Redox-dependent dynamics of putidaredoxin characterized by amide proton exchange

Tracking protein-protein interactions by NMR: conformational selection in human steroidogenic cytochrome P450 CYP17A1 induced by cytochrome b5

The human steroidogenic cytochrome P450 CYP17A1 catalyzes two types of reactions in the biosynthetic pathway leading from pregnenolone to testosterone and several other steroid hormones. The first is the hydroxylation of pregnenolone or progesterone to the corresponding 17α-hydroxy steroid, followed by a lyase reaction that converts these 17α-hydroxy intermediates to the androgens dehydroepiandrosterone and androstenedione, respectively. cytochrome b5 (cytb5) is known to act as both an effector and electron donor for the lyase oxidations, markedly stimulating the rate of the lyase reaction in its presence relative to the rate in its absence. Extensive sequential backbone 1H,15N and 13C nuclear magnetic resonance assignments have now been made for oxidized CYP17A1 bound to the prostate cancer drug and inhibitor abiraterone. This is the first eukaryotic P450 for which such assignments are now available. These assignments allow more complete interpretation of the structural perturbations observed upon cytb5 addition. Possible mechanism(s) for the effector activity of cytb5 are discussed in light of this new information.

Active Site Hydrogen Bonding Induced in Cytochrome P450cam by Effector Putidaredoxin

Cytochrome P450s are diverse and powerful catalysts that can activate molecular oxygen to oxidize a wide variety of substrates. Catalysis relies on effective uptake of two electrons and two protons. For cytochrome P450cam, an archetypal member of the superfamily, the second electron must be supplied by the redox partner putidaredoxin (Pdx). Pdx also plays an effector role beyond electron transfer, but after decades the mechanism remains under investigation. We applied infrared spectroscopy to heme-ligated CN^- to examine the influence of Pdx binding. The results indicate that Pdx induces the population of a conformation wherein the CN^- ligand forms a strong hydrogen bond to a solvent water molecule, experimentally corroborating the formation of a proposed proton delivery network. Further, characterization of T252A P450cam implicates the side chain of Thr252 in regulating the population equilibrium of hydrogen-bonded states within the P450cam/Pdx complex, which could underlie its role in directing activated oxygen toward product formation and preventing reaction uncoupling through peroxide release.

What Your Crystal Structure Will Not Tell You about Enzyme Function

Enzyme function requires that enzyme structures be dynamic. Substrate binding, product release, and transition state stabilization typically involve different enzyme conformers. Furthermore, in multistep enzyme-catalyzed reactions, more than one enzyme conformation may be important for stabilizing different transition states. While X-ray crystallography provides the most detailed structural information of any current methodology, X-ray crystal structures of enzymes capture only those conformations that fit into the crystal lattice, which may or may not be relevant to function. Solution nuclear magnetic resonance (NMR) methods can provide an alternative approach to characterizing enzymes under nonperturbing and controllable conditions, allowing one to identify and localize dynamic processes that are important to function. However, many enzymes are too large for standard approaches to making sequential resonance assignments, a critical first step in analyzing and interpreting the wealth of information inherent in NMR spectra.

This Account describes our long-standing NMR-based research into structural and dynamic aspects of function in the cytochrome P450 monooxygenase superfamily. These heme-containing enzymes typically catalyze the oxidation of unactivated C–H and C=C bonds in a multitude of substrates, often with complete regio- and stereospecificity. Over 600 000 genes in GenBank have been assigned to P450s, yet all known P450 structures exhibit a highly conserved and unique fold. This combination of functional and structural conservation with a vast substrate clientele, each substrate having multiple possible sites for oxidation, makes the P450s a unique target for understanding the role of enzyme structure and dynamics in determining a particular substrate–product combination. P450s are large by solution NMR standards, requiring us to develop specialized approaches for making sequential resonance assignments and interpreting the spectral changes that occur as a function of changing conditions (e.g., oxidation and spin state changes, ligand, substrate or effector binding). Solution conformations are characterized by the fitting of residual dipolar couplings (RDCs) measured for sequence-specifically assigned amide N–H correlations to alignment tensors optimized in the course of restrained molecular dynamics (MD) simulations. The conformational ensembles obtained by such RDC-restrained simulations, which we call “soft annealing”, are then tested by site-directed mutation and spectroscopic and activity assays for relevance. These efforts have gained us insights into cryptic conformational changes associated with substrate and redox partner binding that were not suspected from crystal structures, but were shown by subsequent work to be relevant to function. Furthermore, it appears that many of these changes can be generalized to P450s besides those that we have characterized, providing guidance for enzyme engineering efforts. While past research was primarily directed at the more tractable prokaryotic P450s, our current efforts are aimed at medically relevant human enzymes, including CYP17A1, CYP2D6, and CYP3A4.

Conformational Change Induced by Putidaredoxin Binding to Ferrous CO-ligated Cytochrome P450cam Characterized by 2D IR Spectroscopy

The importance of conformational dynamics to protein function is now well-appreciated. An outstanding question is whether they are involved in the effector role played by putidaredoxin (Pdx) in its reduction of the O₂ complex of cytochrome P450cam (P450cam), an archetypical member of the cytochrome P450 superfamily. Recent studies have reported that binding of Pdx induces a conformational change from a closed to an open state of ferric P450cam, but a similar conformational change does not appear to occur for the ferrous, CO-ligated enzyme. To better understand the effector role of Pdx when binding the ferrous, CO-ligated P450cam, we applied 2D IR spectroscopy to compare the conformations and dynamics of the wild-type (wt) enzyme in the absence and presence of Pdx, as well as of L358P P450cam (L358P), which has served as a putative model for the Pdx complex. The CO vibrations of the Pdx complex and L358P report population of two conformational states in which the CO experiences distinct environments. The dynamics among the CO frequencies indicate that the energy landscape of substates within one conformation are reflective of the closed state of P450cam, and for the other conformation, differ from the free wt enzyme, but are equivalent between the Pdx complex and L358P. The two states co-populated by the Pdx complex are postulated to reflect a loosely bound encounter complex and a more tightly bound state, as is commonly observed for the dynamic complexes of redox partners. Significantly, this study shows that the binding of Pdx to ferrous, CO-ligated P450cam does perturb the conformational ensemble in a way that might underlie the effector role of Pdx.

Identification of productive and futile encounters in an electron transfer protein complex

Well-defined, stereospecific states in protein complexes are often in exchange with an ensemble of more dynamic orientations: the encounter states. The structure of the stereospecific complex between cytochrome P450cam and putidaredoxin was solved recently by X-ray diffraction as well as paramagnetic NMR spectroscopy. Other than the stereospecific complex, the NMR data clearly show the presence of additional states in the complex in solution. In these encounter states, populated for a small percentage of the time, putidaredoxin assumes multiple orientations and samples a large part of the surface of cytochrome P450cam. To characterize the nature of the encounter states, an extensive paramagnetic NMR dataset has been analyzed using the Maximum Occurrence of Regions methodology. The analysis reveals the location and maximal spatial extent of the additional states needed to fully explain the NMR data. Under the assumption of sparsity of the size of the conformational ensemble, several minor states can be located quite precisely. The distribution of these minor states correlates with the electrostatic potential map around cytochrome P450cam. Whereas some minor states are on isolated positively charged patches, others are connected to the stereospecific site via positively charged paths. The existence of electrostatically favorable pathways between the stereospecific interaction site and the different minor states or lack thereof suggests a means to discriminate between productive and futile encounter states.

The IR-¹⁵N-HSQC-AP experiment: a new tool for NMR spectroscopy of paramagnetic molecules

A crucial factor for the understanding of structure-function relationships in metalloproteins is the identification of NMR signals from residues surrounding the metal cofactor. When the latter is paramagnetic, the NMR information in the proximity of the metal center may be scarce, because fast nuclear relaxation quenches signal intensity and coherence transfer efficiency. To identify residues at a short distance from a paramagnetic center, we developed a modified version of the ¹⁵N-HSQC experiment where (1) an inversion recovery filter is added prior to HSQC, (2) the INEPT period has been optimized according to fast relaxation of interested spins, (3) the inverse INEPT has been eliminated and signals acquired as antiphase doublets. The experiment has been successfully tested on a human [Fe₂S₂] protein which is involved in the biogenesis of iron-sulfur proteins. Thirteen HN resonances, unobserved with conventional HSQC experiments, could be identified. The structural arrangement of the protein scaffold in the proximity of the Fe/S cluster is fundamental to comprehend the molecular processes responsible for the transfer of Fe/S groups in the iron-sulfur protein assembly machineries.

Redox state dependence of axial ligand dynamics in Nitrosomonas europaea cytochrome c552

Analysis of NMR spectra reveals that the heme axial Met ligand orientation and dynamics in Nitrosomonas europaea cytochrome c552 (Ne cyt c) are dependent on the heme redox state. In the oxidized state, the heme axial Met is fluxional, interconverting between two conformers related to each other by inversion through the Met δS atom. In the reduced state, there is no evidence of fluxionality, with the Met occupying one conformation similar to that seen in the homologous Pseudomonas aeruginosa cytochrome c551. Comparison of the observed and calculated pseudocontact shifts for oxidized Ne cyt c using the reduced protein structure as a reference structure reveals a redox-dependent change in the structure of the loop bearing the axial Met (loop 3). Analysis of nuclear Overhauser effects (NOEs) and existing structural data provides further support for the redox state dependence of the loop 3 structure. Implications for electron transfer function are discussed.

Conformational plasticity and structure/function relationships in cytochromes P450

The cytochrome P450s are a superfamily of enzymes that are found in all kingdoms of living organisms, and typically catalyze the oxidative addition of atomic oxygen to an unactivated C-C or C-H bond. Over 8000 nonredundant sequences of putative and confirmed P450 enzymes have been identified, but three-dimensional structures have been determined for only a small fraction of these. While all P450 enzymes for which structures have been determined share a common global fold, the flexibility and modularity of structure around the active site account for the ability of P450 enzymes to accommodate a vast number of structurally dissimilar substrates and support a wide range of selective oxidations. In this review, known P450 structures are compared, and some structural criteria for prediction of substrate selectivity and reaction type are suggested. The importance of dynamic processes such as redox-dependent and effector-induced conformational changes in determining catalytic competence and regio- and stereoselectivity is discussed, and noncrystallographic methods for characterizing P450 structures and dynamics, in particular, mass spectrometry and nuclear magnetic resonance spectroscopy are reviewed.

Evidence for conformational heterogeneity of fission protein Fis1 from Saccharomyces cerevisiae

Fission 1 (Fis1) is an evolutionarily conserved, type II integral membrane protein implicated in maintaining the proper morphology of mitochondria and peroxisomes. A concave surface on the cytosolic domain of Fis1 from Saccharomyces cerevisiae is implicated in binding other fission proteins, yet structural studies reveal that this surface is sterically occluded by its N-terminal arm. Here we address the question of whether the N-terminal arm of yeast Fis1 exists in a dynamic equilibrium that would allow access to this functionally important surface. NMR measurements sensitive to dynamics occurring on a wide range of time scales (picoseconds to minutes) were used to assess whether the Fis1 arm is dynamic. Hydrogen-deuterium exchange experiments revealed that the Fis1 arm, alpha-helix 6, and proximal loops were not protected from solvent exchange, consistent with motions on the second to minute time scale. An engineered cysteine, I85C, located on the concave surface that lies underneath the Fis1 arm, was readily modified by a fluorescent probe, revealing more solvent accessibility of this position than would be predicted from the structure. Chemical denaturation, NMR chemical shift perturbation, and residual dipolar coupling experiments support the idea that the dynamic equilibrium can be shifted on the basis of changing pH and temperature, with the changes primarily localizing to the Fis1 arm and proximal regions. The data as a whole are consistent with the Fis1 arm adopting a primarily "closed" conformational state able to undergo dynamic excursions that reveal the concave surface and therefore may be important for binding other fission factors and for Fis1 function.

Redox-dependent dynamics in cytochrome P450cam

Local protein backbone dynamics of the camphor hydroxylase cytochrome P450(cam) (CYP101) depend upon the oxidation and ligation state of the heme iron. (1)H-(15)N correlation nuclear magnetic resonance experiments were used to compare backbone dynamics of oxidized and reduced forms of this 414-residue metalloenzyme via hydrogen-deuterium exchange kinetics (H-D exchange) and (15)N relaxation measurements, and these results are compared with previously published results obtained by H-D exchange mass spectrometry. In general, the reduced enzyme exhibits lower-amplitude motions of secondary structural features than the oxidized enzyme on all of the time scales accessible to these experiments, and these differences are more pronounced in regions of the enzyme involved in substrate access to the active site (B' helix and beta3 and beta5 sheets) and binding of putidaredoxin (C and L helices), the iron-sulfur protein that acts as the effector and reductant of CYP101 in vivo. These results are interpreted in terms of local structural effects of changes in the heme oxidation state, and the relevance of the observed effects to the enzyme mechanism is discussed.

Hydrogen-deuterium exchange mass spectrometry for investigation of backbone dynamics of oxidized and reduced cytochrome P450cam

Backbone dynamics of the camphor monoxygenase cytochrome P450(cam) (CYP101) as a function of oxidation/ligation state of the heme iron were investigated via hydrogen/deuterium exchange (H/D exchange) as monitored by mass spectrometry. Main chain amide NH hydrogens can exchange readily with solvent and the rate of this exchange depends upon, among other things, dynamic fluctuations in local structural elements. A fluxional region of the polypeptide will exchange more quickly with solvent than one that is more constrained. In most regions of the enzyme, exchange rates were similar between oxidized high-spin camphor-bound and reduced camphor- and CO-bound CYP101 (CYP-S and CYP-S-CO, respectively). However, in regions of the protein that have previously been implicated in substrate access by structural and molecular dynamics investigations, the reduced enzyme shows significantly slower exchange rates than the oxidized CYP-S. This observation corresponds to increased flexibility of the oxidized enzyme relative to the reduced form. Structural features previously found to be perturbed in CYP-S-CO upon binding of the biologically relevant effector and reductant putidaredoxin (Pdx) as determined by nuclear magnetic resonance are also more protected from exchange in the reduced state. To our knowledge, this study represents the first experimental investigation of backbone dynamics within the P450 family using this methodology.

Redox-dependent Structural Reorganization in Putidaredoxin, a Vertebrate-type [2Fe-2S] Ferredoxin from Pseudomonas putida

Putidaredoxin (Pdx), a vertebrate-type [2Fe-2S] ferredoxin from Pseudomonas putida, transfers electrons from NADH-putidaredoxin reductase to cytochrome P450cam. Pdx exhibits redox-dependent binding affinities for P450cam and is thought to play an effector role in the monooxygenase reaction catalyzed by this hemoprotein. To understand how the reduced form of Pdx is stabilized and how reduction of the [2Fe-2S] cluster affects molecular properties of the iron-sulfur protein, crystal structures of reduced C73S and C73S/C85S Pdx were solved to 1.45 angstroms and 1.84 angstroms resolution, respectively, and compared to the corresponding 2.0 angstroms and 2.03 angstroms X-ray models of the oxidized mutants. To prevent photoreduction, the latter models were determined using in-house radiation source and the X-ray dose received by Pdx crystals was significantly decreased. Structural analysis showed that in reduced Pdx the Cys45-Ala46 peptide bond flip initiates readjustment of hydrogen bonding interactions between the [2Fe-2S] cluster, the Sgamma atoms of the cysteinyl ligands, and the backbone amide nitrogen atoms that results in tightening of the Cys39-Cys48 metal cluster binding loop around the prosthetic group and shifting of the metal center toward the Cys45-Thr47 peptide. From the metal center binding loop, the redox changes are transmitted to the linked Ile32-Asp38 peptide triggering structural rearrangement between the Tyr33-Asp34, Ser7-Asp9 and Pro102-Asp103 fragments of Pdx. The newly established hydrogen bonding interactions between Ser7, Asp9, Tyr33, Asp34, and Pro102, in turn, not only stabilize the tightened conformation of the [2Fe-2S] cluster binding loop but also assist in formation of a specific structural patch on the surface of Pdx that can be recognized by P450cam. This redox-linked change in surface properties is likely to be responsible for different binding affinity of oxidized and reduced Pdx to the hemoprotein.

Crystal Structure of Putidaredoxin, the [2Fe–2S] Component of the P450cam Monooxygenase System from Pseudomonas putida

Stability of the [2Fe-2S]-containing putidaredoxin (Pdx), the electron donor to cytochrome P450cam in Pseudomonas putida, was improved by mutating non-ligating cysteine residues, Cys73 and Cys85, to serine singly and in combination. The increasing order of stability is Cys73Ser/Cys85Ser>Cys73Ser>Cys85Ser>WT Pdx. Crystal structures of Cys73Ser/Cys85Ser and Cys73Ser mutants of Pdx, solved by single-wavelength anomalous dispersion phasing using the [2Fe-2S] iron atoms to 1.47 A and 1.65 A resolution, respectively, are nearly identical and very similar to those of bovine adrenodoxin (Adx) and Escherichia coli ferredoxin. However, unlike the Adx structure, no motion between the core and interaction domains of Pdx is observed. This higher conformational stability of Pdx might be due to the presence of a more extensive hydrogen bonding network at the interface between the two structural domains around the conserved His49. In particular, formation of a hydrogen bond between the side-chain of Tyr51 and the carbonyl oxygen atom of Glu77 and the presence of two well-ordered water molecules linking the interaction domain and the C-terminal peptide to the core of the molecule are unique to Pdx. The folding topology of the NMR model is similar to that of the X-ray structure of Pdx. The overall rmsd of Calpha positions between the two models is 1.59 A. The largest positional differences are observed for residues 18-21 and 33-37 in the loop regions and the C terminus. The latter two peptides display conformational heterogeneity in the crystal structures. Owing to flexibility, the aromatic ring of the C-terminal Trp106 can closely approach the side-chains of Asp38 and Thr47 (3.2-3.9 A) or move away and leave the active site solvent-exposed. Therefore, Trp106, previously shown to be important in the Pdr-to-Pdx and Pdx-to-P450cam electron transfer reactions is in a position to regulate and/or mediate electron transfer to or from the [2Fe-2S] center of Pdx.

The solution structure of the recombinant hemoglobin from the cyanobacterium Synechocystis sp. PCC 6803 in its hemichrome state

The product of the cyanobacterium Synechocystis sp. PCC 6803 gene slr2097 is a 123 amino acid polypeptide chain belonging to the truncated hemoglobin family. Recombinant, ferric heme-reconstituted Synechocystis sp. PCC 6803 hemoglobin displays bis-histidine coordination of the iron ion. In addition, this protein is capable of covalently attaching a reactive histidine to the heme 2-vinyl group. The structure of the protein in the low-spin ferric state with intact vinyl substituents was solved by NMR methods. It was found that the structure differs from that of known truncated hemoglobins primarily in the orientation of the E helix, which carries His46 (E10) as the distal ligand to the iron; the length and orientation of the F helix, which carries His70 (F8) as the proximal ligand to the iron; and the H-helix, which carries His117 (H16), the reactive histidine. Regions of enhanced flexibility include the short A helix, the loop connecting the E and F helices, and the last seven residues at the carboxy end. The structural data allowed for the rationalization of physical properties of the cyanobacterial protein, such as fast on-rate for small ligand binding, unstable apoprotein fold, and cross-linking ability. Comparison to the truncated hemoglobin from the green alga Chlamydomonas eugametos also suggested how the endogenous hexacoordination affected the structure.

Backbone dynamics of plastocyanin in both oxidation states. Solution structure of the reduced form and comparison with the oxidized state

A model-free analysis based on (15)N R(1), (15)N R(2), and (15)N-(1)H nuclear Overhauser effects was performed on reduced (diamagnetic) and oxidized (paramagnetic) forms of plastocyanin from Synechocystis sp. PCC6803. The protein backbone is rigid, displaying a small degree of mobility in the sub-nanosecond time scale. The loops surrounding the copper ion, involved in physiological electron transfer, feature a higher extent of flexibility in the longer time scale in both redox states, as measured from D(2)O exchange of amide protons and from NH-H(2)O saturation transfer experiments. In contrast to the situation for other electron transfer proteins, no significant difference in the dynamic properties is found between the two redox forms. A solution structure was also determined for the reduced plastocyanin and compared with the solution structure of the oxidized form in order to assess possible structural changes related to the copper ion redox state. Within the attained resolution, the structure of the reduced plastocyanin is indistinguishable from that of the oxidized form, even though small chemical shift differences are observed. The present characterization provides information on both the structural and dynamic behavior of blue copper proteins in solution that is useful to understand further the role(s) of protein dynamics in electron transfer processes.

Temperature dependence of the formal reduction potential of putidaredoxin

Putidaredoxin (Pdx), a [2Fe-2S] redox protein of size M(r) 11,600, transfers two electrons in two separate steps from the flavin containing putidaredoxin reductase to the heme protein, cytochrome CYP101 in the P450cam catalytic cycle. It has recently come to light, through NMR measurements, that there can be appreciable differences in the Pdx conformational dynamics between its reduced and oxidized states. The redox reaction entropy, deltaS(0')rc = (S(0')Pdx(r)-S(0')Pdx(0)), as determined from measurements of the variation in formal potential with temperature, E0'(T), provides a measure of the strength of this influence on Pdx function. We designed a spectroelectrochemical cell using optically transparent tin oxide electrodes, without fixed or diffusible mediators, to measure E0'(T) over the temperature range 0-40 degrees C. The results indicate that the redox reaction entropy for Pdx is biphasic, decreasing from -213 +/- 27 J mol(-1) K(-1) over 0-27 degrees C, to -582 +/- 150 J mol(-1) K (-1) over 27-40 degrees C. These redox reaction entropy changes are significantly more negative than the changes reported for most cytochromes, although our measurement over the temperature interval 0-27 degrees C is in the range reported for other iron-sulfur proteins. This suggests that Pdx (and other ferredoxins) is a less rigid system than monohemes, and that redox-linked changes in conformation, and/or conformational dynamics, impart to these proteins the ability to interact with a number of redox partners.

Proton nuclear magnetic resonance study of the binary complex of cytochrome P450cam and putidaredoxin: interaction and electron transfer rate analysis

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.

The structure of iron-sulfur proteins

Ferredoxins are a group of iron-sulfur proteins for which a wealth of structural and mutational data have recently become available. Previously unknown structures of ferredoxins which are adapted to halophilic, acidophilic or hyperthermophilic environments and new cysteine patterns for cluster ligation and non-cysteine cluster ligation have been described. Site-directed mutagenesis experiments have given insight into factors that influence the geometry, stability, redox potential, electronic properties and electron-transfer reactivity of iron-sulfur clusters.

The solution structure of a gallium-substituted putidaredoxin mutant: GaPdx C85S

The Fe2S2 cluster of the ferredoxin putidaredoxin (Pdx) can be replaced by a single gallium ion, giving rise to a colorless, diamagnetic protein in which, apart from the metal binding site, the major structural features of the native ferredoxin are conserved. The solution structure of the C85S variant of gallium putidaredoxin (C85S GaPdx), in which a non-ligand cysteine is replaced by a serine, has been determined via multidimensional NMR methods using uniformly 15N, 13C labeled samples of C85S GaPdx. Stereospecific assignments of leucine and valine methyl resonances were made using 13C, 1H HSQC spectra obtained with fractionally 13C-labeled samples, and backbone dihedral angle restraints were obtained using a combination of two-dimensional J-modulated 15N, 1H HSQC and three-dimensional (HN)CO(CO)NH experiments. A total of 1117 NOE-derived distance restraints were used in the calculations, including 454 short range (i-j < or = 3), 456 long range (i-j > or = 4) interresidue restraints and 207 non-trivial intraresidue restraints. 97 phi and 55 chi 1 angular restraints were also included in the calculation of a family of 20 structures using a combined distance geometry-simulated annealing protocol. Most regions of the protein are well defined in the calculations, with an RMSD of 0.525 A for backbone atoms excluding the metal binding loop (residues 34-48) and the last three C-terminal residues (residues 103-106). Where comparison is possible, these regions show an increase in dynamic behavior over the native protein, as does the loop containing residues 74-76. Structural and dynamic differences between native Pdx and GaPdx are discussed in relation to charge and packing of the metal binding site.

Exploration of the structural environment of the iron-sulfur cluster in putidaredoxin by nitrogen-15 NMR spectroscopy of selectively labeled cysteine residues

Putidaredoxin is a di-iron protein whose paramagnetic region is not well characterized by 1H detected NMR. We have studied the structure of this region in greater detail by directly observed 15N NMR of oxidized and reduced putidaredoxin preparations in which the six cysteine residues are selectively labeled with 15N. A new method for preparation of a stable form of reduced putidaredoxin has been developed for use in NMR. The 15N NMR spectra of the oxidized and reduced forms are characteristically different, and we have measured and compared 15N chemical shifts, spin-lattice relaxation times (T1), and chemical shift/temperature dependences for both forms. Evidence for localized valencies of the iron atoms in the reduced form is presented. From the 15N T1 values of the oxidized form, reduced distances of the cysteine backbone 15N nuclei from the center of the Fe2S2 cluster have been calculated. These distances are consistent with those calculated from X-ray crystal structure data for five ferredoxins, and confirm the structural similarity of the Fe2S2 clusters in putidaredoxin and in these ferredoxins in the oxidized state.

NMR studies of putidaredoxin: associations of putidaredoxin with NADH-putidaredoxin reductase and cytochrome p450cam

To characterize the electron-transfer reaction in the P450cam monooxygenation system, the binding regions of putidaredoxin (Pdx) to NADH-putidaredoxin reductase (PdR) and P450cam were investigated using isotope-filtered NMR experiments in which uniformly 15N-labeled Pdx ([U-15N]Pdx) is mixed with unlabeled PdR and P450cam. By addition of PdR to Pdx, site specific signal broadening was observed for the N-H correlation peaks from Val-28, Glu-72, Ile-88, and Gln-105. Although previous studies have suggested the contribution from acidic amino acid residues on the G-helix of Pdx to the binding with PdR, no site specific broadening was observed for the resonances from these residues except for Glu-72. The lesser contribution of electrostatic interactions to the Pdx/PdR complex formation was also suggested by our previous study (M. Aoki, K. Ishimori, H. Fukada, K. Takahashi, I. Morishima, Biochim. Biophys. Acta 1384 (1998) 180-188), which is in sharp contrast to the complex formation between adrenodoxin and adrenodoxin reductase. Upon the complex formation between Pdx and P450cam, the site specific NMR line broadening was observed for several amino acid residues distributed near the iron-sulfur cluster, corresponding to the large binding site in the complex formation with P450cam. Since some of the amino acid residues included in the binding site are not conserved for the electron-transfer iron-sulfur proteins such as ferredoxin and adrenodoxin, the interactions formed by these amino acid residues would be highly specific to the binding with P450cam, consistent with very low cross-reactivity to other iron-sulfur proteins in the P450cam monooxygenation system.

Solution structure of reduced microsomal rat cytochrome b5

The solution structure of the major form of the reduced soluble fragment of rat microsomal cytochrome b5 has been solved through 1H-NMR spectroscopy. The protein contains 98 amino acids. Proton assignment was available for residues 1-94, except 90 [Guiles, R. D., Basus, V. J., Kuntz, I. D. & Waskell, L. (1992) Biochemistry 31, 11,365-11,375] and has been confirmed. From 1722 NOEs, of which 1203 were found to be meaningful, a family of 40 energy-minimized structures has been obtained with average backbone rmsd (for residues 5-89) of 0.078 +/- 0.018 nm and average target function of 0.0045 nm2, no distance violations being larger than 0.029 nm. The structure has been compared with the X-ray structure of the oxidized rat mitochondrial isoenzyme and with that of the highly similar bovine microsomal isoenzyme in the oxidized form. The analysis of the elements of secondary structure is instructive in terms of their stability and of their occurrence in related structures, and of the capability of NMR and X-ray spectroscopy to observe them. Some detailed structural variations are noticed among the solved structures of the various isoenzymes and between solid and solution. The structural features in solution of the residues proposed to be involved in protein-protein recognition are found to be largely conserved with respect to the solid state.

A molecular dynamics study of Fe2S2 putidaredoxin: multiple conformations of the C-terminal region

Putidaredoxin (Pdx) plays an essential role as an electron donor and effector in the biochemical cycle involving cytochrome P450cam. Only recently has an NMR-derived structure for this protein been published, but because of the presence of a paramagnetic Fe2S2 center, the NMR assignment could not be completed for residues within a region of 8 A around the active site. That region was modeled by homology with a related protein. The structural refinement for those experiments was done in vacuum, without the use of electrostatic terms in the force field. The present manuscript will describe and discuss a series of long-time, unrestrained, solution molecular dynamic runs for this system. Results will be presented that construct a molecular-level picture that rationalizes experimental results concerning the conformation and mobility of the C-terminal residue Trp106. At least two different conformers are found for this residue during the simulations. The time scale for interconversion between them is found to be in the subnanosecond regime. The results presented here open the possibility for studying binding and electron transfer between Pdx and P450cam, in a framework that allows for dynamical information to be used during the computational process, instead of the single structures deposited on the protein data base.

Redox signal transduction via iron-sulfur clusters in the SoxR transcription activator

Protein iron-sulfur (FeS) centers have recently been implicated in the regulation of gene expression. In the redox-sensing SoxR protein, the oxidation state of [2Fe-2S] centers controls its activity as a transcription activator independent of DNA-binding ability. Thus, FeS centers allosterically link cellular oxidative stress to the expression of defense genes.

Structural features of the metal binding site and dynamics of gallium putidaredoxin, a diamagnetic derivative of a Cys4Fe2S2 ferredoxin

The first reconstitution of an Fe2S2 ferredoxin with a diamagnetic prosthetic group was recently described [Kazanis et al. (1995) J. Am. Chem. Soc., 117, 6625-6626]. The replacement of the iron-sulfur cluster of the bacterial ferredoxin putidaredoxin (Pdx) by gallium (Ga3+) renders the protein diamagnetic and permits the use of high-resolution NMR methods to identify resonances near the metal binding site. We now describe structural features of the metal binding site that are not observable by standard NMR methods in native Pdx due to paramagnetic line broadening. These results provide the first example of high-resolution NMR-derived structural data concerning the metal binding domain of an Fe2S2 ferredoxin, and the first structural information of any sort for the metal binding site of a ferredoxin from this class, which includes adrenodoxin, placental ferredoxin and terpredoxin. Assignments were obtained by applying multidimensional NMR methods to a series of selectively and nonselectively 15N- and 13C/15N-labeled GaPdx samples. For most experiments, a mutant of Pdx was used in which a nonligating Cys85 is replaced by serine. All of the major structural features that were identified in native Pdx are conserved in GaPdx. The overall protein dynamics is considerably faster in GaPdx than in the native protein, as reflected by amide proton exchange rates. The C-terminal residue, Trp106, also exhibits considerable mobility, as indicated by 15N[1H] NOE and 15N T1 values of the C-terminal residue of the protein.

A structure-based model for cytochrome P450cam-putidaredoxin interactions

Putidaredoxin (Pdx) is a Fe2S2 ferredoxin which acts as the physiological reductant of cytochrome P-450cam (CYP101). A model for the solution structure of oxidized Pdx has been determined using NMR methods (Pochapsky et al (1994) Biochemistry 33, 6424-6432). 1H-15N correlations and redox-dependent amide exchange rates have also been described (Lyons et al (1996) Protein Sci 5, 627-639). Data obtained from mutagenesis and kinetic measurements concerning the interactions of Pdx and CYP101 are summarized. A model for the structure of the homologous ferredoxin adrenodoxin (Adx) is also described, and data concerning Adx activity are discussed in relation to this structure. The structures of Pdx and CYP101 were used as starting points for molecular modeling and molecular dynamics simulations. Close approach between the metal centers of the two proteins and interaction between aromatic residues on the surfaces of the proteins are premised. The resulting complex exhibits three intermolecular salt bridges, five intermolecular hydrogen bonds and a 12 A distance between the metal centers. The first direct observations of interaction between Pdx and CYP101 (by two-dimensional NMR of 15N-labeled Pdx in solution with CYP101) are described. The results of the NMR experiments indicate that conformational gating of the electron transfer complex between CYP101 and Pdx may be important.