Site-directed mutagenesis and the role of the oxyanion hole in subtilisin.

Bryan, Philip N.; Pantoliano, Michael W.; Quill, Steven; Hsiao, Humg-Yu; Poulos, T.L.

doi:10.1073/pnas.83.11.3743

Cited by 241 publications

(171 citation statements)

References 24 publications

(22 reference statements)

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“…Finally, the success of these experiments shows that in vitro translation can be used to generate sufficient quantities of backbone amide to ester substitutions to test the importance of their interactions with substrates/intermediates/transition states interactions in other enzymes (e.g., serine proteases, haloalkane dehalogenases, and enoyl-CoA hydratase) (2,20,21).…”

Section: Discussionmentioning

confidence: 99%

“…Such an interaction can contribute to catalysis by increasing in strength as the basicity/proton affinity of the acceptor is increased as the reaction coordinate is traversed (1). Perhaps the best known example of such an interaction is the oxyanion hole in serine proteases, in which the substrate peptide carbonyl group is converted to an anionic tetrahedral intermediate (2). However, the importance of the presumed enhanced hydrogen-bonding interaction between the oxyanion hole and the substrate/intermediate has not been directly evaluated because of the difficulty in mutating the backbone amide group donor and/or the substrate acceptor.…”

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confidence: 99%

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Investigating the role of a backbone to substrate hydrogen bond in OMP decarboxylase using a site-specific amide to ester substitution

Desai

Cembran

Fedorov

et al. 2014

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

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Hydrogen bonds between backbone amide groups of enzymes and their substrates are often observed, but their importance in substrate binding and/or catalysis is not easy to investigate experimentally. We describe the generation and kinetic characterization of a backbone amide to ester substitution in the orotidine 5′-monophosphate (OMP) decarboxylase from Methanobacter thermoautotrophicum (MtOMPDC) to determine the importance of a backbone amide-substrate hydrogen bond. The MtOMPDC-catalyzed reaction is characterized by a rate enhancement (∼10 17 ) that is among the largest for enzyme-catalyzed reactions. The reaction proceeds through a vinyl anion intermediate that may be stabilized by hydrogen bonding interaction between the backbone amide of a conserved active site serine residue (Ser-127) and oxygen (O4) of the pyrimidine moiety and/or electrostatic interactions with the conserved general acidic lysine (Lys-72). In vitro translation in conjunction with amber suppression using an orthogonal amber tRNA charged with L-glycerate ( HO S) was used to generate the ester backbone substitution (S127 HO S). With 5-fluoro OMP (FOMP) as substrate, the amide to ester substitution increased the value of K m by ∼1.5-fold and decreased the value of k cat by ∼50-fold. We conclude that (i) the hydrogen bond between the backbone amide of Ser-127 and O4 of the pyrimidine moiety contributes a modest factor (∼10 2 ) to the 10 17 rate enhancement and (ii) the stabilization of the anionic intermediate is accomplished by electrostatic interactions, including its proximity of Lys-72. These conclusions are in good agreement with predictions obtained from hybrid quantum mechanical/molecular mechanical calculations.enzymology | cell-free translation | unnatural protein residue | flexible tRNA acylation ribozyme E lucidation of the structural strategies by which enzymes achieve their large rate enhancements is essential for understanding the evolution of enzymatic catalysis as well as facilitating the design of enzymes to catalyze novel reactions. Typically, the possible strategies are identified by high-resolution X-ray structural analyses, in which a stable mimic of a reactive intermediate or rate-determining transition state is bound in the active site. Then, site-directed mutagenesis is used to generate substitutions, in which the important interactions are removed or altered, with kinetic analyses and structural studies of the mutant enzymes allowing the importance of the interaction to be assessed. Indeed, for nearly 30 y, this approach has been used to evaluate the importance of interactions involving amino acid side chains. However, structural studies of many enzymes reveal the presence of hydrogen-bonding interactions between a backbone amide group donor and a heteroatom acceptor in the substrate. Such an interaction can contribute to catalysis by increasing in strength as the basicity/proton affinity of the acceptor is increased as the reaction coordinate is traversed (1). Perhaps the best known example of such an interactio...

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Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

Investigating the role of a backbone to substrate hydrogen bond in OMP decarboxylase using a site-specific amide to ester substitution

Desai

Cembran

Fedorov

et al. 2014

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

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“…Stabilization of the intermediate is achieved by formation of two H-bonds with the amide groups of Ser195 and Gly193 (mammalian isoenzymes 4 ) or with the amide groups of Ser195 and the side chain of Asn155 (bacterial isoenzymes 14 ).…”

Section: Introductionmentioning

confidence: 99%

Serine proteases: An ab initio molecular dynamics study

Santis

Carloni

1999

Proteins

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“…1 (Robertus et al, 1972;Kossiakof & Spencer, 1981). The studies of and Bryan et al (1986) give useful estimates of the quantitative importance of hydrogen bonds to transition state stabilization, taking an approach similar to that by Fersht and his colleagues for tyrosyl-tRNA synthetase (see below). The calculated differences in free energy differences between the transition state and the ground state from:…”

Section: Introductionmentioning

confidence: 99%

“…Such information is not yet available for many mutant enzymes, and subtilisin is no exception in this respect, but for the substrate used in the above study it is known that the acylation step is rate-limiting and that the ratio of rate constants for acylation and de-acylation is comfortably high (33) for the wild type enzyme. Since Asn-155--Leu is a nearly isosteric change to a residue which cannot form hydrogen bonds, it is comforting that the calculated AAG* value of 15 kJ -mol-1 (Bryan et al, 1986) (Russell et al, 1987) have emphasized the importance of environmental factors near the catalytic centre and, in particular, the likely importance of electrostatic effects and large changes in the pH dependence which may accompany the removal by mutation of negative charges at surface residues up to 15 nm from the active site. In the case of subtilisin the apparent pK of His-64 can be reduced by 0.4 units by Asp-99-*Ser or Glu-156-+Ser, the functional changes in each case being masked, as predicted, by high ionic strength.…”

Section: Introductionmentioning

confidence: 99%

Protein engineering. The design, synthesis and characterization of factitious proteins

Shaw

1987

Biochemical Journal

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Site-directed mutagenesis and the role of the oxyanion hole in subtilisin.

Cited by 241 publications

References 24 publications

Investigating the role of a backbone to substrate hydrogen bond in OMP decarboxylase using a site-specific amide to ester substitution

Investigating the role of a backbone to substrate hydrogen bond in OMP decarboxylase using a site-specific amide to ester substitution

Serine proteases: An ab initio molecular dynamics study

Protein engineering. The design, synthesis and characterization of factitious proteins

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