Chemical Ligation and Isotope Labeling to Locate Dynamic Effects during Catalysis by Dihydrofolate Reductase

Luk, Louis Y. P.; Ruiz‐Pernía, J. Javier; Adesina, Aduragbemi S.; Loveridge, E. Joel; Tuñón, Iñaki; Moliner, Vincent; Allemann, Rudolf Konrad

doi:10.1002/ange.201503968

Cited by 8 publications

(21 citation statements)

References 44 publications

(61 reference statements)

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“…3,4,37 Committor analysis also permits calculation of the barrier-crossing time for the hydride transfer reactions, which was the same for l- and h-DHFRs (Table 1). The computational data predict that ecDHFR is unlike other enzymes, 8-13 where altered enzyme mass has been demonstrated to influence the probability of barrier crossing. In ecDHFR, any vibrational motions altered by protein mass or temperature do not affect the TS or barrier-crossing parameters.…”

Section: Resultsmentioning

confidence: 93%

“…6,13 These investigations relied on steady-state k cat measurements at pH 9 and single-turnover kinetics at pH 7. It is unclear if the extracted kinetic constants reflect hydride transfer.…”

Section: Resultsmentioning

confidence: 99%

“…13 Those conclusions were drawn from differences in steady-state k cat and in the rate constants of fitting single-turnover kinetic data to a double-exponential equation. 6,13 However, the extracted rate constants might not report on hydride transfer chemistry at all temperatures since substrate KIEs were not reported. Transition state theory is often used to rationalize such results, but the application of traditional TS theory has been questioned in understanding protein dynamics in enzymatic reactions.…”

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confidence: 99%

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Hydride Transfer in DHFR by Transition Path Sampling, Kinetic Isotope Effects, and Heavy Enzyme Studies

et al. 2015

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Escherichia coli dihydrofolate reductase (ecDHFR) is used to study fundamental principles of enzyme catalysis. It remains controversial whether fast protein motions are coupled to the hydride transfer catalyzed by ecDHFR. Previous studies with heavy ecDHFR proteins labeled with 13C, 15N, and nonexchangeable 2H reported enzyme mass-dependent hydride transfer kinetics for ecDHFR. Here, we report refined experimental and computational studies to establish that hydride transfer is independent of protein mass. Instead, we found the rate constant for substrate dissociation to be faster for heavy DHFR. Previously reported kinetic differences between light and heavy DHFRs likely arise from kinetic steps other than the chemical step. This study confirms that fast (femtosecond to picosecond) protein motions in ecDHFR are not coupled to hydride transfer and provides an integrative computational and experimental approach to resolve fast dynamics coupled to chemical steps in enzyme catalysis.

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Section: Resultsmentioning

confidence: 93%

Section: Resultsmentioning

confidence: 99%

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confidence: 99%

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Hydride Transfer in DHFR by Transition Path Sampling, Kinetic Isotope Effects, and Heavy Enzyme Studies

et al. 2015

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“…A number of studies have illustrated the importance of enzyme motions and have suggested the presence of networks of vibrational modes that enable conformational sampling of productive substrate binding and/or reaction geometries (e.g. refs ). Modulating such a network would then have the potential to tune enzyme activity without altering the fine detail of the electrostatic environment at the active site, which is the key requirement for catalysis.…”

Section: Resultsmentioning

confidence: 99%

A complete thermodynamic analysis of enzyme turnover links the free energy landscape to enzyme catalysis

et al. 2017

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Our understanding of how enzymes work is coloured by static structure depictions where the enzyme scaffold is presented as either immobile, or in equilibrium between well-defined static conformations. Proteins, however, exhibit a large degree of motion over a broad range of timescales and magnitudes and this is defined thermodynamically by the enzyme free energy landscape (FEL). The role and importance of enzyme motion is extremely contentious. Much of the challenge is in the experimental detection of so called 'conformational sampling' involved in enzyme turnover. Herein we apply combined pressure and temperature kinetics studies to elucidate the full suite of thermodynamic parameters defining an enzyme FEL as it relates to enzyme turnover. We find that the key thermodynamic parameters governing vibrational modes related to enzyme turnover are the isobaric expansivity term and the change in heat capacity for enzyme catalysis. Variation in the enzyme FEL affects these terms. Our analysis is supported by a range of biophysical and computational approaches that specifically capture information on protein vibrational modes and the FEL (all atom flexibility calculations, red edge excitation shift spectroscopy and viscosity studies) that provide independent evidence for our findings. Our data suggest that restricting the enzyme FEL may be a powerful strategy when attempting to rationally engineer enzymes, particularly to alter thermal activity. Moreover, we demonstrate how rational predictions can be made with a rapid computational approach.

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“…Protein-based approaches offer the ability to function efficiently under mild reaction conditions. 5,6 Transferase, [13][14][15] oxidoreductase, [16][17][18] ligase, 19,20 transpeptidase 2,4,[21][22][23][24][25][26][27] and (split-)intein [28][29][30] have been applied for protein bioconjugation. Nevertheless, adapting these enzymes or proteins for synthetic applications, which deviate from their natural function, oen results in technical issues.…”

Section: Introductionmentioning

confidence: 99%

Use of an asparaginyl endopeptidase for chemo-enzymatic peptide and protein labeling

et al. 2020

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Chemical Ligation and Isotope Labeling to Locate Dynamic Effects during Catalysis by Dihydrofolate Reductase

Cited by 8 publications

References 44 publications

Hydride Transfer in DHFR by Transition Path Sampling, Kinetic Isotope Effects, and Heavy Enzyme Studies

Hydride Transfer in DHFR by Transition Path Sampling, Kinetic Isotope Effects, and Heavy Enzyme Studies

A complete thermodynamic analysis of enzyme turnover links the free energy landscape to enzyme catalysis

Use of an asparaginyl endopeptidase for chemo-enzymatic peptide and protein labeling

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