Sequence-Dependent Motions of DNA: A Normal Mode Analysis at the Base-Pair Level

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Sequence-Dependent Motions of DNA: A Normal Mode Analysis at the Base-Pair Level

Atsushi Matsumoto and Wilma K. Olson

Department of Chemistry, Rutgers, the State University of New Jersey, Wright-Rieman Laboratories, Piscataway, New Jersey 08854-8087 USA

Computer simulation of the dynamic structure of DNA can be carried out at various levels of resolution. Detailed high resolutioninformation about the motions of DNA is typically collected forthe atoms in a few turns of double helix. At low resolution, bycontrast, the sequence-dependence features of DNA are usuallyneglected and molecules with thousands of base pairs are treatedas ideal elastic rods. The present normal mode analysis of DNAin terms of six base-pair "step" parameters per chain residueaddresses the dynamic structure of the double helix at intermediateresolution, i.e., the mesoscopic level of a few hundred base pairs.Sequence-dependent effects are incorporated into the calculationsby taking advantage of "knowledge-based" harmonic energy functionsdeduced from the mean values and dispersion of the base-pair "step"parameters in high-resolution DNA crystal structures. Spatialarrangements sampled along the dominant low frequency modes haveend-to-end distances comparable to those of exact polymer modelswhich incorporate all possible chain configurations. The normalmode analysis accounts for the overall bending, i.e., persistencelength, of the double helix and shows how known discrepanciesin the measured twisting constants of long DNA molecules couldoriginate in the deformability of neighboring base-pair steps.The calculations also reveal how the natural coupling of localconformational variables affects the global motions of DNA. Successfulcorrespondence of the computed stretching modulus with experimentaldata requires that the DNA base pairs be inclined with respectto the direction of stretching, with chain extension effectedby low energy transverse motions that preserve the strong vander Waals' attractions of neighboring base-pair planes. The calculationsfurther show how one can "engineer" the macroscopic propertiesof DNA in terms of dimer deformability so that polymers whichare intrinsically straight in the equilibrium state exhibit themesoscopic bending anisotropy essential to DNA curvature and loopformation.

Biophys J, July 2002, p. 22-41, Vol. 83, No. 1
© 2002 by the Biophysical Society 0006-3495/02/07/22/20 $2.00

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