Structure and Hydration of BamHI DNA Recognition Site: A Molecular Dynamics Investigation

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Biophys J, September 2000, p. 1263-1272, Vol. 79, No. 3

Structure and Hydration of BamHI DNA Recognition Site: A Molecular Dynamics Investigation

T. Castrignanò,^* G. Chillemi, and A. Desideri^*

^*INFM and Department of Biology, University of Rome "Tor Vergata," 00133 Rome; and CASPUR, Supercomputing Center for University and Research, c/o Università "La Sapienza," 00185 Rome, Italy

The results of a 3-ns molecular dynamics simulation of the dodecamer duplex d(TATGGATCCATA)₂ recognized by the BamHI endonucleaseare presented here. The DNA has been simulated as a flexible moleculeusing an AMBER force field and the Ewald summation method, whicheliminates the undesired effects of truncation and permits evaluationof the full effects of electrostatic forces. The starting B conformationevolves toward a configuration quite close to that observed throughx-ray diffraction in its complex with BamHI. This configurationis fairly stable and the Watson-Crick hydrogen bonds are wellmaintained over the simulation trajectory. Hydration analysisindicates a preferential hydration for the phosphate rather thanfor the ester oxygens. Hydration shells in both the major andminor groove were observed. In both grooves the C-G pairs werefound to be more hydrated than A-T pairs. The "spine of hydration"in the minor groove was clear. Water residence times are longerin the minor groove than in the major groove, although relativelyshort in both cases. No special long values are observed for siteswhere water molecules were observed by x-ray diffraction, indicatingthat water molecules having a high probability of being locatedin a specific site are also fast-exchanging.

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