Resonance Raman studies of lactoperoxidase

Resonance Raman (RR) spectra obtained at three excitation wavelengths are reported for various ferric, ferrous, and ferryl derivatives of bovine lactoperoxidase. The RR spectra of the ferric derivatives show the full complement of the vinyl stretching and scissor modes indicating that the two vinyls in the protoporphyrin IX prosthetic group are present in unmodified forms. The cysteine thiol complex exhibits a RR spectrum identical to that of the native enzyme, an observation which strongly suggests a nonheme binding site for the thiol substrates. The different ferrous complexes of lactoperoxidase which result from heme reduction at slightly alkaline and acidic pH gave identical low-frequency RR spectra. Differences are observed, however, in the high-frequency region. Reduction in the presence of cyanide, however, yields two time-resolved complexes. Changes in the ligand field during the conversion to the final form of the cyanoferrous complex are proposed based on the changes observed in the low-frequency vibrational spectrum. Comparisons are made between the low-frequency RR spectra of the limiting form of the cyanoferrous and the nitric oxide lactoperoxidase complexes. The similarity between the RR spectra of these two complexes in the 150-500 cm-1 region supports the assignment of structures for these complexes where the six-coordinate heme iron is displaced from the heme plane and away from the proximal histidine ligand.     

Resonance Raman detection of the Fe-S bond in endothelial nitric oxide synthase

We report the first low-frequency resonance Raman spectra of ferric endothelial nitric oxide synthase (eNOS) holoenzyme, including the frequency of the Fe-S vibration in the presence of the substrate L-arginine. This is the first direct measurement of the strength of the Fe-S bond in NOS. The Fe-S vibration is observed at 338 cm(-1) with excitation at 363.8 nm. The assignment of this band to the Fe-S stretching vibration was confirmed by the observation of isotopic shifts in eNOS reconstituted with 54Fe- and 57Fe-labeled hemin. Furthermore, the frequency of this vibration is close to those observed in cytochrome P450(cam) and chloroperoxidase (CPO). The frequency of this vibration is lower in eNOS than in P450(cam) and CPO, which can be explained by differences in hydrogen bonding to the proximal cysteine heme ligand. On addition of substrate to eNOS, we also observe several low-frequency vibrations, which are associated with the heme pyrrole groups. The enhancement of these vibrations suggests that substrate binding results in protein-mediated changes of the heme geometry, which may provide the protein with an additional tuning element for the redox potential of the heme iron. The implications of our findings for the function of eNOS will be discussed by comparison with P450(cam) and model compounds.     

Investigations of vibrational coherence in the low-frequency region of ferric heme proteins

Femtosecond coherence spectroscopy is applied to a series of ferric heme protein samples. The low-frequency vibrational spectra that are revealed show dominant oscillations near 40 cm⁻¹. MbCN is taken as a typical example of a histidine-ligated, six-coordinate, ferric heme and a comprehensive spectroscopic analysis is carried out. The results of this analysis reveal a new heme photoproduct species, absorbing near 418 nm, which is consistent with the photolysis of the His⁹³ axial ligand. The photoproduct undergoes subsequent rebinding/recovery with a time constant of ∼4 ps. The photoproduct lineshapes are consistent with a photolysis quantum yield of 75-100%, although the observation of a relatively strong six-coordinate heme coherence near 252 cm⁻¹ (assigned to ν₉ in the MbCN Raman spectrum) suggests that the 75% lower limit is much more likely. The phase and amplitude excitation profiles of the low-frequency mode at 40 cm⁻¹ suggest that this mode is strongly coupled to the MbCN photoproduct species and it is assigned to the doming mode of the transient penta-coordinated material. The absolute phase of the 40 cm⁻¹ mode is found to be π/2 on the red side of 418 nm and it jumps to 3π/2 as excitation is tuned to the blue side of 418 nm. The absolute phase of the 40 cm⁻¹ signal is not explained by the standard theory for resonant impulsive stimulated Raman scattering. New mechanisms that give a dominant momentum impulse to the resonant wavepacket, rather than a coordinate displacement, are discussed. The possibilities of heme iron atom recoil after photolysis, as well as ultrafast nonradiative decay, are explored as potential ways to generate the strong momentum impulse needed to understand the phase properties of the 40 cm⁻¹ mode.     

Neuronal nitric oxide synthase ligand and protein vibrations at the substrate binding site. A study by FTIR

Improvements in sensitivity and data processing of Fourier transform infrared (FTIR) spectroscopy enable it to be used to detect changes in protein structure at the atomic level. This paper reports a study of neuronal nitric oxide synthase (nNOS) by FTIR difference spectroscopy in the 1000-2500 cm(-1) range where vibrational bands of ligands, prosthetic groups, and protein and amino acid side chains are found. We have exploited the photolyzable CO compound of the ferrous heme of nNOS to produce light-induced CO photolysis difference spectra and to compare spectra after hydrogen/deuterium exchange. In (reduced) minus (reduced plus CO) difference spectra, negative bands at 1931 and 1907 cm(-1) are observed due to photolysis of multiple forms of ferrous heme-ligated CO, similar to those observed by resonance Raman spectroscopy [Wang et al. (1997) Biochemistry 36, 4595-4606]. Photolysis of the ferrous heme CO compound is accompanied by hitherto unreported changes in the 1000-2000 cm(-1) region that arise from changes of protein backbone, substrate, amino acid side chain, and cofactor vibrations. Preliminary assignments of vibrations are made on the basis of frequencies and the effects of hydrogen/deuterium exchange, and in the light of known atomic structures.     

EPR studies on the photo-induced intermediates of ferric NO complexes of rat neuronal nitric oxide synthase trapped at low temperature.

Rat neuronal nitric oxide synthase (nNOS) was expressed in Escherichia coli and purified. Although the nitric oxide (NO) complex of the ferric heme was EPR-silent, photo-illumination at 5 K to the NO complex of the ferric nNOS in the substrate-free form produced a new high spin EPR signal similar to that of the ferric heme of N(omega)-nitro-L-arginine-bound nNOS, suggesting that the photo-dissociated NO might move away from the heme. Low photo-dissociability of NO in this complex indicated less restricted movement of the dissociated NO in the distal region of the heme, which might result in the rapid rebinding of the NO to the ferric heme at 5 K. In the presence of substrate L-arginine, derivatives, or product L-citrulline, the photo-products from the ferric NO complexes exhibited large novel EPR signals with a spin-coupled interaction between the ferric heme (S = 5/2) and the photolyzed NO (S = 1/2), suggesting a stereochemically restricted interaction between the photo-dissociated NO and the guanidino- or the ureido-group of the substrate analogues at the distal heme region of nNOS. The photo-product from the NO complex produced from citrulline-bound nNOS might be the same intermediate species as that formed in the last step of the catalytic cycle.     

Heme environment in aldoxime dehydratase involved in carbon-nitrogen triple bond synthesis

Resonance Raman spectra have been measured to characterize the heme environment in aldoxime dehydratase (OxdA), a novel hemoprotein, which catalyzes the dehydration of aldoxime into nitrile. The spectra showed that the ferric heme in the enzyme is six-coordinate low spin, whereas the ferrous heme is five-coordinate high spin. We assign a prominent vibration that occurs at 226 cm(-1) in the ferrous enzyme to the Fe-proximal histidine stretching vibration. In the CO-bound form of OxdA, the correlation between the Fe-CO stretching (512 cm(-1)) and C-O stretching (1950 cm(-1)) frequencies also supports our assignment of proximal histidine coordination.     

Time-resolved absorption and magnetic circular dichroism spectroscopy of cytochrome c3 from Desulfovibrio.

The UV-visible absorption and magnetic circular dichroism (MCD) spectra of the ferric, ferrous, CO-ligated forms and kinetic photolysis intermediates of the tetraheme electron-transfer protein cytochrome c3 (Cc3) are reported. Consistent with bis-histidinyl axial coordination of the hemes in this Class III c-type cytochrome, the Soret and visible region MCD spectra of ferric and ferrous Cc3 are very similar to those of other bis-histidine axially coordinated hemeproteins such as cytochrome b5. The MCD spectra indicate low spin state for both the ferric (S = 1/2) and ferrous (S = 0) oxidation states. CO replaces histidine as the axial sixth ligand at each heme site, forming a low-spin complex with an MCD spectrum similar to that of myoglobin-CO. Photodissociation of Cc3-CO (observed photolysis yield = 30%) produces a transient five-coordinate, high-spin (S = 2) species with an MCD spectrum similar to deoxymyoglobin. The recombination kinetics of CO with heme Fe are complex and appear to involve at least five first-order or pseudo first-order rate processes, corresponding to time constants of 5.7 microseconds, 62 microseconds, 425 microseconds, 2.9 ms, and a time constant greater than 1 s. The observed rate constants were insensitive to variation of the actinic photon flux, suggesting noncooperative heme-CO rebinding. The growing in of an MCD signal characteristic of bis-histidine axial ligation within tens of microseconds after photodissociation shows that, although heme-CO binding is thermodynamically favored at 1 atm CO, binding of histidine to the sixth axial site competes kinetically with CO rebinding.     

Active site of bovine adrenocortical cytochrome P-450(11) beta studied by resonance Raman and electron paramagnetic resonance spectroscopies: distinction from cytochrome P-450scc

Cytochrome P-45011 beta was purified as the 11-deoxycorticosterone-bound form from bovine adrenocortical mitochondria and its active site was investigated by resonance Raman and EPR spectroscopies. Resonance Raman spectra of the purified sample revealed that the heme iron adopts the pure pentacoordinated ferric high-spin state on the basis of the nu 10 (1629cm-1) and nu 3 (1490 cm-1) mode frequencies, which are higher than those of the hexacoordinated ferric high-spin cytochrome P-450scc-substrate complexes. In the ferrous-CO state, a Fe2(+)-CO stretching mode was identified at 481.5 cm-1 on the basis of an isotopic substitution technique; this frequency is very close to that of cytochrome P-450scc in the cholesterol-complexed state (483 cm-1). The EPR spectra of the purified sample at 4.2 K showed ferric high-spin signals (at g = 7.98, 3.65, and 1.71) that were clearly distinct from the cytochrome P-450scc ferric high-spin signals (g = 8.06, 3.55, and 1.68) and confirmed previous assignments of ferric high-spin signals in adrenocortical mitochondria. The EPR spectra of the nitric oxide (NO) complex of ferrous cytochrome P-45011 beta showed EPR signals with rhombic symmetry (gx = 2.068, gz = 2.001, and gy = 1.961) very similar to those of the ferrous cytochrome P-450scc-NO complex in the presence of 22(S)-hydroxycholesterol and 20(R),22-(R)-dihydroxycholesterol at 77 K.(ABSTRACT TRUNCATED AT 250 WORDS)     

Resonance Raman investigations of Escherichia coli-expressed Pseudomonas putida cytochrome P450 and P420.

High-resolution resonance Raman spectra of the ferric, ferrous, and carbonmonoxy (CO)-bound forms of wild-type Escherichia coli-expressed Pseudomonas putida cytochrome P450cam and its P420 form are reported. The ferric and ferrous species of P450 and P420 have been studied in both the presence and absence of excess camphor substrate. In ferric, camphor-bound, P450 (mos), the E. coli-expressed P450 is found to be spectroscopically indistinguishable from the native material. Although substrate binding to P450 is known to displace water molecules from the heme pocket, altering the coordination and spin state of the heme iron, the presence of camphor substrate in P420 samples is found to have essentially no effect on the Raman spectra of the heme in either the oxidized or reduced state. A detailed study of the Raman and absorption spectra of P450 and P420 reveals that the P420 heme is in equilibrium between a high-spin, five-coordinate (HS,5C) form and low-spin six-coordinate (LS,6C) form in both the ferric and ferrous oxidation states. In the ferric P420 state, H2O evidently remains as a heme ligand, while alterations of the protein tertiary structure lead to a significant reduction in affinity for Cys(357) thiolate binding to the heme iron. Ferrous P420 also consists of an equilibrium between HS,5C and LS,6C states, with the spectroscopic evidence indicating that H2O and histidine are the most likely axial ligands. The spectral characteristics of the CO complex of P420 are found to be almost identical to those of a low pH of Mb. Moreover, we find that the 10-ns transient Raman spectrum of the photolyzed P420 CO complex possesses a band at 220 cm-1, which is strong evidence in favor of histidine ligation in the CO-bound state. The equilibrium structure of ferrous P420 does not show this band, indicating that Fe-His bond formation is favored when the iron becomes more acidic upon CO binding. Raman spectra of stationary samples of the CO complex of P450 reveal VFe-CO peaks corresponding to both substrate-bound and substrate-free species and demonstrate that substrate dissociation is coupled to CO photolysis. Analysis of the relative band intensities as a function of photolysis indicates that the CO photolysis and rebinding rates are faster than camphor rebinding and that CO binds to the heme faster when camphor is not in the distal pocket.     

Molecular basis for nitric oxide dynamics and affinity with Alcaligenes xylosoxidans cytochrome c

The bacterial heme protein cytochrome ? from Alcaligenes xylosoxidans (AXCP) reacts with nitric oxide (NO) to form a 5-coordinate ferrous nitrosyl heme complex. The crystal structure of ferrous nitrosyl AXCP has previously revealed that NO is bound in an unprecedented manner on the proximal side of the heme. To understand how the protein structure of AXCP controls NO dynamics, we performed absorption and Raman time-resolved studies at the heme level as well as a molecular computational dynamics study at the entire protein structure level. We found that after NO dissociation from the heme iron, the structure of the proximal heme pocket of AXCP confines NO close to the iron so that an ultrafast (7 ps) and complete (99 +/- 1%) geminate rebinding occurs, whereas the proximal histidine does not rebind to the heme iron on the timescale of NO geminate rebinding. The distal side controls the initial NO binding, whereas the proximal heme pocket controls its release. These dynamic properties allow the trapping of NO within the protein core and represent an extreme behavior observed among heme proteins.     

Binding of NO and CO to the d(1) Heme of cd(1) nitrite reductase from Pseudomonas aeruginosa

The cd(1) nitrite reductase, a key enzyme in bacterial denitrification, catalyzes the one-electron reduction of nitrite to nitric oxide. The enzyme contains two redox centers, a c-type heme and a unique d(1) heme, which is a dioxoisobacteriochlorin. Nitric oxide, generated by this enzymatic pathway, if not removed from the medium, can bind to the ferrous d(1) cofactor with extremely high affinity and inhibit enzyme activity. In this paper, we report the resonance Raman investigation of the properties of nitric oxide and carbon monoxide binding to the d(1) site of the reduced enzyme. The Fe-ligand (Fe-NO and Fe-CO) stretching vibrational frequencies are unusually high in comparison to those of other ferrous heme complexes. The frequencies of the Fe-NO and N-O stretching modes appear at 585 and 1626 cm(-1), respectively, in the NO complex, while the frequencies of the Fe-CO and C-O stretching modes are at 563 and 1972 cm(-1), respectively, for the CO complex. Also, the widths (fwhm) of the Fe-CO and C-O stretching modes are smaller than those observed in the corresponding complexes of other heme proteins. The unusual spectroscopic characteristics of the d(1) cofactor are discussed in terms of both its unique electronic properties and the strongly polar distal environment around the iron-bound ligand. It is likely that the influence of a highly ruffled structure of heme d(1) on its electronic properties is the major factor causing anomalous Fe-ligand vibrational frequencies.     

The potential of Angeli's salt to decrease nitric oxide scavenging by plasma hemoglobin

Release of hemoglobin from the erythrocyte during intravascular hemolysis contributes to the pathology of a variety of diseased states. This effect is partially due to the enhanced ability of cell-free plasma hemoglobin, which is primarily found in the ferrous, oxygenated state, to scavenge nitric oxide. Oxidation of the cell-free hemoglobin to methemoglobin, which does not effectively scavenge nitric oxide, using inhaled nitric oxide has been shown to be effective in limiting pulmonary and systemic vasoconstriction. However, the ferric heme species may be reduced back to ferrous hemoglobin in plasma and has the potential to drive injurious redox chemistry. We propose that compounds that selectively convert cell-free hemoglobin to ferric, and ideally iron-nitrosylated heme species that do not actively scavenge nitric oxide, would effectively treat intravascular hemolysis. We show here that nitroxyl generated by Angeli's salt (sodium alpha-oxyhyponitrite, Na2N2O3) preferentially reacts with cell-free hemoglobin compared to that encapsulated in the red blood cell under physiologically relevant conditions. Nitroxyl oxidizes oxygenated ferrous hemoglobin to methemoglobin and can convert the methemoglobin to a more stable, less toxic species, iron-nitrosyl hemoglobin. These results support the notion that Angeli's salt or a similar compound could be used to effectively treat conditions associated with intravascular hemolysis.     

Reactions of ferrous neuroglobin and cytoglobin with nitrite under anaerobic conditions

Recent evidence suggests that the reaction of nitrite with deoxygenated hemoglobin and myoglobin contributes to the generation of nitric oxide and S-nitrosothiols in vivo under conditions of low oxygen availability. We have investigated whether ferrous neuroglobin and cytoglobin, the two hexacoordinate globins from vertebrates expressed in brain and in a variety of tissues, respectively, also react with nitrite under anaerobic conditions. Using absorption spectroscopy, we find that ferrous neuroglobin and nitrite react with a second-order rate constant similar to that of myoglobin, whereas the ferrous heme of cytoglobin does not react with nitrite. Deconvolution of absorbance spectra shows that, in the course of the reaction of neuroglobin with nitrite, ferric Fe(III) heme is generated in excess of nitrosyl Fe(II)-NO heme as due to the low affinity of ferrous neuroglobin for nitric oxide. By using ferrous myoglobin as scavenger for nitric oxide, we find that nitric oxide dissociates from ferrous neuroglobin much faster than previously appreciated, consistently with the decay of the Fe(II)-NO product during the reaction. Both neuroglobin and cytoglobin are S-nitrosated when reacting with nitrite, with neuroglobin showing higher levels of S-nitrosation. The possible biological significance of the reaction between nitrite and neuroglobin in vivo under brain hypoxia is discussed.     

Interactions of soluble guanylate cyclase with diatomics as probed by resonance Raman spectroscopy

Soluble guanylate cyclase (sGC, EC 4.6.1.2) acts as a sensor for nitric oxide (NO), but is also activated by carbon monoxide in the presence of an allosteric modulator. Resonance Raman studies on the structure-function relations of sGC are reviewed with a focus on the CO-adduct in the presence and absence of allosteric modulator, YC-1, and substrate analogues. It is demonstrated that the sGC isolated from bovine lung contains one species with a five-coordinate (5c) ferrous high-spin heme with the Fe-His stretching mode at 204 cm(-1), but its CO adduct yields two species with different conformations about the heme pocket with the Fe-CO stretching (nuFe-CO) mode at 473 and 489 cm(-1), both of which are His- and CO-coordinated 6c ferrous adducts. Addition of YC-1 to it changes their population and further addition of GTP yields one kind of 6c (nuFe-CO=489 cm(-1)) in addition to 5c CO-adduct (nuFe-CO=521 cm(-1)). Under this condition the enzymatic activity becomes nearly the same level as that of NO adduct. Addition of gamma-S-GTP yields the same effect as GTP does but cGMP and GDP gives much less effects. Unexpectedly, ATP cancels the effects of GTP. The structural meaning of these spectroscopic observations is discussed in detail.     

Residues in the distal heme pocket of neuroglobin. Implications for the multiple ligand binding steps

Amino acid residues in the ligand binding pocket of human neuroglobin have been identified by site-directed mutagenesis and their properties investigated by resonance Raman and flash photolysis methods. Wild-type neuroglobin has been shown to have six-coordinate heme in both ferric and ferrous states. Substitution of His96 by alanine leads to complete loss of heme, indicating that His96 is the proximal ligand. The resonance Raman spectra of M69L and K67T mutants were similar to those of wild-type (WT) neuroglobin in both ferric and ferrous states. By contrast, H64V was six-coordinate high-spin and five-coordinate high-spin in the ferric and ferrous states, respectively, at acidic pH. The spectra were pH-dependent and six-coordinate with the low-spin component dominating at alkaline pH. In a double mutant H64V/K67T, the high-spin component alone was detected in the both ferric and the ferrous states. This implies that His64 is the endogenous ligand and that Lys67 is situated nearby in the distal pocket. In the ferrous H64V and H64V/K67T mutants, the nu(Fe-His) stretching frequency appears at 221 cm(-1), which is similar to that of deoxymyoglobin. In the ferrous CO-bound state, the nu(Fe-CO) stretching frequency was detected at 521 and 494 cm(-1) in WT, M69L, and K67T, while only the 494 cm(-1) component was detected in the H64V and H64V/K67T mutants. Thus, the 521 cm(-1) component is attributed to the presence of polar His64. The CO binding kinetics were biphasic for WT, H64V, and K67T and monophasic for H64V/K67T. Thus, His64 and Lys67 comprise a unique distal heme pocket in neuroglobin.     

Structural dynamics in the active site of murine neuroglobin and its effects on ligand binding

We have examined the effects of active site residues on ligand binding to the heme iron of mouse neuroglobin using steady-state and time-resolved visible spectroscopy. Absorption spectra of the native protein, mutants H64L and K67L and double mutant H64L/K67L were recorded for the ferric and ferrous states over a wide pH range (pH 4-11), which allowed us to identify a number of different species with different ligands at the sixth coordination, to characterize their spectroscopic properties, and to determine the pK values of active site residues. In flash photolysis experiments on CO-ligated samples, reaction intermediates and the competition of ligands for the sixth coordination were studied. These data provide insights into structural changes in the active site and the role of the key residues His64 and Lys67. His64 interferes with exogenous ligand access to the heme iron. Lys67 sequesters the distal pocket from the solvent. The heme iron is very reactive, as inferred from the fast ligand binding kinetics and the ability to bind water or hydroxyl ligands to the ferrous heme. Fast bond formation favors geminate rebinding; yet the large fraction of bimolecular rebinding observed in the kinetics implies that ligand escape from the distal pocket is highly efficient. Even slight pH variations cause pronounced changes in the association rate of exogenous ligands near physiological pH, which may be important in functional processes.     

Study on the redox state dependent gamma(CH) vibrational modes of the c-type heme

Absorbance Fourier transform infrared (FTIR) spectra of model compounds for heme proteins such as protoporphyrin-IX, hemin, and hematin have been directly compared to the data of electrochemically induced FTIR difference spectra of small c-type proteins, i.e., microperoxidase-11, and cytochrome c. A band at 840-830 cm(-1) occurring in all studied samples dominated the spectra. The position of this vibrational mode depends on pH and the oxidation state, and could be assigned to the gamma(CH) mode of the porphyrin ring. Further features, such as the ring vibrations sensitive for the presence of iron and its oxidation state, are shown in the low-frequency infrared region between 750 and 650 cm(-1).     

Formation of a bis(histidyl) heme iron complex in manganese peroxidase at high pH and restoration of the native enzyme structure by calcium

Manganese peroxidase (MnP) from Phanerochaete chrysosporium undergoes a pH-dependent conformational change evidenced by changes in the electronic absorption spectrum. This high- to low-spin alkaline transition occurs at approximately 2 pH units lower in an F190I mutant MnP when compared to the wild-type enzyme. Herein, we provide evidence that these spectral changes are attributable to the formation of a bis(histidyl) heme iron complex in both proteins at high pH. The resonance Raman (RR) spectra of both ferric proteins at high pH are similar, indicating similar heme environments in both proteins, and resemble that of ferric cytochrome b(558), a protein that contains a bis-His iron complex. Upon reduction with dithionite at high pH, the visible spectra of both the wild-type and F190I MnP exhibit absorption maxima at 429, 529, and 558 nm, resembling the absorption spectrum of ferrous cytochrome b(558). RR spectra of the reduced wild-type and F190I mutant proteins at high pH are also similar to the RR spectrum of ferrous cytochrome b(558), further suggesting that the alkaline low-spin species is a bis(histidyl) heme derivative. No shift in the low-frequency RR bands was observed in 75% (18)O-labeled water, indicating that the low-spin species is most likely not a hydroxo-heme derivative. Electronic and RR spectra also indicate that addition of Ca(2+) to either the ferric or ferrous enzymes at high pH completely restores the high-spin pentacoordinate species. Other divalent metals, such as Mn(2+), Mg(2+), Zn(2+), or Cd(2+), do not restore the enzyme under the conditions studied.     

Evidence for nonhydrogen bonded compound II in cyclic reaction of hemoglobin I from Lucina pectinata with hydrogen peroxide

Studies that elucidate the behavior of the hemoglobins (Hbs) and myoglobins upon reaction with hydrogen peroxide are essential to the development of oxygen carrier substitutes. Stopped-flow kinetics and resonance Raman data show that the reaction between hydrogen peroxide and oxygenated and deoxygenated ferric Hb I (oxy- and deoxy-HbI) from Lucina pectinata produce compound I and compound II ferryl species. The rate constants ratio (k23/k41) between the formation of compound II from compound I (k23) and the oxidation of the ferrous HbI (k41, i.e., 25 M(-1) s(-1)) of 12 x 10(-4) M suggests that HbI has a peroxidative capacity for removing H2O2 from solution. Resonance Raman presents the formation of both, met-aquo-HbI and compound II ferryl species in the cyclic reaction of HbI with H2O2. The ferric HbI species is maintained by the presence of H2O2; it can produce HbI compound I, or it can be reduced to a deoxy-HbI derivative to form HbI compound II upon reaction with H2O2. The compound II ferryl vibration frequency appears at 805 and 769 cm(-1) for HbIFe(IV)=(16)O and HbIFe(IV)=(18)O species, respectively. This ferryl mode indicates the absence of hydrogen bonding between the carbonyl group of the distal Q64 and the HbIFe(IV)=O ferryl moiety. The observation suggests that both the trans-ligand effect and the polarizabilty of the HbI heme pocket are responsible for the observed ferryl oxo vibrational energy. The vibrational mode also suggests that the carbonyl group of the distal Q64 is oriented toward the iron of the heme group, increasing the distal pocket electron density.     

Mechanism and biological role of nitric oxide binding to cytochrome c'

The binding of nitric oxide to ferric and ferrous Chromatium vinosum cytochrome c' was studied. The extinction coefficients for the ferric and ferrous nitric oxide complexes were measured. A binding model that included both a conformational change and dissociation of the dimer into subunits provided the best fit for the ferric cytochrome c' data. The NO (nitric oxide) binding affinity of the WT ferric form was found to be comparable to the affinities displayed by the ferric myoglobins and hemoglobins. Using an improved fitting model, positive cooperativity was found for the binding of NO to the WT ferric and ferrous forms, while anticooperativity was the case for the Y16F mutant. Structural explanations accounting for the binding are proposed. The NO affinity of ferrous cytochrome c' was found to be much lower than the affinities of myoglobins, hemoglobins, and pentacoordinate heme models. Structural factors accounting for the difference in affinities were analyzed. The NO affinity of ferrous cytochrome c' was found to be in the range typical of receptors and carriers. In addition, cytochrome c' was found to react with cytosolic light-irradiated membranes in the presence of succinate and carbon monoxide. With these results, a biochemical model of cytochrome c' functioning as a nitric oxide carrier was proposed.