Spectroscopic and equilibrium studies of ligand and organic substrate binding to indolamine 2,3-dioxygenase

The binding of a number of ligands to the heme protein indolamine 2,3-dioxygenase has been examined with UV-visible absorption and with natural and magnetic circular dichroism spectroscopy. Relatively large ligands (e.g., norharman) which do not readily form complexes with myoglobin and horseradish peroxidase (HRP) can bind to the dioxygenase. Except for only a few cases (e.g., 4-phenylimidazole) for the ferric dioxygenase, a direct competition for the enzyme rarely occurs between the substrate L-tryptophan (Trp) and the ligands examined. L-Trp and small heme ligands (CN-,N3-,F-) markedly enhance the affinity of each other for the ferric enzyme in a reciprocal manner, exhibiting positive cooperativity. For the ferrous enzyme, L-Trp exerts negative cooperativity with some ligands such as imidazoles, alkyl isocyanides, and CO binding to the enzyme. This likely reflects the proximity of the Trp binding site to the heme iron. Other indolamine substrates also exert similar but smaller cooperative effects on the binding of azide or ethyl isocyanide. The pH dependence of the ligand affinity of the dioxygenase is similar to that of myoglobin rather than that of HRP. These results suggest that indolamine 2,3-dioxygenase has the active-site heme pocket whose environmental structure is similar to, but whose size is considerably larger than, that of myoglobin, a typical O2-binding heme protein. Although the L-Trp affinity of the ferric cyanide and ferrous CO enzyme varies only slightly between pH 5.5 and 9.5, the unligated ferric and ferrous enzymes have considerably higher affinity for L-Trp at alkaline pH than at acidic pH. L-Trp binding to the ferrous dioxygenase is affected by an ionizable residue with a pKa value of 7.3.     

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.     

Rapid P450 heme iron reduction by laser photoexcitation of Mycobacterium tuberculosis CYP121 and CYP51B1. Analysis of CO complexation reactions and reversibility of the P450/P420 equilibrium

We demonstrate that photoexcitation of NAD(P)H reduces heme iron of Mycobacterium tuberculosis P450s CYP121 and CYP51B1 on the microsecond time scale. Rates of formation for the ferrous-carbonmonoxy (Fe(II)-CO) complex were determined across a range of coenzyme/CO concentrations. CYP121 reaction transients were biphasic. A hyperbolic dependence on CO concentration was observed, consistent with the presence of a CO binding site in ferric CYP121. CYP51B1 absorption transients for Fe(II)-CO complex formation were monophasic. The reaction rate was second order with respect to [CO], suggesting the absence of a CO-binding site in ferric CYP51B1. In the absence of CO, heme iron reduction by photoexcited NAD(P)H is fast ( approximately 10,000-11,000 s(-1)) with both P450s. For CYP121, transients revealed initial production of the thiolate-coordinated (P450) complex (absorbance maximum at 448 nm), followed by a slower phase reporting partial conversion to the thiol-coordinated P420 species (at 420 nm). The slow phase amplitude increased at lower pH values, consistent with heme cysteinate protonation underlying the transition. Thus, CO binding occurs to the thiolate-coordinated ferrous form prior to cysteinate protonation. For CYP51B1, slow conversions of both the ferrous/Fe(II)-CO forms to species with spectral maxima at 423/421.5 nm occurred following photoexcitation in the absence/presence of CO. This reflected conversion from ferrous thiolate- to thiol-coordinated forms in both cases, indicating instability of the thiolate-coordinated ferrous CYP51B1. CYP121 Fe(II)-CO complex pH titrations revealed reversible spectral transitions between P450 and P420 forms. Our data provide strong evidence for P420 formation linked to reversible heme thiolate protonation, and demonstrate key differences in heme chemistry and CO binding for CYP121 and CYP51B1.     

Optical and magnetic resonance studies of formate binding to horse liver catalase and sperm whale myoglobin.

The binding of formate ion, a substrate for the peroxidatic reaction of catalase, has been investigated by magnetic resonance techniques. Comparative studies of formate binding to ferric myoglobin have also been performed. The nuclear magnetic relaxation (NMR) rate of formate and water protons is enhanced by the presence of ferric horse liver catalase. The enhancement is not changed significantly by the addition of cyanide, indicating that water and formate are still bound in the presence of cyanide. Formate proton to heme iron distances determined by magnetic resonance techniques indicate that formate does not directly bind to the heme iron of catalase or myoglobin but to the globin, and NMR relaxation occurs as a result of outersphere mechanisms. Evidence that water forms an innersphere complex with the iron atom of the catalase heme is presented. In similar experiments with ferric myoglobin, the addition of cyanide caused a large decrease in the enhancement of the proton relaxation rate of both formate and water, indicating the displacement of water and formate from the heme and the vicinity of the heme, respectively. Broad, high-spin, ferric ion electron paramagnetic resonance absorptions of catalase and myoglobin at room temperature obtained in the presence and absence of formate show that formate does not alter appreciably the heme environment of catalase or myoglobin or the spin state of the heme iron. Studies on the binding of formate to catalase as monitored by changes in the heme absorption spectrum in the visible region show one-to-one stoichiometry with heme concentration. However, the small changes observed in the visible region of the optical spectrum on addition of formate ion are attributed to a secondary effect of formate on the heme environment, rather than direct binding of formate to the heme moiety.     

Imidazole, the ligand trans to mercaptide in ferric cytochrome P-450. An EPR study of proteins and model compounds.

A crystal field analysis of EPR data for various low spin ferric cytochromes P-450 suggests that in all of them, regardless of source or method of induction, the heme ligands are a sulfur atom, presumably from cysteine, and an imidazole from histidine. The imidazole can be displaced in the ferric protein by cyanide, guanidine, or by an amine, analogous to its displacement by CO or NO in the ferrous protein. The resulting changes in the EPR parameters for the ferric protein are consistent with similar substitutions in heme thiol model compounds. The analysis of the latter can be understood on the basis of alterations of the electronic structure of the ligands to the heme iron.     

Resonance Raman studies of cytochrome P450BM3 and its complexes with exogenous ligands.

Resonance Raman spectra are reported for both the heme domain and holoenzyme of cytochrome P450BM3 in the resting state and for the ferric NO, ferrous CO, and ferrous NO adducts in the absence and presence of the substrate, palmitate. Comparison of the spectrum of the palmitate-bound form of the heme domain with that of the holoenzyme indicates that the presence of the flavin reductase domain alters the structure of the heme domain in such a way that water accessibility to the distal pocket is greater for the holoenzyme, a result that is consistent with analogous studies of cytochrome P450cam. The data for the exogenous ligand adducts are compared to those previously reported for corresponding derivatives of cytochrome P450cam and document significant and important differences for the two proteins. Specifically, while the binding of substrate induces relatively dramatic changes in the nu(Fe-XY) modes of the ferrous CO, ferric NO, and ferrous NO derivatives of cytochrome P450cam, no significant changes are observed for the corresponding derivatives of cytochrome P450BM3 upon binding of palmitate. In fact, the spectral data for substrate-free cytochrome P450BM3 provide evidence for distortion of the Fe-XY fragment, even in the absence of substrate. This apparent distortion, which is nonexistent in the case of substrate-free cytochrome P450cam, is most reasonably attributed to interaction of the Fe-XY fragment with the F87 phenylalanine side chain. This residue is known to lie very close to the heme iron in the substrate-free derivative of cytochrome P450BM3 and has been suggested to prevent hydroxylation of the terminal, omega, position of long-chain fatty acids.     

DiGeorge critical region 8 (DGCR8) is a double-cysteine-ligated heme protein

All known heme-thiolate proteins ligate the heme iron using one cysteine side chain. We previously found that DiGeorge Critical Region 8 (DGCR8), an essential microRNA processing factor, associates with heme of unknown redox state when overexpressed in Escherichia coli. On the basis of the similarity of the 450-nm Soret absorption peak of the DGCR8-heme complex to that of cytochrome P450 containing ferrous heme with CO bound, we identified cysteine 352 as a probable axial ligand in DGCR8. Here we further characterize the DGCR8-heme interaction using biochemical and spectroscopic methods. The DGCR8-heme complex is highly stable, with a half-life exceeding 4 days. Mutation of the conserved proline 351 to an alanine increases the rate of heme dissociation and allows the DGCR8-heme complex to be reconstituted biochemically. Surprisingly, DGCR8 binds ferric heme without CO to generate a hyperporphyrin spectrum. The electronic absorption, magnetic circular dichroism, and electron paramagnetic resonance spectra of the DGCR8-heme complex suggest a ferric heme bearing two cysteine ligands. This model was further confirmed using selenomethionine-substituted DGCR8 and mercury titration. DGCR8 is the first example of a heme-binding protein with two endogenous cysteine side chains serving as axial ligands. We further show that native DGCR8 binds heme when expressed in eukaryotic cells. This study provides a chemical basis for understanding the function of the DGCR8-heme interaction in microRNA maturation.     

Effects of cholesterol analogues and inhibitors on the heme moiety of cytochrome P-450scc: a resonance Raman study

Interactions of cholesterol analogues and inhibitors with the heme moiety of cytochrome P-450scc were examined by resonance Raman spectroscopy. The Raman spectra of ferric cytochrome P-450scc complexed with inhibitors such as cyanide, phenyl isocyanide, aminoglutethimide, and metyrapone were characteristic of low-spin state and were very similar. However, the effect of exchange of the sixth ligand from the oxygen atom (ferric low-spin state) to the nitrogen atom upon aminoglutethimide and metyrapone binding was seen as down-frequency shifts of the v3 band from 1503 to 1501 and 1502 cm-1, respectively, while cyanide and phenyl isocyanide binding caused an up-frequency shift of the v3 band to 1505 cm-1. The effects of cholesterol analogues [22(R)-hydroxycholesterol, 22(S)-hydroxycholesterol, 22-ketocholesterol, 20(S)-hydroxycholesterol, and 25-hydroxycholesterol] on a Fe2+-CO stretching frequency of cytochrome P-450scc in ferrous CO form were examined. The 22(R)-hydroxycholesterol complex could not give a clear Fe2+-CO stretching Raman band due to a strong photodissociability. 22(S)-Hydroxycholesterol and 25-hydroxycholesterol complexes gave the Raman bands at 487 and 483 cm-1, respectively, whereas 20(S)-hydroxycholesterol and 22-ketocholesterol complexes gave Fe2+-CO stretching frequencies (478 cm-1) almost identical with that without substrate (477 cm-1). These findings suggest the existence of the following physiologically important natures of the cytochrome P-450scc active site: (1) there is a strong steric interaction between heme-bound carbon monoxide and the 22(R)-hydroxyl group or the 22(R)-hydrogen of the steroid side chain and (2) the hydroxylation at the 20S position may cause a conformational change of the side-chain group relative to the heme.     

Unique features of recombinant heme oxygenase of Drosophila melanogaster compared with those of other heme oxygenases studied.

We cloned a cDNA for a Drosophila melanogaster homologue of mammalian heme oxygenase (HO) and constructed a bacterial expression system of a truncated, soluble form of D. melanogaster HO (DmDeltaHO). The purified DmDeltaHO degraded hemin to biliverdin, CO and iron in the presence of reducing systems such as NADPH/cytochrome P450 reductase and sodium ascorbate, although the reaction rate was slower than that of mammalian HOs. Some properties of DmHO, however, are quite different from other known HOs. Thus DmDeltaHO bound hemin stoichiometrically to form a hemin-enzyme complex like other HOs, but this complex did not show an absorption spectrum of hexa-coordinated heme protein. The absorption spectrum of the ferric complex was not influenced by changing the pH of the solution. Interestingly, an EPR study revealed that the iron of heme was not involved in binding heme to the enzyme. Hydrogen peroxide failed to convert it into verdoheme. A spectrum of the ferrous-CO form of verdoheme was not detected during the reaction from hemin under oxygen and CO. Degradation of hemin catalyzed by DmDeltaHO yielded three isomers of biliverdin, of which biliverdin IXalpha and two other isomers (IXbeta and IXdelta) accounted for 75% and 25%, respectively. Taken together, we conclude that, although DmHO acts as a real HO in D. melanogaster, its active-site structure is quite different from those of other known HOs.     

Circular dichroism studies of low-spin ferric cytochrome P-450CAM ligand complexes

Circular dichroism (CD) spectroscopy has been used to probe the active site of bacterial ferric cytochrome P-450CAM. The endogenous sixth ligand to the heme iron has been displaced by an extensive series of exogenous oxygen, nitrogen, sulfur and other neutral and anionic donor ligands in an attempt to examine systematically the steric and electronic factors that influence the coupling of the heme chromophore to its protein environment. General trends for each ligand class are reported and discussed. Both the wavelengths and the intensities of the CD bands vary with ligand type and structure. All but one of the complexes exhibit negative CD maxima in their delta and Soret bands. Comparison to ferric myoglobin-thiolate complexes indicates that the negative sign observed for the cytochrome P-450 spectra is not a property of the thiolate fifth ligand, but rather arises from a different interaction of the cytochrome P-450 heme with its protein environment. Complexes with neutral oxygen donors display CD spectra that most closely resemble the spectrum of the native low-spin enzyme. Hyperporphyrin (split Soret) cytochrome P-450 complexes with thiolates, phosphines and cyanide trans to cysteinate have complex CD spectra, reflecting the intrinsic non-degeneracy of the Soret pi pi transitions. The extensive work presented herein provides an empirical foundation for use in analyzing the interaction of heme chromophores with their protein surroundings, not only for the cytochrome P-450 monooxygenases but also for heme proteins in general.     

Ligand and halide binding properties of chloroperoxidase: peroxidase-type active site heme environment with cytochrome P-450 type endogenous axial ligand and spectroscopic properties

Equilibrium binding studies of exogenous ligands and halides to the active site heme iron of chloroperoxidase have been carried out from pH 2 to 7. Over twenty ligands have been studied including C, N, O, P, and S donors and the four halides. As judged from changes in the optical absorption spectra, direct binding of the ligands to the heme iron of ferric or ferrous chloroperoxidase occurs in all cases; this has been ascertained for the ferric enzyme in several cases through competition experiments with cyanide. All of the ligands except for the halides, nitrate, and acetate form exclusively low-spin complexes in analogy to results obtained with the spectroscopically related protein, cytochrome P-450-CAM [Sono, M., & Dawson, J.H. (1982) J. Biol. Chem. 257, 5496-5502]. The titration results show that, for the ferric enzyme, (i) weakly acidic ligands (pKa greater than 3) bind to the enzyme in their neutral (protonated) form, followed by deprotonation upon ligation to the heme iron. In contrast, (ii) strongly acidic ligands (pKa less than 0) including SCN-, NO3-, and the halides except for F- likely bind in their anionic (deprotonated) form to the acid form of the enzyme: a single ionizable group on the protein with a pKa less than 2 is involved in this binding. For the ferrous enzyme, (iii) a single ionizable group with the pKa value of 5.5 affects ligand binding. These results reveal that chloroperoxidase, in spite of the previously established close spectroscopic and heme iron coordination structure similarities to the P-450 enzymes, clearly belongs to the hydroperoxidases in terms of its ligand binding properties and active site heme environment. Magnetic circular dichroism studies indicate that the alkaline form (pH 9.5) of ferric chloroperoxidase has an RS-ferric heme-N donor ligand coordination structure with the N donor likely derived from histidine imidazole.     

Stereochemical properties of the binding site of liver microsomal cytochrome P-450 as studied by substrate analogous spin labels.

For the characterization of the substrate binding site optical and EPR measurements with spin labelled substrates on solubilized and pure cytochrome P-450 were performed. Analogously to the unlabelled derivatives spin labelled n-alkylamines and isocyanides with different chain lengths are type II substrates. The Ks-values evaluated from optical (P-450 = 1.98 . 10(-6) M) and ESR (P-450 = 1.98 . 10(-4) M) measurements are very similar indicating no concentration dependences. Contrary to the unlabelled n-alkylamines the spin labelled compounds show an affinity almost independent of the chain lengths. The SL-substrates with a short distance between the functional group and the NO-group bound to P-450 induce pronounced changes of the ligand field of the heme iron and a large broadening of the signal of the immobilized nitroxide indicating intensive interactions between the unpaired electron of the nitroxide group and the paramagnetic heme iron. Elongation of the alkyl chains results in spectra of the Fe3+ complexes with only slight modification and a remained unbroadened signal of the immobilized nitroxide. The binding of the substrate through their functional groups together with a 1:1 stoichiometry of the P-450 SL-IC-complex give evidence for the same binding site in the near vicinity of the heme iron.     

Spectral characterization of diarylpropane oxygenase, a novel peroxide-dependent, lignin-degrading heme enzyme

Diarylpropane oxygenase, an H2O2-dependent lignin-degrading enzyme from the basidiomycete fungus Phanerochaete chrysosporium, catalyzes the oxygenation of various lignin model compounds with incorporation of a single atom of dioxygen (O2). Diarylpropane oxygenase is also capable of oxidizing some alcohols to aldehydes and/or ketones. This enzyme (Mr = 41,000) contains a single iron protoporphyrin IX prosthetic group. Previous studies revealed that the Soret maximum of the ferrous-CO complex of diarylpropane oxygenase is at approximately 420 nm, as in ferrous-CO myoglobin (Mb), and not like the approximately 450 nm absorption of the CO complex of the ubiquitous heme monooxygenase, cytochrome P-450. This spectral difference between two functionally similar heme enzymes is of interest. To elucidate the structural requirements for heme iron-based oxygenase reactions, we have compared the electronic absorption, EPR, and resonance Raman (RR) spectral properties of diarylpropane oxygenase with those of other heme proteins and enzymes of known axial ligation. The absorption spectra of native (ferric), cyano, and ferrous diarylpropane oxygenase closely resemble those of the analogous myoglobin complexes. The EPR g values of native diarylpropane oxygenase, 5.83 and 1.99, also agree well with those of aquometMb. The RR spectra of ferric diarylpropane oxygenase have their spin- and oxidation-state marker bands at frequencies analogous to those of aquometMb and indicate a high-spin, hexacoordinate ferric iron. The RR spectra of ferrous diarylpropane oxygenase have frequencies analogous to those of deoxy-Mb that suggest a high-spin, pentacoordinate Fe(II) in the reduced form. The RR spectra of both ferric and ferrous diarylpropane oxygenase are less similar to those of horseradish peroxidase, catalase, or cytochrome c peroxidase and are clearly distinct from those of P-450. These observations suggest that the fifth ligand to the heme iron of diarylpropane oxygenase is a neutral histidine and that the iron environment must resemble that of the oxygen transport protein, myoglobin, rather than that of the peroxidases, catalase, or P-450. Given the functional similarity between diarylpropane oxygenase and P-450, this work implies that the mechanism of oxygen insertion for the two systems is different.     

Characterization of rabbit liver cytochrome P-450 (laurate omega-1 hydroxylase) synthesized in transformed yeast cells

Three cDNAs for chimeras between cytochrome P-450s (pHP3 and pHP2-1) were constructed and inserted between the alcohol dehydrogenase promoter and terminator regions of the yeast expression vector pAAH5 to form expression plasmids, pAH3P2, pAH3E2, and pAH3A2. pAH3P2 contained the entire coding sequence of cytochrome P-450 (pHP2-1) except for the 3rd, the 8th, the 36th, and the 42nd residues of the total of 490 amino acids. Nucleotide sequences of pAH3P2 were replaced with those of cytochrome P-450 (pHP3) in the region coding for the NH2-terminal 210 and 262 amino acid residues to yield pAH3E2 and pAH3A2, respectively. The three expression plasmids were introduced into Saccharomyces cerevisiae AH22 cells and cytochrome P-450 s (3P2, 3E2, and 3A2) were purified from the microsomal fractions of the transformed yeast cells. In the oxidized state either of the cytochromes exhibited a low- and high-spin mixed-type spectrum of cytochrome P-450. The reduced CO complex of the cytochromes showed a Soret absorption maximum at 450 nm. When laurate or caprate was added to ferric cytochrome P-450 s (3P2 and 3E2), the spectrum was converted to that of the typical high-spin type, indicating the binding of the fatty acids to the substrate site of the cytochromes. On the other hand, the addition of the fatty acids to ferric cytochrome P-450 (3A2) induced no spectral change. Only chemicals having a carboxyl group caused such spectral conversion of cytochrome P-450 (3P2) among dodecyl compounds examined.(ABSTRACT TRUNCATED AT 250 WORDS)     

Crystal structure of OxyC,a cytochrome P450 implicated in an oxidative C-C coupling reaction during vancomycin biosynthesis

Gene inactivation studies point to the involvement of OxyC in catalyzing the last oxidative phenol coupling reaction during glycopeptide antibiotic biosynthesis. Presently, the substrate and exact timing of the OxyC reaction are unknown. The substrate might be the bicyclic heptapeptide or a thioester derivative bound to a protein carrier domain. OxyC from the vancomycin producer Amycolatopsis orientalis was produced in Escherichia coli and crystallized, and its structure was determined to 1.9 A resolution. OxyC gave UV-visible spectra characteristic of a P450-like hemoprotein in the low spin ferric state. After reduction to the ferrous state by dithionite the CO-ligated form gave a 450-nm peak in a UV-difference spectrum. The addition of vancomycin aglycone to OxyC produced type I changes to the UV spectrum. OxyC exhibits the typical P450-fold, with the Cys ligand loop containing the signature sequence FGHGX-HXCLG and Cys-356 being the proximal axial thiolate ligand of the heme iron. The observation of a water molecule bound to the heme iron is consistent with the UV-visible spectra of OxyC indicating a low spin heme. A polyethylene glycol molecule occupying the active site might mimic the bicyclic heptapeptide substrate. Analysis of the structure of Oxy-proteins and other P450s indicates regions that might be involved in binding of the redox partner and possibly the protein carrier domain.     

Magnetic circular dichroism studies of hepatic microsomal cytochrome P-450.

Magnetic circular dichroism (MCD) spectra have been measured for cytochrome P-450 (P-450) purified from phenobarbital-induced rabbit liver microsomes. The temperature dependence of some of the MCD spectra has also been determined. The MCD spectrum of oxidized P-450 seems to suggest that it is in a state intermediate between the ferric low-spin states. Model experiments suggest that this anomaly arises from the coordination of a thiolate anion to the heme. Reduced P-450 shows a very peculiar MCD spectrum; the spectrum as well as its temperature dependence suggest that the heme in reduced P-450 is a "mixture" in terms of redox and/or spin states. The MCD spectrum of the CO complex of reduced P-450 exhibits an apparent Faraday A term around 450 nm which consists of about 50% C term and 50% the other terms, indicating that it is not in a purely ferrous low-spin state. The CO complex of reduced cytochrome P-420 (P-420), on the other hand, shows an MCD spectrum characteristic of a ferrous low-spin heme. It is suggested from model experiments that the thiolate anion coordinates to the heme trans to CO in the P-450-CO complex. The Soret region of the MCD spectrum of the EtNC complex of reduced P-450 is characterized by two apparent A terms around 430 and 455 nm, whereas that of the corresponding complex of P-420 has only one apparent A term around 434 nm.     

Axial coordination of ferric Aplysia myoglobin

Resonance Raman spectra of ferric Aplysia myoglobin in the ligand-free and the azide-bound forms have been studied over a wide pH range to determine the coordination states of the heme iron atom. In the hydroxide form at high pH (approximately 9) the iron is six-coordinate and is in a high/low spin equilibrium. As the pH is lowered below the acid/alkaline transition (pKa = 7.5), the heme becomes five-coordinate. When the pH is lowered even further no other changes in the resonance Raman spectrum are detected; thus, the heme remains five-coordinate down to pH 4, the lowest value studied. For ferric azide-bound Aplysia myoglobin, the iron is six-coordinate in a high/low spin equilibrium at all pH values (4.8-9). These data indicate (i) that the unusual reactivity toward azide previously observed at neutral pH is indeed related to the absence of a coordinated water molecule, and (ii) that causes other than the heme coordination are responsible for the spectral differences and the ligand-binding kinetics differences observed below pH 6.     

Features of intermediary steps around the 688-nm substance in the heme oxygenase reaction

The degradation of protoheme in the heme oxygenase reaction involves three oxidation steps: from protoheme to hydroxyheme, from hydroxyheme to a 688-nm substance, a protein-bound intermediate, and from the 688-nm substance to a biliverdin-iron complex. The 688-nm substance has a ferrous iron and it readily binds carbon monoxide to form a CO-complex, called the 638-nm substance (Yoshida, T., Noguchi, M., & Kikuchi, G. (1980) J. Biochem. 88, 557-563). The ferric 688-nm substance was prepared from the 638-nm substance by the addition of potassium ferricyanide together with aspiration to eliminate CO. The ferric 688-nm substance did not show any distinct absorption maximum in the red region of the absorption spectrum. The ferric 688-nm substance was readily reduced on the addition of the NADPH-cytochrome P-450 reductase system, but the ferric 688-nm substance could also be reduced spontaneously though at a very low rate. The ferrous 688-nm substance free from excess reducing agents was prepared by passing the 638-nm substance through a column of Sephadex G-25. The ferrous 688-nm substance was degraded to a biliverdin-iron complex much more rapidly in the presence of the NADPH-cytochrome P-450 reductase system than in its absence, indicating that a reducing equivalent is essential for the initiation of heme degradation even when starting from the ferrous 688-nm substance. Cyanide was found to bind to the ferrous 688-nm substance to form a stable compound; the cyanide compound formed could revert to neither the ferrous 688-nm substance nor the 638-nm substance.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cyanide binding to Lucina pectinata hemoglobin I and to sperm whale myoglobin: an x-ray crystallographic study.

The x-ray crystal structures of the cyanide derivative of Lucina pectinata monomeric hemoglobin I (L. pectinata HbI) and sperm whale (Physeter catodon) myoglobin (Mb), generally taken as reference models for monomeric hemoproteins carrying hydrogen sulfide and oxygen, respectively, have been determined at 1.9 A (R-factor = 0. 184), and 1.8 A (R-factor = 0.181) resolution, respectively, at room temperature (lambda = 1.542 A). Moreover, the x-ray crystal structure of the L. pectinata HbI:cyanide derivative has been studied at 1.4-A resolution (R-factor = 0.118) and 100 K (on a synchrotron source lambda = 0.998 A). At room temperature, the cyanide ligand is roughly parallel to the heme plane of L. pectinata HbI, being located approximately 2.5 A from the iron atom. On the other hand, the crystal structure of the L. pectinata HbI:cyanide derivative at 100 K shows that the diatomic ligand is coordinated to the iron atom in an orientation almost perpendicular to the heme (the Fe-C distance being 1.95 A), adopting a coordination geometry strictly reminescent of that observed in sperm whale Mb, at room temperature. The unusual cyanide distal site orientation observed in L. pectinata HbI, at room temperature, may reflect reduction of the heme Fe(III) atom induced by free radical species during x-ray data collection using Cu Kalpha radiation.     

Proton magnetic resonance studies of peroxidases from turnip and horseradish.

Proton NMR spectra at 270 MHz have been measured for horseradish peroxidase and turnip peroxidase isoenzymes (P1, P2, P3 and P7) in both their high spin ferric native states and as the low spin ferric cyanide complexes. Resonances of amino acids near the heme have been identified and used to investigate variations in the structure of the heme crevice amongst the enzymes. Ligand proton resonances have been resolved in spectra of the cyanide complexes of the peroxidases and these provide information on the heme electronic structure. The electronic structure of the heme and the tertiary structure of the heme crevice are essentially the same in the acidic turnip isoenzymes, P1, P2 and, to a lesser extent, P3 but differ in the basic turnip enzyme, P7. The heme electronic structure and nature of the iron ligands in peroxidases are discussed. Further evidence is presented for histidine as the proximal ligand. A heme-linked ionizable group with a pK of 6.5 has been detected by NMR in the cyanide complex of horseradish peroxidase.