Atomistic Understanding of Kinetic Pathways for Single Base-Pair Binding and Unbinding in DNA

Atomistic Understanding of Kinetic Pathways for Single Base-Pair Binding and Unbinding in DNA

We combine free-energy calculations and molecular dynamics to elucidate a mechanism for DNA base-pair binding and unbinding in atomic detail. Specifically, transition-path sampling is used to overcome computational limitations associated with conventional techniques to harvest many trajectories for...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS Vol. 100; no. 24; pp. 13922 - 13927
Main Authors: Hagan, Michael F., Dinner, Aaron R., Chandler, David, Chakraborty, Arup K.
Format: Journal Article
Language:English
Published: United States National Academy of Sciences 25-11-2003
National Acad Sciences
Subjects:
Atomic interactions
Base Pairing
Biological Sciences
Biophysical Phenomena
Biophysics
Coordinate systems
Deoxyribonucleic acid
DNA
DNA - chemistry
DNA - metabolism
Free energy
Hydrogen Bonding
Hydrogen bonds
Kinetics
Models, Molecular
molecular dynamics
Nucleic Acid Conformation
Nucleic acids
Oligomers
Solvents
Thermodynamics
Trajectories
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Summary:We combine free-energy calculations and molecular dynamics to elucidate a mechanism for DNA base-pair binding and unbinding in atomic detail. Specifically, transition-path sampling is used to overcome computational limitations associated with conventional techniques to harvest many trajectories for the flipping of a terminal cytosine in a 3-bp oligomer in explicit water. Comparison with free-energy projections obtained with umbrella sampling reveals four coordinates that separate true dynamic transition states from stable reactant and product states. Unbinding proceeds via two qualitatively different pathways: one in which the flipping base breaks its intramolecular hydrogen bonds before it unstacks and another in which it ruptures both sets of interactions simultaneously. Both on- and off-pathway intermediates are observed. The relation of the results to coarse-grained models for DNA-based biosensors is discussed.
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Present address: Department of Chemistry, James Franck Institute, Institute for Biophysical Dynamics, University of Chicago, Chicago, IL 60637.
Abbreviation: TPS, transition-path sampling.
Contributed by David Chandler, October 2, 2003
To whom correspondence may be addressed. E-mail: arup@uclink.berkeley.edu or chandler@cchem.berkeley.edu.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.2036378100