TY - JOUR
T1 - Correct and incorrect nucleotide incorporation pathways in DNA polymerase β
AU - Radhakrishnan, Ravi
AU - Schlick, Tamar
N1 - Funding Information:
We thank Dr. P. Sherwood for his help in compiling the CHARMM-GAMESS interface, Dr. M. Karplus for allowing us to use the CHARMM program, and Dr. N. Glykos for his help with the PCA. R. Radhakrishnan acknowledges a grant from the Whitaker Foundation and computational resources provided by the National Center for Supercomputing Alliance under Grant DAC 1103423 and National Partnership for Advanced Computational Infrastructure under Grant MCB060006. T. Schlick acknowledges support by NSF Grant MCB-0316771, NIH Grants R01 GM55164 and 1R01ES012692, donors of the American Chemical Society Petroleum Research Fund, and Philip Morris International. Computing facilities provided by the N.C.S.A. supercomputing center are highly appreciated.
PY - 2006/11/24
Y1 - 2006/11/24
N2 - Tracking the structural and energetic changes in the pathways of DNA replication and repair is central to the understanding of these important processes. Here we report favorable mechanisms of the polymerase-catalyzed phosphoryl transfer reactions corresponding to correct and incorrect nucleotide incorporations in the DNA by using a novel protocol involving energy minimizations, dynamics simulations, quasi-harmonic free energy calculations, and mixed quantum mechanics/molecular mechanics dynamics simulations. Though the pathway proposed may not be unique and invites variations, geometric and energetic arguments support the series of transient intermediates in the phosphoryl transfer pathways uncovered here for both the G:C and G:A systems involving a Grotthuss hopping mechanism of proton transfer between water molecules and the three conserved aspartate residues in pol β's active-site. In the G:C system, the rate-limiting step is the initial proton hop with a free energy of activation of at least 17 kcal/mol, which corresponds closely to measured kpol values. Fidelity discrimination in pol β can be explained by a significant loss of stability of the closed ternary complex of the enzyme in the G:A system and much higher activation energy of the initial step of nucleophilic attack, namely deprotonation of terminal DNA primer O3′H group. Thus, subtle differences in the enzyme active-site between matched and mismatched base pairs generate significant differences in catalytic performance.
AB - Tracking the structural and energetic changes in the pathways of DNA replication and repair is central to the understanding of these important processes. Here we report favorable mechanisms of the polymerase-catalyzed phosphoryl transfer reactions corresponding to correct and incorrect nucleotide incorporations in the DNA by using a novel protocol involving energy minimizations, dynamics simulations, quasi-harmonic free energy calculations, and mixed quantum mechanics/molecular mechanics dynamics simulations. Though the pathway proposed may not be unique and invites variations, geometric and energetic arguments support the series of transient intermediates in the phosphoryl transfer pathways uncovered here for both the G:C and G:A systems involving a Grotthuss hopping mechanism of proton transfer between water molecules and the three conserved aspartate residues in pol β's active-site. In the G:C system, the rate-limiting step is the initial proton hop with a free energy of activation of at least 17 kcal/mol, which corresponds closely to measured kpol values. Fidelity discrimination in pol β can be explained by a significant loss of stability of the closed ternary complex of the enzyme in the G:A system and much higher activation energy of the initial step of nucleophilic attack, namely deprotonation of terminal DNA primer O3′H group. Thus, subtle differences in the enzyme active-site between matched and mismatched base pairs generate significant differences in catalytic performance.
KW - Phosphoryl transfer
KW - Polymerase fidelity
KW - Quantum mechanics molecular mechanics simulations
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U2 - 10.1016/j.bbrc.2006.09.059
DO - 10.1016/j.bbrc.2006.09.059
M3 - Article
C2 - 17022941
AN - SCOPUS:33749616576
SN - 0006-291X
VL - 350
SP - 521
EP - 529
JO - Biochemical and Biophysical Research Communications
JF - Biochemical and Biophysical Research Communications
IS - 3
ER -