A comparative resonance Raman analysis of heme-binding PAS domains: heme iron coordination structures of the BjFixL, AxPDEA1, EcDos, and MtDos proteins

The heme-PAS is a specialized domain with which a broad class of signal-transducing heme proteins detect physiological heme ligands. Such domains exhibit a wide range of ligand binding parameters, yet they are all expected to feature an alpha-beta heme binding fold and a predominantly hydrophobic heme distal pocket without a distal histidine. We have compared, for the first time, the resonance Raman spectra of several heme-PASs: the heme-binding domains of Bradyrhizobium japonicum FixL, Escherichia coli Dos, Acetobacter xylinum PDEA1, and Methanobacterium thermoautotrophicum Dos. In all cases, the nu(Fe)-(CO) and nu(C-O) values of the carbonmonoxy forms were consistent with coordination of the heme iron to histidine on the proximal side and binding of the CO without electrostatic interaction with the heme distal pocket. EcDos was unusual in having predominantly hexacoordinate heme iron in the deoxy and met forms. Despite an evident lack of CO interaction with the EcDos heme pocket, relatively low Fe-O(2) (562 cm(-1)) and N-O (1576 cm(-1)) stretching frequencies indicated that strong polar interactions with that heme distal pocket are possible for highly bent ligands such as O(2) or NO. None of the newly studied NO adducts exhibited evidence of the Fe-His rupture and pentacoordination previously noted for Sinorhizobium meliloti FixL. A low Fe-His stretching frequency, formerly interpreted as a strained Fe-His bond, and the slow association of O(2) with S. meliloti FixL failed to correlate with the newly studied proteins having low association rate or low equilibrium association constants for binding of O(2). We conclude that although heme-PASs share some features, they represent distinct signal transduction mechanisms.     

Resonance Raman studies indicate a unique heme active site in prostaglandin H synthase

Prostaglandin H synthase isoforms 1 and 2 (PGHS-1 and -2) catalyze the first two steps in the biosynthesis of prostaglandins. Resonance Raman spectroscopy was used to characterize the PGHS heme active site and its immediate environment. Ferric PGHS-1 has a predominant six-coordinate high-spin heme at room temperature, with water as the sixth ligand. The proximal histidine ligand (or the distal water ligand) of this hexacoordinate high-spin heme species was reversibly photolabile, leading to a pentacoordinate high-spin ferric heme iron. Ferrous PGHS-1 has a single species of five-coordinate high-spin heme, as evident from nu(2) at 1558 cm(-1) and nu(3) at 1471 cm(-1). nu(4) at 1359 cm(-1) indicates that histidine is the proximal ligand. A weak band at 226-228 cm(-1) was tentatively assigned as the Fe-His stretching vibration. Cyanoferric PGHS-1 exhibited a nu(Fe)(-)(CN) line at 446 cm(-1) and delta(Fe)(-)(C)(-)(N) at 410 cm(-1), indicating a "linear" Fe-C-N binding conformation with the proximal histidine. This linkage agrees well with the open distal heme pocket in PGHS-1. The ferrous PGHS-1 CO complex exhibited three important marker lines: nu(Fe)(-)(CO) (531 cm(-1)), delta(Fe)(-)(C)(-)(O) (567 cm(-1)), and nu(C)(-)(O) (1954 cm(-1)). No hydrogen bonding was detected for the heme-bound CO in PGHS-1. These frequencies markedly deviated from the nu(Fe)(-)(CO)/nu(C)(-)(O) correlation curve for heme proteins and porphyrins with a proximal histidine or imidazolate, suggesting an extremely weak bond between the heme iron and the proximal histidine in PGHS-1. At alkaline pH, PGHS-1 is converted to a second CO binding conformation (nu(Fe)(-)(CO): 496 cm(-1)) where disruption of the hydrogen bonding interactions to the proximal histidine may occur.     

Interactions between nitric oxide and indoleamine 2,3-dioxygenase

Indoleamine 2,3-dioxygenase (IDO) is a heme-containing enzyme, which catalyzes the initial and rate-determining step of L-tryptophan (L-Trp) metabolism via the kynurenine pathway in nonhepatic tissues. Similar to inducible nitric oxide synthase (iNOS), IDO is induced by interferon-gamma and lipopolysaccharide in the inflammatory response. In vivo studies indicate that the nitric oxide (NO) produced by iNOS inhibits IDO activity by directly interacting with it and by promoting its degradation through the proteasome pathway. In this work, the molecular mechanisms underlying the interactions between NO and human recombinant IDO (hIDO) were systematically studied with optical absorption and resonance Raman spectroscopies. Resonance Raman data show that the heme prosthetic group in the NO-bound hIDO is situated in a unique protein environment and adopts an out-of-plane deformed geometry that is sensitive to L-Trp binding. Under mildly acidic conditions, the proximal heme iron-His bond is prone to rupture, resulting in a five-coordinate (5C) NO-bound species. The bond breakage reaction induces significant conformational changes in the protein matrix, which may account for the NO-induced inactivation of hIDO and its enhanced proteasome-linked degradation in vivo. Moreover, it was found that the NO-induced bond breakage reaction occurs more rapidly in the ferrous protein than in the ferric protein and is fully inhibited by L-Trp binding. The spectroscopic data presented here not only provide the first glimpse of the possible regulatory mechanism of hIDO by NO in the cell at the molecular level, but they also suggest that the NO-dependent regulation can be modulated by cellular factors, such as the NO abundance, pH, redox environment, and L-Trp availability.     

Ligand migration in human indoleamine-2,3 dioxygenase

Human indoleamine 2,3-dioxygenase (hIDO), a monomeric heme enzyme, catalyzes the oxidative degradation of L-tryptophan (L-Trp) and other indoleamine derivatives. Its activity follows typical Michaelis-Menten behavior only for L-Trp concentrations up to 50 μM; a further increase in the concentration of L-Trp causes a decrease in the activity. This substrate inhibition of hIDO is a result of the binding of a second L-Trp molecule in an inhibitory substrate binding site of the enzyme. The molecular details of the reaction and the inhibition are not yet known. In the following, we summarize the present knowledge about this heme enzyme.     

Accessibility of the distal heme face, rather than Fe-His bond strength, determines the heme-nitrosyl coordination number of cytochromes c': evidence from spectroscopic studies

The heme coordination chemistry and spectroscopic properties of Rhodobacter capsulatus cytochrome c' (RCCP) have been compared to data from Alcaligenes xylosoxidans (AXCP), with the aim of understanding the basis for their different reactivities with nitric oxide (NO). Whereas ferrous AXCP reacts with NO to form a predominantly five-coordinate heme-nitrosyl complex via a six-coordinate intermediate, RCCP forms an equilibrium mixture of six-coordinate and five-coordinate heme-nitrosyl species in approximately equal proportions. Ferrous RCCP and AXCP both exhibit high Fe-His stretching frequencies (227 and 231 cm(-)(1), respectively), suggesting that factors other than the Fe-His bond strength account for their differences in heme-nitrosyl coordination number. Resonance Raman spectra of ferrous-nitrosyl RCCP confirm the presence of both five-coordinate and six-coordinate heme-NO complexes. The six-coordinate heme-nitrosyl of RCCP exhibits a fairly typical Fe-NO stretching frequency (569 cm(-)(1)), in contrast to the relatively high value (579 cm(-)(1)) of the AXCP six-coordinate heme-nitrosyl intermediate. It is proposed that NO experiences greater steric hindrance in binding to the distal face of AXCP, as compared to RCCP, leading to a more distorted Fe-N-O geometry and an elevated Fe-NO stretching frequency. Evidence that RCCP has a more accessible distal coordination site than in AXCP stems from the fact that ferric RCCP readily forms a heme complex with exogenous imidazole, whereas AXCP does not. A model is proposed in which distal heme-face accessibility, rather than the proximal Fe-His bond strength, determines the heme-nitrosyl coordination number in cytochromes c'.     

Crystal structures of CO and NO adducts of MauG in complex with pre-methylamine dehydrogenase: implications for the mechanism of dioxygen activation

MauG is a diheme enzyme responsible for the post-translational formation of the catalytic tryptophan tryptophylquinone (TTQ) cofactor in methylamine dehydrogenase (MADH). MauG can utilize hydrogen peroxide, or molecular oxygen and reducing equivalents, to complete this reaction via a catalytic bis-Fe(IV) intermediate. Crystal structures of diferrous, Fe(II)-CO, and Fe(II)-NO forms of MauG in complex with its preMADH substrate have been determined and compared to one another as well as to the structure of the resting diferric MauG-preMADH complex. CO and NO each bind exclusively to the 5-coordinate high-spin heme with no change in ligation of the 6-coordinate low-spin heme. These structures reveal likely roles for amino acid residues in the distal pocket of the high-spin heme in oxygen binding and activation. Glu113 is implicated in the protonation of heme-bound diatomic oxygen intermediates in promoting cleavage of the O-O bond. Pro107 is shown to change conformation on the binding of each ligand and may play a steric role in oxygen activation by positioning the distal oxygen near Glu113. Gln103 is in a position to provide a hydrogen bond to the Fe(IV)═O moiety that may account for the unusual stability of this species in MauG.     

Determinants of the heme-CO vibrational modes in the H-NOX family

The Heme Nitric oxide/OXygen binding (H-NOX) family of proteins have important functions in gaseous ligand signaling in organisms from bacteria to humans, including nitric oxide (NO) sensing in mammals, and provide a model system for probing ligand selectivity in hemoproteins. A unique vibrational feature that is ubiquitous throughout the H-NOX family is the presence of a high C-O stretching frequency. To investigate the cause of this spectroscopic characteristic, the Fe-CO and C-O stretching frequencies were probed in the H-NOX domain from Thermoanaerobacter tengcongensis (Tt H-NOX) using resonance Raman (RR) spectroscopy. Four classes of heme pocket mutants were generated to assess the changes in stretching frequency: (i) the distal H-bonding network, (ii) the proximal histidine ligand, (iii) modulation of the heme conformation via Ile-5 and Pro-115, and (iv) the conserved Tyr-Ser-Arg (YxSxR) motif. These mutations revealed important electrostatic interactions that dampen the back-donation of the Fe(II) d(π) electrons into the CO π* orbitals. The most significant change occurred upon disruption of the H-bonds between the strictly conserved YxSxR motif and the heme propionate groups, producing two dominant CO-bound heme conformations. One conformer was structurally similar to Tt H-NOX WT, whereas the other displayed a decrease in ν(C-O) of up to ～70 cm(-1) relative to the WT protein, with minimal changes in ν(Fe-CO). Taken together, these results show that the electrostatic interactions in the Tt H-NOX binding pocket are primarily responsible for the high ν(C-O) by decreasing the Fe d(π) → CO π* back-donation and suggest that the dominant mechanism by which this family modulates the Fe(II)-CO bond likely involves the YxSxR motif.     

The critical role of the proximal calcium ion in the structural properties of horseradish peroxidase

The extent to which the structural Ca(2+) ions of horseradish peroxidase (HRPC) are a determinant in defining the heme pocket architecture is investigated by electronic absorption and resonance Raman spectroscopy upon removal of one Ca(2+) ion. The Fe(III) heme states are modified upon Ca(2+) depletion, with an uncommon quantum mechanically mixed spin state becoming the dominant species. Ca(2+)-depleted HRPC forms complexes with benzohydroxamic acid and CO which display spectra very similar to those of native HRPC, indicating that any changes to the distal cavity structural properties upon Ca(2+) depletion are easily reversed. Contrary to the native protein, the Ca(2+)-depleted ferrous form displays a low-spin bis-histidyl heme state and a small proportion of high-spin heme. Furthermore, the nu(Fe-Im) stretching mode downshifts 27 cm(-1) upon Ca(2+) depletion revealing a significant structural perturbation of the proximal cavity near the histidine ligand. The specific activity of the Ca(2+)-depleted enzyme is 50% that of the native form. The effects on enzyme activity and spectral features observed upon Ca(2+) depletion are reversible upon reconstitution. Evaluation of the present and previous data firmly favors the proximal Ca(2+) ion as that which is lost upon Ca(2+) depletion and which likely plays the more critical role in regulating the heme pocket structural and catalytic properties.     

Modulation of the NO<Emphasis Type="Italic"> trans</Emphasis> effect in heme proteins: implications for the activation of soluble guanylate cyclase

The binding of NO to the iron heme in guanylate cyclase and other heme proteins induces the cleavage of the proximal histidine bonded to the metal. In this study we assess by means of density functional theory (DFT) electronic structure calculations the role of H-bonding to histidine in the modulation of this effect. We have considered in the first place a model of the isolated active site coordinated with imidazole and imidazolate to mimic the effects of a very strong H-bond. We have also investigated four selected ferrous heme proteins with different proximal histidine environments: the O(2) sensing FixL, horseradish peroxidase C, and the alpha and beta subunits of human hemoglobin. Our results indicate that polarization and charge transfer effects associated with H-bonding to the proximal histidine play a fundamental role in the modulation of the NO trans effect in heme proteins. We also find computational evidence suggesting that protein structural constraints may affect significantly the cleavage of the Fe-His bond.     

Iron coordination structures of oxygen sensor FixL characterized by Fe K-edge extended x-ray absorption fine structure and resonance raman spectroscopy.

FixL is a heme-based O(2) sensor protein involved in a two-component system of a symbiotic bacterium. In the present study, the iron coordination structure in the heme domain of Rhizobium meliloti FixLT (RmFixLT, a soluble truncated FixL) was examined using Fe K-edge extended x-ray absorption fine structure (EXAFS) and resonance Raman spectroscopic techniques. In the EXAFS analyses, the interatomic distances and angles of the Fe-ligand bond and the iron displacement from the heme plane were obtained for RmFixLT in the Fe(2+), Fe(2+)O(2), Fe(2+)CO, Fe(3+), Fe(3+)F(-), and Fe(3+)CN(-) states. An apparent correlation was found between the heme-nitrogen (proximal His-194) distance in the heme domain and the phosphorylation activity of the histidine kinase domain. Comparison of the Fe-CO coordination geometry between RmFixLT and RmFixLH (heme domain of RmFixL), based on the EXAFS and Raman results, has suggested that the kinase domain directly or indirectly influences steric interaction between the iron-bound ligand and the heme pocket. Referring to the crystal structure of the heme domain of Bradyrhizobium japonicum FixL (Gong, W., Hao, B., Mansy, S. S., Gonzalez, G., Gilles-Gonzalez, M. A., and Chan, M. K. (1998) Proc. Natl. Acad. Sci. U. S. A. 95, 15177-15182), we discussed details of the iron coordination structure of RmFixLT and RmFixLH in relation to an intramolecular signal transduction mechanism in its O(2) sensing.     

Ultrahigh resolution structures of nitrophorin 4: heme distortion in ferrous CO and NO complexes

Nitrophorin 4 (NP4), a nitric oxide (NO)-transport protein from the blood-sucking insect Rhodnius prolixus, uses a ferric (Fe3+) heme to deliver NO to its victims. NO binding to NP4 induces a large conformational change and complete desolvation of the distal pocket. The heme is markedly nonplanar, displaying a ruffling distortion postulated to contribute to stabilization of the ferric iron. Here, we report the ferrous (Fe2+) complexes of NP4 with NO, CO, and H2O formed after chemical reduction of the protein and the characterization of these complexes by absorption spectroscopy, flash photolysis, and ultrahigh-resolution crystallography (resolutions vary from 0.9 to 1.08 A). The absorption spectra, both in solution and in the crystal, are typical for six-coordinated ferrous complexes. Closure and desolvation of the distal pocket occurs upon binding CO or NO to the iron regardless of the heme oxidation state, confirming that the conformational change is driven by distal ligand polarity. The degree of heme ruffling is coupled to the nature of the ligand and the iron oxidation state in the following order: (Fe3+)-NO > (Fe2+)-NO > (Fe2+)-CO > (Fe3+)-H2O > (Fe2+)-H2O. The ferrous coordination geometry is as expected, except for the proximal histidine bond, which is shorter than typically found in model compounds. These data are consistent with heme ruffling and coordination geometry serving to stabilize the ferric state of the nitrophorins, a requirement for their physiological function. Possible roles for heme distortion and NO bending in heme protein function are discussed.     

Raman evidence for specific substrate-induced structural changes in the heme pocket of human cytochrome P450 aromatase during the three consecutive oxygen activation steps

Specific substrate-induced structural changes in the heme pocket are proposed for human cytochrome P450 aromatase (P450arom) which undergoes three consecutive oxygen activation steps. We have experimentally investigated this heme environment by resonance Raman spectra of both substrate-free and substrate-bound forms of the purified enzyme. The Fe-CO stretching mode (nu(Fe)(-)(CO)) of the CO complex and Fe(3+)-S stretching mode (nu(Fe)(-)(S)) of the oxidized form were monitored as a structural marker of the distal and proximal sides of the heme, respectively. The nu(Fe)(-)(CO) mode was upshifted from 477 to 485 and to 490 cm(-)(1) by the binding of androstenedione and 19-aldehyde-androstenedione, substrates for the first and third steps, respectively, whereas nu(Fe)(-)(CO) was not observed for P450arom with 19-hydroxyandrostenedione, a substrate for the second step, indicating that the heme distal site is very flexible and changes its structure depending on the substrate. The 19-aldehyde-androstenedione binding could reduce the electron donation from the axial thiolate, which was evident from the low-frequency shift of nu(Fe)(-)(S) by 5 cm(-)(1) compared to that of androstenedione-bound P450arom. Changes in the environment in the heme distal site and the reduced electron donation from the axial thiolate upon 19-aldehyde-androstenedione binding might stabilize the ferric peroxo species, an active intermediate for the third step, with the suppression of the formation of compound I (Fe(4+)=O porphyrin(+)(*)) that is the active species for the first and second steps. We, therefore, propose that the substrates can regulate the formation of alternative reaction intermediates by modulating the structure on both the heme distal and proximal sites in P450arom.     

Complex formation of cytochrome P450cam with Putidaredoxin. Evidence for protein-specific interactions involving the proximal thiolate ligand.

We have performed resonance Raman studies on ferrous NO- and CO-adducts of cytochrome P450(cam) and investigated the effects of diprotein complex formation with reduced putidaredoxin. We have found that the Fe-NO stretching mode of NO-P450(cam) can be resolved into two peaks at 551 and 561 cm(-1), and the binding of putidaredoxin increases the intensity of the high frequency component. Because the Fe-NO mode has been shown to be more sensitive to the nature of the heme proximal ligand than to the distal pocket environment, such a perturbation upon putidaredoxin binding is suggestive of changes in conformation or electronic structure that affect the proximal iron-cysteine bond. In accordance with this idea, the isotope shifts for the Fe-XO stretching and Fe-X-O bending modes (X = N or C) are insensitive to the presence or absence of putidaredoxin, indicating that the geometry of the Fe-X-O unit is not significantly altered by the complex formation. On the other hand, complex formation does induce a perturbation of the low frequency heme vibrational modes, suggesting that alterations of the heme electronic structure and/or geometry take place when putidaredoxin binds. We also find that cytochrome b(5) minimally affects the heme active site of the enzyme, although both putidaredoxin and cytochrome b(5) bind to the same or similar site on P450(cam). These observations suggest that there is a key specific interaction between P450(cam) and putidaredoxin, and that this interaction increases the population of a protein conformation that exhibits structural and/or electronic distortions of the heme group associated with the proximal side of the heme pocket and the S --> Fe electron donation. These electronic and structural changes are potentially correlated with H-bonding to the proximal cysteine.     

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.     

Resonance Raman studies of iron spin and axial coordination in distal pocket mutants of ferric myoglobin

We have used resonance Raman spectroscopy to study 11 distal pocket mutants and the "wild type" and native ferric sperm whale myoglobin. The characteristic Raman core-size markers v4, v3, v2, and v10 are utilized to assign the spin and coordination state of each sample. It is demonstrated that replacements of the distal and proximal histidines can discriminate against H2O as a sixth ligand and favor a pentacoordinate Fe3+ atom. Soret absorption band blueshifts are correlated with the pentacoordinate heme environment. One E7 replacement (Arg) leads to an iron spin state change and produces a low spin species. The Glu and Ala mutations at position E11 leave the protein's spin and coordination unaltered. A laser-induced photoreduction effect is observed in all pentacoordinate mutants and seems to be correlated with the loss of the heme-bound water molecule.     

The optical spectra of fluoride complexes can effectively probe H-bonding interactions in the distal cavity of heme proteins

Fluoride complexes of heme proteins are characterized by unique spectroscopic properties, that provide a simple and direct means to monitor the interactions of the distal heme pocket environment with the iron-bound ligand. In particular, a strong correlation has been demonstrated between the wavelength of the iron-porphyrin charge transfer band at 600-620 nm (CT1) and the strength of H-bonding donation from the distal amino acid side chains to the fluoride ion. In parallel, resonance Raman spectra with excitation within either the CT1 band or the charge transfer band at 450-460 nm (CT2) have revealed that the iron-fluoride stretching frequency is directly affected by H-bonding to the fluoride ion. On this basis, globins and peroxidases display distinct spectroscopic features, which are strongly dependent on the capability of their distal residues (i.e. histidine, arginine and tryptophan) to be involved in H-bonding with the ligand. In particular, in peroxidases strong H-bonding corresponds to a low iron-fluoride stretching frequency and to a red-shifted CT1 band. The reverse is observed in myoglobin. Interestingly, a truncated hemoglobin of microbial origin (Thermobifida fusca) investigated in the present work, displays the specific spectroscopic signature of a peroxidase, in agreement with the presence of strong H-bonding residues, i.e., tyrosine and tryptophan, within the distal pocket.     

Crystal structures of ferrous and CO-, CN(-)-, and NO-bound forms of rat heme oxygenase-1 (HO-1) in complex with heme: structural implications for discrimination between CO and O2 in HO-1

Heme oxygenase (HO) catalyzes heme degradation by utilizing O(2) and reducing equivalents to produce biliverdin IX alpha, iron, and CO. To avoid product inhibition, the heme[bond]HO complex (heme[bond]HO) is structured to markedly increase its affinity for O(2) while suppressing its affinity for CO. We determined the crystal structures of rat ferrous heme[bond]HO and heme[bond]HO bound to CO, CN(-), and NO at 2.3, 1.8, 2.0, and 1.7 A resolution, respectively. The heme pocket of ferrous heme-HO has the same conformation as that of the previously determined ferric form, but no ligand is visible on the distal side of the ferrous heme. Fe[bond]CO and Fe[bond]CN(-) are tilted, whereas the Fe[bond]NO is bent. The structure of heme[bond]HO bound to NO is identical to that bound to N(3)(-), which is also bent as in the case of O(2). Notably, in the CO- and CN(-)-bound forms, the heme and its ligands shift toward the alpha-meso carbon, and the distal F-helix shifts in the opposite direction. These shifts allow CO or CN(-) to bind in a tilted fashion without a collision between the distal ligand and Gly139 O and cause disruption of one salt bridge between the heme and basic residue. The structural identity of the ferrous and ferric states of heme[bond]HO indicates that these shifts are not produced on reduction of heme iron. Neither such conformational changes nor a heme shift occurs on NO or N(3)(-) binding. Heme[bond]HO therefore recognizes CO and O(2) by their binding geometries. The marked reduction in the ratio of affinities of CO to O(2) for heme[bond]HO achieved by an increase in O(2) affinity [Migita, C. T., Matera, K. M., Ikeda-Saito, M., Olson, J. S., Fujii, H., Yoshimura, T., Zhou, H., and Yoshida, T. (1998) J. Biol. Chem. 273, 945-949] is explained by hydrogen bonding and polar interactions that are favorable for O(2) binding, as well as by characteristic structural changes in the CO-bound form.     

Structural characterization of cytochrome c peroxidase by resonance Raman scattering

Resonance Raman scattering studies are reported on freshly prepared and aged ferric, ligand-free ferrous, and CO-bound ferrous cytochrome c peroxidase. The ferric form of the fresh enzyme has a heme which is penta-coordinate high spin, independent of buffer over the pH range 4.3-7, as determined by well established Raman marker lines. The aged enzyme displays a mixture of spin and coordination states, but it can be stabilized in the penta-coordinate high spin form in the presence of phosphate. These results can be accounted for by considering the size of the channel (6 A wide, 11 A long) between the distal side of the heme and the outer surface of the protein. A phosphate ion may be accommodated in this channel resulting in the stabilization of the distal heme pocket. The ferrous cytochrome c peroxidase in both the ligand-free and CO-bound states has an acidic and an alkaline form. The acidic form has the characteristic spectral features of peroxidases: a high frequency iron-histidine stretching mode (248 cm-1), a high frequency Fe-CO stretching mode (537 cm-1), and a low frequency C-O stretching mode (1922 cm-1). At alkaline pH these frequencies become similar to those of hemoglobin and myoglobin, with the corresponding modes located at 227, 510, and 1948 cm-1, respectively. We attribute the acid/alkaline transition in the ferrous forms of cytochrome c peroxidase to a rearrangement mainly of the proximal side of the heme, culminating in a change of steric interactions between the proximal histidine and the heme or of the hydrogen bonding network involving the proximal histidine. The new data presented here reconcile many inconsistencies reported in the past.