Variation of transition-state structure as a function of the nucleotide in reactions catalyzed by dehydrogenases. 2. Formate dehydrogenase

Hermes, Jeffrey D.; Morrical, Scott W.; O’Leary, Marion H.; Cleland, W. W.

doi:10.1021/bi00318a016

Cited by 134 publications

(140 citation statements)

References 22 publications

(28 reference statements)

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“…A similar diminution of the secondary isotope effect in response to deuteration at the primary position has been observed with formate dehydrogenase (35). In glutamate mutase we observe a qualitatively similar phenomenon, with the secondary tritium isotope effect being deflated from 0.76 to about 1.05.…”

Section: Hydrogen Tunneling and Coupled Motion?supporting

confidence: 84%

Evidence for Coupled Motion and Hydrogen Tunneling of the Reaction Catalyzed by Glutamate Mutase

Cheng

Marsh

2006

Biochemistry

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Glutamate mutase is one of a group of adenosylcobalamin-dependent enzymes that catalyze unusual isomerizations that proceed through organic radical intermediates generated by homolytic fission of coenzyme's unique cobalt-carbon bond. These enzymes are part of a larger family of enzymes that catalyze radical chemistry in which a key step is the abstraction of a hydrogen atom from an otherwise inert substrate. To gain insight into the mechanism of hydrogen transfer we previously used presteady state, rapid quench techniques to measure the α-secondary tritium kinetic and equilibrium isotope effects associated with the formation of 5'-deoxyadenosine when glutamate mutase was reacted with [5'-3 H]-adenosylcobalamin and L-glutamate. We showed that both the kinetic and equilibrium isotope effects are large and inverse, 0.76 and 0.72 respectively. We have now repeated these measurements using glutamate deuterated in the position of hydrogen abstraction. The effect of introducing a primary deuterium kinetic isotope effect on the hydrogen transfer step is to reduce the magnitude of the secondary kinetic isotope effect to a value close to unity, 1.05 ± 0.08, whereas the equilibrium isotope effect is unchanged. The significant reduction in the secondary kinetic isotope effect is consistent with motions of the 5'-hydrogen atoms being coupled in the transition state to the motion of the hydrogen undergoing transfer, in a reaction that involves a large degree of quantum tunneling. Keywordsenzyme; coenzyme-B 12 ; protein-radical; isomerization; transition state; secondary isotope effects Glutamate mutase is one of a group of adenosylcobalamin 1 (AdoCbl, coenzyme B 12 ) dependent enzymes that catalyze unusual carbon skeleton isomerisations. These rearrangements formally involve a 1,2 hydrogen atom migration and proceed through a mechanism involving carbon-based free radical intermediates (1-6). The initial steps of these reactions involve homolysis of the reactive cobalt-carbon bond of the coenzyme to form cob (II)alamin and 5'-deoxyadenosyl radical. The adenosyl radical then abstracts the migrating hydrogen from the substrate to form 5-deoxyadenosine and substrate radical (or protein radical in the case of AdoCbl-dependent ribonucleotide reductase). These steps have been studied in some detail for several B 12 enzymes and in each case homolysis and hydrogen abstraction are found to be kinetically coupled (7-10), as evidenced by the appearance of a kinetic isotope

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Section: Hydrogen Tunneling and Coupled Motion?supporting

confidence: 84%

Evidence for Coupled Motion and Hydrogen Tunneling of the Reaction Catalyzed by Glutamate Mutase

Cheng

Marsh

2006

Biochemistry

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“…These studies also show that solvent viscosity, point mutations of the protein, and substrate binding can modulate the time scales and relative amplitudes of protein dynamics (28). We report a study of the enzyme formate dehydrogenase (FDH) that catalyzes the nicotinamide adenine dinucleotide (NAD þ )-dependent oxidation of formate to carbon dioxide via hydride transfer to the C-4 carbon of the nicotinamide ring of NAD þ (37,38). FDH is an industrially important enzyme in the regeneration of NADH and NADPH for biocatalysis (39,40).…”

Section: D Ir Spectroscopy | Enzyme Dynamicsmentioning

confidence: 99%

Characterizing the dynamics of functionally relevant complexes of formate dehydrogenase

Bandaria

Dutta

Nydegger

et al. 2010

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

118

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The potential for femtosecond to picosecond time-scale motions to influence the rate of the intrinsic chemical step in enzymecatalyzed reactions is a source of significant controversy. Among the central challenges in resolving this controversy is the difficulty of experimentally characterizing thermally activated motions at this time scale in functionally relevant enzyme complexes. We report a series of measurements to address this problem using twodimensional infrared spectroscopy to characterize the time scales of active-site motions in complexes of formate dehydrogenase with the transition-state-analog inhibitor azide (N − 3 ). We observe that the frequency-frequency time correlation functions (FFCF) for the ternary complexes with NAD þ and NADH decay completely with slow time constants of 3.2 ps and 4.6 ps, respectively. This result suggests that in the vicinity of the transition state, the active-site enzyme structure samples a narrow and relatively rigid conformational distribution indicating that the transition-state structure is well organized for the reaction. In contrast, for the binary complex, we observe a significant static contribution to the FFCF similar to what is seen in other enzymes, indicating the presence of the slow motions that occur on time scales longer than our measurement window. 2D IR spectroscopy | enzyme dynamicsT he functional role of protein motions at the femtosecond to picosecond time scale is a hotly debated topic in enzymology. Although such a role could be general in nature, many experimental (1-10) and theoretical (11-23) studies of enzymecatalyzed hydrogen transfers have invoked protein motions at this time scale to explain anomalous kinetic isotope effects (KIE) and their temperature dependence. These studies result in the development of theoretical models, often referred to as Marcus-like models, in which the environmental reorganization that precedes the hydrogen-tunneling event has evolved to optimize the conformation of the transition state for tunneling (1,7,24). Fig. 1 illustrates the physical picture underlying such models. Heavy atom motions along the reorganization coordinate carry the system to a point where the donor and acceptor wells in the double-well hydrogen atom potential are degenerate and tunneling can proceed. At this position, the donor-acceptor distance and its fluctuations determine the tunneling probability. Mathematically, the rate constant for hydrogen transfer in these models is given by expressions of the form where C is the fraction of reactive complexes, the first exponential, in analogy with the Marcus theory for electron transfer, reflects the reorganization of the heavy atoms that modulates the relative energies of the reactants and the products to minimize the energy defect between the zero-point levels of the donor and acceptor wells. ΔG°is the driving force for the reaction, and λ is the reorganization energy. The second exponential gives the overlap between the donor and acceptor wave functions as a function of the donor-acceptor distan...

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“…whether concerted or stepwise) of various double proton-transfer reactions. 1,[3][4][5][9][10][11] This rule states that isotopic disproportionation equilibrium constants are nearly identical with the classical value. 35 It was proven to be exact for systems obeying partition functions with small quantum corrections.…”

Section: Introductionmentioning

confidence: 94%

“…The study of KIEs in such reactions is of particular interest. There have been numerous experimental [1][2][3][4][5][6][7][8][9][10][11][12][13][14]22,23 and theoretical [15][16][17][18][19][20][21][24][25][26][27][28][29][30][31][32][33][34] studies performed on proton transfer in systems of chemical and biochemical interest.…”

Section: Introductionmentioning

confidence: 99%

Primary and Solvent Kinetic Isotope Effects in the Water-Assisted Tautomerization of Formamidine: An ab Initio Direct Dynamics Study

Bell

Truong

1997

J. Phys. Chem. A

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We present an ab initio direct dynamics study of the primary and solvent kinetic isotopes effects (KIEs) for the water-assisted tautomerization in the formamidine-water complex. These calculations are based on a variational transition state theory plus multidimensional semiclassical tunneling corrections with potential energy information calculated at the MP2 level of theory using the 6-31G(d,p) basis set. We found that both the primary and solvent KIEs are large at low temperatures and are due not only to tunneling but also to quantum effects in vibrational motions. The primary KIEs were larger than the solvent KIEs. This results from differences due to the effect of deuteration on vibrational modes. Bending modes show significant inverse KIEs, while those of the reactive OH and NH vibrations show both inverse and normal effects. Such effects can be explained by examining changes in the zero-point energies of these modes. The adherence of the HH/HD/DD rates to the rule of the geometric mean is also examined.

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Variation of transition-state structure as a function of the nucleotide in reactions catalyzed by dehydrogenases. 2. Formate dehydrogenase

Cited by 134 publications

References 22 publications

Evidence for Coupled Motion and Hydrogen Tunneling of the Reaction Catalyzed by Glutamate Mutase

Evidence for Coupled Motion and Hydrogen Tunneling of the Reaction Catalyzed by Glutamate Mutase

Characterizing the dynamics of functionally relevant complexes of formate dehydrogenase

Primary and Solvent Kinetic Isotope Effects in the Water-Assisted Tautomerization of Formamidine: An ab Initio Direct Dynamics Study

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