The stereochemistry of a four-way DNA junction: a theoretical study

doi:10.1093/nar/18.9.2671

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Nucleic Acids Research, 1990, Vol. 18, No. 9 2671-2683
© 1990

Molecular Biology

The stereochemistry of a four-way DNA junction: a theoretical study

Eberhard von Kitzing, David M.J. Lilley¹ and Stephan Diekmann²

Abteilung Zellphysiologie, Max-Planck-Institut für Medizinische forschung Postfach 103820, D-6900 Heidelberg, FRG ¹Department of Biochemistry, The University Dundee DD1 4HN, UK ²Abteilung Molekulare Biologie, Max-Planck-Institut für Biophysikalische Chemie Am Fassburg, D-3400 Göttingen-Nikolausberg, FRG

Received January 19, 1990. Accepted March 7, 1990.

The stereochemical conformation of the four-way helical junctionin DNA (the Holliday junction; the ostulated central intermediateof geneticr ecombination) has been analysed, using molecularmechanical computer modelling. A version of the AMBER programpackage was employed, that had been modified to include theinfluence of counterions and a global optimisation procedure.Starting from an extended planar structure, the conformationwas varied in order to minimise the energy, and we discuss threestructures obtained by this procedure. One structure is closelyrelated to a square-planar cross, in which there is no stackinginteraction between the four double helical stems. This structureis probably closely similar to that observed experimentallyin the absence of cations. The remaining two structures arebased on related, yet distinct, conformations, in which thereis pairwise coaxial stacking of neighbouring stems. In thesestructures, the four DNA stems adopt the form of two quasi-continuoushelices, in which base stacking is very similar to that foundin standard B-DNA geometry. The two stacked helices so formedare not aligned parallel to each other, but subtend an angleof approximately 60^°. The strands that exchange betweenone stacked helix and the other are disposed about the smallerangle of the cross (i.e. 60^° rather than 120^°), generatingan approximately antiparallel alignment of DNA sequences. Thisstructure is precisely the stacked X-structure proposed on thebasis of experimental data. The calculations indicate distortionsfrom standard BDNA conformation that are required to adopt thestacked X-structure; a widening of the minor groove at the junction,and reorientation of the central phosphate groups of the exchangingstrands. An important feature of the stacked X-structure isthat it presents two structurally distinct sides. These maybe recognised differently by enzymes, providing a rationalisationfor the points of cleavage by Holliday resolvases.

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