Catalytic-site design for inverse heavy-enzyme isotope effects in human purine nucleoside phosphorylase

Harijan, R.K.; Zoi, Ioanna; Antoniou, Dimitri; Schwartz, Steven D.; Schramm, Vern L.

doi:10.1073/pnas.1704786114

Cited by 24 publications

(45 citation statements)

References 39 publications

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“…Strategies previously employed in the literature by various groups include isotopically labelling the entire enzyme or labelling either of single amino acid residues or of particular segments, such as mobile loops (Figure ) . The effects of protein isotope labelling on transition states have been characterised in different enzymes including purine nucleotide phosphorylase (PNP), HIV protease (HIV‐1 PR), alanine racemase, dihydrofolate reductase (DHFR), pentaerythritol tetranitrate reductase (PETNR), formate dehydrogenase (FDH), lactate dehydrogenase (LDH) and alcohol dehydrogenase . In most of these cases, isotope labelling reduced the rate of the chemical step ––.…”

Section: Heavy Enzymesmentioning

confidence: 99%

“…Theoreticians have proposed that introducing a new “promoting motion” would improve the activity of aromatic amine dehydrogenase but this has never been tested experimentally . Similarly, work on PNP has shown that the efficiency of barrier crossing in a heavy enzyme can be modified by mutations that enhance promoting vibrations . Experimentally, this resulted in the inversion of the enzyme KIE from a normal KIE of 1.31 to an inverse KIE of 0.75 .…”

Section: Future Outlook For Protein Engineeringmentioning

confidence: 99%

“…Similarly, work on PNP has shown that the efficiency of barrier crossing in a heavy enzyme can be modified by mutations that enhance promoting vibrations . Experimentally, this resulted in the inversion of the enzyme KIE from a normal KIE of 1.31 to an inverse KIE of 0.75 . However, the mutant enzyme was less catalytically efficient than the wild type.…”

Section: Future Outlook For Protein Engineeringmentioning

confidence: 99%

See 2 more Smart Citations

Heavy Enzymes and the Rational Redesign of Protein Catalysts

Scott

Luk

Tuñón³

et al. 2019

ChemBioChem

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An unsolved mystery in biology concerns the link between enzyme catalysis and protein motions. Comparison between isotopically labelled “heavy” dihydrofolate reductases and their natural‐abundance counterparts has suggested that the coupling of protein motions to the chemistry of the catalysed reaction is minimised in the case of hydride transfer. In alcohol dehydrogenases, unnatural, bulky substrates that induce additional electrostatic rearrangements of the active site enhance coupled motions. This finding could provide a new route to engineering enzymes with altered substrate specificity, because amino acid residues responsible for dynamic coupling with a given substrate present as hotspots for mutagenesis. Detailed understanding of the biophysics of enzyme catalysis based on insights gained from analysis of “heavy” enzymes might eventually allow routine engineering of enzymes to catalyse reactions of choice.

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Section: Heavy Enzymesmentioning

confidence: 99%

Section: Future Outlook For Protein Engineeringmentioning

confidence: 99%

Section: Future Outlook For Protein Engineeringmentioning

confidence: 99%

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Heavy Enzymes and the Rational Redesign of Protein Catalysts

Scott

Luk

Tuñón³

et al. 2019

ChemBioChem

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“…Few reports have indicated that heavy enzymes can have faster chemistry than the light counterpart. With PNP, TPS explored the possibility that a mass-altered catalytic site mutant protein could be designed to exhibit increased chemistry rates relative to its unlabeled counterpart at the catalytic site (19). The analysis indicated that altering phenylalanine 159 to tyrosine (F159Y) would create an enzyme where the femtosecond dynamics of the heavy enzyme were more likely to find the transition state than the same enzyme in its natural isotopic form.…”

mentioning

confidence: 99%

“…This protein design element from TPS was confirmed by demonstrating a k chem light / k chem heavy of 0.75. However, the F159Y mutation in PNP also caused less efficient catalytic site chemistry, slowing it by a factor of 32 (19). An inverse heavy-enzyme isotope effect was also Significance Enzymes achieve catalytic efficiency by optimizing contacts between reactants and catalytic site amino acids.…”

mentioning

confidence: 99%

Inverse enzyme isotope effects in human purine nucleoside phosphorylase with heavy asparagine labels

Harijan

Zoi

Antoniou

et al. 2018

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

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Transition path-sampling calculations with several enzymes have indicated that local catalytic site femtosecond motions are linked to transition state barrier crossing. Experimentally, femtosecond motions can be perturbed by labeling the protein with amino acids containing C,N, and nonexchangeable H. A slowed chemical step at the catalytic site with variable effects on steady-state kinetics is usually observed for heavy enzymes. Heavy human purine nucleoside phosphorylase (PNP) is slowed significantly (/ = 1.36). An asparagine (Asn243) at the catalytic site is involved in purine leaving-group activation in the PNP catalytic mechanism. In a PNP produced with isotopically heavy asparagines, the chemical step is faster (/ = 0.78). When all amino acids in PNP are heavy except for the asparagines, the chemical step is also faster (/ = 0.71). Substrate-trapping experiments provided independent confirmation of improved catalysis in these constructs. Transition path-sampling analysis of these partially labeled PNPs indicate altered femtosecond catalytic site motions with improved Asn243 interactions to the purine leaving group. Altered transition state barrier recrossing has been proposed as an explanation for heavy-PNP isotope effects but is incompatible with these isotope effects. Rate-limiting product release governs steady-state kinetics in this enzyme, and kinetic constants were unaffected in the labeled PNPs. The study suggests that mass-constrained femtosecond motions at the catalytic site of PNP can improve transition state barrier crossing by more frequent sampling of essential catalytic site contacts.

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Mechanistic Insights on Human Phosphoglucomutase Revealed by Transition Path Sampling and Molecular Dynamics Calculations

Brás

Fernandes

Ramos

et al. 2018

Chemistry A European J

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Human α-phosphoglucomutase 1 (α-PGM) catalyzes the isomerization of glucose-1-phosphate into glucose-6-phosphate (G6P) through two sequential phosphoryl transfer steps with a glucose-1,6-bisphosphate (G16P) intermediate. Given that the release of G6P in the gluconeogenesis raises the glucose output levels, α-PGM represents a tempting pharmacological target for type 2 diabetes. Here, we provide the first theoretical study of the catalytic mechanism of human α-PGM. We performed transition-path sampling simulations to unveil the atomic details of the two catalytic chemical steps, which could be key for developing transition state (TS) analogue molecules with inhibitory properties. Our calculations revealed that both steps proceed through a concerted S 2-like mechanism, with a loose metaphosphate-like TS. Even though experimental data suggests that the two steps are identical, we observed noticeable differences: 1) the transition state ensemble has a well-defined TS region and a late TS for the second step, and 2) larger coordinated protein motions are required to reach the TS of the second step. We have identified key residues (Arg23, Ser117, His118, Lys389), and the Mg ion that contribute in different ways to the reaction coordinate. Accelerated molecular dynamics simulations suggest that the G16P intermediate may reorient without leaving the enzymatic binding pocket, through significant conformational rearrangements of the G16P and of specific loop regions of the human α-PGM.

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Catalytic-site design for inverse heavy-enzyme isotope effects in human purine nucleoside phosphorylase

Cited by 24 publications

References 39 publications

Heavy Enzymes and the Rational Redesign of Protein Catalysts

Heavy Enzymes and the Rational Redesign of Protein Catalysts

Inverse enzyme isotope effects in human purine nucleoside phosphorylase with heavy asparagine labels

Mechanistic Insights on Human Phosphoglucomutase Revealed by Transition Path Sampling and Molecular Dynamics Calculations

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