should be able to provide the heme assignments, aid in identifying the catalytic residues, and provide information on the spatial disposition of such residues in the active site for cyanide complexes of a number of intermediate to large paramagnetic heme peroxidases, as well as for other paramagnetic metalloenzymes with line widths of ∼ 100 Hz. Moreover, paramagnetic-induced hyperfine shifts and linewidths to ∼100 Hz need not interfere with the complete solution structure determination of a small paramagnetic protein solely on the basis of 2D NMR data.