Stepwise induced fit in the pico- to nanosecond time scale governs the complexation of the even-skipped transcriptional repressor homeodomain to DNA.

Induced fit effects in the complex of a DNA decamer with two even-skipped transcriptional repressor homeodomain molecules were investigated by means of molecular dynamics simulations. Dynamics of these effects are found to be in the time scale from pico- to nanoseconds. First steps are made by the fast-moving DNA backbone phosphates, which upon binding change their B(I)/B(II) substate distribution.

Hydration of hydroxypyrrole influences binding of ImHpPyPy-beta-Dp polyamide to DNA.

Ligands which are able to recognize DNA sequence specifically are of fundamental interest as transcription controlling drugs. Recently a polyamide ligand was developed (ImHpPyPy-beta-Dp) which differentiates in a dimeric arrangement between all four possible base pair steps in the minor groove. This is a landmark for the design of DNA binding drugs because it was believed that such a recognition could only be possible in the major groove of DNA.

PvuII-endonuclease induces structural alterations at the scissile phosphate group of its cognate DNA.

We investigated the PvuII endonuclease with its cognate DNA by means of molecular dynamics simulations. Comparing the complexed DNA with a reference simulation of free DNA, we saw structural changes at the scissile phosphodiester bond. At this GpC step, the enzyme induces the highest twist and axial rise, inclination is increased and the minor groove widened.

Indirect readout of the trp-repressor-operator complex by B-DNA's backbone conformation transitions.

Although the trp-repressor-operator complex is one of the best studied transcriptional controlling systems, some questions regarding the specific recognition of the operator by the repressor remain. We performed a 2.35 ns long molecular dynamics simulation to clarify the influence of the two B-DNA backbone conformational substates B(I) and B(II) on complexation.