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.     

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.     

Two types of conformers with distinct Fe-C-O configuration in the ferrous CO complex of horseradish peroxidase. Resonance Raman and infarared spectroscopic studies with native and deuteroheme-substituted enzymes

The presence of at least two types of conformers in the ferrous CO complex of horseradish peroxidase has been demonstrated with the use of native and deuteroheme-substituted enzymes. Type I conformers, predominant in acidic pH, exhibited both an Fe-CO stretching and an Fe-C-O bending Raman line together with an infrared C-O stretch band below 1920 em-1. On the other hand, type II conformers, dominant species in alkaline pH, showed only an Fe-CO stretching Raman line with the C-O stretch above 1930 cm-1. They were interconvertible either by the changes in pH or by the binding of benzhydroxamate, a substrate for the enzyme. The pKa value for the pH-dependent interconversion of CO complex of deuteroheme-substituted enzyme was 8.3. These findings were interpreted to mean that the bound CO molecule in type I conformers was more tilted over the heme-plane than that in type II conformers. A steric hindrance by the bound substrate or the protonated form of a distal amino acid residue, presumably of histidine, is considered to be the cause for the isomerization. By summarizing present and previous data on the vibrational frequencies of heme-carbonyl complexes, we found that there are inverse-linear relationships between the square of Fe-CO and that of C-O stretching frequencies, while squares of Fe-CO stretching and Fe-C-O bending frequencies were linearly correlated with each other. Also found is that the dissociation rate constant of CO molecule from heme-carbonyl complexes is a linear function of the Fe-CO stretching frequency. The significance of these results is discussed.     

Simultaneous resonance Raman detection of the heme a3-Fe-CO and CuB-CO species in CO-bound ba3-cytochrome c oxidase from Thermus thermophilus. Evidence for a charge transfer CuB-CO transition

Understanding of the chemical nature of the dioxygen and nitric oxide moiety of ba3-cytochrome c oxidase from Thermus thermophilus is crucial for elucidation of its physiological function. In the present work, direct resonance Raman (RR) observation of the Fe-C-O stretching and bending modes and the C-O stretching mode of the CuB-CO complex unambiguously establishes the vibrational characteristics of the heme-copper moiety in ba3-oxidase. We assigned the bands at 507 and 568 cm(-1) to the Fe-CO stretching and Fe-C-O bending modes, respectively. The frequencies of these modes in conjunction with the C-O mode at 1973 cm(-1) showed, despite the extreme values of the Fe-CO and C-O stretching vibrations, the presence of the alpha-conformation in the catalytic center of the enzyme. These data, distinctly different from those observed for the caa3-oxidase, are discussed in terms of the proposed coupling of the alpha-and beta-conformations that occur in the binuclear center of heme-copper oxidases with enzymatic activity. The CuB-CO complex was identified by its nu(CO) at 2053 cm(-1) and was strongly enhanced with 413.1 nm excitation indicating the presence of a metal-to-ligand charge transfer transition state near 410 nm. These findings provide, for the first time, RR vibrational information on the EPR silent CuB(I) that is located at the O2 delivery channel and has been proposed to play a crucial role in both the catalytic and proton pumping mechanisms of heme-copper oxidases.     

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.     

Resonance Raman detection of a v(Fe-CO) stretching frequency in cytochrome P-450scc from bovine adrenocortical mitochondria

Resonance Raman scattering experiments on CO-complexed cytochrome P-450scc from bovine adrenocortical mitochondria demonstrate the simultaneous enhancement of v(Fe-CO) stretching and bound v(C-O) stretching frequencies at 477 and 1953 cm-1, respectively. These assignments were made on the basis of frequency shifts with the isotope 12C18O. This unusually low v(Fe-CO) stretching frequency in cytochrome P-450scc, compared with other CO-complexed hemoproteins such as CO-hemoglobin and -myoglobin, is presumably due to the thiolate ligation to the heme iron trans to CO and due to the linear and perpendicular configuration of CO binding to the heme.     

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.     

Effect of the distal residues on the vibrational modes of the Fe-CO bond in hemoglobin studied by protein engineering

Using an Escherichia coli gene expression system, we have engineered human hemoglobin (Hb) mutants having the distal histidine (E7) and valine (E11) residues replaced by other amino acids. The interaction between the mutated distal residues and bound carbon monoxide has been studied by Soret-excited resonance Raman spectroscopy. The replacement of Val-E11 by Ala, Leu, Ile, and Met has no effect on the v(C-O), v(Fe-CO) stretching or delta(Fe-C-O) bending frequencies in both the alpha and beta subunits of Hb, although some of these mutations affect the CO affinity as much as 40-fold. The strain imposed on the protein by the binding of CO is not localized in the Fe-CO bond and is probably distributed among many bonds in the globin. The replacement of His-E7 by Val or Gly brings the stretching frequencies v(Fe-CO) and v(C-O) close to those of free heme complexes. In contrast, the substitution of His-E7 by Gln, which is flexible and polar, produces no effects on the resonance Raman spectrum of either alpha- or beta-globin. The replacement of His-E7 of beta-globin by Phe shows the same effect as replacement by Gly or Val. Therefore, the steric bulk of the distal residues is not the primary determinant of the Fe-CO ligand vibrational frequencies. The ability of both histidine and glutamine to alter the v(C-O), v(Fe-CO), or delta(Fe-C-O) frequencies may be attributed to the polar nature of their side chains which can interact with bound CO in a similar manner.     

Carbon monoxide adducts of KatG and KatG(S315T) as probes of the heme site and isoniazid binding

KatG, the catalase peroxidase from Mycobacterium tuberculosis, is important in the activation of the antitubercular drug, isoniazid. About 50% of isoniazid-resistant clinical isolates contain a mutation in KatG wherein the serine at position 315 is substituted with threonine, KatG(S315T). The heme pockets of KatG and KatG(S315T) and their interactions with isoniazid are probed using resonance Raman (rR) spectroscopy to characterize their ferrous CO complexes. Three vibrational modes, C-O and Fe-C stretching and Fe-CO bending, are assigned using 12CO and 13CO isotope shifts. Two conformers are observed for KatG-CO and KatG(S315T)-CO. Resonance Raman features assigned to form I are consistent with it having a neutral proximal histidine ligand and the Fe-C-O moiety hydrogen bonded to a distal residue. The nu(C-O) band for form I is sharp, consistent with a conformationally homogeneous Fe-CO unit. Form II also has a neutral proximal histidine ligand but is not hydrogen bonded. This appears to result in a conformationally disordered Fe-CO unit, as evidenced by a comparatively broad C-O stretching band. The 13CO-sensitive bands assigned to form II are predominant in the KatG(S315T)-CO rR spectrum. Isoniazid binding is apparent from the resonance Raman signatures of both WT KatG-CO and KatG(S315T)-CO. Moreover, isoniazid binding elicits an increase in the form I population of wild-type KatG-CO while having little, if any, effect on the already low population of form I of KatG(S315T)-CO. Since oxyKatG (compound III) also contains a low-spin diatomic ligand-heme adduct (heme-O2), it is reasonable to suggest that it too would exist as a mixture of conformers. Because the small form I population of KatG(S315T)-CO correlates with its inability to activate INH, we hypothesize that form I plays a role in INH activation.     

Role of substrate functional groups in binding to nitric oxide synthase

The interactions between the heme CO ligand in the oxygenase domain of nitric oxide synthase and a set of substrate analogues were determined by measuring the resonance Raman spectra of the Fe-C-O vibrational modes. Substrates were selected that have variations in all the functional units: the guanidino group, the amino acid site and the number of methylene units connecting the two ends. In comparison to the substrate free form of the enzyme, Interactions of the analogues with the CO moiety caused the Fe-CO stretching and the Fe-C-O bending modes to shift in frequency due to the electrostatic environment. An unmodified guanidino group interacted with the CO in a similar fashion despite changes in the amino acid end. However, an unmodified amino acid end is required for catalysis owing to the H-bonding network involving the substrate, the heme and the pterin cofactor.     

Structural characterization of a binuclear center of a Cu-containing NO reductase homologue from Roseobacter denitrificans: EPR and resonance Raman studies

Aerobic phototrophic bacterium Roseobacter denitrificans has a nitric oxide reductase (NOR) homologue with cytochrome c oxidase (CcO) activity. It is composed of two subunits that are homologous with NorC and NorB, and contains heme c, heme b, and copper in a 1:2:1 stoichiometry. This enzyme has virtually no NOR activity. Electron paramagnetic resonance (EPR) spectra of the air-oxidized enzyme showed signals of two low-spin hemes at 15 K. The high-spin heme species having relatively low signal intensity indicated that major part of heme b₃ is EPR-silent due to an antiferromagnetic coupling to an adjacent Cu_B forming a Fe-Cu binuclear center. Resonance Raman (RR) spectrum of the oxidized enzyme suggested that heme b₃ is six-coordinate high-spin species and the other hemes are six-coordinate low-spin species. The RR spectrum of the reduced enzyme showed that all the ferrous hemes are six-coordinate low-spin species. ν(Fe-CO) and ν(C-O) stretching modes were observed at 523 and 1969 cm⁻¹, respectively, for CO-bound enzyme. In spite of the similarity to NOR in the primary structure, the frequency of ν(Fe-CO) mode is close to those of aa₃- and bo₃-type oxidases rather than that of NOR.     

Resonance Raman interrogation of the consequences of heme rotational disorder in myoglobin and its ligated derivatives

Resonance Raman spectroscopy is employed to characterize heme site structural changes arising from conformational heterogeneity in deoxyMb and ligated derivatives, i.e., the ferrous CO (MbCO) and ferric cyanide (MbCN) complexes. The spectra for the reversed forms of these derivatives have been extracted from the spectra of reconstituted samples. Dramatic changes in the low-frequency spectra are observed, where newly observed RR modes of the reversed forms are assigned using protohemes that are selectively deuterated at the four methyl groups or at the four methine carbons. Interestingly, while substantial changes in the disposition of the peripheral vinyl and propionate groups can be inferred from the dramatic spectral shifts, the bonds to the internal histidyl imidazole ligand and those of the Fe-CO and Fe-CN fragments are not significantly affected by the heme rotation, as judged by lack of significant shifts in the nu(Fe-N(His)), nu(Fe-C), and nu(C-O) modes. In fact, the apparent lack of an effect on these key vibrational parameters of the Fe-N(His), Fe-CO, and Fe-CN fragments is entirely consistent with previously reported equilibrium and kinetic studies that document virtually identical functional properties for the native and reversed forms.     

Interaction of soluble guanylate cyclase with YC-1: kinetic and resonance Raman studies

The enzyme-soluble guanylate cyclase (sGC), which converts GTP to cGMP, is a receptor for the signaling agent nitric oxide (NO). YC-1, a synthetic benzylindazole derivative, has been shown to activate sGC in an NO-independent fashion. In the presence of carbon monoxide (CO), which by itself activates sGC approximately 5-fold, YC-1 activates sGC to a level comparable to stimulation by NO alone. We have used kinetic analyses and resonance Raman spectroscopy (RR) to investigate the interaction of YC-1 and CO with guanylate cyclase. In the presence of CO and 200 microM YC-1, the V(max)/K(m GTP) increases 226-fold. While YC-1 does not perturb the RR spectrum of the ferrous form of baculovirus/Sf9 cell expressed sGC, it induces a shift in the Fe-CO stretching frequency for the CO-bound form from 474 to 492 cm(-1). Similarly, YC-1 has no effect on the RR spectrum of ferrous beta1(1-385), the isolated sGC heme-binding domain, but shifts the nu(Fe-CO) of CO-beta1(1-385) from 478 to 491 cm(-1), indicating that YC-1 binds in heme-binding region of sGC. In addition, the CO-bound forms of sGC and beta1(1-385) in the presence of YC-1 lie on the nu(Fe-CO) vs nu(C-O) correlation curve for proximal ligands with imidazole character, which suggests that histidine remains the heme proximal ligand in the presence of YC-1. Interestingly, YC-1 does not shift nu(Fe-CO) for the CO-bound form of H105G(Im), the imidazole-rescued heme ligand mutant of beta1(1-385). The data are consistent with binding of CO and YC-1 to the sGC heme-binding domain leading to conformational changes that give rise to an increase in catalytic turnover and a change in the electrostatic environment of the heme pocket.     

Resonance Raman characterization of the heme cofactor in cystathionine beta-synthase. Identification of the Fe-S(Cys) vibration in the six-coordinate low-spin heme

Human cystathionine beta-synthase (CBS) is an essential enzyme for the removal of the toxic metabolite homocysteine. Heme and pyridoxal phosphate (PLP) cofactors are necessary to catalyze the condensation of homocysteine and serine to generate cystathionine. While the role for the PLP cofactor is thought to be similar to that in other PLP-dependent enzymes that catalyze beta-replacement reactions, the exact role for the heme remains unclear. In this study, we have characterized the heme cofactor of CBS in both the ferric and ferrous states using resonance Raman spectroscopy. Positive identification of a cysteine ligand was achieved by global (34)S isotopic substitution which allowed us to assign the nu(Fe-S) for the six-coordinate low-spin ferric heme at 312 cm(-1). In addition, the CO adduct of ferrous CBS has vibrational frequencies characteristic of a histidine-heme-CO complex in a hydrophobic environment, and indicates that the Fe-S(Cys) bond is labile. We have also found that addition of HgCl(2) to the ferric heme causes conversion of the low-spin heme to a five-coordinate high-spin heme with loss of the cysteine ligand. The present spectroscopic studies do not support a reaction mechanism in which homocysteine binds directly to the heme via displacement of the Cys ligand in the binary enzyme complex, as had been previously proposed.     

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'.     

Substrate-ligand interactions in Geobacillus stearothermophilus nitric oxide synthase

Nitric oxide synthase (NOS) generates NO via a sequential two-step reaction [l-arginine (l-Arg) --> N-hydroxy-l-arginine (NOHA) --> l-citrulline + NO]. Each step of the reaction follows a distinct mechanism defined by the chemical environment introduced by each substrate bound to the heme active site. The dioxygen complex of the NOS enzyme from a thermophilic bacterium, Geobacillus stearothermophilus (gsNOS), is unusually stable; hence, it provides a unique model for the studies of the mechanistic differences between the two steps of the NOS reaction. By using CO as a structural probe, we found that gsNOS exhibits two conformations in the absence of substrate, as indicated by the presence of two sets of nu(Fe-CO)/nu(C-O) modes in the resonance Raman spectra. In the nu(Fe-CO) versus nu(C-O) inverse correlation plot, one set of data falls on the correlation line characterized by mammalian NOSs (mNOS), whereas the other set of data lies on a new correlation line defined by a bacterial NOS from Bacillus subtilis (bsNOS), reflecting a difference in the proximal Fe-Cys bond strength in the two conformers of gsNOS. The addition of l-Arg stabilizes the conformer associated with the mNOS correlation line, whereas NOHA stabilizes the conformer associated with the bsNOS correlation line, although both substrates introduce a positive electrostatic potential into the distal heme pocket. To assess how substrate binding affects Fe-Cys bond strength, the frequency of the Fe-Cys stretching mode of gsNOS was monitored by resonance Raman spectroscopy with 363.8 nm excitation. In the substrate-free form, the Fe-Cys stretching mode was detected at 342.5 cm(-1), similar to that of bsNOS. The binding of l-Arg and NOHA brings about a small decrease and increase in the Fe-Cys stretching frequency, respectively. The implication of these unique structural features with respect to the oxygen chemistry of NOS is discussed.     

Structural characterization of the proximal and distal histidine environment of cytoglobin and neuroglobin

Cytoglobin (Cgb) and neuroglobin (Ngb) are the first examples of hexacoordinated globins from humans and other vertebrates in which a histidine (His) residue at the sixth position of the heme iron is an endogenous ligand in both the ferric and ferrous forms. Static and time-resolved resonance Raman and FT-IR spectroscopic techniques were applied in examining the structures in the heme environment of these globins. Picosecond time-resolved resonance Raman (ps-TR3) spectroscopy of transient five-coordinate heme species produced by the photolysis of carbon monoxide (CO) adducts of Cgb and Ngb showed Fe-His stretching (nu(Fe-His)) bands at 229 and 221 cm(-1), respectively. No time-dependent shift in the nu(Fe-His) band of Cgb and Ngb was detected in the 20-1000 ps time domain, in contrast to the case of myoglobin (Mb). These spectroscopic data, combined with previously reported crystallographic data, suggest that the structure of the heme pocket in Cgb and Ngb is altered upon CO binding in a manner different from that of Mb and that the scales of the structural alteration are different for Cgb and Ngb. The structural property of the heme distal side of the ligand-bound forms was investigated by observing the sets of (nu(Fe-CO), nu(C-O), delta(Fe-C-O)) and (nu(Fe-NO), nu(N-O), delta(Fe-N-O)) for the CO and nitric oxide (NO) complexes of Cgb and Ngb. A comparison of the spectra of some distal mutants of Cgb (H81A, H81V, R84A, R84K, and R84T) and Ngb (H64A, H64V, K67A, K67R, and K67T) showed that the CO adducts of Cgb and Ngb contained three conformers and that the distal His (His81 in Cgb and His64 in Ngb) mainly contributes to the interconversion of the conformers. These structural characteristics of Cgb and Ngb are discussed in relation to their ligand binding and physiological properties.     

A specific interaction of L-tryptophan with CO of CO-bound indoleamine 2,3-dioxygenase identified by resonance Raman spectroscopy

Indoleamine 2,3-dioxygenase (IDO) is a heme enzyme which catalyzes dioxygenation of l-Trp (tryptophan), yielding N-formylkynurenine. IDO thus plays a key role in l-Trp catabolism in mammals. In the present study, resonance Raman (RR) spectra of the reduced carbon monoxide- (CO-) bound form of IDO were measured in order to gain insights into the active site environment of O(2). Binding of CO to l-Trp-bound IDO causes a significant change in the electronic and RR spectra of the heme, indicating that the π* orbitals of the carbon atom of CO interact with π orbitals of Fe and the porphyrin. On the other hand, binding of CO to d-Trp-bound IDO does not induce the same change. This is also the case with substrate-free IDO. Based on the distinct absorption spectra and RR bands of the vibrational signature of CO (ν(CO), δ(FeCO), and ν(Fe-CO)) of the l-Trp-bound species relative to the other two species, it is confirmed that sterically constrained geometry of the Fe-O-O unit exists as previously reported (Terentis, A. C., et al. (2002) J. Biol. Chem. 277, 15788-15794). In contrast, binding of d-Trp does not induce such constraint. The comparable values of V(max) reported for l-Trp and d-Trp are interpreted as a result of a change in the rate-limiting step in the reaction cycle of the enzyme induced by the d-enantiomer relative to the l-enantiomer. Enhancements of the overtone and the combination Raman modes of the Fe-CO stretching vibration are evident. The anharmonicity of the Fe-CO stretching oscillator is significantly higher than those of oxygen carrier proteins. This is a specific character of IDO and might be responsible for the unique reactivity of this enzyme.     

Resonance Raman and ligand binding studies of the oxygen-sensing signal transducer protein HemAT from Bacillus subtilis

HemAT-Bs is a heme-containing signal transducer protein responsible for aerotaxis of Bacillus subtilis. The recombinant HemAT-Bs expressed in Escherichia coli was purified as the oxy form in which oxygen was bound to the ferrous heme. Oxygen binding and dissociation rate constants were determined to be k(on) = 32 microm(-1) s(-1) and k(off) = 23 s(-1), respectively, revealing that HemAT-Bs has a moderate oxygen affinity similar to that of sperm whale myoglobin (Mb). The rate constant for autoxidation at 37 degrees C was 0.06 h(-1), which is also close to that of Mb. Although the electronic absorption spectra of HemAT-Bs were similar to those of Mb, HemAT-Bs showed some unique characteristics in its resonance Raman spectra. Oxygen-bound HemAT-Bs gave the nu(Fe-O(2)) band at a noticeably low frequency (560 cm(-1)), which suggests a unique hydrogen bonding between a distal amino acid residue and the proximal atom of the bound oxygen molecule. Deoxy HemAT-Bs gave the nu(Fe-His) band at a higher frequency (225 cm(-1)) than those of ordinary His-coordinated deoxy heme proteins. CO-bound HemAT-Bs gave the nu(Fe-CO) and nu(C-O) bands at 494 and 1964 cm(-1), respectively, which fall on the same nu(C-O) versus nu(Fe-CO) correlation line as that of Mb. Based on these results, the structural and functional properties of HemAT-Bs are discussed.