Supramolecular polyplexes from Janus peptide nucleic acids (bm-PNA-G5): self-assembled bm-PNA G-quadruplex and its tetraduplex with DNA

Abstract

Nucleic acids (DNA and RNA) can form diverse secondary structures ranging from hairpins to duplex, triplex, G4-tetraplex and C4-i-motifs. Many of the DNA analogues designed as antisense oligonucleotides (ASO) are also adept at embracing such folded structures, although to different extents with altered stabilities. One such analogue, peptide nucleic acid (PNA), which is uncharged and achiral, forms hybrids with complementary DNA/RNA with greater stability and specificity than DNA:DNA/RNA hybrids. Like DNAs, these single-stranded PNAs can form PNA:DNA/RNA duplexes, PNA:DNA:PNA triplexes, PNA-G4 tetraplexes and PNA-C4-i-motifs. We have recently designed Janus-like bimodal PNAs endowed with two different nucleobase sequences on either side of a single aminoethylglycyl (aeg) PNA backbone and shown that these can simultaneously bind to two complementary DNA sequences from both faces of PNA. This leads to the formation of supramolecular polyplexes such as double duplexes, triple duplexes and triplexes of double duplexes with appropriate complementary DNA/RNA. Herein, we demonstrate that Janus/bimodal PNA with a poly G-sequence on the triazole side of the PNA backbone and mixed bases on the t-amide side, templates the initial formation of a (PNA-G5)₄ tetraplex (triazole side), followed by the formation of a PNA:DNA duplex (t-amide side). Such a polyplex shows synergistic overall stabilisation compared to the isolated duplexes/quadruplex. The assembly of polyplexes with a shared backbone for duplexes and tetraplexes is programmable and may have potential applications in the self-assembly of nucleic acid nano- and origami structures. It is also shown that Janus PNAs enter the cells better than the standard aeg-PNA oligomers, and hence have implications for in vivo applications as well.