Influence of PNA containing 8-aza-7-deazaadenine on structure stability and binding affinity of PNA·DNA duplex: insights from thermodynamics, counter ion, hydration and molecular dynamics analysis.

This paper describes the synthesis of a novel 8-aza-7-deazapurin-2,6-diamine (DPP)-containing peptide nucleic acid (PNA) monomer and Boc protecting group-based oligomerization of PNA, replacing adenine (A) with DPP monomers in the PNA strand. The PNA oligomers were synthesized against the biologically relevant SV40 promoter region (2494-AATTTTTTTTATTTA-2508) of pEGFP-N3 plasmid. The DPP-PNA·DNA duplex showed enhanced stability as compared to normal duplex (A-PNA·DNA). The electronic distribution of DPP monomer suggested that DPP had better electron donor properties over 2,6-diamino purine. UV melting and thermodynamic analysis revealed that the PNA oligomer containing a diaminopyrazolo(3,4-d)pyrimidine moiety (DPP) stabilized the PNA·DNA hybrids compared to A-PNA·DNA. DPP-PNA·DNA duplex showed higher water activity (Δnw = 38.5) in comparison to A-PNA·DNA duplex (Δnw = 14.5). The 50 ns molecular dynamics simulations of PNA·DNA duplex containing DPP or unmodified nucleobase-A showed average H-bond distances in the DPP-dT base pair of 2.90 Å (OH-N bond) and 2.91 Å (NH-N bond), which were comparably shorter than in the A-dT base pair, in which the average distances were 3.18 Å (OH-N bond) and 2.97 Å (NH-N bond), and there was one additional H-bond in the DPP-dT base pair of around 2.98 Å (O2H-N2 bond), supporting the higher stability of DPP-PNA·DNA. The analysis of molecular dynamics simulation data showed that the system binding free energy increased at a rate of approximately -4.5 kcal mol(-1) per DPP base of the PNA·DNA duplex. In summary, increased thermal stability, stronger hydrogen bonding and more stable conformation in the DPP-PNA·DNA duplex make it a better candidate as antisense/antigene therapeutic agents.

Evaluation of electronic effect of phenyl ring substituents on the DNA minor groove binding properties of novel bis and terbenzimidazoles: synthesis and spectroscopic studies of ligand-DNA interaction.

Several minor groove binding agents (MGBD) were synthesized to study their binding behaviors and sequence specificity with DNA. In order to further understand the binding interactions of the MGBD to DNA, we have synthesized some novel benzimidazoles, which have electron donating (OCH(3), OCH(2)CH(3), OH, O(CH(2))(3)NH(2)) and electron withdrawing cyano groups on the phenyl ring. The interaction of these new benzimidazoles along with parent compounds Hoechst 33342 have been studied with CT DNA, two A-T rich [d(GA(5)T(5)C) and d(CGCA(3)T(3)G)] and one G-C rich [d(GCATGGCCATGC)] oligonucleotide sequences using electrospray ionization mass spectrometry (ESI-MS), absorption, fluorescence, and circular dichroism (CD) spectroscopy. Bisubstituted analogs, which have electron-donating groups, were found to form more stable ligand-DNA complex than Hoechst 33342, while the benzimidazole with electron withdrawing cyano group resulted comparatively in less stable ligand DNA complex. The ESI-MS also gave reliable information about the A-T sequence selectivity as we did not observe any signal with G-C sequence in mass with parent as well as novel ligands. Similar studies with ESI-MS suggest that Hoechst 33342, ETBBZ, and MMBBZ form complexes of 2:1 stoichiometry with d(GA(5)T(5)C) duplex while rest of the ligands form complexes of 1:1 stoichiometry with d(GA(5)T(5)C). Thus, this present study provides the rationalization for the difference in binding behaviors of minor groove binding benzimidazole analogs having different substitution on the phenyl ring.

Benzimidazoles: a minor groove-binding ligand-induced stabilization of triple helix.

Nonintercalating minor groove-binding ligands netropsin, Hoechst 33258, and DAPI are reported to destabilize the triplex. Ligands with different substitutions on the phenyl ring of bis- and terbenzimidazoles were evaluated for their effect on the stability of C+.GC triplex and Hoogsteen duplex. We found that newly synthesized benzimidazoles stabilize the triplex as shown by fluorescence and melting studies. Modeling studies showed that these molecules bind in the Watson-Crick minor groove of triplex, which can exert a profound impact on the properties of the host triplex. Circular dichroism-binding studies indicate 5.77 base triplets/ligand as an apparent binding site for bis- and 8.66 for terbenzimidazoles. The stabilization of triplex can be attributed to the protonation of nitrogens and amines of benzimidazoles at pH 5.2 that compensate the negative charge of phosphate backbone to reduce the repulsion between the strands resulting in the stabilization.