Enthalpy-driven nuclease-like activity and mechanism of peptide-chlorambucil conjugates.

We report the results of attaching the anticancer drug chlorambucil (CLB) to two high-affinity DNA binding peptides: Met-Hyp-Arg-Lys-(Py)4-Lys-Arg-NH2 (HyM-10) and Gln-Hyp-Arg-Lys-(Py)4-Lys-Arg-NH2 (HyQ-10). These CLB-peptide conjugates cleave DNA very effectively and sequence-selectively without the use of chemicals, heat, or UV irradiation. Polyacrylamide gel electrophoresis identifies the sites where CLB-HyM-10 and CLB-HyQ-10 attack a complementary pair of 5'-(32)P-labeled duplexes derived from pBR322 in the absence of piperidine or other chemical additives.

Energetic studies on DNA-peptide interaction in relation to the enthalpy-entropy compensation paradox.

This study aims to interpret the energetic basis of complex DNA-peptide interactions according to a novel allosteric interaction network approach. In common with other designed peptides, five new conjugates incorporating the XPRK or XHypRK motif (Hyp = hydroxyproline) attached to a N-methylpyrrole (Py) tract with a basic tail have been found to display cooperative binding to DNA involving multiple monodentate as well as interstrand bidentate interactions. Using quantitative DNase I footprinting it appears that allosteric communication via cooperative binding to multiple sites on complementary DNA strands corresponds to two different types of DNA-peptide interaction network.

Novel DNA-peptide interaction networks.

Allostery in the binding of peptides to DNA has been studied by quantitative DNase I footprinting using four newly designed peptides containing the XP(Hyp)RK motif and N-methylpyrrole (Py) moieties. Apparent binding constants in the micromolar range as well as Hill coefficients were determined for each peptide. The results, together with previous studies on five other peptides support the proposal that interaction network cooperativity is highly preferred in DNA-peptide interactions that involve multiple recognition sites.