Stabilization of an abasic site paired against an unnatural triazolyl nitrobenzene nucleoside.

An abasic site is the most frequently observed among the various forms of DNA lesions in genomic DNA. If left unrepaired, an abasic site might turn out to be a principle cause for deleterious mutations and can be threat to cellular survival. Thus, to keep cellular integrity and measure the extent of DNA damage, recognition and stabilization of the abasic sites (apurinic/apyrimidinic site = Ap) are essential. Further, it is crucial to detect and stabilise the abasic site for towards the development of new diagnostics and chemotherapeutics. Herein, we report the stabilization of an abasic DNA duplex wherein the abasic site paired against a novel unnatural nucleoside, triazolylnitrobenzene (TNBBAc). This nucleoside is bulky and exhibits, high polarizability and good stacking propensity. Robust hetero-pair stabilization is another feature of it. Therefore, it is interesting to study the stabilization of an abasic DNA containing a synthesized triazolylnitrobenzene nucleoside TNBBAc We planned to study the thermal as well as the thermodynamic origin of abasic DNA stabilization by our synthesized oligonucleotide probe containing TNBBAc nucleoside. We observed that the nucleoside TNBBAc offered good thermal stabilization of a TNBBAc-Φ duplex via strong intercalative stacking interaction alongside an abasic site. The UV-visible spectroscopic study supported the intercalative stacking interaction. The stabilization though is marginal, but it would shed light on the design of bases of significant volume to stabilise abasic DNA to a greater extent.

Design of "Click" Fluorescent Labeled 2'-deoxyuridines via C5-[4-(2-Propynyl(methyl)amino)]phenyl Acetylene as a Universal Linker: Synthesis, Photophysical Properties, and Interaction with BSA.

Microenvironment-sensitive fluorescent nucleosides present attractive advantages over single-emitting dyes for sensing inter-biomolecular interactions involving DNA. Herein, we report the rational design and synthesis of triazolyl push-pull fluorophore-labeled uridines via the intermediacy of C5-[4-(2-propynyl(methyl)amino)]phenyl acetylene as a universal linker. The synthesized nucleosides showed interesting solvatochromic characteristic and/or intramolecular charge transfer (ICT) features. A few of them also exhibited dual-emitting characteristics evidencing our designing concept. The HOMO-LUMO distribution showed that the emissive states of these nucleosides were characterized with more significant electron redistribution between the C5-[4-(2-propynyl(methyl)amino)]phenyl triazolyl donor moiety and the aromatic chromophores linked to it, leading to modulated emission property. The solvent polarity sensitivity of these nucleosides was also tested. The synthesized triazolyl benzonitrile (10C), naphthyl (10E), and pyrenyl (10G) nucleosides were found to exhibit interesting ICT and dual (LE/ICT) emission properties. The dual-emitting pyrenyl nucleoside maintained a good ratiometric response in the BSA protein microenvironment, enabling the switch-on ratiometric sensing of BSA as the only protein biomolecule. Thus, it is expected that the new fluorescent nucleoside analogues would be useful in designing DNA probes for nucleic acid analysis or studying DNA-protein interactions via a drastic change in fluorescence response due to a change in micropolarity.