Abstract
N-methylpyrrole (Py)-N-methylimidazole (Im) polyamides are small organic molecules that bind to DNA with sequence specificity and can be used as synthetic DNA-binding ligands. In this study, five hairpin eight-ring Py–Im polyamides 1–5 with different number of Im rings were synthesized, and their binding behaviour was investigated with surface plasmon resonance assay. It was found that association rate (ka) of the Py–Im polyamides with their target DNA decreased with the number of Im in the Py–Im polyamides. The structures of four-ring Py–Im polyamides derived from density functional theory revealed that the dihedral angle of the Py amide carbonyl is 14∼18°, whereas that of the Im is significantly smaller. As the minor groove of DNA has a helical structure, planar Py–Im polyamides need to change their conformation to fit it upon binding to the minor groove. The data explain that an increase in planarity of Py–Im polyamide induced by the incorporation of Im reduces the association rate of Py–Im polyamides. This fundamental knowledge of the binding of Py–Im polyamides to DNA will facilitate the design of hairpin Py–Im polyamides as synthetic DNA-binding modules.
Highlights
N-Methylpyrrole (Py)-N-methylimidazole (Im) polyamides are small organic molecules that can recognize specific DNA sequences in the minor groove of B-formDNA, according to DNA recognition rules [1,2]
Py–Im polyamides have been conjugated with a peptide or a small organic molecule to create synthetic transcriptional activators that stimulate gene expression [10,11,12,13]
To investigate the binding properties of Py and Im in hairpin Py–Im polyamides, we designed and synthesized five hairpin eight-ring Py–Im polyamides 1–5 (Figure 1) by the Fmoc-chemistry solid-phase synthesis method
Summary
N-Methylpyrrole (Py)-N-methylimidazole (Im) polyamides are small organic molecules that can recognize specific DNA sequences in the minor groove of B-form. Py–Im polyamides have been conjugated with a peptide or a small organic molecule to create synthetic transcriptional activators that stimulate gene expression [10,11,12,13]. Only a few of their corresponding association rate constants and dissociation rate constants have been reported [14,15,16] It may be crucial for the design of a synthetic DNA-binding module to determine KDs. It may be crucial for the design of a synthetic DNA-binding module to determine KDs
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