Laser flash induced electron transfer in P450cam monooxygenase: putidaredoxin reductase-putidaredoxin interaction

The P450cam monooxygenase from Pseudomonas putida consists of three redox proteins: NADH-putidaredoxin reductase (Pdr), putidaredoxin (Pdx), and cytochrome P450cam. The redox properties of the FAD-containing Pdr and the mechanism of Pdr-Pdx complex formation are the least studied aspects of this system. We have utilized laser flash photolysis techniques to produce the one-electron-reduced species of Pdr, to characterize its spectral and electron-transferring properties, and to investigate the mechanism of its interaction with Pdx. Upon flash-induced reduction by 5-deazariboflavin semiquinone, the flavoprotein forms a blue neutral FAD semiquinone (FADH(*)). The FAD semiquinone was unstable and partially disproportionated into fully oxidized and fully reduced flavin. The rate of FADH(*) decay was dependent on ionic strength and NAD(+). In the mixture of Pdr and Pdx, where the flavoprotein was present in excess, electron transfer (ET) from FADH(*) to the iron-sulfur cluster was observed. The Pdr-to-Pdx ET rates were maximal at an ionic strength of 0.35 where a kinetic dissociation constant (K(d)) for the transient Pdr-Pdx complex and a limiting k(obs) value were equal to 5 microM and 226 s(-1), respectively. This indicates that FADH(*) is a kinetically significant intermediate in the turnover of P450cam monooxygenase. Transient kinetics as a function of ionic strength suggest that, in contrast to the Pdx-P450cam redox couple where complex formation is predominantly electrostatic, the Pdx-Pdr association is driven by nonelectrostatic interactions.     

Putidaredoxin-to-cytochrome P450cam electron transfer: differences between the two reductive steps required for catalysis

Cytochrome P450cam (P450cam) is the terminal monooxygenase in a three-component camphor-hydroxylating system from Pseudomonas putida. The reaction cycle requires two distinct electron transfer (ET) processes from the [2Fe-2S] containing putidaredoxin (Pdx) to P450cam. Even though the mechanism of interaction and ET between the two proteins has been under investigation for over 30 years, the second reductive step and the effector role of Pdx are not fully understood. We utilized mutagenesis, kinetic, and computer modeling approaches to better understand differences between the two Pdx-to-P450cam ET events. Our results indicate that interacting residues and the ET pathways in the complexes formed between reduced Pdx (Pdx(r)) and the ferric and ferrous dioxygen-bound forms of P450cam (oxy-P450cam) are different. Pdx Asp38 and Trp106 were found to be key players in both reductive steps. Compared to the wild-type Pdx, the D38A, W106A, and delta106 mutants exhibited considerably higher Kd values for ferric P450cam and retained ca. 20% of the first electron transferring ability. In contrast, the binding affinity of the mutants for oxy-P450cam was not substantially altered while the second ET rates were <1%. On the basis of the kinetic and modeling data we conclude that (i) P450cam-Pdx interaction is highly specific in part because it is guided/controlled by the redox state of both partners; (ii) there are alternative ET routes from Pdx(r) to ferric P450cam and a unique pathway to oxy-P450cam involving Asp38; (iii) Pdx Trp106 is a key structural element that couples the second ET event to product formation possibly via its "push" effect on the heme-binding loop.     

A scanning tunneling microscopy (STM) investigation of complex formation between cytochrome P450(cam) and putidaredoxin

We have previously reported the scanning tunnelling microscopy (STM) imaging under buffer of the heme monooxygenase cytochrome P450(cam) from Pseudomonas putida [Faraday Discuss. 116 (2000) 1]. We describe here the adsorption and STM imaging under buffer of complexes of a mutant of cytochrome P450(cam), K344C, and wild-type putidaredoxin (Pdx) on gold(111). The images of Pdx on its own on gold(111) are not uniform, presumably due to multiple orientations of protein adsorption because of the presence of five or more cysteines on the protein surface. STM imaging of a 1:1 mixture of P450(cam)-K344C/Pdx showed a regular array of pairs of different-sized proteins 20-25 A apart arranged in rows across the gold(111) surface which we attribute to the P450(cam)/Pdx complex. The images of the pairs are more regular than those of Pdx on its own, probably as a result of complex formation with P450(cam) partly overcoming the heterogeneity of Pdx adsorption. As far as we are aware this is the first report of STM imaging of a protein/protein complex, and the first direct observation of P450(cam)/Pdx complex formation which is a key step in the catalytic cycle of P450(cam) catalysis. The redox centers of the two proteins are ca. 20 A apart, too far for rapid intracomplex electron transfer. Whether the observed complex is competent for electron transfer or physiologically relevant is not known, and further work is in progress to elucidate the protein-protein interaction.     

L358P mutation on cytochrome P450cam simulates structural changes upon putidaredoxin binding: the structural changes trigger electron transfer to oxy-P450cam from electron donors

To investigate the functional and structural characterization of a crucial cytochrome P450cam (P450cam)-putidaredoxin (Pdx) complex, we utilized a mutant whose spectroscopic property corresponds to the properties of the wild type P450cam in the presence of Pdx. The 1H NMR spectrum of the carbonmonoxy adduct of the mutant, the Leu-358 --> Pro mutant (L358P), in the absence of Pdx showed that the ring current-shifted signals arising from d-camphor were upfield-shifted and observed as resolved signals, which are typical for the wild type enzyme in the presence of Pdx. Signals from the beta-proton of the axial cysteine and the gamma-methyl group of Thr-252 were also shifted upfield and down-field, respectively, in the L358P mutant as observed for Pdx-bound wild type P450cam. The close similarity in the NMR spectra suggests that the heme environment of the L358P mutant mimics that of the Pdx-bound enzyme. The functional analysis of the L358P mutant has revealed that the oxygen adduct of the L358P mutant can promote the oxygenation reaction for d-camphor with nonphysiological electron donors such as dithionite and ascorbic acid, showing that oxygenated L358P is "activated" to receive electron from the donor. Based on the structural and functional characterization of the L358P mutant, we conclude that the Pdx-induced structural changes in P450cam would facilitate the electron transfer from the electron donor, and the Pdx binding to P450cam would be a trigger for the electron transfer to oxygenated P450cam.     

The role of water molecules in the association of cytochrome P450cam with putidaredoxin. An osmotic pressure study

We have investigated the osmotic pressure dependence of the association between ferric cytochrome P450cam and putidaredoxin (Pdx) to gain an insight into the role of water molecules in the P450cam-reduced Pdx complexation amenable to physiological electron transfer. The association constant was evaluated from the electron transfer rates from reduced Pdx to P450cam. The natural logarithm of the association constant K(a) was linearly reduced by the osmotic pressure, and osmotic stress yields uptake of 25 waters upon association. In contrast, uptake of only 13 waters is observed from the osmotic pressure dependence of the association in the nonphysiological redox partners P450cam and oxidized Pdx. Although general protein-protein associations proceed through dehydration around the complex interface, the interfacial waters could mediate hydrogen-bonding interactions. Therefore, about 10 more interfacial waters imply an additional water-mediated hydrogen-bonding network in the P450cam.reduced Pdx complex, which does not exist in the complex with oxidized Pdx. It is also possible that the water-mediated hydrogen-bonding interactions support a high P450cam affinity for reduced (K(a) = 0.83 microm(-1)) relative to oxidized (K(a) = 0.058 microm(-1)) Pdx. This study points to a novel role of solvents in assisting redox state-dependent interaction between P450cam and Pdx.     

Steady-state kinetic investigation of cytochrome P450cam: interaction with redox partners and reaction with molecular oxygen

Cytochrome P450cam (CYP101) is a prokaryotic monooxygenase that requires two proteins, putidaredoxin reductase (PdR) and putidaredoxin (Pdx), to supply electrons from NADH. This study addresses the mechanism by which electrons are transported from PdR to P450cam through Pdx and used to activate O(2) at the heme of P450cam. It is shown that k(cat)/Km(O2) is independent of the PdR concentration and hyperbolically dependent on Pdx. The phenomenon of saturation of reaction rates with either P450cam or PdR at high ratios of one enzyme to the other is investigated and shown to be consistent with a change in the rate limiting step. Either the reduction of Pdx by PdR (high P450) or the reduction of P450 by Pdx (high PdR) determines the rate. These data support a mechanism where Pdx acts as a shuttle for transport of electrons from PdR to P450cam, effectively ruling out the formation of a kinetically significant PdR/Pdx/P450cam complex.     

FTIR studies of the redox partner interaction in cytochrome P450: The Pdx–P450cam couple

Recently we have developed a new approach to study protein–protein interactions using Fourier transform infrared spectroscopy in combination with titration experiments and principal component analysis (FTIR-TPCA). In the present paper we review the FTIR-TPCA results obtained for the interaction between cytochrome P450 and the redox partner protein in two P450 systems, the Pseudomonas putida P450cam (CYP101) with putidaredoxin (P450cam–Pdx), and the Bacillus megaterium P450BM-3 (CYP102) heme domain with the FMN domain (P450BMP–FMND). Both P450 systems reveal similarities in the structural changes that occur upon redox partner complex formation. These involve an increase in β-sheets and α-helix content, a decrease in the population of random coil/3₁₀-helix structure, a redistribution of turn structures within the interacting proteins and changes in the protonation states or hydrogen-bonding of amino acid carboxylic side chains. We discuss in detail the P450cam–Pdx interaction in comparison with literature data and conclusions drawn from experiments obtained by other spectroscopic techniques. The results are also interpreted in the context of a 3D structural model of the Pdx–P450cam complex.     

Putidaredoxin-cytochrome p450cam interaction. Spin state of the heme iron modulates putidaredoxin structure

During the monooxygenase reaction catalyzed by cytochrome P450cam (P450cam), a ternary complex of P450cam, reduced putidaredoxin, and d-camphor is formed as an obligatory reaction intermediate. When ligands such as CO, NO, and O2 bind to the heme iron of P450cam in the intermediate complex, the EPR spectrum of reduced putidaredoxin with a characteristic signal at 346 millitesla at 77 K changed into a spectrum having a new signal at 348 millitesla. The experiment with O2 was carried out by employing a mutant P450cam with Asp251 --> Asn or Gly where the rate of electron transfer from putidaredoxin to oxyferrous P450cam is considerably reduced. Such a ligand-induced EPR spectral change of putidaredoxin was also shown in situ in Pseudomonas putida. Mutations introduced into the neighborhood of the iron-sulfur cluster of putidaredoxin revealed that a Ser44 --> Gly mutation mimicked the ligand-induced spectral change of putidaredoxin. Arg109 and Arg112, which are in the putative putidaredoxin binding site of P450cam, were essential for the spectral changes of putidaredoxin in the complex. These results indicate that a change in the P450cam active site that is the consequence of an altered spin state is transmitted to putidaredoxin within the ternary complex and produces a conformational change of the 2Fe-2S active center.     

Infrared spectroscopic and mutational studies on putidaredoxin-induced conformational changes in ferrous CO-P450cam

Ferrous-carbon monoxide bound form of cytochrome P450cam (CO-P450cam) has two infrared (IR) CO stretching bands at 1940 and 1932 cm(-1). The former band is dominant (>95% in area) for CO-P450cam free of putidaredoxin (Pdx), while the latter band is dominant (>95% in area) in the complex of CO-P450cam with reduced Pdx. The binding of Pdx to CO-P450cam thus evokes a conformational change in the heme active site. To study the mechanism involved in the conformational change, surface amino acid residues Arg79, Arg109, and Arg112 in P450cam were replaced with Lys, Gln, and Met. IR spectroscopic and kinetic analyses of the mutants revealed that an enzyme that has a larger 1932 cm(-1) band area upon Pdx-binding has a larger catalytic activity. Examination of the crystal structures of R109K and R112K suggested that the interaction between the guanidium group of Arg112 and Pdx is important for the conformational change. The mutations did not change a coupling ratio between the hydroxylation product and oxygen consumed. We interpret these findings to mean that the interaction of P450cam with Pdx through Arg112 enhances electron donation from the proximal ligand (Cys357) to the O-O bond of iron-bound O(2) and, possibly, promotes electron transfer from reduced Pdx to oxyP450cam, thereby facilitating the O-O bond splitting.     

Engineering of a hybrid biotransformation system for cytochrome P450sca-2 in Escherichia coli

P450sca-2 is an industrially important enzyme that stereoselectively converts mevastatin into pravastatin. However, little information or engineering efforts have been reported for this enzyme or its redox partner. In this study, we successfully reconstituted the P450sca-2 activity in Escherichia coli by co-expression with putidaredoxin reductase (Pdr) and putidaredoxin (Pdx) from the Pseudomonas putida cytochrome P450cam system. With an HPLC-based screening assay, random mutagenesis was applied to yield a mutant (R8-5C) with a pravastatin yield of the whole-cell biotransformation 4.1-fold that of the wild type. P450sca-2 wild-type and R8-5C were characterized in terms of mevastatin binding and hydroxylation, electron transfer, and circular dichroism spectroscopy. R8-5C showed an active P450 expression level that was 3.8-fold that of the wild type, with relatively smaller changes in the apparent k_cat/K_M with respect to the substrate mevastatin (1.3-fold) or Pdx (1.5-fold) compared with the wild type. Thus, the increase in the pravastatin yield of the whole-cell biotransformation primarily came from the improved active P450 expression, which has resulted largely from better heme incorporation, although none of the six mutations of R8-5C are located near the heme active site. These results will facilitate further engineering of this P450sca-2 system and provide useful clues for improving other hybrid P450 systems.     

Crystal structure of the cytochrome p450cam mutant that exhibits the same spectral perturbations induced by putidaredoxin binding

The cytochrome P450cam active site is known to be perturbed by binding to its redox partner, putidaredoxin (Pdx). Pdx binding also enhances the camphor monooxygenation reaction (Nagano, S., Shimada, H., Tarumi, A., Hishiki, T., Kimata-Ariga, Y., Egawa, T., Suematsu, M., Park, S.-Y., Adachi, S., Shiro, Y., and Ishimura, Y. (2003) Biochemistry 42, 14507-14514). These effects are unique to Pdx because nonphysiological electron donors are unable to support camphor monooxygenation. The accompanying 1H NMR paper (Tosha, T., Yoshioka, S., Ishimori, K., and Morishima, I. (2004) J. Biol. Chem. 279, 42836-42843) shows that the conformation of active site residues, Thr-252 and Cys-357, and the substrate in the ferrous (Fe(II)) CO complex of the L358P mutant mimics that of the wild-type enzyme complexed to Pdx. To explore how these changes are transmitted from the Pdx-binding site to the active site, we have solved the crystal structures of the ferrous and ferrous-CO complex of wild-type and the L358P mutant. Comparison of these structures shows that the L358P mutation results in the movement of Arg-112, a residue known to be important for putidaredoxin binding, toward the heme. This change could optimize the Pdx-binding site leading to a higher affinity for Pdx. The mutation also pushes the heme toward the substrate and ligand binding pocket, which relocates the substrate to a position favorable for regio-selective hydroxylation. The camphor is held more firmly in place as indicated by a lower average temperature factor. Residues involved in the catalytically important proton shuttle system in the I helix are also altered by the mutation. Such conformational alterations and the enhanced reactivity of the mutant oxy complex with non-physiological electron donors suggest that Pdx binding optimizes the distal pocket for monooxygenation of camphor.     

Crystal structure of putidaredoxin reductase from Pseudomonas putida, the final structural component of the cytochrome P450cam monooxygenase

The crystal structure of recombinant putidaredoxin reductase (Pdr), an FAD-containing NADH-dependent flavoprotein component of the cytochrome P450cam monooxygenase from Pseudomonas putida, has been determined to 1.90 A resolution. The protein has a fold similar to that of disulfide reductases and consists of the FAD-binding, NAD-binding, and C-terminal domains. Compared to homologous flavoenzymes, the reductase component of biphenyl dioxygenase (BphA4) and apoptosis-inducing factor, Pdr lacks one of the arginine residues that compensates partially for the negative charge on the pyrophosphate of FAD. This uncompensated negative charge is likely to decrease the electron-accepting ability of the flavin. The aromatic side-chain of the "gatekeeper" Tyr159 is in the "out" conformation and leaves the nicotinamide-binding site of Pdr completely open. The presence of electron density in the NAD-binding channel indicates that NAD originating from Escherichia coli is partially bound to Pdr. A structural comparison of Pdr with homologous flavoproteins indicates that an open and accessible nicotinamide-binding site, the presence of an acidic residue in the middle part of the NAD-binding channel that binds the nicotinamide ribose, and multiple positively charged arginine residues surrounding the entrance of the NAD-binding channel are the special structural elements that assist tighter and more specific binding of the oxidized pyridine nucleotide by the BphA4-like flavoproteins. The crystallographic model of Pdr explains differences in the electron transfer mechanism in the Pdr-putidaredoxin redox couple and their mammalian counterparts, adrenodoxin reductase and adrenodoxin.     

Mechanism of O2 activation by cytochrome P450cam studied by isotope effects and transient state kinetics

The early steps in dioxygen activation by the monooxygenase cytochrome P450cam (CYP101) include binding of O2 to ferrous P450cam to yield the ferric-superoxo form (oxyP450cam) followed by an irreversible, long-range electron transfer from putidaredoxin to reduce the oxyP450cam. The steady state kinetic parameter kcat/Km(O2) has been studied by a variety of probes that indicate a small D2O solvent isotope effect (1.21 +/- 0.08), a very small solvent viscosogen effect, and a 16O/18O isotope effect of 1.0147 +/- 0.0007. This latter value, which can be compared with the 16O/18O equilibrium isotope effect of 1.0048 +/- 0.0003 measured for oxyP450cam formation, is attributed to a primarily rate-limiting outer-sphere electron transfer from the heme iron center as O2 that has prebound to protein approaches the active site cofactor. The electron transfer from putidaredoxin to oxyP450cam was investigated by rapid mixing at 25 degrees C to complement previous lower-temperature measurements. A rate of 390 +/- 23 s-1 (and a near-unity solvent isotope effect) supports the view that the long-range electron transfer from reduced putidaredoxin to oxyP450cam is rapid relative to dissociation of O2 from the enzyme. P450cam represents the first enzymatic reaction of O2 in which both equilibrium and kinetic 16O/18O isotope effects have been measured.     

The putidaredoxin reductase-putidaredoxin electron transfer complex: theoretical and experimental studies

Interaction and electron transfer between putidaredoxin reductase (Pdr) and putidaredoxin (Pdx) from Pseudomonas putida was studied by molecular modeling, mutagenesis, and stopped flow techniques. Based on the crystal structures of Pdr and Pdx, a complex between the proteins was generated using computer graphics methods. In the model, Pdx is docked above the isoalloxazine ring of FAD of Pdr with the distance between the flavin and [2Fe-2S] of 14.6 A. This mode of interaction allows Pdx to easily adjust and optimize orientation of its cofactor relative to Pdr. The key residues of Pdx located at the center, Asp(38) and Trp(106), and at the edge of the protein-protein interface, Tyr(33) and Arg(66), were mutated to test the Pdr-Pdx computer model. The Y33F, Y33A, D38N, D38A, R66A, R66E, W106F, W106A, and Delta106 mutations did not affect assembly of the [2Fe-2S] cluster and resulted in a marginal change in the redox potential of Pdx. The electron-accepting ability of Delta106 Pdx was similar to that of the wild-type protein, whereas electron transfer rates from Pdr to other mutants were diminished to various degrees with the smallest and largest effects on the kinetic parameters of the Pdr-to-Pdx electron transfer reaction caused by the Trp(106) and Tyr(33)/Arg(66) substitutions, respectively. Compared with wild-type Pdx, the binding affinity of all studied mutants to Pdr was significantly higher. Experimental results were in agreement with theoretical predictions and suggest that: (i) Pdr-Pdx complex formation is mainly driven by steric complementarity, (ii) bulky side chains of Tyr(33), Arg(66), and Trp(106) prevent tight binding of oxidized Pdx and facilitate dissociation of the reduced iron-sulfur protein from Pdr, and (iii) transfer of an electron from FAD to [2Fe-2S] can occur with various orientations between the cofactors through multiple electron transfer pathways that do not involve Trp(106) but are likely to include Asp(38) and Cys(39).     

Activity profile of glutathione-dependent enzymes and respiratory chain complexes in rats supplemented with antioxidants and treated with carcinogens

A real-time optical biosensor study on the interactions between putidaredoxin reductase (PdR), putidaredoxin (Pd), and cytochrome P450cam (P450cam) within the P450cam system was conducted. The binary Pd/P450cam and Pd/PdR complexes were revealed and kinetically characterized. The dominant role of electrostatic interactions in formation of productive electron transfer complexes was demonstrated. It was found that Pd/P450cam complex formation and decay obeys biphasic kinetics in contrast to the monophasic one for complexes formed by other redox partners within the system. Evidence for PdR/P450cam complex formation was obtained. It was found that, in contrast to Pd, which binds only to its redox partners, PdR and P450cam were able to form PdR/PdR and P450cam/P450cam complexes. A ternary PdR/Pd/P450cam complex was also registered. Its lifetime was sufficient to permit up to 60 turnovers to occur. The binding of Pd to P450cam and to PdR within the ternary complex occurred at distinct sites, with Pd serving as a bridge between the two proteins.     

Putidaredoxin reductase,a new function for an old protein

Properties of recombinant wild type (WT) and six-histidine tag-fused (His(6)) putidaredoxin reductase (Pdr), a FAD-containing component of the soluble cytochrome P450cam monooxygenase system from Pseudomonas putida, have been studied. Both WT and His(6) Pdr were found to undergo a monomer-dimer association-dissociation and were partially present as an NAD(+)-bound form. Although molecular, spectral, and electron transferring properties of recombinant His(6) Pdr to artificial and native electron acceptors were similar to those of the WT protein, the presence of eight additional C-terminal amino acid residues, Pro-Arg-His-His-His-His-His-His, had a crucial effect on the enzyme interaction with oxidized pyridine nucleotide. Under anaerobic conditions, NAD(+) induced in His(6) Pdr spectral changes indicative of flavin reduction and formation of the charge transfer complex between the reduced FAD and NAD(+). The reaction proceeded considerably faster in the presence of free histidine and thiol-reducing agents, such as dithiothreitol and reduced glutathione. In the presence of any of these three reagents, NAD(+) was capable of inducing reduction of the flavin in WT Pdr. Free thiol groups were identified as an internal source of electrons in the enzyme. The results showed that WT and His(6) Pdr were able to function as NAD(H)-dependent dithiol/disulfide oxidoreductases catalyzing both forward and reverse reactions, NAD(+)-dependent oxidation of thiols, and NADH-dependent reduction of disulfides. This function of the flavoprotein can be dissociated from electron transfer to putidaredoxin. Similarity of Pdr to the enzymes of the glutathione reductase family is discussed.     

Molecular dynamics of the P450cam–Pdx complex reveals complex stability and novel interface contacts

Cytochrome P450cam catalyzes the stereo and regiospecific hydroxylation of camphor to 5‐exo‐hydroxylcamphor. The two electrons for the oxidation of camphor are provided by putidaredoxin (Pdx), a Fe₂S₂ containing protein. Two recent crystal structures of the P450cam–Pdx complex, one solved with the aid of covalent cross‐linking and one without, have provided a structural picture of the redox partner interaction. To study the stability of the complex structure and the minor differences between the recent crystal structures, a 100 nanosecond molecular dynamics (MD) simulation of the cross‐linked structure, mutated in silico to wild type and the linker molecule removed, was performed. The complex was stable over the course of the simulation though conformational changes including the movement of the C helix of P450cam further toward Pdx allowed for the formation of a number of new contacts at the complex interface that remained stable throughout the simulation. While several minor crystal contacts were lost in the simulation, all major contacts that had been experimentally studied previously were maintained. The equilibrated MD structure contained a mixture of contacts resembling both the cross‐linked and noncovalent structures and the newly identified interactions. Finally, the reformation of the P450cam Asp251–Arg186 ion pair in the MD simulation mirrors the ion pair observed in the more promiscuous CYP101D1 and suggests that the Asp251–Arg186 ion pair may be important.     

Cytochrome P-450cam and putidaredoxin interaction during electron transfer.

Cytochrome P-450cam, the bacterial hemeprotein which catalyzes the 5-exo-hydroxylation of d-camphor, requires two electrons to activate molecular oxygen for this monooxygenase reaction. These two electrons are transferred to cytochrome P-450cam in two one-electron steps by the physiological reductant, putidaredoxin. The present study of the kinetics of reduction of cytochrome P-450cam by reduced putidaredoxin has shown that the reaction obeys first order kinetics with a rate constant of 33 s-1 at 25 degrees C with respect to: 1) the appearance of the carbon monoxide complex of Fe(II) cytochrome P-450cam; 2) the disappearance of the 645 nm absorbance band of high-spin Fe(III) cytochrome P-450cam; and 3) the disappearance of the g = 1.94 EPR signal of reduced putidaredoxin. This data was interpreted as indicative of the rapid formation of a bimolecular complex between reduced putidaredoxin Fe(III) cytochrome P-450cam. The existence of the complex was first shown indirectly by kinetic analysis and secondly directly by electron paramagnetic resonance spectroscopic analysis of samples which were freeze-quenched approximately 16 ms after mixing. The direct evidence for complex formation was the loss of the EPR signal of Fe(III) cytochrome P-450cam upon formation of the complex while the EPR signal of reduced putidaredoxin decays with the same kinetics as the appearance of Fe(II) cytochrome P-450. The mechanism of the loss of the EPR signal of cytochrome P-450 upon formation of the complex is not apparent at this time but may involve a conformational change of cytochrome P-450cam following complex formation.     

Cysteinyl-tRNA formation: the last puzzle of aminoacyl-tRNA synthesis

A 1H nuclear magnetic resonance study of the complex of cytochrome P450cam-putidaredoxin has been performed. Isocyanide is bound to cytochrome P450cam in order to increase the stability of the protein both in the reduced and the oxidized state. Diprotein complex formation was detected through variation of the heme methyl proton resonances which have been assigned in the two redox states. The electron transfer rate at equilibrium was determinated by magnetization transfer experiments. The observed rate of oxidation of reduced cytochrome P450 by the oxidized putidaredoxin is 27 (+/- 7) per s.     

Molecular mechanism of the electron transfer reaction in cytochrome P450(cam)--putidaredoxin: roles of glutamine 360 at the heme proximal site

We characterized electron transfer (ET) from putidaredoxin (Pdx) to the mutants of cytochrome P450(cam) (P450(cam)), in which one of the residues located on the putative binding site to Pdx, Gln360, was replaced with Glu, Lys, and Leu. The kinetic analysis of the ET reactions from reduced Pdx to ferric P450(cam) (the first ET) and to ferrous oxygenated P450(cam) (the second ET) showed the dissociation constants (K(m)) that were moderately perturbed for the Lys and Leu mutants and the distinctly increased for the Glu mutant. Although the alterations in K(m) indicate that Gln360 is located at the Pdx binding site, the effects of the Gln360 mutations (0.66-20-fold of that of wild type) are smaller than those of the Arg112 mutants (25-2500-fold of that of wild type) [Unno, M., et al. (1996) J. Biol. Chem. 271, 17869-17874], allowing us to conclude that Gln360 much less contributes to the complexation with Pdx than Arg112. The first ET rate (35 s(-1) for wild-type P450(cam)) was substantially reduced in the Glu mutant (5.4 s(-1)), while less perturbation was observed for the Lys (53 s(-1)) and Leu (23 s(-1)) mutants. In the second ET reaction, the retarded ET rate was detected only in the Glu mutant but not in the Lys and Leu mutants. These results showed the smaller mutational effects of Gln360 on the ET reactions than those of the Arg112 mutants. In contrast to the moderate perturbations in the kinetic parameters, the mutations at Gln360 significantly affected both the standard enthalpy and entropy of the redox reaction of P450(cam), which cause the negative shift of the redox potentials for the Fe(3+)/Fe(2+) couple by 20-70 mV. Since the amide group of Gln360 is located near the carbonyl oxygen of the amide group of the axial cysteine, it is plausible that the mutation at Gln360 perturbs the electronic interaction of the axial ligand with heme iron, resulting in the reduction of the redox potentials. We, therefore, conclude that Gln360 primarily regulates the ET reaction of P450(cam) by modulating the redox potential of the heme iron and not by the specific interaction with Pdx or the formation of the ET pathway that are proposed as the regulation mechanism of Arg112.