Small Temperature Dependence of the Kinetic Isotope Effect for the Hydride Transfer Reaction Catalyzed by Escherichia coli Dihydrofolate Reductase

Pu, Jingzhi; Ma, Shuhua; Gao, Jiali; Truhlar, Donald G.

doi:10.1021/jp051184c

Cited by 115 publications

(223 citation statements)

References 49 publications

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“…For example, Neria and Karplus (32) used transmission coefficient calculations and constrained molecular dynamics (MD) trajectories to determine that the protein environment in triosephosphate isomerase (TIM) is essentially rigid (i.e., dynamically unresponsive) on the timescale of the intrinsic reaction dynamics; this finding is consistent with the lack of longlengthscale dynamical correlations reported in the current study. Furthermore, Truhlar and coworkers (33,34) and Karplus and Cui (35) both demonstrated that quasi-classical tunneling coefficients for hydrogen transfer evaluated at instantaneous enzyme configurations in the transition state region fluctuate significantly with donor-acceptor motions and other local active-site vibrations, which is likely consistent with the direct observation of short-lengthscale dynamical correlations reported here. However, by using quantized molecular dynamics to sample the ensemble of reactive trajectories in DHFR catalysis and to perform nonequilibrium ensemble averages that directly probe dynamical correlation, we provide a framework for strengthening and generalizing these earlier analyses.…”

Section: Resultssupporting

confidence: 84%

Dynamics and dissipation in enzyme catalysis

Boekelheide

Salomón-Ferrer²,

Miller³

2011

Proc. Natl. Acad. Sci. U.S.A.

150

160

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We use quantized molecular dynamics simulations to characterize the role of enzyme vibrations in facilitating dihydrofolate reductase hydride transfer. By sampling the full ensemble of reactive trajectories, we are able to quantify and distinguish between statistical and dynamical correlations in the enzyme motion. We demonstrate the existence of nonequilibrium dynamical coupling between protein residues and the hydride tunneling reaction, and we characterize the spatial and temporal extent of these dynamical effects. Unlike statistical correlations, which give rise to nanometer-scale coupling between distal protein residues and the intrinsic reaction, dynamical correlations vanish at distances beyond 4-6 Å from the transferring hydride. This work finds a minimal role for nonlocal vibrational dynamics in enzyme catalysis, and it supports a model in which nanometer-scale protein fluctuations statistically modulate-or gate-the barrier for the intrinsic reaction.enzyme dynamics | hydrogen tunneling | path integral | ring polymer molecular dynamics P rotein motions are central to enzyme catalysis, with conformational changes on the micro-and millisecond timescale wellestablished to govern progress along the catalytic cycle (1, 2). Less is known about the role of faster, atomic-scale fluctuations that occur in the protein environment of the active site. The textbook view of enzyme-catalyzed reaction mechanisms neglects the functional role of such fluctuations and describes a static protein environment that both scaffolds the active-site region and reduces the reaction barrier (3). This view has grown controversial amid evidence that active-site chemistry is coupled to motions in the enzyme (4-6), and it has been explicitly challenged by recent proposals that enzyme-catalyzed reactions are driven by vibrational excitations that channel energy into the intrinsic reaction coordinate (7,8) or promote reactive tunneling (9, 10). In the following, we combine quantized molecular dynamics and rareevent sampling methods to determine the mechanism by which protein motions couple to reactive tunneling in dihydrofolate reductase and to clarify the role of nonequilibrium vibrational dynamics in enzyme catalysis.Manifestations of enzyme motion include both statistical and dynamical correlations. Statistical correlations are properties of the equilibrium ensemble and describe, for example, the degree to which fluctuations in the spatial position of one atom are influenced by fluctuations in another; these correlations govern the free-energy (FE) landscape and determine the transition state theory kinetics of the system (6). Dynamical correlations are properties of the time-evolution of the system and describe coupling between inertial atomic motions, as in a collective vibrational mode. Compelling evidence for long-ranged (i.e., nanometer-scale) networks of statistical correlations in enzymes emerges from genomic analysis (11), molecular dynamics simulations (11-13), and kinetic studies of double-mutant enzymes (14-16). But the rol...

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Section: Resultssupporting

confidence: 84%

Dynamics and dissipation in enzyme catalysis

Boekelheide

Salomón-Ferrer²,

Miller³

2011

Proc. Natl. Acad. Sci. U.S.A.

150

160

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“…While studying ecDHFR for example, Garcia-Viloca et al (7) predicted a 2° KIE (which is a sensitive probe of the reaction's potential surface and was later confirmed experimentally (31)); Pu et al (8) could reproduce the trends of temperature dependence for 1° KIEs, and Agarwal et al (28) could reproduce and predict several experimental data. All these studies could address the role of protein motion and other mechanistic features that are not directly accessible by experimental studies.…”

Section: "Marcus Like" Models (Environmentally Coupled Tunneling)mentioning

confidence: 94%

“…Furthermore the essential role of DHFR in DNA synthesis and in a variety of anabolic pathways makes it a common target for antiproliferative therapeutics. Due to its biological and pharmacological importance, and it being a small monomeric enzyme, DHFR has been the subject of intensive structural and kinetic investigation over many years, serving as a paradigm of enzymatic systems in many experimental and theoretical studies (1)(2)(3)(4)(5)(6)(7)(8). † This work was supported by NIH R01 GM65368-01 and NSF CHE-0133117 to A.K.…”

Section: Introductionmentioning

confidence: 99%

Effects of a Distal Mutation on Active Site Chemistry

et al. 2006

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Previous studies of E. coli dihydrofolate reductase (ecDHFR) have demonstrated that residue G121, which is 19Å away from the catalytic center, is involved in catalysis and long distance dynamical motions were implied. Specifically, the ecDHFR mutant G121V has been extensively studied by various experimental and theoretical tools, and the mutation's effect on kinetic, structural, and dynamical features of the enzyme explored. The current work examined the effect of this mutation on the physical nature of the catalyzed hydride transfer step by means of intrinsic kinetic isotope effects (KIEs), their temperature dependence and activation parameters as described before for the wild type ecDHFR (Sikorski et al. 2004, J. Am. Chem. Soc., 126, 4778-4779). The temperature dependence of initial velocities was used to estimate activation parameters. Isotope effects on the preexponential Arrhenius factors, and the activation energy could be rationalized by an environmentally coupled hydrogen tunneling model, similar to the one used for the wild type enzyme. Yet, in contrast to the wild type, fluctuations of the donor-acceptor distance were now required. Secondary (2°) KIEs were also measured for both H and D transfer and, as in the case of the wild type enzyme, no coupled motion was detected. Despite these similarities, the reduced rates, the slightly inflated 1° KIEs and their temperature dependence, together with relatively deflated 2° KIEs, indicate that the potential surface prearrangement was not as ideal as for the wild type enzyme. These findings support theoretical studies suggesting that the G121V mutation lead to a different conformational ensemble of reactive states and less effective rearrangement of the potential surface, but has only small effect on H-tunneling.Dihydrofolate reductase from Escherichia coli (ecDHFR) is a small monomeric enzyme (18 kDa) that consists of eight-stranded β-sheet and four α-helices connected with several loop regions. It catalyzes the reduction of 7,8-dihydrofolate (DHF) to 5,6,7, with the concomitant oxidation of NADPH (nicotinamide adenine dinucleotide phosphate, reduced form) to NADP + , in which a hydride is stereospecifically transferred from the pro-R C4 position of the nicotinamide ring to the si face of the C6 position of pterin. This enzyme helps maintain intracellular pools of THF used in the biosynthesis of purine nucleotides and some amino acids. Furthermore the essential role of DHFR in DNA synthesis and in a variety of anabolic pathways makes it a common target for antiproliferative therapeutics. Due to its biological and pharmacological importance, and it being a small monomeric enzyme, DHFR has been the subject of intensive structural and kinetic investigation over many years, serving as a paradigm of enzymatic systems in many experimental and theoretical studies (1)(2)(3)(4)(5)(6)(7)(8). † This work was supported by NIH R01 GM65368-01 and NSF CHE-0133117 to A.K. The complete kinetic scheme for wild type ecDHFR was derived from equilibrium binding, steady-sta...

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“…Whereas some authors postulate dynamics as a key driving force in catalysis (1)(2)(3)(4), others have performed analyses showing activation free-energy reduction, which is an equilibrium property, to be the source of catalysis (6)(7)(8)(9)(10)(11)(12)(13)(14). Enzyme reactions, and particularly their dynamics, present formidable challenges for study, and progress requires a combination of theoretical, experimental, and computational approaches (5,(15)(16)(17)(18) (20). The physical steps of ligand association and dissociation have been shown to depend on movements between these two conformations (20,21).…”

mentioning

confidence: 99%

Unraveling the role of protein dynamics in dihydrofolate reductase catalysis

Luk

Ruiz‐Pernía

Dawson

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

127

262

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Protein dynamics have controversially been proposed to be at the heart of enzyme catalysis, but identification and analysis of dynamical effects in enzyme-catalyzed reactions have proved very challenging. Here, we tackle this question by comparing an enzyme with its heavy ( 15 N, 13 C, 2 H substituted) counterpart, providing a subtle probe of dynamics. The crucial hydride transfer step of the reaction (the chemical step) occurs more slowly in the heavy enzyme. A combination of experimental results, quantum mechanics/molecular mechanics simulations, and theoretical analyses identify the origins of the observed differences in reactivity. The generally slightly slower reaction in the heavy enzyme reflects differences in environmental coupling to the hydride transfer step. Importantly, the barrier and contribution of quantum tunneling are not affected, indicating no significant role for "promoting motions" in driving tunneling or modulating the barrier. The chemical step is slower in the heavy enzyme because protein motions coupled to the reaction coordinate are slower. The fact that the heavy enzyme is only slightly less active than its light counterpart shows that protein dynamics have a small, but measurable, effect on the chemical reaction rate.kinetics | computational chemistry | biological chemistry | biophysics | quantum biology

show abstract

Small Temperature Dependence of the Kinetic Isotope Effect for the Hydride Transfer Reaction Catalyzed by Escherichia coli Dihydrofolate Reductase

Cited by 115 publications

References 49 publications

Dynamics and dissipation in enzyme catalysis

Dynamics and dissipation in enzyme catalysis

Effects of a Distal Mutation on Active Site Chemistry

Unraveling the role of protein dynamics in dihydrofolate reductase catalysis

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