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

Redox partner recognition and selectivity of cytochrome P450lin (CYP111A1)

The strict requirement of cytochrome P450cam for its native ferredoxin redox partner, putidaredoxin (Pdx), is not exhibited by any other known cytochrome P450 (CYP) system and the molecular details of redox partner selectivity are still not completely understood. We therefore examined the selectivity of a related Pseudomonas cytochrome P450, P450lin, by testing its activity with non-native redox partners. We found that P450lin could utilize Arx, the native redox partner of CYP101D1, to enable turnover of its substrate, linalool, while Pdx showed limited activity. Arx exhibited a higher sequence similarity to P450lins native redox partner, linredoxin (Ldx) than Pdx, including several residues that are believed to be at the interface of the two proteins, based on the P450cam-Pdx complex structure. We therefore mutated Pdx to resemble Ldx and Arx and found that a double mutant, D38L/∆106, displayed higher activity than Arx. In addition, Pdx D38L/∆106 does not induce a low-spin shift in linalool bound P450lin but does destabilize the P450lin-oxycomplex. Together our results suggest that P450lin and its redox partners may form a similar interface to P450cam-Pdx, but the interactions that allow for productive turnover are different.

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.

Molecular Dynamics Simulation for All

The impact of molecular dynamics (MD) simulations in molecular biology and drug discovery has expanded dramatically in recent years. These simulations capture the behavior of proteins and other biomolecules in full atomic detail and at very fine temporal resolution. Major improvements in simulation speed, accuracy, and accessibility, together with the proliferation of experimental structural data, have increased the appeal of biomolecular simulation to experimentalists-a trend particularly noticeable in, although certainly not limited to, neuroscience. Simulations have proven valuable in deciphering functional mechanisms of proteins and other biomolecules, in uncovering the structural basis for disease, and in the design and optimization of small molecules, peptides, and proteins. Here we describe, in practical terms, the types of information MD simulations can provide and the ways in which they typically motivate further experimental work.

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.

Spectroscopic studies of the cytochrome P450 reaction mechanisms

The cytochrome P450 monooxygenases (P450s) are thiolate heme proteins that can, often under physiological conditions, catalyze many distinct oxidative transformations on a wide variety of molecules, including relatively simple alkanes or fatty acids, as well as more complex compounds such as steroids and exogenous pollutants. They perform such impressive chemistry utilizing a sophisticated catalytic cycle that involves a series of consecutive chemical transformations of heme prosthetic group. Each of these steps provides a unique spectral signature that reflects changes in oxidation or spin states, deformation of the porphyrin ring or alteration of dioxygen moieties. For a long time, the focus of cytochrome P450 research was to understand the underlying reaction mechanism of each enzymatic step, with the biggest challenge being identification and characterization of the powerful oxidizing intermediates. Spectroscopic methods, such as electronic absorption (UV-Vis), electron paramagnetic resonance (EPR), nuclear magnetic resonance (NMR), electron nuclear double resonance (ENDOR), Mössbauer, X-ray absorption (XAS), and resonance Raman (rR), have been useful tools in providing multifaceted and detailed mechanistic insights into the biophysics and biochemistry of these fascinating enzymes. The combination of spectroscopic techniques with novel approaches, such as cryoreduction and Nanodisc technology, allowed for generation, trapping and characterizing long sought transient intermediates, a task that has been difficult to achieve using other methods. Results obtained from the UV-Vis, rR and EPR spectroscopies are the main focus of this review, while the remaining spectroscopic techniques are briefly summarized. This article is part of a Special Issue entitled: Cytochrome P450 biodiversity and biotechnology, edited by Erika Plettner, Gianfranco Gilardi, Luet Wong, Vlada Urlacher, Jared Goldstone.

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.

Modulation of the interaction between human P450 3A4 and B. megaterium reductase via engineered loops

Chimerogenesis involving cytochromes P450 is a successful approach to generate catalytically self-sufficient enzymes. However, the connection between the different functional modules should allow a certain degree of flexibility in order to obtain functional and catalytically efficient proteins. We previously applied the molecular Lego approach to develop a chimeric P450 3A4 enzyme linked to the reductase domain of P450 BM3 (BMR). Three constructs were designed with the connecting loop containing no glycine, 3 glycine or 5 glycine residues and showed a different catalytic activity and coupling efficiency. Here we investigate how the linker affects the ability of P450 3A4 to bind substrates and inhibitors. We measure the electron transfer rates and the catalytic properties of the enzyme also in the presence of ketoconazole as inhibitor. The data show that the construct 3A4-5GLY-BMR with the longest loop better retains the binding ability and cooperativity for testosterone, compared to P450 3A4. In both 3A4-3GLY-BMR and 3A4-5GLY-BMR, the substrate induces an increase in the first electron transfer rate and a shorter lag phase related to a domain rearrangements, when compared to the construct without Gly. These data are consistent with docking results and secondary structure predictions showing a propensity to form helical structures in the loop of the 3A4-BMR and 3A4-3GLY-BMR. All three chimeras retain the ability to bind the inhibitor ketoconazole and show an IC₅₀ comparable with those reported for the wild type protein. This article is part of a Special Issue entitled: Cytochrome P450 biodiversity and biotechnology, edited by Erika Plettner, Gianfranco Gilardi, Luet Wong, Vlada Urlacher, Jared Goldstone.

Recruitment and Regulation of the Non-ribosomal Peptide Synthetase Modifying Cytochrome P450 Involved in Nikkomycin Biosynthesis

The β-hydroxylation of l-histidine is the first step in the biosynthesis of the imidazolone base of the antifungal drug nikkomycin. The cytochrome P450 (NikQ) hydroxylates the amino acid while it is appended via a phosphopantetheine linker to the non-ribosomal peptide synthetase (NRPS) NikP1. The latter enzyme is comprised of an MbtH and single adenylation and thiolation domains, a minimal composition that allows for detailed binding and kinetics studies using an intact and homogeneous NRPS substrate. Electron paramagnetic resonance studies confirm that a stable complex is formed with NikQ and NikP1 when the amino acid is tethered. Size exclusion chromatography is used to further refine the principal components that are required for this interaction. NikQ binds NikP1 in the fully charged state, but binding also occurs when NikP1 is lacking both the phosphopantetheine arm and appended amino acid. This demonstrates that the interaction is mainly guided by presentation of the thiolation domain interface, rather than the attached amino acid. Electrochemistry and transient kinetics have been used to probe the influence of l-His-NikP1 binding on catalysis by NikQ. Unlike many P450s, the binding of substrate fails to induce significant changes on the redox potential and autoxidation properties of NikQ and slows down the binding of dioxygen to the ferrous enzyme to initiate catalysis. Collectively, these studies demonstrate a complex interplay between the NRPS maturation process and the recruitment and regulation of an auxiliary tailoring enzyme required for natural product biosynthesis.