Reaction mechanism for mammalian pyruvate dehydrogenase using natural lipoyl domain substrates.

The pyruvate dehydrogenase (E1) component of the pyruvate dehydrogenase complex (PDC) catalyzes a two-step reaction. Recombinant production of substrate amounts of the lipoyl domains of the dihydrolipoyl transacetylase (E2) component of the mammalian PDC allowed kinetic characterization of the rapid physiological reaction catalyzed by E1. Using either the N-terminal (L1) or the internal (L2) lipoyl domain of E2 as a substrate, analyses of steady state kinetic data support a ping pong mechanism. Using standard E1 preparations, Michaelis constants (Km) were 52 +/- 14 microM for L1 and 24.8 +/- 3.8 microM for pyruvate and k(cat) was 26.3 s(-1). With less common, higher activity preparations of E1, the Km values were > or =160 microM for L1 and > or =35 microM for pyruvate and k(cat) was > or =70 s(-1). Similar results were found with the L2 domain. The best synthetic lipoylated-peptide (L2 residues 163-177) was a much poorer substrate (Km > or =15 mM, k(cat) approximately equals 5 s(-1); k(cat)/Km decreased >1,500-fold) than L1 or L2, but a far better substrate in the E1 reaction than free lipoamide (k(cat)/Km increased >500-fold). Each lipoate source was an effective substrate in the dihydrolipoyl dehydrogenase (E3) reaction, but E3 had a lower Km for the L2 domain than for lipoamide or the lipoylated peptides. In contrast to measurements with slow E1 model reactions that use artificial acceptors, we confirmed that the natural E1 reaction, using lipoyl domain acceptors, was completely inhibited (>99%) by phosphorylation of E1 and the phosphorylation strongly inhibited the reverse of the second step catalyzed by E1. The mechanisms by which phosphorylation interferes with E1 activity is interpreted based on accrued results and the location of phosphorylation sites mapped onto the 3-D structure of related alpha-keto acid dehydrogenases.

Active site analysis of P450 enzymes: comparative magnetic circular dichroism spectroscopy.

Recent structural studies indicate that the substrate- and O2-binding distal pocket of the P450 enzymes are not identical. Thus, P450terp (CYP108) from the alpha-terpineol-metabolizing Pseudomonad differs from P450cam (CYP-101) (C. A. Hasemann et al., J. Mol. Biol. 236, 1169, 1994). In contrast, the distal pockets of P450terp and P450BMP (CYP102 heme domain; Bacillus megaterium) are more closely similar, including novel hydrogen-bonding interactions between the distal H2O ligand and the I helix (C. A. Hasemann et al., Structure, 3, 41-62, 1995). To evaluate the significance of these differences, we have compared solution magnetic circular dichroism (MCD) spectra of P450terp with spectra of other P450 enzymes (e.g., P450cam, P450BMP, P450BM-3holo, and P450BM1), as well as with spectra of chloroperoxidase and NO synthase. Spectra of native P450terp are more similar to those of P450BMP and those of mammalian P450LM-2 than to those of P450cam. Upon substrate-binding, the MCD spectra of ferric P450terp and all other thiolate-ligated heme systems examined to date display a strong Soret band that is distinctly unique relative to the typical Soret MCD pattern(s) of catalases or other 5-coordinate ferric heme systems. This intense negative MCD feature thus appears diagnostic for cysteinate-linked ferric hemes. In the case of ferrous P450s, the intensity of the Soret-region MCD trough varies between substrate-bound and substrate-free enzymes (despite the fact that the substrate is NOT in direct contact with the heme moiety). A novel finding of particular interest is the clear spectral shifts of the Soret MCD band between the substrate-bound and substrate-free forms of ferrous-CO-P450terp. No such observation has been made previously. Furthermore, the band positions for BOTH types of P450terp are red-shifted from known bands of ferrous-CO-P50cam. These data thus indicate a surprising sensitivity of MCD spectra to active-site polarity and to H2O occupancy, concurring with reports of distal pocket effects on CO-binding rates and equilibrium constants. Comparative analysis of the spectral properties of P450terp with MCD spectra of other P450 enzymes, as well as with chloroperoxidase and NO synthase, demonstrates both the expected similarities and the significant differences that reflect active-site structural features. The detailed spectral analysis of P450terp relative to other P450 enzymes presented herein includes the first observation of a substrate-induced spectral shift for a ferrous-CO-P450. Furthermore, testable structural predictions for P450-BM-1 and for the novel NO synthase enzyme (neither of which has been crystallized to date) are made herein. This work thus provides insights into structurally defined P450s and may also lead to understanding of other P450 enzymes.

Spectral analysis of lactoperoxidase. Evidence for a common heme in mammalian peroxidases.

The identity of the non-extractable heme of mammalian lactoperoxidase (LPO) has remained unsolved for over 40 years. Accepted possibilities include a constrained heme b or an 8-thiomethylene-modified heme b. Recent studies of myeloperoxidase (MPO) (Fenna, R., Zeng, J., and Davey, C. (1995) Arch. Biochem. Biophys. 316, 653-656; Taylor, K. L., Strobel, F., Yue, K. T., Ram, P., Pohl, J., Woods, A. S., and Kinkade, J. M., Jr. (1995) Arch. Biochem. Biophys. 316, 635-642) suggest possible prosthetic group similarities between MPO and LPO. To address heme identity for LPO, we used comparative magnetic circular dichroism (MCD) spectroscopy of LPO versus myoglobin (Mb), horseradish peroxidase (HRP), and MPO. MCD spectra of native Fe3+-LPO and Fe3+-CN--LPO are approximately 10 nm red shifted from analogous forms of Mb and HRP, including the formate-Mb adduct. MCD spectra of native LPO and MPO are opposite in sign, and MCD spectra of their cyanoadducts also differ. These data indicate the LPO heme is distinct from heme b of Mb and HRP as well as from "heme m" of MPO. From this work and literature analysis, we suggest that the non-extractable "heme l" of LPO has the two vinyl groups of heme b but lacks the 2-sulfonium-vinyl linkage of heme m. The observed red shifts in LPO spectra may derive from ester linkages to protein as for MPO. Strong spectral analogies between LPO and mammalian peroxidases (e.g. from saliva, eosinophils, thyroid, intestine) indicate similar prosthetic heme moieties.

Comparative analysis of catalases: spectral evidence against heme-bound water for the solution enzymes.

A recent X-ray structural analysis of M. luteus catalase indicates heme-bound H2O trans to the proximal tyrosinate ligand, a finding in contrast to previous X-ray data reporting a 5-coordinate heme for bovine liver catalase. The presence of heme-bound H2O, requiring displacement prior to substrate-binding, is likely to be catalytically significant for catalases. We have used magnetic circular dichroism (MCD) spectroscopy, a highly accurate method for assignment of heme spin- and coordination-states, to study native, solution forms of bovine liver, M. luteus, and A. niger catalases. All three enzymes display similar spectral features with the weak (approximately 5 delta epsilon M [moles.cm.Tesla]-1) intensity typical of a 5-coordinate high-spin ferric heme. No evidence for H2O-ligation, inducing a 6-coordinate heme, occurred upon variation of pH or buffer composition. Therefore, we suggest that the catalytically significant structure of catalases has an unoccupied heme binding site trans to the proximal tyrosinate heme ligand.

Active-site analysis of ferric P450 enzymes: hydrogen-bonding effects on the circular dichroism spectra.

Active-site CD spectra were analyzed for P450's with known x-ray structures (P450terp, P450BM-3, P450cam). CD spectral patterns for Fe(3+)-substrate-free P450's reflect structure/function properties of the distal pocket. P450terp and P450BM-3 have an H-bond between 6th ligand and I-helix [Hasemann, C.A., et al. (1995) Structure, 3, 41-62], and the Soret CD band at approximately 410 nm is approximately 2-fold larger than that at approximately 350 nm. For P450cam, the two CD bands are more nearly equal, and the 6th ligand is not H-bonded to the I-helix. The CD spectral pattern can be used to predict active-site structural properties, e.g., H-bonding and polarity.

Identification of the tryptophan residue in the thiamin pyrophosphate binding site of mammalian pyruvate dehydrogenase.

The pyruvate dehydrogenase (E1) component of the mammalian pyruvate dehydrogenase complex catalyzes the oxidative decarboxylation of pyruvate with the formation of an acetyl residue and reducing equivalents, which are transferred sequentially to the dihydrolipoyl acetyltransferase and dihydrolipoamide dehydrogenase components. To examine the role of tryptophanyl residue(s) in the active site of E1, the enzyme was modified with the tryptophan-specific reagent N-bromosuccinimide. Modification of 2 tryptophan residues/mol of bovine E1 (out of 12 in a tetramer alpha 2 beta 2) resulted in complete inactivation of the enzyme. The inactivation was prevented by preincubation with thiamin pyrophosphate (TPP), indicating that the modified tryptophan residue(s) is part of the active site of this enzyme. Fluorescence studies showed that thiamin pyrophosphate interacts with tryptophan residue(s) of E1. The magnetic circular dichroism (MCD) spectral intensity at approximately 292 nm was decreased by approximately 15% for E1 + TPP relative to the intensity for E1 alone. Because this MCD band is uniquely sensitive to and quantitative for tryptophan, the simplest interpretation is that 1 out of 6 tryptophan residues present in E1 (alpha beta dimer) interacts with TPP. The natural circular dichroism (CD) spectrum of E1 is dramatically altered upon binding TPP, with concomitant induction of optical activity at approximately 263 nm for the nonchiral TPP macrocycle. From CD studies, it is also inferred that loss of activity following N-bromosuccinimide treatment occurred without significant changes in the overall secondary structure of the protein. A single peptide was isolated by differential peptide mapping in the presence and absence of thiamin pyrophosphate following modification with N-bromosuccinimide. This peptide generated from human E1 was found to correspond to amino acid residues 116-143 in the deduced sequence of human E1 beta, suggesting that the tryptophan residue 135 in the beta subunit of human E1 functions in the active site of E1. The amino acid sequence surrounding this tryptophan residue are conserved in E1 beta from several species, suggesting that this region may constitute a structurally and/or functionally essential part of the enzyme.

Isolation and characterization of a hemocyte aggregation inhibitor from hemolymph of Manduca sexta larvae.

A protein that inhibits hemocyte aggregation has been isolated from hemolymph of Manduca sexta larvae and named hemocyte aggregation inhibitor protein (HAIP). HAIP has a M(r) = 50,000, pI = 8.5, and contains 7% carbohydrate. It is present at 230 +/- 20 micrograms/ml in hemolymph of day 3 fifth instar larvae. Antibodies to HAIP do not cross-react with M. sexta hemolin, which is similar in size and charge and also inhibits hemocyte aggregation. HAIP and hemolin have some similarity in amino acid composition and NH2-terminal sequence, but are different in overall secondary structure, as determined by CD spectroscopy. The concentration of HAIP in hemolymph is not affected by injection of larvae with bacteria. A protein of approximately 50,000 daltons that reacts with antibody to M. sexta HAIP is present in hemolymph of Bombyx mori, Heliothis zea, and Galleria mellonella. Although the function of HAIP in vivo is not yet clear, it may have a role in modulating adhesion of hemocytes during defensive responses.

Coordination structure of the ferric heme iron in engineered distal histidine myoglobin mutants.

Recombinant human myoglobin mutants with the distal His residue (E7, His64) replaced by Leu, Val, or Gln residues were prepared by site-directed mutagenesis and expression in Escherichia coli. Electronic and coordination structures of the ferric heme iron in the recombinant myoglobin proteins were examined by optical absorption, EPR, 1H NMR, magnetic circular dichroism, and x-ray spectroscopy. Mutations, His-->Val and His-->Leu, remove the heme-bound water molecule resulting in a five-coordinate heme iron at neutral pH, while the heme-bound water molecule appears to be retained in the engineered myoglobin with His-->Gln substitution as in the wild-type protein. The distal Val and distal Leu ferric myoglobin mutants at neutral pH exhibited EPR spectra with g perpendicular values smaller than 6, which could be interpreted as an admixture of intermediate (S = 3/2) and high (S = 5/2) spin states. At alkaline pH, the distal Gln mutant is in the same so-called "hydroxy low spin" form as the wild-type protein, while the distal Leu and distal Val mutants are in high spin states. The ligand binding properties of these recombinant myoglobin proteins were studied by measurements of azide equilibrium and cyanide binding. The distal Leu and distal Val mutants exhibited diminished azide affinity and extremely slow cyanide binding, while the distal Gln mutant showed azide affinity and cyanide association rate constants similar to those of the wild-type protein.

Modelling heme d1. The spectral properties of copper(II) porphyrindiones.

The heme d1 macrocycle of Ps. aeruginosa dissimilatory nitrite reductase is an iron porphyrin-3,8-dione with a 17-acrylate substituent. We have compared the RR properties of Cu-d1, the copper(II) TME of extracted heme d1, with those of models that differ only with respect to the acrylate: Cu-17-acrylate mesoporphyrin-3,8-dione (2) and Cu-mesoporphyrin-3,8-dione (3). The RR spectrum of Cu-d1 is very similar to that of 2, including v(C = O) at approximately 1720 cm-1. Replacement of the acrylate with propionate changes the spectrum markedly. For example, the v(C = O) mode of 3 shifts to 1712 cm-1, and peaks of Cu-d1 and 2 at approximately 1400 and approximately 1535 cm-1 are shifted or absent from the spectrum of 3. FTIR spectra of 2 and 3 also differ in their voxo(C = O) frequencies. The acrylate thus has a surprisingly strong influence on the electronic structural and spectral properties of heme d1. These data provide a foundation for studies of the novel biological porphyrindione macrocycles.

Spectroscopic characterization of secondary amine mono-oxygenase. Comparison to cytochrome P-450 and myoglobin.

Secondary amine mono-oxygenase from Pseudomonas aminovorans catalyzes the NAD(P)H- and dioxygen-dependent N-dealkylation of secondary amines to yield a primary amine and an aldehyde. Heme iron, flavin, and non-heme iron prosthetic groups are known to be present in the oligomeric enzyme. The N-dealkylation reaction is also catalyzed by the only other heme-containing mono-oxygenase, cytochrome P-450. In order to identify the heme iron axial ligands of secondary amine mono-oxygenase so as to better define the structural requirements for oxygen activation by heme enzymes, we have investigated the spectroscopic properties of the enzyme. The application of three different spectroscopic techniques, UV-visible absorption, magnetic circular dichroism and electron paramagnetic resonance, to study eight separate enzyme derivatives has provided extensive and convincing evidence for the presence of a proximal histidine ligand. This conclusion is based primarily on comparisons of the spectral properties of the enzyme with those of parallel derivatives of myoglobin (histidine proximal ligand) and P-450 (cysteinate proximal ligand). Spectral studies of ferric secondary amine mono-oxygenase as a function of pH have led to the proposal that the distal ligand is water. Deprotonation of the distal water ligand occurs upon either raising the pH to 9.0 or substrate (dimethylamine) binding. In contrast, the deoxyferrous enzyme appears to have a weakly bound nitrogen donor distal ligand. Initial spectroscopic studies of the iron-sulfur units in the enzyme are interpreted in terms of a pair of Fe2S2 clusters. Secondary amine mono-oxygenase is unique in its ability to function as cytochrome P-450 in activating molecular oxygen but to do so with a myoglobin-like active site. As such, it provides an important system with which to probe structure-function relations in heme-containing oxygenases.

Modeling low-pH hemoproteins.

A tetracoordinate ferrous heme (iron-porphyrin) has been proposed as an intermediate at low pH (less than 3.0) for respiratory hemoproteins, peroxidases, and model heme complexes. This intermediate is believed to arise via protonation of the N(epsilon) atom of the proximal histidine and consequent cleavage of the Fe-N(epsilon) bond. To establish a spectral signature for the proposed low-pH tetracoordinate species, we have obtained Soret excitation resonance Raman spectra on samples of crystallographically defined, tetracoordinate iron(II)-octaethylporphyrin (Fe.OEP; S = 1). The high-frequency (greater than or equal to 900 cm-1) resonance Raman spectral features of Fe.OEP are clearly distinct from those of high-spin pentacoordinate or low-spin hexacoordinate ferrous hemes. Rather, they are at frequencies more typically observed for low-spin hexacoordinate ferric porphyrins. Comparative spectral analysis of tetracoordinate Fe.OEP and other proposed tetracoordinate ferrous hemes (e.g. iron(II)-protoporphyrin IX) demonstrates little or no macrocycle effect on the resonance Raman frequencies above 900 cm-1. This work thus serves to provide a testable spectral signature by which the existence of the proposed tetracoordinate biological intermediate may be verified and by which its functional significance may be tested.

Comparative spectral analysis of mammalian, fungal, and bacterial catalases. Resonance Raman evidence for iron-tyrosinate coordination.

Resonance Raman spectra are reported for catalases from bovine liver, the ascomycete fungus Aspergillus niger, and the bacterium Micrococcus luteus. The vibrational frequencies of the oxidation-, spin-, and coordination number-sensitive spectral bands are indicative of high spin pentacoordinate hemes in the resting ferric enzymes of each of these organisms. This result is in accord with the crystal structure of bovine catalase (Fita, I., and Rossmann, M.G. (1985) J. Mol. Biol. 185, 21-37). In contrast, the crystallographic study of catalase from the ascomycete Penicillium vitale (Vainshtein, B. K., Melik-Adamyan, W. R., Barynin, V. V., Vagin, A.A., Grebenko, A. I., Borisov, V. V., Bartels, K. S., Fita, I., and Rossmann, M. G. (1986) J. Mol. Biol. 188, 49-61) showed electron density on the distal side of the heme which could imply the presence of a sixth ligand, possibly a water molecule. However, both of these crystallographic studies showed the proximal ligand in catalase to be a tyrosine. The present study confirms tyrosinate coordination in each of the three catalases from the appearance of selected resonance-enhanced tyrosine vibrational modes. The most characteristic band is the tyrosinate ring mode at approximately 1612 cm-1 which is maximally enhanced with 488.0 nm excitation. The appearance of tyrosinate modes at 1607 and 1245 cm-1 in the resonance Raman spectra of M. luteus cyano catalase serves to identify tyrosine as an axial ligand in bacterial as well as eukaryotic catalases. Unlike non-heme iron tyrosinate proteins, whose resonance Raman spectra are dominated by several intense bands diagnostic of tyrosine ligation, the heme-linked tyrosine modes are not easily distinguished from the large number of porphyrin vibrations.

Spectroscopic analysis of chlorophyll model complexes: methyl ester ClFe(III)pheophorbides.

As models for chlorophyll a (Chl a), methyl ester ClFe(III)pheophorbides (1, pheophorbide a; 2, mesopheophorbide a; and 3, mesopyropheophorbide a) were examined by Fourier transform infrared (FTIR) absorption and resonance Raman (RR) spectroscopy. The infrared (IR) chlorin band above 1600 cm-1, assigned as a Ca-Cm mode (Andersson et al. (1987) J. Am. Chem. Soc. 109, 2908-2916) is shown to be metal-sensitive and responsive to spin state and coordination number for dihydroporphyrins, as well as being diagnostic for the chlorin vs. porphyrin or bacteriochlorin macrocycle. Frequency variations for this metallochlorin IR band thus parallel those of the v10 RR mode of porphyrins in their predictive utility. Qy excitation SERRS spectra of Chl a were compared with Qy excitation RR spectra of 1 and methyl Ni(II)pyropheophorbide a. The data demonstrate that 5-coordinate ClFe(III)pheophorbides are better models for chlorophylls than are ruffled 4-coordinate Ni(II)pheophorbides. Major spectral differences between the three chlorophyll models are associated with the C-9 keto and/or C-10 carbomethoxy vibrational modes. The approx. 1700 cm-1 IR band was formerly assigned solely to v(C = O) of the C-9 keto group. However, this IR feature shifts down to approx. 1685 cm-1 and nearly doubles in intensity when the C-10 carbomethoxy is removed, as for 3. Similar frequency downshifts coupled with intensity increases in the IR are found in the literature on chlorophylls. RR spectra of pheophorbides having the C-10 carbomethoxy group (1 and 2) have bands at both approx. 1700 and approx. 1735 cm-1. However, the C-9 keto v(C = O) mode of pyrophorbins also downshifts to approx. 1685 cm-1, as in the IR spectra. The approx. 1735 cm-1 ester RR mode disappears in the case of pyrophorbins, and is never RR active for nonconjugated esters of porphyrins or chlorins. These data demonstrate an interaction between the C-10 and C-9 carbonyls of phorbins. They also indicate that phorbins tend toward conjugation of the C-10 ester. Biological examples of such conjugation effects have recently been reported, e.g., for the Chl a pi-cation radical (Heald et al. (1988) J. Phys. Chem. 92, 4820-4824). Because the phorbin E ring is the major structural feature distinguishing chlorophylls from non-photosynthetic systems, the participation of the C-10 ester in ring conjugation is suggestive of its biological importance.

Lignin peroxidase: resonance Raman spectral evidence for compound II and for a temperature-dependent coordination-state equilibrium in the ferric enzyme.

Resonance Raman (RR) spectroscopy of lignin peroxidase (ligninase, dairylpropane oxygenase) from the basidiomycete Phanerochaete chrysosporium suggests two different coordination states for the native ferric enzyme. Evidence for a high-spin, hexacoordinate ferric protoporphyrin IX was presented by Andersson et al. [Andersson, L. A., Renganathan, V., Chiu, A.A., Loehr, T. M., & Gold, M. H. (1985) J. Biol. Chem. 260, 6080-6087], whereas Kuila et al. [Kuila, D., Tien, M., Fee, J. A., & Ondrias, M. R. (1985) Biochemistry 24, 3394-3397] proposed a high-spin, pentacoordinate ferric system. Because the two RR spectral studies were performed at different temperatures, we explored the possibility that lignin peroxidase might exhibit temperature-dependent coordination-state equilibria. Resonance Raman results presented herein indicate that this hypothesis is indeed correct. At or near 25 degrees C, the ferric iron of lignin peroxidase is predominantly high spin, pentacoordinate; however, at less than or equal to 2 degrees C, the high-spin, hexacoordinate state dominates, as indicated by the frequencies of well-documented spin- and coordination-state marker bands for iron protoporphyrin IX. The temperature-dependent behavior of lignin peroxidase is thus similar to that of cytochrome c peroxidase (CCP). Furthermore, lignin peroxidase, like horseradish peroxidase (HRP) and CCP, clearly has a vacant coordination site trans to the native fifth ligand at ambient temperature. High-frequency RR spectra of compound II of lignin peroxidase are also presented. The observed shifts to higher frequency for both the oxidation-state marker band v4 and the spin- and coordination-state marker band v10 are similar to those reported for the compound II forms of HRP and lactoperoxidase and for ferryl myoglobin.(ABSTRACT TRUNCATED AT 250 WORDS)

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.

Sulfmyoglobin. Resonance Raman spectroscopic evidence for an iron-chlorin prosthetic group.

The green heme protein sulfmyoglobin (SMb) has been suggested to contain a sulfur-modified iron chlorin prosthetic group. To evaluate this hypothesis, we have obtained high-frequency (greater than 1000 cm-1) resonance Raman spectra of both oxidized and reduced SMb with 457.9-, 488.0-, 514.5-, 568.2-, and 647.1-nm excitation. The SMb spectra are compared to those of native met- and deoxymyoglobin (Mb). Vibrational frequencies for SMb are generally similar to those of Mb, suggesting a high-spin state for both the Fe(III) and Fe(II) SMb species, as is typical of native Mb. However, major differences between SMb and Mb occur both for patterns of relative spectral intensities and for depolarization ratios. In particular, all B1g-depolarized porphyrin modes in the Mb spectra have become polarized, totally symmetric vibrational modes in the SMb spectra. These contrasts reflect a dramatic lowering of the effective symmetry for the SMb prosthetic group. Several new bands are observed in SMb spectra that are not present in spectra of either native Mb or iron protoporphyrin IX complexes. The observation of additional polarized bands flanking the oxidation state marker, V4, is of particular interest. In a parallel study, we compared the resonance Raman spectral properties of iron protoporphyrin IX-derived chlorins and metallo-octaethylchlorins with those of the analogous porphyrins: the chlorin spectra exhibited altered intensity patterns, an increased number of totally symmetric (polarized) vibrational bands, and several new vibrational bands, including one or two in the region of the oxidation state marker, V4. Thus, the resonance Raman spectral characteristics of SMb and metallo-chlorins are complementary and strongly support a chlorin prosthetic group for SMb. Furthermore, they establish testable criteria for investigating the prosthetic group structures of other green heme proteins by resonance Raman spectroscopy.

The influence of oxygen donor ligation on the spectroscopic properties of ferric cytochrome P-450: ester, ether and ketone co-ordination to the haem iron.

Homogeneous low-spin complexes of cytochrome P-450-CAM with esters, ethers and ketones have been prepared and characterized by u.v.-visible absorption, circular dichroism (CD), magnetic circular dichroism (MCD) and electron paramagnetic resonance (EPR) spectroscopy. Direct haem iron ligation has been verified by competition for binding with well-known haem ligands. The u.v.-visible spectra of the oxygen-donor complexes exhibit near-u.v. (delta) transitions near 356 nm, Soret maxima at 417 +/- 1 nm, beta bands near 536 nm and alpha peaks near 569 nm, with alpha greater than beta in intensity. Negative delta and Soret CD troughs are seen. The MCD spectra have minima at approximately 356 nm, intense derivative-shaped Soret features centred at approximately 416 nm and four characteristic features beyond 450 nm. The EPR spectra of these complexes, while similar to that of the native enzyme, exhibit slight variances. Anomalous spectral and substrate binding properties have been reported in the study of cytochrome P-450 under conditions employing solvents and non-phosphate buffers containing oxygen functionalities, and have been attributed to 'solvent effects'. The present work, in combination with our previous report of alcohol, amide and carboxylate oxygen donor complexes of cytochrome P-450, is evidence that a wide variety of oxygen-donor species are capable of direct ligation to the haem iron of cytochrome P-450. This leads us to suggest oxygen-donor ligation to cytochrome P-450 as the origin of spectral and substrate binding anomalies previously attributed to solvent effects.

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.

The diverse spectroscopic properties of ferrous cytochrome P-450-CAM ligand complexes.

The UV-visible absorption, magnetic circular dichroism (MCD) and CD spectral characteristics of a variety of low spin ferrous P-450-ligand complexes have been carefully determined in order to establish whether all such complexes are hyperporphyrins as previously suggested in the literature. Two general spectral classes are found to occur. Complexes in the first class are, indeed, hyperporphyrin in nature, with pi-acceptor ligands such as CO, NO, phosphine, nitrosoalkanes and isocyanides trans to cysteinate. Individual, but minor, variations in the spectral properties of the hyperporphyrins suggest that subclasses exist, wherein the nature of the trans ligand to thiolate affects the orbital overlap pattern and thus the observed spectra. Adducts in the second spectral class, which have sigma-donor nitrogen and sulfur ligands, also have the red-shifted Soret absorption maximum but are spectrally distinct in all other respects from the hyperporphyrins. Comparison of the MCD spectra of the second category to those of ferrous cytochromes b5, c, and P-420 suggests that the axial cysteinate ligand is still present in the nonhyper ferrous P-450 species. Thus, the combination of a strongly electron-donating cysteinate ligand and a trans sigma-donor, not the orbital mixing mechanism, is most likely the origin of the red-shifted Soret absorption maximum of nonhyper ferrous P-450 ligand complexes. Further, the nature of the total electronic interactions between both axial ligands and the heme iron of ferrous P-450 and not solely the cysteinate ligand determines whether the ligand complexes will be of the hyper or nonhyperporphyrin category. These findings are strengthened by the simultaneous use of three different spectroscopic techniques; together they provide a more detailed explanation for the unusual spectroscopic properties of cytochrome P-450.

Endogenous cysteine ligation in ferric and ferrous cytochrome P-450. Direct evidence from x-ray absorption spectroscopy.

Extended x-ray absorption fine structure spectroscopy has been applied to the elucidation of the structure of the heme iron site of bacterial cytochrome P-450. The low spin ferric, high spin ferric, ferrous, and ferrous carbonyl states of the enzyme have been examined. Curve-fitting analysis of the data provides direct and compelling evidence for the presence of a sulfur atom in the first coordination sphere of the iron. The iron-nitrogen (porphyrin) distances indicate five coordination in high spin ferric and ferrous P-450 and six coordination in low spin ferric and ferrous carbonyl P-450. The iron-sulfur distances are consistent with thiolate ligation, presumably from cysteinate, in all four states of the enzyme. In each case, the iron-sulfur bond distance is equal to or shorter than the analogous Fe-S bonds in model iron porphyrin thiolate complexes whose crystal structures have been determined. Since known thiol-sulfur:iron-heme bond distances are noticeably longer than the corresponding thiolate bonds, the X-ray absorption fine structure results strongly suggest that, in each P-450 state examined, the sulfur donor is a thiolate. The results reported in this paper concerning the ligand identity, state of protonation, and metal-ligand bond distances are of critical importance to a complete description of the P-450 reaction cycle and its mechanism of oxygen activation.