1H nuclear magnetic resonance study of the prosthetic group in sulfhemoglobin.

The molecular and electronic structure of the modified prosthetic group of sulfhemoglobin (SHb) was investigated by 1H NMR for the low-spin ferric cyano-met and high-spin ferrous deoxy sulfhemoglobin complex. The 1H NMR resonances of the two subunits in the cyano-met SHb complex were differentiated on the basis of the differential stability toward regeneration of native subunits. The subunit origin for the two sets of resonances was established by formation of the sulfglobin protein for the isolated alpha-chain prior to assembling with the native beta-subunit to yield a tetramer with sulfhemin in the alpha-subunits. The subunit peak assignments establish that it is the beta-subunit of SHb which regenerates more rapidly to native protein. The hyperfine shifted sulfhemin peaks were assigned based on steady-state nuclear Overhauser effects which demonstrated that similarly hyperfine shifted peaks exhibit the same dipolar connectivities observed in the analogous sulfmyoglobin complex. Hence it is concluded that pyrrole B is the site of reaction in both hemoglobin and myoglobin. The initially formed SHb complex failed to equilibrate to yield a complex with a sulfhemin sufficiently stable to extraction as found previously for sulfmyoglobin. However, apoHb readily bound the green sulfhemin extracted from the terminal alkaline equilibration product of sulfmyoglobin. The inhibition on the equilibration to the alkaline form with the exocyclic thiolene ring is attributed to the interaction with Val FG5. The observations of the same dipolar connectivities among similarly hyperfine shifted peaks in the directly prepared and reconstituted SHb complexes further support the same structure for the sulfhemin in sulfmyoglobin and SHb. The strongly hyperfine shifted peaks in the deoxy form of both SHb complexes were found very similar to those of the analogous sulfmyoglobin complexes. The proximal His labile ring proton signal appears to experience a 5- to 10-ppm decrease upon conversion of a native globin to sulfglobin. This attenuation may provide a probe for differentiating chlorins and hemins in globin pockets.

Determination of the chirality of the saturated pyrrole in sulfmyoglobin using the nuclear Overhauser effect.

The interproton nuclear Overhauser effect (NOE) and paramagnetic dipolar relaxation rates for hyperfine-shifted resonances in the proton NMR spectra of sperm whale met-cyano sulfmyoglobin have led to the location and assignment of the proton signals of the heme pocket residue isoleucine 99 (FG5) in two sulfmyoglobin isomers. Dipolar relaxation rates of these protein signals indicate a highly conserved geometry of the heme pocket upon sulfmyoglobin formation, while the similar upfield direction of dipolar shifts for this residue to that observed in native sperm whale myoglobin reflects largely retained magnetic properties. Dipolar connectivity of this protein residue to the substituents of the reacted heme pyrrole ring B defines the stereochemistry of the puckered thiolene ring found in one isomer, with the 3-CH3 tilted out of the heme plane proximally. The chirality of the saturated carbons of pyrrole ring B in both the initial sulfmyoglobin product and the terminal alkaline product is consistent with a mechanism of formation in which an atom of sulfur is incorporated distally to form an episulfide across ring B, followed by reaction of the vinyl group to yield the thiolene ring that retains the C3 chirality.

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.

Identification of the altered pyrrole in the isomeric sulfmyoglobins: hyperfine shift patterns as indicators of ring saturation in ferric chlorins.

Analysis of the 1H NMR hyperfine shift patterns of isomeric sulfmyoglobins is carried out in the met-aquo and met-cyano states to determine the site of saturation in each protein. The utility of the patterns for structure elucidation is established by specific deuterium labeling of the heme methyls of the terminal base product. On the basis of the known saturation of ring B in this isomer [Chatfield, M.J., La Mar, G.N., Lecomte, J.T.J., Balch, A.L., Smith, K.M., & Langry, K.C. (1986) J. Am. Chem. Soc. 108, 7108-7110], the methyl resonance of the saturated ring is found to have strongly attenuated contact shift. Thus, the heme methyl contact shift pattern is diagnostic for the saturated pyrrole in the high-spin state. This rationale is then applied to analyze the assigned NMR spectra of the initial and terminal acid sulfmyoglobin products, revealing that the same ring B is saturated in each isomer. In contrast, the heme methyl contact shift pattern in low-spin ferric complexes reveals that the methyls both on the affected pyrrole and on the trans pyrrole are influenced similarly on sulfmyoglobin formation, precluding the use of this methyl shift pattern as a unique indicator of the site of saturation. Identification of exchangeable proximal histidine resonances for met-aquo sulfmyoglobin complexes with shifts similar to that in native myoglobin dictates inconsequential axial alterations in the sulfmyoglobins, while location of downfield meso proton resonances analogous to those of the native protein demonstrates the retention of the coordinate water in the active site of met-sulfmyoglobin.

Proton NMR characterization of isomeric sulfmyoglobins: preparation, interconversion, reactivity patterns, and structural features.

The preparations of sulfmyoglobin (sulf-Mb) by standard procedures have been found heterogeneous by 1H NMR spectroscopy. Presented here are the results of a comprehensive study of the factors that influence the selection among the three dominant isomeric forms of sperm whale sulf-Mb and their resulting detailed optical and 1H NMR properties as related to their detectability and structural properties of the heme pocket. A single isomer is formed initially in the deoxy state; further treatment in any desired oxidation/ligation state can yield two other major isomers. Acid catalysis and chromatography facilitate formation of a second isomer, particularly in the high-spin state. At neutral pH, a third isomer is formed by a first-order process. The processes that alter oxidation/ligation state are found to be reversible and are judged to affect only the metal center, but the three isomeric sulf-Mbs are found to exhibit significantly different ligand affinity and chemical stability. The present results allow, for the first time, a rational approach for preparing a given isomeric sulf-Mb in an optimally pure state for subsequent characterization by other techniques. While optical spectroscopy can distinguish the alkaline forms, only 1H NMR clearly distinguishes all three ferric isomers. The ring current shifts in the carbonyl complexes of reduced sulf-Mb complexes support saturation for a pyrrole in each isomer. The hyperfine shift patterns in the various oxidation/spin states of sulf-Mbs indicate relatively small structural alteration, and the proximal and distal sides of the heme suggest that peripheral electronic effects are responsible for the differentially reduced ligand affinities for the three isomeric sulf-Mbs. The first 1H NMR spectra of sulfhemoglobins are presented, which indicate a structure similar to that of the initially formed sulf-Mb isomer but also suggest the presence of a similar molecular heterogeneity as found for sulf-Mb, albeit to a smaller extent.

Proton NMR study of the influence of heme vinyl groups on the formation of the isomeric forms of sulfmyoglobin.

The formation of sulfmyoglobin has been investigated for myoglobin reconstituted with hemins having vinyls replaced by hydrogens to determine the participation of the vinyl groups in the reaction processes. Green complexes are produced in all cases, proving that vinyls are not obligatory for the formation of sulfproteins. In the presence of the 4-vinyl group, the 1H NMR spectra of the met-cyano derivatives indicate the formation of three green species; however, the most stable of these products is not formed in the absence of this group, confirming reaction of the 4-vinyl in this species. Two new red extractable sulfmyoglobin derivatives are formed in the absence of the 4-vinyl group.

Multiple forms of sulfmyoglobin as detected by 1H nuclear magnetic resonance spectroscopy.

The proton nuclear magnetic resonance spectrum of sulfmyoglobin prepared in standard fashion reveals the presence of three forms, A, B, and C, with different chemical reactivity. Conditions for some interconversions of these forms are given. The 1H NMR spectra of the different forms show similar patterns. It appears that the differences between forms involve chemical modification on the porphyrin periphery. The altered heme can be extracted from FeIII(CN) sulfmyoglobin C to give a stable green substance.