Christopher R. Pudney

Biocatalysis with thermostable enzymes: Structure and properties of a thermophilic “ene”-reductase related to Old Yellow Enzyme

We report the crystal structure of a thermophilic “ene” reductase (TOYE) isolated from Thermoanaerobacter pseudethanolicus E39. The crystal structure reveals a tetrameric enzyme and an active site that is relatively large compared to most other structurally determined and related Old Yellow Enzymes. The enzyme adopts higher order oligomeric states (octamers and dodecamers) in solution, as revealed by sedimentation velocity and multiangle laser light scattering. Bead modelling indicates that the solution structure is consistent with the basic tetrameric structure observed in crystallographic studies and electron microscopy. TOYE is stable at high temperatures (Tm>70 °C) and shows increased resistance to denaturation in water‐miscible organic solvents compared to the mesophilic Old Yellow Enzyme family member, pentaerythritol tetranitrate reductase. TOYE has typical ene‐reductase properties of the Old Yellow Enzyme family. There is currently major interest in using Old Yellow Enzyme family members in the preparative biocatalysis of a number of activated alkenes. The increased stability of TOYE in organic solvents is advantageous for biotransformations in which water‐miscible organic solvents and biphasic reaction conditions are required to both deliver novel substrates and minimize product racemisation.

Evidence To Support the Hypothesis That Promoting Vibrations Enhance the Rate of an Enzyme Catalyzed H-Tunneling Reaction

In recent years there has been a shift away from transition state theory models for H-transfer reactions. Models that incorporate tunneling as the mechanism of H-transfer are now recognized as a better description of such reactions. Central to many models of H-tunneling is the notion that specific vibrational modes of the protein and/or substrate can increase the probability of a H-tunneling reaction, modes that are termed promoting vibrations. Thus far there has been limited evidence that promoting vibrations can increase the rate of H-transfer. In the present communication we examine the single hydride transfer from both NADPH and NADH to FMN in the reductive half-reaction of pentaerythritol tetranitrate reductase (PETNR). We find that there is a significant promoting vibration with NADPH but not with NADH and that the observed rate of hydride transfer is significantly (approximately 15x) faster with NADPH. We rule out differences in rate due to variation in driving force and the donor-acceptor distance, suggesting it is the promoting vibration with NADPH that is the origin of the increased observed rate. This study therefore provides direct evidence that promoting vibrations can lead to an increase in rate.

Barrier Compression Enhances an Enzymatic Hydrogen‐Transfer Reaction

Putting the squeeze on: Hydrostatic pressure causes a shortening of the charge-transfer bond in the binary complex of morphinone reductase and NADH(4) (see diagram). Molecular dynamics simulations suggest that pressure reduces the average reaction barrier width by restricting the conformational space available to the flavin mononucleotide and NADH within the active site. The apparent rate of catalysis increases with pressure.

Coupled Motions Direct Electrons along Human Microsomal P450 Chains

Directional electron transfer through biological redox chains can be achieved by coupling reaction chemistry to conformational changes in individual redox enzymes.

Parallel pathways and free-energy landscapes for enzymatic hydride transfer probed by hydrostatic pressure

Mutation of an active‐site residue in morphinone reductase leads to a conformationally rich landscape that enhances the rate of hydride transfer from NADH to FMN at standard pressure (1 bar). Increasing the pressure causes interconversion between different conformational substates in the mutant enzyme. While high pressure reduces the donor–acceptor distance in the wild‐type enzyme, increased conformational freedom “dampens” its effect in the mutant.

Gating mechanisms for biological electron transfer: Integrating structure with biophysics reveals the nature of redox control in cytochrome P450 reductase and copper-dependent nitrite reductase

Biological electron transfer is a fundamentally important reaction. Despite the apparent simplicity of these reactions (in that no bonds are made or broken), their experimental interrogation is often complicated because of adiabatic control exerted through associated chemical and conformational change. We have studied the nature of this control in several enzyme systems, cytochrome P450 reductase, methionine synthase reductase and copper‐dependent nitrite reductase. Specifically, we review the evidence for conformational control in cytochrome P450 reductase and methionine synthase reductase and chemical control i.e. proton coupled electron transfer in nitrite reductase. This evidence has accrued through the use and integration of structural, spectroscopic and advanced kinetic methods. This integrated approach is shown to be powerful in dissecting control mechanisms for biological electron transfer and will likely find widespread application in the study of related biological redox systems.

Structural and mechanistic aspects of flavoproteins: probes of hydrogen tunnelling

At least half of all enzyme‐catalysed reactions are thought to involve a hydrogen transfer. In the last 10 years, it has become apparent that many of these reactions will occur, in part, or in full, by quantum mechanical tunnelling. We are particularly interested in the role of promoting vibrations on H transfer, and the Old Yellow Enzyme family of flavoproteins has proven to be an excellent model system with which to examine such reactions. In this minireview, we describe new and established experimental methods used to study H‐tunnelling in these enzymes and we consider some practical issues important to such studies. The application of these methods has provided strong evidence linking protein dynamics and H‐tunnelling in biological systems.

Bipartite recognition and conformational sampling mechanisms for hydride transfer from nicotinamide coenzyme to FMN in pentaerythritol tetranitrate reductase.

Elucidating the origin of substrate and coenzyme specificity has been the focus of much work relating to enzyme engineering. Many enzymes exhibit tight specificity for particular substrates despite a close structural relationship to other nonreactive compounds. This tight specificity is especially remarkable and important biologically for the coenzymes NADH and NADPH. In the present study, we examined the preference of pentaerythritol tetranitrate reductase, an ‘old yellow enzyme’ family member, for the coenzymes NADPH over NADH. Using structural and mutagenesis studies, we have previously established that the coenzyme nicotinamide group is the key binding determinant in old yellow enzymes [ Khan H et al. (2005)FEBS J272, 4660–4671]. We have now performed detailed transient‐state studies using NAD(P)H and the nonreactive analogues 1,4,5,6‐tetrahydroNAD(P)H [NAD(P)H4], leading us to uncover an additional binding step in the reductive half‐reaction of pentaerythritol tetranitrate reductase. We suggest that this initial binding step may primarily reflect binding of the adenine ribophosphate portion of the coenzyme, and that the second step reflects a rearrangement of the nicotinamide. Bipartite recognition, in which the adenine ribophosphate moiety localizes the coenzyme in the active site region, enables subsequent and localized searches of configurational space by the nicotinamide moiety to form the catalytically relevant charge‐transfer complex. We suggest that this localized search contributes to catalytic efficiency via the principle of ‘reduction in dimensionality’.

Atomistic insight into the origin of the temperature-dependence of kinetic isotope effects and H-tunnelling in enzyme systems is revealed through combined experimental studies and biomolecular simulation

The physical basis of the catalytic power of enzymes remains contentious despite sustained and intensive research efforts. Knowledge of enzyme catalysis is predominantly descriptive, gained from traditional protein crystallography and solution studies. Our goal is to understand catalysis by developing a complete and quantitative picture of catalytic processes, incorporating dynamic aspects and the role of quantum tunnelling. Embracing ideas that we have spearheaded from our work on quantum mechanical tunnelling effects linked to protein dynamics for H-transfer reactions, we review our recent progress in mapping macroscopic kinetic descriptors to an atomistic understanding of dynamics linked to biological H-tunnelling reactions.

Enzymatic single-molecule kinetic isotope effects

Ensemble-based measurements of kinetic isotope effects (KIEs) have advanced physical understanding of enzyme-catalyzed reactions, but controversies remain. KIEs are used as reporters of rate-limiting H-transfer steps, quantum mechanical tunnelling, dynamics and multiple reactive states. Single molecule (SM) enzymatic KIEs could provide new information on the physical basis of enzyme catalysis. Here, single pair fluorescence energy transfer (spFRET) was used to measure SM enzymatic KIEs on the H-transfer catalyzed by the enzyme pentaerythritol tetranitrate reductase. We evaluated a range of methods for extracting the SM KIE from single molecule spFRET time traces. The SM KIE enabled separation of contributions from nonenzymatic protein and fluorophore processes and H-transfer reactions. Our work demonstrates SM KIE analysis as a new method for deconvolving reaction chemistry from intrinsic dynamics.