Comparative Analysis of DNA-Binding Selectivity of Hairpin and Cyclic Pyrrole-Imidazole Polyamides Based on Next-Generation Sequencing

Strong and Specific Recognition of CAG/CTG Repeat DNA (5'-dWGCWGCW-3') by a Cyclic Pyrrole-Imidazole Polyamide

Abnormally expanded CAG/CTG repeat DNA sequences lead to a variety of neurological diseases, such as Huntington's disease. Here, we synthesized a cyclic pyrrole‐imidazole polyamide (cPIP), which can bind to the minor groove of the CAG/CTG DNA sequence. The double‐stranded DNA melting temperature (T_m) and surface plasmon resonance assays revealed the high binding affinity of the cPIP. In addition, next‐generation sequencing showed that the cPIP had high specificity for its target DNA sequence.

DNA binding site kinetics of a large antiviral polyamide

Polyamides (PAs) are powerful DNA ligands that can bind the minor groove of DNA with high affinity and specificity. While the characterization of PA-DNA behavior has focused principally on hairpin PAs 6-8 rings in size, there is increasing evidence that their behavior does not necessarily reflect the complexities that are emerging from studies of larger hairpin PAs, particularly concerning sequence mismatch tolerance and observed but unaddressed high PA-target site binding stoichiometries. To explore these complexities in more detail, kinetics studies of binding a large anti-HPV hairpin polyamide to an isolated DNA recognition site are described. Using a fluorescence assay, two distinct binding phases are observed for the first time in hairpin PA literature. PA14 concentration dependence analysis indicates that the faster binding event is diffusion-controlled; the apparent, second event is significantly slower (350-1500 fold). Both association phases are sampled in 1:1 complexes, consistent with cooperative binding of two PA molecules even under this condition. Fitting of the slow phase to a biexponential model yields two λ_on,app that differ by 4-5-fold, which is consistent with the high mismatch tolerance and binding site stoichiometry previously observed. A/T patterns in the recognition sequence do not affect these decay constants significantly. Dissociation decay constants are among the slowest reported for hairpin PAs (10^-3 s^-1), independent of A/T pattern, and may point to the efficacy of PA14 as an antiviral.

Single position substitution of hairpin pyrrole-imidazole polyamides imparts distinct DNA-binding profiles across the human genome

Pyrrole–imidazole (Py–Im) polyamides are synthetic molecules that can be rationally designed to target specific DNA sequences to both disrupt and recruit transcriptional machinery. While in vitro binding has been extensively studied, in vivo effects are often difficult to predict using current models of DNA binding. Determining the impact of genomic architecture and the local chromatin landscape on polyamide-DNA sequence specificity remains an unresolved question that impedes their effective deployment in vivo. In this report we identified polyamide–DNA interaction sites across the entire genome, by covalently crosslinking and capturing these events in the nuclei of human LNCaP cells. This technique confirms the ability of two eight ring hairpin-polyamides, with similar architectures but differing at a single ring position (Py to Im), to retain in vitro specificities and display distinct genome-wide binding profiles.

The Road Not Taken with Pyrrole-Imidazole Polyamides: Off-Target Effects and Genomic Binding

The high sequence specificity of minor groove-binding N-methylpyrrole-N-methylimidazole polyamides have made significant advances in cancer and disease biology, yet there have been few comprehensive reports on their off-target effects, most likely as a consequence of the lack of available tools in evaluating genomic binding, an essential aspect that has gone seriously underexplored. Compared to other N-heterocycles, the off-target effects of these polyamides and their specificity for the DNA minor groove and primary base pair recognition require the development of new analytical methods, which are missing in the field today. This review aims to highlight the current progress in deciphering the off-target effects of these N-heterocyclic molecules and suggests new ways that next-generating sequencing can be used in addressing off-target effects.

Sequence-specific DNA binding Pyrrole-imidazole polyamides and their applications

Pyrrole-imidazole polyamides (Py-Im polyamides) are cell-permeable compounds that bind to the minor groove of double-stranded DNA in a sequence-specific manner without causing denaturation of the DNA. These compounds can be used to control gene expression and to stain specific sequences in cells. Here, we review the history, structural variations, and functional investigations of Py-Im polyamides.