The conformation of P450cam in complex with putidaredoxin is dependent on oxidation state

3site Multisubstrate-Bound State of Cytochrome P450cam

We identified a multisubstrate-bound state, hereby referred as a 3site state, in cytochrome P450cam via integrating molecular dynamics simulation with nuclear magnetic resonance (NMR) pseudocontact shift measurements. The 3site state is a result of simultaneous binding of three camphor molecules in three locations around P450cam: (a) in a well-established "catalytic" site near heme, (b) in a kink-separated "waiting" site along channel-1, and (c) in a previously reported "allosteric" site at E, F, G, and H helical junctions. These three spatially distinct binding modes in the 3site state mutually communicate with each other via homotropic allostery and act cooperatively to render P450cam functional. The 3site state shows a significantly superior fit with NMR pseudo contact shift (PCS) data with a Q-score of 0.045 than previously known bound states and consists of D251 free of salt-bridges with K178 and R186, rendering the enzyme functionally primed. To date, none of the reported cocomplex of P450cam with its redox partner putidaredoxin (pdx) has been able to match solution NMR data and controversial pdx-induced opening of P450cam's channel-1 remains a matter of recurrent discourse. In this regard, inclusion of pdx to the 3site state is able to perfectly fit the NMR PCS measurement with a Q-score of 0.08 and disfavors the pdx-induced opening of channel-1, reconciling previously unexplained remarkably fast hydroxylation kinetics with a koff of 10.2 s-1. Together, our findings hint that previous experimental observations may have inadvertently captured the 3site state as an in vitro solution state, instead of the catalytic state alone, and provided a distinct departure from the conventional understanding of cytochrome P450.

Updating the Paradigm: Redox Partner Binding and Conformational Dynamics in Cytochromes P450

This Account summarizes recent findings centered on the role that redox partner binding, allostery, and conformational dynamics plays in cytochrome P450 proton coupled electron transfer. P450s are one of Nature's largest enzyme families and it is not uncommon to find a P450 wherever substrate oxidation is required in the formation of essential molecules critical to the life of the organism or in xenobiotic detoxification. P450s can operate on a remarkably large range of substrates from the very small to the very large, yet the overall P450 three-dimensional structure is conserved. Given this conservation of structure, it is generally assumed that the basic catalytic mechanism is conserved. In nearly all P450s, the O₂ O-O bond must be cleaved heterolytically enabling one oxygen atom, the distal oxygen, to depart as water and leave behind a heme iron-linked O atom as the powerful oxidant that is used to activate the nearby substrate. For this process to proceed efficiently, externally supplied electrons and protons are required. Two protons must be added to the departing O atom while an electron is transferred from a redox partner that typically contains either a Fe₂S₂ or FMN redox center. The paradigm P450 used to unravel the details of these mechanisms has been the bacterial CYP101A1 or P450cam. P450cam is specific for its own Fe₂S₂ redox partner, putidaredoxin or Pdx, and it has long been postulated that Pdx plays an effector/allosteric role by possibly switching P450cam to an active conformation. Crystal structures, spectroscopic data, and direct binding experiments of the P450cam-Pdx complex provide some answers. Pdx shifts the conformation of P450cam to a more open state, a transition that is postulated to trigger the proton relay network required for O₂ activation. An essential part of this proton relay network is a highly conserved Asp (sometimes Glu) that is known to be critical for activity in a number of P450s. How this Asp and proton delivery networks are connected to redox partner binding is quite simple. In the closed state, this Asp is tied down by salt bridges, but these salt bridges are ruptured when Pdx binds, leaving the Asp free to serve its role in proton transfer. An alternative hypothesis suggests that a specific proton relay network is not really necessary. In this scenario, the Asp plays a structural role in the open/close transition and merely opening the active site access channel is sufficient to enable solvent protons in for O₂ protonation. Experiments designed to test these various hypotheses have revealed some surprises in both P450cam and other bacterial P450s. Molecular dynamics and crystallography show that P450cam can undergo rather significant conformational gymnastics that result in a large restructuring of the active site requiring multiple cis/trans proline isomerizations. It also has been found that X-ray driven substrate hydroxylation is a useful tool for better understanding the role that the essential Asp and surrounding residues play in catalysis. Here we summarize these recent results which provide a much more dynamic picture of P450 catalysis.

Partial Opening of Cytochrome P450cam (CYP101A1) Is Driven by Allostery and Putidaredoxin Binding

Cytochrome P450cam (CYP101A1) catalyzes the regio- and stereo-specific 5-exo-hydroxylation of camphor via a multistep catalytic cycle that involves two-electron transfer steps, with an absolute requirement that the second electron be donated by the ferrodoxin, putidaredoxin (Pdx). Whether P450cam, once camphor has bound to the active site and the substrate entry channel has closed, opens up upon Pdx binding, during the second electron transfer step, or it remains closed is still a matter of debate. A potential allosteric site for camphor binding has been identified and postulated to play a role in the binding of Pdx. Here, we have revisited paramagnetic NMR spectroscopy data and determined a heterogeneous ensemble of structures that explains the data, provides a complete representation of the P450cam/Pdx complex in solution, and reconciles alternative hypotheses. The allosteric camphor binding site is always present, and the conformational changes induced by camphor binding to this site facilitates Pdx binding. We also determined that the state to which Pdx binds comprises an ensemble of structures that have features of both the open and closed state. These results demonstrate that there is a finely balanced interaction between allosteric camphor binding and the binding of Pdx at high camphor concentrations.

Development of MEMS directed evolution strategy for multiplied throughput and convergent evolution of cytochrome P450 enzymes

Directed evolution (DE) inspired by natural evolution (NE) has been achieving tremendous successes in protein/enzyme engineering. However, the conventional "one-protein-for-one-task" DE cannot match the "multi-proteins-for-multi-tasks" NE in terms of screening throughput and efficiency, thus often failing to meet the fast-growing demands for biocatalysts with desired properties. In this study, we design a novel "multi-enzymes-for-multi-substrates" (MEMS) DE model and establish the proof-of-concept by running a NE-mimicking and higher-throughput screening on the basis of "two-P450s-against-seven-substrates" (2P×7S) in one pot. With the multiplied throughput and improved hit rate, we witness a series of convergent evolution events of the two archetypal cytochrome P450 enzymes (P450 BM3 and P450cam) in laboratory. It is anticipated that the new strategy of MEMS DE will find broader application for a larger repertoire of enzymes in the future. Furthermore, structural and substrate docking analysis of the two functionally convergent P450 variants provide important insights into how distinct P450 active-sites can reach a common catalytic goal.

Dynamics underlying hydroxylation selectivity of cytochrome P450cam

Structural heterogeneity and the dynamics of the complexes of enzymes with substrates can determine the selectivity of catalysis; however, fully characterizing how remains challenging as heterogeneity and dynamics can vary at the spatial level of an amino acid residue and involve rapid timescales. We demonstrate the nascent approach of site-specific two-dimensional infrared (IR) spectroscopy to investigate the archetypical cytochrome P450, P450cam, to better delineate the mechanism of the lower regioselectivity of hydroxylation of the substrate norcamphor in comparison to the native substrate camphor. Specific locations are targeted throughout the enzyme by selectively introducing cyano groups that have frequencies in a spectrally isolated region of the protein IR spectrum as local vibrational probes. Linear and two-dimensional IR spectroscopy were applied to measure the heterogeneity and dynamics at each probe and investigate how they differentiate camphor and norcamphor recognition. The IR data indicate that the norcamphor complex does not fully induce a large-scale conformational change to a closed state of the enzyme adopted in the camphor complex. Additionally, a probe directed at the bound substrate experiences rapidly interconverting states in the norcamphor complex that explain the hydroxylation product distribution. Altogether, the study reveals large- and small-scale structural heterogeneity and dynamics that could contribute to selectivity of a cytochrome P450 and illustrates the approach of site-selective IR spectroscopy to elucidate protein dynamics.

Linkage between Proximal and Distal Movements of P450cam Induced by Putidaredoxin

Putidaredoxin (Pdx) is the exclusive reductase and a structural effector for P450cam (CYP101A1). However, the mechanism of how Pdx modulates the conformational states of P450cam remains elusive. Here we report a putative communication pathway for the Pdx-induced conformational change in P450cam using results of double electron-electron resonance (DEER) spectroscopy and molecular dynamics simulations. Use of solution state DEER measurements allows us to observe subtle conformational changes in the internal helices in P450cam among closed, open, and P450cam-Pdx complex states. Molecular dynamics simulations and dynamic network analysis suggest that Pdx binding is coupled to small coordinated movements of several regions of P450cam, including helices C, B', I, G, and F. These changes provide a linkage between the Pdx binding site on the proximal side of the enzyme and helices F/G on the distal side and the site of the largest movement resulting from the Pdx-induced closed-to-open transition. This study provides a detailed rationale for how Pdx exerts its long-recognized effector function at the active site from its binding site on the opposite face of the enzyme.

Proton relay network in P450cam formed upon docking of putidaredoxin

Cytochromes P450 are versatile heme-based enzymes responsible for vital life processes. Of these, P450cam (substrate camphor) has been most studied. Despite this, precise mechanisms of the key O─O cleavage step remain partly elusive to date; effects observed in various enzyme mutants remain partly unexplained. We have carried out extended (to 1000 ns) MM-MD and follow-on quantum mechanics/molecular mechanics computations, both on the well-studied FeOO state and on Cpd(0) (compound 0). Our simulations include (all camphor-bound): (a) WT (wild type), FeOO state. (b) WT, Cpd(0). (c) Pdx (Putidaredoxin, redox partner of P450)-docked-WT, FeOO state. (d) Pdx-docked WT, Cpd(0). (e) Pdx-docked T252A mutant, Cpd(0). Among our key findings: (a) Effect of Pdx docking appears to go far beyond that indicated in prior studies: it leads to specific alterations in secondary structure that create the crucial proton relay network. (b) Specific proton relay networks we identify are: FeOO(H)⋯T252⋯nH ₂ O⋯D251 in WT; FeOO(H)⋯nH ₂ O⋯D251 in T252A mutant; both occur with Pdx docking. (c) Direct interaction of D251 with -FeOOH is, respectively, rare/frequent in WT/T252A mutant. (d) In WT, T252 is in the proton relay network. (e) Positioning of camphor appears significant: when camphor is part of H-bonding network, second protonation appears to be facilitated.

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.

An Intermediate Conformational State of Cytochrome P450cam-CN in Complex with Putidaredoxin

Cytochrome P450cam is an archetypal example of the vast family of heme monooxygenases and serves as a model for an enzyme that is highly specific for both its substrate and reductase. During catalysis, it undergoes significant conformational changes of the F and G helices upon binding its substrate and redox partner, putidaredoxin (Pdx). Recent studies have shown that Pdx binding to the closed camphor-bound form of ferric P450cam results in its conversion to a fully open state. However, during catalytic turnover, it remains unclear whether this same conformational change also occurs or whether it is coupled to the formation of the critical compound I intermediate. Here, we have examined P450cam bound simultaneously by camphor, CN^-, and Pdx as a mimic of the catalytically competent ferrous oxy-P450cam-Pdx state. The combined use of double electron-electron resonance and molecular dynamics showed direct observation of intermediate conformational states of the enzyme upon CN^- and subsequent Pdx binding. This state is coupled to the movement of the I helix and residues at the active site, including Arg-186, Asp-251, and Thr-252. These movements enable occupation of a water molecule that has been implicated in proton delivery and peroxy bond cleavage to give compound I. These findings provide a detailed understanding of how the Pdx-induced conformational change may sequentially promote compound I formation followed by product release, while retaining stereoselective hydroxylation of the substrate of this highly specific monooxygenase.

Ligand and Redox Partner Binding Generates a New Conformational State in Cytochrome P450cam (CYP101A1)

It has become increasingly clear that cytochromes P450 can cycle back and forth between two extreme conformational states termed the closed and open states. In the well-studied cytochrome P450cam, the binding of its redox partner, putidaredoxin (Pdx), shifts P450cam toward the open state. Shifting to the open state is thought to be important in the formation of a proton relay network essential for O-O bond cleavage and formation of the active Fe(IV)═O intermediate. Another important intermediate is the oxy-P450cam complex when bound to Pdx. Trapping this intermediate in crystallo is challenging owing to its instability, but the CN^- complex is both stable and an excellent mimic of the O₂ complex. Here we present the P450cam-Pdx structure complexed with CN^-. CN^- results in large conformational changes including cis/trans isomerization of proline residues. Changes include large rearrangements of active-site residues and the formation of new active-site access channel that we have termed channel 2. The formation of channel 2 has also been observed in our previous molecular dynamics simulations wherein substrate binding to an allosteric site remote from the active site opens up channel 2. This new structure supports an extensive amount of previous work showing that distant regions of the structure are dynamically coupled and underscores the potentially important role that large conformational changes and dynamics play in P450 catalysis.

Mapping the Substrate Recognition Pathway in Cytochrome P450

Cytochrome P450s are ubiquitous metalloenzymes involved in the metabolism and detoxification of foreign components via catalysis of the hydroxylation reactions of a vast array of organic substrates. However, the mechanism underlying the pharmaceutically critical process of substrate access to the catalytic center of cytochrome P450 is a long-standing puzzle, further complicated by the crystallographic evidence of a closed catalytic center in both substrate-free and substrate-bound cytochrome P450. Here, we address a crucial question whether the conformational heterogeneity prevalent in cytochrome P450 translates to heterogeneous pathways for substrate access to the catalytic center of these metalloenzymes. By atomistically capturing the full process of spontaneous substrate association from bulk solvent to the occluded catalytic center of an archetypal system P450cam in multi-microsecond-long continuous unbiased molecular dynamics simulations, we here demonstrate that the substrate recognition in P450cam always occurs through a single well-defined dominant pathway. The simulated final bound pose resulting from these unguided simulations is in striking resemblance with the crystallographic bound pose. Each individual binding trajectory reveals that the substrate, initially placed at random locations in bulk solvent, spontaneously lands on a single key channel on the protein-surface of P450cam and resides there for an uncharacteristically long period, before correctly identifying the occluded target-binding cavity. Surprisingly, the passage of substrate to the closed catalytic center is not accompanied by any large-scale opening in protein. Rather, the unbiased simulated trajectories (∼57 μs) and underlying Markov state model, in combination with free-energy analysis, unequivocally show that the substrate recognition process in P450cam needs a substrate-induced side-chain displacement coupled with a complex array of dynamical interconversions of multiple metastable substrate conformations. Further, the work reconciles multiple precedent experimental and theoretical observations on P450cam and establishes a comprehensive view of substrate-recognition in cytochrome P450 that only occurs via substrate-induced structural rearrangements.

Mechanisms of Cytochrome P450-Catalyzed Oxidations

Enzymes are complex biological catalysts and are critical to life. Most oxidations of chemicals are catalyzed by cytochrome P450 (P450, CYP) enzymes, which generally utilize mixed-function oxidase stoichiometry, utilizing pyridine nucleotides as electron donors: NAD(P)H + O₂ + R → NAD(P)⁺ + RO + H₂O (where R is a carbon substrate and RO is an oxidized product). The catalysis of oxidations is largely understood in the context of the heme iron-oxygen complex generally referred to as Compound I, formally FeO³⁺, whose basis was in peroxidase chemistry. Many X-ray crystal structures of P450s are now available (≥ 822 structures from ≥146 different P450s) and have helped in understanding catalytic specificity. In addition to hydroxylations, P450s catalyze more complex oxidations, including C-C bond formation and cleavage. Enzymes derived from P450s by directed evolution can even catalyze more unusual reactions, e.g. cyclopropanation. Current P450 questions under investigation include the potential role of the intermediate Compound 0 (formally Fe^III-O₂ ^-) in catalysis of some reactions, the roles of high- and low-spin forms of Compound I, the mechanism of desaturation, the roles of open and closed structures of P450s in catalysis, the extent of processivity in multi-step oxidations, and the role of the accessory protein cytochrome b ₅. More global questions include exactly how structure drives function, prediction of catalysis, and roles of multiple protein conformations.

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.

Conformational Changes in Cytochrome P450cam and the Effector Role of Putidaredoxin

The cytochromes P450 form an enormous family of over 20 000 enzyme variants found in all branches of life. They catalyze the O2 dependent monooxygenation of a wide range of substrates in reactions important to drug metabolism, biosynthesis and energy utilization. Understanding how they function is important for biomedical science and requires a full description of their notorious propensity for specificity and promiscuity. The bacterial P450cam is an unusual example, having the most well characterized chemical mechanism of all of the forms. It also undergoes an increasingly well characterized structural change upon substrate binding, which may be similar to to that displayed by some, but not all forms of P450. Finally, P450cam is one of the rare forms that have a strict requirement for a particular electron donor, putidaredoxin (pdx). Pdx provides the required electrons for enzyme turnover, but it also induces specific changes in the enzyme to allow enzyme turnover, long known as its effector role. This review summarizes recent crystallographic and double electron–electron resonance studies that have revealed the effects of substrate and pdx binding on the structure of P450cam. We describe an emerging idea for how pdx exerts its effector function by inducing a conformational change in the enzyme. This change then propagates to the active site to enable cleavage of the ferric–hydroperoxy bond during catalysis, and appears to provide a very elegant approach for P450cam to attain both high efficiency and protection from oxidative damage.

Effect of redox partner binding on CYP101D1 conformational dynamics

We have compared the thermodynamics of substrate and redox partner binding of P450cam to its close homologue, CYP101D1, using isothermal titration calorimetry (ITC). CYP101D1 binds camphor about 10-fold more weakly than P450cam which is consistent with the inability of camphor to cause a complete low- to high-spin shift in CYP101D1. Even so molecular dynamics simulations show that camphor is very stable in the CYP101D1 active site similar to P450cam. ITC data on the binding of the CYP101D1 ferredoxin redox partner (abbreviated Arx) shows that the substrate-bound closed state of CYP101D1 binds Arx more tightly than the substrate-free open form. This is just the opposite to P450cam where Pdx (ferredoxin redox partner of P450cam) favors binding to the P450cam open state. In addition, CYP101D1-Arx binding has a large negative ΔS while the P450cam-Pdx has a much smaller ΔS indicating that interactions at the docking interface are different. The most obvious difference is that PDXD38 which forms an important ion pair with P450camR112 at the center of the interface is ArxL39 in Arx. This suggests that Arx may adopt a different orientation than Pdx in order to optimize nonpolar interactions with ArxL39.

Use of Phenoxyaniline Analogues To Generate Biochemical Insights into the Interactio n of Polybrominated Diphenyl Ether with CYP2B Enzymes

Human hepatic cytochromes P450 (CYP) are integral to xenobiotic metabolism. CYP2B6 is a major catalyst of biotransformation of environmental toxicants, including polybrominated diphenyl ethers (PBDEs). CYP2B substrates tend to contain halogen atoms, but the biochemical basis for this selectivity and for species specific determinants of metabolism has not been identified. Spectral binding titrations and inhibition studies were performed to investigate interactions of rat CYP2B1, rabbit CYP2B4, and CYP2B6 with a series of phenoxyaniline (POA) congeners that are analogues of PBDEs. For most congeners, there was a <3-fold difference between the spectral binding constants (K_S) and IC₅₀ values. In contrast, large discrepancies between these values were observed for POA and 3-chloro-4-phenoxyaniline. CYP2B1 was the enzyme most sensitive to POA congeners, so the Val-363 residue from that enzyme was introduced into CYP2B4 or CYP2B6. This substitution partially altered the protein-ligand interaction profiles to make them more similar to that of CYP2B1. Addition of cytochrome P450 oxidoreductase (POR) to titrations of CYP2B6 with POA or 2'4'5'TCPOA decreased the affinity of both ligands for the enzyme. Addition of cytochrome b₅ to a recombinant enzyme system containing POR and CYP2B6 increased the POA IC₅₀ value and decreased the 2'4'5'TCPOA IC₅₀ value. Overall, the inconsistency between K_S and IC₅₀ values for POA versus 2'4'5'TCPOA is largely due to the effects of redox partner binding. These results provide insight into the biochemical basis of binding of diphenyl ethers to human CYP2B6 and changes in CYP2B6-mediated metabolism that are dependent on POA congener and redox partner identity.

Effect of Redox Partner Binding on Cytochrome P450 Conformational Dynamics

Previous crystal structures of cytochrome P450cam complexed with its redox partner, putidaredoxin (Pdx), shows that P450cam adopts the open conformation. It has been hypothesized that the Pdx-induced shift toward the open state frees the essential Asp251 from salt bridges with Arg186 and Lys178 so that Asp251 can participate in a proton relay network required for O₂ activation. This in part explains why P450cam has such a strict requirement for Pdx. One problem with this view is that looser substrate-protein interactions in the open state may not be compatible with the observed regio- and stereoselective hydroxylation. In the present study, molecular dynamics simulations show that Pdx binding favors a conformation that stabilizes the active site and decreases camphor mobility yet retains a partially open conformation compatible with the required proton relay network. The R186A mutant which frees Asp251 in the absence of Pdx retains good enzyme activity, and the crystal structure shows that product, 5-exo-hydroxycamphor, is bound. This indicates that rupture of the Asp251-Arg186 relaxes selectivity with respect to source of electrons and enables X-ray generated reducing equivalents to support substrate hydroxylation. These combined computational and experimental results are consistent with the proposed role of Pdx in assisting the release of Asp251 from ion pairs so that it can participate in proton-coupled electron transfer.

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.

A Comparative Analysis of the Effector Role of Redox Partner Binding in Bacterial P450s

The camphor monooxygenase, cytochrome P450cam, exhibits a strict requirement for its own redox partner, putidaredoxin (Pdx), a two-iron-sulfur ferredoxin. The closest homologue to P450cam, CYP101D1, is structurally very similar, uses a similar redox partner, and exhibits nearly identical enzymatic properties in the monooxygenation of camphor to give the same single 5-exo-hydroxy camphor product. However, CYP101D1 does not strictly require its own ferredoxin (Arx) for activity because Pdx can support CYP101D1 catalysis but Arx cannot support P450cam catalysis. We have further examined the differences between these two P450s by determining the effect of spin equilibrium, redox properties, and stability of oxygen complexes. We find that Arx shifts the spin state equilibrium toward high-spin, which is the opposite of the effect of Pdx on P450cam. In both P450s, redox partner binding destabilizes the oxy-P450 complex but this effect is much weaker with CYP101D1. In addition, resonance Raman data show that structural perturbations observed in P450cam upon addition of Pdx are absent in CYP101D1. These data indicate that Arx does not play the same effector role in catalysis as Pdx does with P450cam. The most relevant structural difference between these two P450s centers on a catalytically important Asp residue required for proton-coupled electron transfer. We postulate that with P450cam larger Pdx-assisted motions are required to free this Asp for catalysis while the smaller number of restrictions in CYP101D1 precludes the need for redox partner-assisted structural changes.

Effector Roles of Putidaredoxin on Cytochrome P450cam Conformational States

In this study, the effector role of Pdx (putidaredoxin) on cytochrome P450cam conformation is refined by attaching two different spin labels, MTSL or BSL (bifunctional spin-label) onto the F or G helices and using DEER (double electron-electron resonance) to measure the distance between labels. Recent EPR and crystallographic studies have observed that oxidized Pdx induces substrate-bound P450cam to change from the closed to the open state. However, this change was not observed by DEER in the reduced Pdx complex with carbon-monoxide-bound P450cam (Fe(2+)CO). In addition, recent NMR studies have failed to observe a change in P450cam conformation upon binding Pdx. Hence, resolving these issues is important for a full understanding the effector role of Pdx. Here we show that oxidized Pdx induces camphor-bound P450cam to shift from the closed to the open conformation when labeled on either the F or G helices with MTSL. BSL at these sites can either narrow the distance distribution widths dramatically or alter the extent of the conformational change. In addition, we report DEER spectra on a mixed oxidation state containing oxidized Pdx and ferrous CO-bound P450cam, showing that P450cam remains closed. This indicates that CO binding to the heme prevents P450cam from opening, overriding the influence exerted by Pdx binding. Finally, we report the open form P450cam crystal structure with substrate bound, which suggests that crystal packing effects may prevent conformational conversion. Using multiple labeling approaches, DEER provides a unique perspective to resolve how the conformation of P450cam depends on Pdx and ligand states.

Conformational selectivity in cytochrome P450 redox partner interactions

The heme iron of cytochromes P450 must be reduced to bind and activate molecular oxygen for substrate oxidation. Reducing equivalents are derived from a redox partner, which requires the formation of a protein-protein complex. A subject of increasing discussion is the role that redox partner binding plays, if any, in favoring significant structural changes in the P450s that are required for activity. Many P450s now have been shown to experience large open and closed motions. Several structural and spectral studies indicate that the well-studied P450cam adopts the open conformation when its redox partner, putidaredoxin (Pdx), binds, whereas recent NMR studies indicate that this view is incorrect. Given the relevance of this discrepancy to P450 chemistry, it is important to determine whether Pdx favors the open or closed form of P450cam. Here, we have used both computational and experimental isothermal titration calorimetry studies that unequivocally show Pdx favors binding to the open form of P450cam. Analyses of molecular-dynamic trajectories also provide insights into intermediate conformational states that could be relevant to catalysis.

Delicate conformational balance of the redox enzyme cytochrome P450cam

The energy landscapes of proteins are highly complex and can be influenced by changes in physical and chemical conditions under which the protein is studied. The redox enzyme cytochrome P450cam undergoes a multistep catalytic cycle wherein two electrons are transferred to the heme group and the enzyme visits several conformational states. Using paramagnetic NMR spectroscopy with a lanthanoid tag, we show that the enzyme bound to its redox partner, putidaredoxin, is in a closed state at ambient temperature in solution. This result contrasts with recent crystal structures of the complex, which suggest that the enzyme opens up when bound to its partner. The closed state supports a model of catalysis in which the substrate is locked in the active site pocket and the enzyme acts as an insulator for the reactive intermediates of the reaction.

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 Fe2 S2 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.

Diiron oxidation state control of substrate access to the active site of soluble methane monooxygenase mediated by the regulatory component

The regulatory component (MMOB) of soluble methane monooxygenase (sMMO) has a unique N-terminal tail not found in regulatory proteins of other bacterial multicomponent monooxygenases. This N-terminal tail is indispensable for proper function, yet its solution structure and role in catalysis remain elusive. Here, by using double electron–electron resonance (DEER) spectroscopy, we show that the oxidation state of the hydroxylase component, MMOH, modulates the conformation of the N-terminal tail in the MMOH–2MMOB complex, which in turn facilitates catalysis. The results reveal that the N-terminal tail switches from a relaxed, flexible conformational state to an ordered state upon MMOH reduction from the diiron(III) to the diiron(II) state. This observation suggests that some of the crystallographically observed allosteric effects that result in the connection of substrate ingress cavities in the MMOH–2MMOB complex may not occur in solution in the diiron(III) state. Thus, O₂ may not have easy access to the active site until after reduction of the diiron center. The observed conformational change is also consistent with a higher binding affinity of MMOB to MMOH in the diiron(II) state, which may allow MMOB to displace more readily the reductase component (MMOR) from MMOH following reduction.