Stabilization of multi-stranded nucleic acid structures using 3'-S-phosphorothiolate linkages

Stabilization of an intermolecular i-motif by lipid modification of cytosine-oligodeoxynucleotides

This paper describes the stabilization of an intermolecular i-motif by lipophilic modification on the 3'-terminus of oligonucleotides. The hydrophobic aliphatic chain connected at the 3'-terminus of a trinucleotide (dC)3 promoted the formation of an i-motif and significantly enhanced the quadruplex's stability. The impact of lipophilic modification on i-motif's thermal stability was studied by UV-thermal denaturation melting experiments and isothermal titration calorimetry. We found that alkyl chains containing more than 14 carbon atoms could elevate the i-motif structure's stability in a wide range of pH and concentrations.

Improved i-motif thermal stability by insertion of anthraquinone monomers

In order to gain insight into how to improve thermal stability of i-motifs when used in the context of biomedical and nanotechnological applications, novel anthraquinone-modified i-motifs were synthesized by insertion of 1,8-, 1,4-, 1,5- and 2,6-disubstituted anthraquinone monomers into the TAA loops of a 22mer cytosine-rich human telomeric DNA sequence. The influence of the four anthraquinone linkers on the i-motif thermal stability was investigated at 295 nm and pH 5.5. Anthraquinone monomers modulate the i-motif stability in a position-depending manner and the modulation also depends on the substitution pattern of the anthraquinone. The insertion of anthraquinone was found to stabilize the i-motif structure when replacing any one of the positions of the central TAA loop and the thermal stabilities were typically higher than those previously found for i-motifs containing pyrene-modified uracilyl unlocked nucleic acid monomers or twisted intercalating nucleic acid. The 2,6-disubstituted anthraquinone linker replacing T₁₀ enabled a significant increase of i-motif thermal melting by 8.2 °C. A substantial increase of 5.0 °C in i-motif thermal melting was recorded when both A₆ and T₁₆ were modified with a double replacement by the 2,6-isomer into the TAA loops in the outer regions. The largest destabilization is observed for the 1,5-disubstituted anthraquinone linker upon the replacement of A₁₈. CD curves of anthraquinone-modified variants imply no structural changes in all cases under potassium buffer conditions compared with those of the native i-motif. Molecular modeling studies explained the increased thermal stabilities of anthraquinone-modified i-motifs.

Fundamental aspects of the nucleic acid i-motif structures

The latest research on fundamental aspects of i-motif structures is reviewed with special attention to their hypothetical rolein vivo.

Modulation of i-motif thermodynamic stability by the introduction of UNA (unlocked nucleic acid) monomers

The influence of acyclic RNA derivatives, UNA (unlocked nucleic acid) monomers, on i-DNA thermodynamic stability has been investigated. The 22nt human telomeric fragment was chosen as the model sequence for stability studies. UNA monomers modulate i-motif stability in a position-depending manner. The largest destabilization is observed for position C14, while UNA placed in position A12 causes significant increase of i-DNA thermodynamic stability. CD curves of UNA-modified variants imply no structural changes relative to the native i-motif.