Structural Dynamics and Cation Interactions of DNA Quadruplex
Molecules Containing Mixed Guanine/Cytosine Quartets Revealed by
Large-Scale MD Simulations
posted on 2001-03-15, 00:00authored byNad'a Špačková, Imre Berger, Jiří Šponer
Large-scale molecular dynamics (MD) simulations have been utilized to study G-DNA quadruplex
molecules containing mixed GCGC and all-guanine GGGG quartet layers. Incorporation of mixed GCGC
quartets into G-DNA stems substantially enhances their sequence variability. The mixed quadruplexes form
rigid assemblies that require integral monovalent cations for their stabilization. The interaction of cations with
the all-guanine quartets is the leading contribution for the stability of the four-stranded assemblies, while the
mixed quartets are rather tolerated within the structure. The simulations predict that two cations are preferred
to stabilize a four-layer quadruplex stem composed of two GCGC and two all-guanine quartets. The distribution
of cations in the structure is influenced by the position of the GCGC quartets within the quadruplex, the
presence and arrangement of thymidine loops connecting the guanine/cytosine stretches forming the stems,
and the cation type present (Na+ or K+). The simulations identify multiple nanosecond-scale stable arrangements
of the thymidine loops present in the molecules investigated. In these thymidine loops, several structured
pockets are identified capable of temporarily coordinating cations. However, no stable association of cations
to a loop has been observed. The simulations reveal several paths through the thymidine loop regions that can
be followed by the cations when exchanging between the central ion channel in the quadruplex stem and the
surrounding solvent. We have carried out 20 independent simulations while the length of simulations reaches
a total of 90 ns, rendering this study one of the most extensive MD investigations carried out on nucleic acids
so far. The trajectories provide a largely converged characterization of the structural dynamics of these four-stranded G-DNA molecules.