EPR spectroscopy studies on the structural transition of nitrosyl hemoglobin in the arterial-venous cycle of DEANO-treated rats as it relates to the proposed nitrosyl hemoglobin/nitrosothiol hemoglobin exchange

In vivo studies show a dynamic cycle in which alpha-nitrosylated hemoglobin is mainly in the relaxed state in arterial blood of rats treated with 2-(N,N-diethylamino)-diazenolate-2-oxide, but converts mainly to the tense state during the arterial-venous transit. A detailed analysis shows that different electron paramagnetic resonance spectra recorded for alpha-nitrosyl hemoglobin in arterial and venous blood at 77 K originate only from a different ratio between 5- and 6-coordinate heme without any change in the concentration of nitrosyl hemoglobin. In venous blood, the five- and six-coordination equilibrium of the alpha-nitrosyl heme is shifted in favor of the 5-coordinate state (58% venous vs. 20% arterial). These results are not consistent with the recently proposed exchange of nitrosyl heme with the beta-93 nitrosothiol group of hemoglobin during the arterial-venous cycle.     

An infrared study of NO bonding to heme B and hemoglobin A. Evidence for inositol hexaphosphate induced cleavage of proximal histidine to iron bonds.

Five- and six-coordinate nitrosyl hemes have been prepared and their infrared, electron paramagnetic resonance (EPR), and visible-Soret spectra compared with the corresponding spectra for nitrosyl hemoglobin A (Hba-NO) determined both in the presence and the absence of inositol hexaphosphate (IHP). The five- and six-coordinate NO complexes prepared from either dipyridine or pyridine carbonyl protoheme dimethyl ester had N-O stretch bands (nuno) near 1675 and 1625 cm-1, respectively. These frequencies are sensitive to change in solvent (nuno decreased as the dipole moment of the solvent increased) and, with six-coordinate species, to changes in trans ligand. However, these solvent and trans ligand effects were small compared with the difference (ca. 50 cm-11) between five- and six -coordinate species. The nature of the trans ligand affected the relative proportions of the two...     

Electron paramagnetic resonance studies of heme c and its nitrosyl derivative in Vibrio (Achromobacter) fischeri nitrite reductase

Interactions of Vibrio (formerly Achromobacter) fischeri nitrite reductase were studied by electron paramagnetic resonance spectroscopy. The spectrum of the oxidized enzyme showed a number of features which were attributed to two low-spin ferric hemes. These comprised an unusual derivative peak at g = 3.7 and a spectrum at g = 2.88, 2.26, and 1.51. Neither heme was reactive in the oxidized state with the substrate nitrite and with cyanide and azide. When frozen under turnover conditions (i.e., reduction in the presence of excess nitrite), the enzyme showed the spectrum of a nitrosyl heme derivative. The g = 2.88, 2.26, and 1.51 signals reappeared partially on reoxidation by nitrite, indicating that the nitrosyl species which remained arose from the g = 3.7 heme. The nitrosyl derivative showed a 14N nuclear hyperfine splitting, Az = 1.65 mT. The nitrosyl derivative was produced by treatment of the oxidized nitrite reductase with nitric oxide or hydroxylamine. Exchange of nitric oxide between the nitrosyl derivative and NO gas in solution was observed by using the [15N]nitrosyl compound. A possible reaction cycle for the enzyme is discussed, which involves reduction of the enzyme followed by binding of nitrite to one heme and formation of the nitrosyl intermediate.     

Gelation of sickle hemoglobin. III. Nitrosyl hemoglobin.

Sickle cell nitrosyl hemoglobin was examined for gelation by an ultracentrifugal method previously described (Briehl &; Ewert, 1973) and by birefringence. In the presence of inositol hexaphosphate gelation which exhibited the endothermic temperature dependence seen in gels of deoxyhemoglobin S was observed by both techniques. In the absence of inositol hexaphosphate no gelation was observed, nor did nitrosyl hemoglobin A exhibit gelation. On the assumption that gelation is dependent on the deoxy or T (low ligand affinity) as opposed to the oxy or R (high ligand affinity) quaternary structure this supports the conclusion that nitrosyl hemoglobin S in inositol hexaphosphate assumes the T structure, in contrast to the other liganded ferrohemoglobin derivatives oxy and carbon monoxide hemoglobin. Assuming further that the quaternary structures and isomerizations are the same in hemoglobins A and S it can also be concluded that nitrosyl hemoglobin A in inositol hexaphosphate assumes the T state. Since no gelation was seen in stripped nitrosyl hemoglobin S, inositol hexaphosphate serves to effect an R to T switch in this derivative. Thus R-T isomerization in nitrosyl hemoglobin occurs without change in ligand binding at the sixth position of the heme group confirming the conclusion of Salhany (1974) and Salhany et al. (1974).Lowering of the pH toward 6 favors gelation of NO hemoglobin S as it does of deoxy and aquomethemoglobin S (Briehl &; Ewert, 1973,1974), consistent with a favoring of the T structure due to strengthening of the interchain salt bridges and the binding of inositol hexaphosphate and/or changes in site-to-site interactions on which gelation depends.     

Spectroscopic comparison of the heme active sites in WT KatG and its S315T mutant

KatG, the catalase-peroxidase from Mycobacterium tuberculosis, has been characterized by resonance Raman, electron spin resonance, and visible spectroscopies. The mutant KatG(S315T), which is found in about 50% of isoniazid-resistant clinical isolates, is also spectroscopically characterized. The electron spin resonance spectrum of ferrous nitrosyl KatG is consistent with a proximal histidine ligand. The Fe-His stretching vibration observed at 244 cm(-1) for ferrous wild-type KatG and KatG(S315T) confirms the imidazolate character of the proximal histidine in their five-coordinate high-spin complexes. The ferrous forms of wild-type KatG and KatG(S315T) are mixtures of six-coordinate low-spin and five-coordinate high-spin hemes. The optical and resonance Raman signatures of ferric wild-type KatG indicate that a majority of the heme exists in a five-coordinate high-spin state, but six-coordinate hemes are also present. At room temperature, more six-coordinate low-spin heme is observed in ferrous and ferric KatG(S315T) than in the WT enzyme. While the nature of the sixth ligand of LS ferric wild-type KatG is not completely clear, visible, resonance Raman, and electron spin resonance data of KatG(S315T) indicate that its sixth ligand is a neutral nitrogen donor. Possible effects of these differences on enzyme activity are discussed.     

FTIR and resonance Raman studies of nitric oxide binding to H93G cavity mutants of myoglobin.

Nitric oxide (NO) binds to the myoglobin (Mb) cavity mutant, H93G, forming either a five- or six-coordinate Fe-NO complex. The H93G mutation eliminates the covalent attachment between the protein and the proximal ligand, allowing NO to bind H93G possibly from the proximal side of the heme rather than the typical diatomic binding pocket on the distal side. The question of whether NO binds on the distal or proximal side was addressed by FTIR spectroscopy of the N-O vibrational frequency nuN(-O) for a set of Mb mutants that perturb the electrostatic environment of the heme pocket. Vibrational spectra of five- and six-coordinate MbNO complexes indicate that nu(N-O) shifts (by as much as 26 cm(-1)) to higher energies for the distal mutants H64V and H64V/H93G relative to the energies of wild-type and H93G MbNO, while nu(N-O) is not affected by the proximal side mutation S92A/H93G. This result suggests that NO binds on the distal side of heme in the five- and six-coordinate MbNO complexes of H93G. Additionally, values of the Fe-NO vibrational frequency nu(Fe-NO) as measured by resonance Raman spectroscopy are reported for the distal and proximal double mutants of H93G. These results suggest that nu(Fe-NO) is not very sensitive to mutations that perturb the electrostatic environment of the heme pocket, leading to the observation that nu(N-O) and nu(Fe-NO) are not quantitatively correlated for the MbNO complexes presented here. Furthermore, nu(N-O) and nu(Fe-NO) do not correlate well with equilibrium constants for imidazole binding to the five-coordinate MbNO complexes of the H93G double mutants. The data presented here do not appear to support the presence of pi-back-bonding or an inverse trans effect of NO binding in Mb mutants that alter the electrostatic environment of the heme pocket.     

Resonance Raman studies of cytochrome c' support the binding of NO and CO to opposite sides of the heme: implications for ligand discrimination in heme-based sensors

Resonance Raman (RR) studies have been conducted on Alcaligenes xylosoxidans cytochrome c', a mono-His ligated hemoprotein which reversibly binds NO and CO but not O(2). Recent crystallographic characterization of this protein has revealed the first example of a hemoprotein which can utilize both sides of its heme (distal and proximal) for binding exogenous ligands to its Fe center. The present RR investigation of the Fe coordination and heme pocket environments of ferrous, carbonyl, and nitrosyl forms of cytochrome c' in solution fully supports the structures determined by X-ray crystallography and offers insights into mechanisms of ligand discrimination in heme-based sensors. Ferrous cytochrome c' reacts with CO to form a six-coordinate heme-CO complex, whereas reaction with NO results in cleavage of the proximal linkage to give a five-coordinate heme-NO adduct, despite the relatively high stretching frequency (231 cm(-1)) of the ferrous Fe-N(His) bond. RR spectra of the six-coordinate CO adduct indicate that CO binds to the Fe in a nonpolar environment in line with its location in the hydrophobic distal heme pocket. On the other hand, RR data for the five-coordinate NO adduct suggest a positively polarized environment for the NO ligand, consistent with its binding close to Arg 124 on the opposite (proximal) side of the heme. Parallels between certain physicochemical properties of cytochrome c' and those of heme-based sensor proteins raise the possibility that the latter may also utilize both sides of their hemes to discriminate between NO and CO binding.     

Infrared and electron paramagnetic resonance study of nitrosyl(protoporphyrin IX dimethyl ester)iron(II) and its complexes with nitrogenous bases as model systems for nitrosylhemoproteins: effect of solvent polarity

Infrared and electron paramagnetic resonance spectra of nitrosyl(protoporphyrin IX dimethyl ester)iron(II)(Fe(PPDME)(NO)) and its complexes with nitrogenous bases (N bases) such as imidazoles, pyridines, aliphatic amines, and anilines have been measured in various solvents. At room temperature, giso, Aiso, and nu NO values of five-coordinate Fe(PPDME)(NO) decreased with an increase in solvent polarity parameter ET, indicating the interaction between the solvent and the vacant axial coordination position. It has been found that the nu NO value of six-coordinate species is very sensitive to the solvent polarity, while the giso value is less sensitive. The solvent effect on the equilibrium constants, which are evaluated from the intensity change of the NO stretching band for five- and six-coordinate species, is discussed.     

Nitrosyl adducts of FixL as probes of heme environment

This report presents a spectroscopic investigation of the nitrosyl adducts of FixL, the sensor in the signal transduction system responsible for regulating nitrogen fixation in Rhizobium meliloti. Variable-temperature resonance Raman (RR), electron spin resonance (ESR), and variable-temperature UV-visible absorption data are presented for the ferrous NO adducts of two FixL deletion derivatives, FixLN (the heme-containing domain) and FixL* (a functional heme-kinase). A temperature-dependent equilibrium is observed between the five-coordinate (5-c) and six-coordinate (6-c) ferrous nitrosyl adducts, with lower temperatures favoring formation of the 6-c nitrosyl adduct. This equilibrium is perturbed as the solution freezes, and the amount of 5-c FixL-NO increases sharply until a nearly constant ratio of 6-c to 5-c adducts is obtained. Complexation between the heme domain of FixL and its response regulator, FixJ, is revealed through specfic FixJ-induced increase in the energy separation between 5-c and 6-c FixL-NO. Ferric nitrosyl adducts of FixL* and FixLN autoreduce to their corresponding ferrous nitrosyl adducts. The kinetic behavior of this reduction is monophasic for FixL*-NO, while the reaction for ferric FixLN-NO is biphasic. These results suggest conformational inhomogeneity in the heme pocket of FixLN and conformational homogeneity in that of FixL*. Hence the kinase domain plays a role in distal pocket conformational stability. Implications for the signal transduction mechanism are discussed.     

Electron-nuclear coupling in nitrosyl heme proteins and in nitrosyl ferrous and oxy cobaltous tetraphenylporphyrin complexes

Electron spin echo envelope modulation (ESEEM) spectroscopy has been used to study electron-nuclear interactions in the following isoelectronic S = 1/2 complexes: NO-FeII(TPP) (TPP = tetraphenylporphyrin) with and without axial nitrogenous base, nitrosylhemoglobin in R and T states, and O2-CoII(TPP) with and without axial base. Only the porphyrin pyrrole nitrogens contribute to the ESEEM of the 6-coordinate nitrosyl FeII(TPP) complexes, nitrosylhemoglobin (R-state), and the nitrosyl complexes of alpha and beta chains. Pyrrole nitrogens in the 5-coordinate complex NO-FeII(TPP) are coupled too weakly to unpaired spin and therefore do not contribute to the ESEEM. A partially saturated T-state nitrosylhemoglobin does not exhibit echo envelope modulations characteristic of 6-coordinate nitrosyl species, which confirms that the proximal imidazole bond to heme iron is disrupted. Study of 6-coordinate O2-CoII(TPP)(L) complexes (L = nitrogenous base) using 14N- and 15N-labeled ligands and porphyrins enabled a detailed analysis of coupling parameters for both pyrrole and axial nitrogens. The pyrrole 14N coupling frequencies are similar to those in NO-FeII(TPP)(L). The Fermi contact couplings for axially bound nitrogen, calculated from simulation of ESEEM spectra for a series of O2-CoII(TPP)(L) complexes (L = pyridine, 4-picoline, 4-cyanopyridine, 4-carboxypyridine, and 1-, 2-, and 4-methylimidazole) illustrate a trend toward stronger hyperfine interactions with weaker bases.     

The effect of quaternary structure on the state of the alpha and beta subunits within nitrosyl haemoglobin. Low temperature photodissociation and the ESR spectra.

Photodissociation of nitrosyl haemoglobin and nitrosyl hybrids, in which either the alpha or beta subunit is in the nitrosyl form has been stidued at liquid helium temperature (4.2 degrees K) by electron spin resonance and optical absorption spectroscopy. In the presence of inositol hexaphosphate, the photodissociated form of nitrosyl haemoglobin showed an anomalous absorption spectrum in the near infrared region. The experiments with nitrosyl hybrids showed that the alphaNO subunit within the T state haemoglobin is predominantly responsible for the anomalous photodissociated form and the ESR spectrum with three distinct hypefines. The ESR spectrum of alphaNO2betadeoxy2 with inositol hexaphosphate appeared to be very similar to that of the 5-coordinated NO-haem complexes but the absorption spectrum of its photodissociated form was similar to none of protoporphyrin Fe(II) derivatives so far reported. This result suggests that the anomalous photodissociated form may be attributable to some structural distortion of porphyrin or a new electronic state of the haem with different spin state from that of deoxyhaemoglobin.     

Analysis of heme structural heterogeneity in Mycobacterium tuberculosis catalase-peroxidase (KatG)

Mycobacterium tuberculosis catalase-peroxidase (KatG) is a heme enzyme considered important for virulence, which is also responsible for activation of the anti-tuberculosis pro-drug isoniazid. Here, we present an analysis of heterogeneity in KatG heme structure using optical, resonance Raman, and EPR spectroscopy. Examination of ferric KatG under a variety of conditions, including enzyme in the presence of fluoride, chloride, or isoniazid, and at different stages during purification in different buffers allowed for assignment of spectral features to both five- and six-coordinate heme. Five-coordinate heme is suggested to be representative of "native" enzyme, since this species was predominant in the enzyme examined immediately after one chromatographic protocol. Quantum mechanically mixed spin heme is the most abundant form in such partially purified enzyme. Reduction and reoxidation of six-coordinate KatG or the addition of glycerol or isoniazid restored five-coordinate heme iron, consistent with displacement of a weakly bound distal water molecule. The rate of formation of KatG Compound I is not retarded by the presence of six-coordinate heme either in wild-type KatG or in a mutant (KatG[Y155S]) associated with isoniazid resistance, which contains abundant six-coordinate heme. These results reveal a number of similarities and differences between KatG and other Class I peroxidases.     

Identification of the proximal ligand His-20 in heme oxygenase (Hmu O) from Corynebacterium diphtheriae. Oxidative cleavage of the heme macrocycle does not require the proximal histidine

The coordination and spin-state of the Corynebacterium diphtheriae heme oxygenase (Hmu O) and the proximal Hmu O H20A mutant have been characterized by UV-visible and resonance Raman (RR) spectrophotometry. At neutral pH the ferric heme-Hmu O complex is a mixture of six-coordinate high spin and six-coordinate low spin species. Changes in the UV-visible and high frequency RR spectra are observed as a function of pH and temperature, with the six-coordinate high spin species being converted to six-coordinate low spin. The low frequency region of the ferrous RR spectrum identified the proximal ligand to the heme as a neutral imidazole with a Fe-His stretching mode at 222 cm(-1). The RR characterization of the heme-CO complex in wt-Hmu O confirms that the proximal imidazole is neither ionized or strongly hydrogen-bonded. Based on sequence identity with the mammalian enzymes the proximal ligand in HO-1 (His-25) and HO-2 (His-45) is conserved (His-20) in the bacterial enzyme. Site-specific mutagenesis identified His-20 as the proximal mutant based on electronic and resonance Raman spectrophotometric analysis. Titration of the heme-Hmu O complex with imidazole restored full catalytic activity to the enzyme, and the coordination of imidazole to the heme was confirmed by RR. However, in the absence of imidazole, the H20A Hmu O mutant was found to catalyze the initial alpha-meso-hydroxylation of the heme. The product of the aerobic reaction was determined to be ferrous verdoheme. Hydrolytic conversion of the verdoheme product to biliverdin concluded that oxidative cleavage of the porphyrin macrocycle was specific for the alpha-meso-carbon. The present data show that, in marked contrast to the human HO-1, the proximal ligand is not essential for the initial alpha-meso-hydroxylation of heme in the C. diphtheriae heme oxygenase-catalyzed reaction.     

Proximal and distal effects on the coordination chemistry of ferric Scapharca homodimeric hemoglobin as revealed by heme pocket mutants

The ferric form of the homodimeric hemoglobin from Scapharca inaequivalvis (HbI) displays a unique pH-dependent behavior involving the interconversion among a monomeric low-spin hemichrome, a dimeric high-spin aquomet six-coordinate derivative, and a dimeric high-spin five-coordinate species that prevail at acidic, neutral, and alkaline pH values, respectively. In the five-coordinate derivative, the iron atom is bound to a hydroxyl group on the distal side since the proximal Fe-histidine bond is broken, possibly due to the packing strain exerted by the Phe97 residue on the imidazole ring [Das, T. K., Boffi, A., Chiancone, E. and Rousseau, D. L. (1999) J. Biol. Chem. 274, 2916-2919]. To determine the proximal and distal effects on the coordination and spin state of the iron atom and on the association state, two heme pocket mutants have been investigated by means of optical absorption, resonance Raman spectroscopy, and analytical ultracentrifugation. Mutation of the distal histidine to an apolar valine causes dramatic changes in the coordination and spin state of the iron atom that lead to the formation of a five-coordinate derivative, in which the proximal Fe-histidine bond is retained, at acidic pH values and a high-spin, hydroxyl-bound six-coordinate derivative at neutral and alkaline pH values. At variance with native HbI, the His69 --> Val mutant is always high-spin and does not undergo dissociation into monomers at acidic pH values. The Phe97 --> Leu mutant, like the native protein, forms a monomeric hemichrome species at acidic pH values. However, at alkaline pH, it does not give rise to the unusual hydroxyl-bound five-coordinate derivative but forms a six-coordinate derivative with the proximal His and distal hydroxyl as iron ligands.     

Heterologous overexpression and purification of cytochrome c' from Rhodobacter capsulatus and a mutant (K42E) in the dimerization region. Mutation does not alter oligomerization but impacts the heme iron spin state and nitric oxide binding properties

Rhodobacter capsulatus cytochrome c' (RCCP) has been overexpressed in Escherichia coli, and its spectroscopic and ligand-binding properties have been investigated. It is concluded that the heterologously expressed protein is assembled correctly, as judged by UV-vis absorption, EPR, and resonance Raman (RR) spectroscopy of the unligated protein as well as forms in which the heme is ligated by CO or NO. To probe the oligomerization state of RCCP and its potential influence on heme reactivity, we have compared the properties of wild-type RCCP with a mutant (K42E) that lacks a salt bridge at the subunit interface. Analytical ultracentrifugation indicates that wild-type and K42E proteins are both monomeric in solution, contrary to the homodimeric structure of the crystalline state. Surprisingly, the K42E mutation produces a number of changes at the heme center (nearly 20 A distant), including perturbation of the ferric spin-state equilibrium and a change in the ferrous heme-nitrosyl complex from a six-coordinate/five-coordinate mixture to a predominantly five-coordinate heme-NO species. RR spectra indicate that ferrous K42E and wild-type RCCP both have relatively high Fe-His stretching frequencies, suggesting that the more favored five-coordinate heme-nitrosyl formation in K42E is not caused by a weaker Fe2+-His bond. Nevertheless, the altered reactivity of ferrous K42E with NO, together with its modified ferric spin state, shows that structural changes originating at the dimer interface can affect the properties of the heme center, raising the exciting possibility that intermolecular encounters at the protein surface might modulate the reactivity of cytochrome c' in vivo.     

Resonance Raman enhancement of the Mn-N-O bending mode in nitrosyl manganese "strapped" and "open" heme complexes

Resonance Raman spectra of the MnII-NO moiety in synthetic nitrosyl manganese heme complexes with and without steric hindrance are reported. The "strapped" hemes having a hydrocarbon strap (variable length) across one face of the heme hinder the perpendicular bonding of a linear ligand. These complexes were employed to investigate the effects of ligand distortion (primarily tilting) on Mn-NO stretching, Mn-N-O bending, and N-O stretching modes. It is demonstrated that ligand distortion in the MnII-NO system is a valid mechanism for causing the resonance enhancement of the Mn-N-O bending mode, similar to that observed in the FeII-CO system (Yu, N.-T., E. A. Kerr, B. Ward, and C. K. Chang. 1983. Biochemistry. 22:4534-4540). More interesting is the observation of the delta(Mn-N-O) enhancement caused by the tilting of the trans Mn-N epsilon bond in the "open" heme complexes (e.g., heme-5 and proto-1X dimethylester) with 1,2-dimethylimidazole or piperidine as a base. The nu(Mn-NO) and nu(N-O) modes exhibit an increase and a decrease, respectively, as the strap length decreases (hence the steric hindrance increases). Both nu(Mn-NO) and nu(N-O) frequencies are insensitive to the strength of the trans base. The results from "strapped" and "open" model heme systems imply that the Mn-N-O geometry is essentially linear and perpendicular in the nitrosyl complexes of monomeric manganese insect hemoglobin CTT IV and sperm whale myoglobin. The unusually low nu(N-O) frequency in the manganese myoglobin complex may be caused by the distal histidine-NO interaction. The delta(Mn-N-O) enhancement in both nitrosyl manganese CTT IV and nitrosyl manganese myoglobin may be caused by a tilting of the Mn"-Nf (proximal histidine) bond.     

Temperature dependence of Q-band electron paramagnetic resonance spectra of nitrosyl heme proteins

The Q-band (35 GHz) electron paramagnetic resonance (EPR) spectra of nitrosyl hemoglobin (HbNO) and nitrosyl myoglobin (MbNO) were studied as a function of temperature between 19 K and 200 K. The spectra of both heme proteins show two classes of variations as a function of temperature. The first one has previously been associated with the existence of two paramagnetic species, one with rhombic and the other with axial symmetry. The second one manifests itself in changes in the g-factors and linewidths of each species. These changes are correlated with the conformational substates model and associate the variations of g-values with changes in the angle of the N(his)-Fe-N(NO) bond in the rhombic species and with changes in the distance between Fe and N of the proximal (F8) histidine in the axial species.     

Iron nitrosyl hemoglobin formation from the reactions of hemoglobin and hydroxyurea

Hydroxyurea represents an approved treatment for sickle cell anemia and acts as a nitric oxide donor under oxidative conditions in vitro. Electron paramagnetic resonance spectroscopy shows that hydroxyurea reacts with oxy-, deoxy-, and methemoglobin to produce 2-6% of iron nitrosyl hemoglobin. No S-nitrosohemoglobin forms during these reactions. Cyanide and carbon monoxide trapping studies reveal that hydroxyurea oxidizes deoxyhemoglobin to methemoglobin and reduces methemoglobin to deoxyhemoglobin. Similar experiments reveal that iron nitrosyl hemoglobin formation specifically occurs during the reaction of hydroxyurea and methemoglobin. Experiments with hydroxyurea analogues indicate that nitric oxide transfer requires an unsubstituted acylhydroxylamine group and that the reactions of hydroxyurea and deoxy- and methemoglobin likely proceed by inner-sphere mechanisms. The formation of nitrate during the reaction of hydroxyurea and oxyhemoglobin and the lack of nitrous oxide production in these reactions suggest the intermediacy of nitric oxide as opposed to its redox form nitroxyl. A mechanistic model that includes a redox cycle between deoxyhemoglobin and methemoglobin has been forwarded to explain these results that define the reactivity of hydroxyurea and hemoglobin. These direct nitric oxide producing reactions of hydroxyurea and hemoglobin may contribute to the overall pathophysiological properties of this drug.     

The effect of inositol hexaphosphate on the absorption spectra of alpha and beta chains in nitrosyl hemoglobin.

The spectral changes of nitrosyl hemoglobin on addition of inositol hexaphosphate were studied in hybrid-heme hemoglobins. The results showed that the decrease in absorption in the Soret region was mainly due to a spectral change in alpha chains, and that the tension on heme in the quaternary T structure was much stronger in alpha than in beta chains.     

Heme structure of hemoglobin M Iwate [alpha 87(F8)His-->Tyr]: a UV and visible resonance Raman study

Heme structures of a natural mutant hemoglobin (Hb), Hb M Iwate [alpha87(F8)His-->Tyr], and protonation of its F8-Tyr were examined with the 244-nm excited UV resonance Raman (UVRR) and the 406.7- and 441.6-nm excited visible resonance Raman (RR) spectroscopy. It was clarified from the UVRR bands at 1605 and 1166 cm(-)(1) characteristic of tyrosinate that the tyrosine (F8) of the abnormal subunit in Hb M Iwate adopts a deprotonated form. UV Raman bands of other Tyr residues indicated that the protein takes the T-quaternary structure even in the met form. Although both hemes of alpha and beta subunits in metHb A take a six-coordinate (6c) high-spin structure, the 406.7-nm excited RR spectrum of metHb M Iwate indicated that the abnormal alpha subunit adopts a 5c high-spin structure. The present results and our previous observation of the nu(Fe)(-)(O(tyrosine)) Raman band [Nagai et al. (1989) Biochemistry 28, 2418-2422] have proved that F8-tyrosinate is covalently bound to Fe(III) heme in the alpha subunit of Hb M Iwate. As a result, peripheral groups of porphyrin ring, especially the vinyl and the propionate side chains, were so strongly influenced that the RR spectrum in the low-frequency region excited at 406.7 nm is distinctly changed from the normal pattern. When Hb M Iwate was fully reduced, the characteristic UVRR bands of tyrosinate disappeared and the Raman bands of tyrosine at 1620 (Y8a), 1207 (Y7a), and 1177 cm(-)(1) (Y9a) increased in intensity. Coordination of distal His(E7) to the Fe(II) heme in the reduced alpha subunit of Hb M Iwate was proved by the observation of the nu(Fe)(-)(His) RR band in the 441.6-nm excited RR spectrum at the same frequency as that of its isolated alpha chain. The effects of the distal-His coordination on the heme appeared as a distortion of the peripheral groups of heme. A possible mechanism for the formation of a Fe(III)-tyrosinate bond in Hb M Iwate is discussed.