Abstract
Polypurine reverse-Hoogsteen (PPRH) oligonucleotides are non-modified DNA molecules composed of two mirror-symmetrical polypurine stretches linked by a five-thymidine loop. They can fold into reverse-Hoogsteen hairpins and bind to their polypyrimidine target sequence by Watson-Crick bonds forming a three-stranded structure. They have been successfully used to knockdown gene expression and to repair single-point mutations in cells. In this work, we provide an in vitro characterization (UV and fluorescence spectroscopy, gel electrophoresis and nuclease assays) of the structure and stability of two repair-PPRH oligonucleotides and of the complexes they form with their single-stranded targets. We show that one PPRH oligonucleotide forms a hairpin, while the other folds, in potassium, into a guanine-quadruplex (G4). However, the hairpin-prone oligonucleotide does not form a triplex with its single-stranded target, while the G4-prone oligonucleotide converts from a G4 into a reverse-Hoogsteen hairpin forming a triplex with its target sequence. Our work proves, in particular, that folding of a PPRH oligonucleotide into a G4 does not necessarily impair sequence-specific DNA recognition by triplex formation. It also illustrates an original example of DNA structural conversion of a G4 into a reverse-Hoogsteen hairpin driven by triplex formation; this kind of conversion might occur at particular loci of genomic DNA.
Highlights
Our group succeeded in repairing single point mutations in cells using synthetic oligonucleotides that we named Polypurine reverse-Hoogsteen (PPRH) oligonucleotides[22,23,24]
Our interest now is to carefully investigate the secondary structures and stabilities of PPRH and repair-PPRH oligonucleotides and of the complexes they form with their single-stranded target sequences
To gain insight into the structures formed by HpE6 and HpE2 oligonucleotides and their stabilities, we carried out an investigation by ultraviolet light (UV)-absorption and fluorescence spectroscopy under different ionic conditions (100 mM NaCl or KCl, in the absence or in the presence of 10 mM MgCl2) and by non-denaturing polyacrylamide gel electrophoresis (PAGE)
Summary
Our group succeeded in repairing single point mutations in cells using synthetic oligonucleotides that we named Polypurine reverse-Hoogsteen (PPRH) oligonucleotides[22,23,24]. Each of the two repair-PPRH oligonucleotides, HpE6rep[6] and HpE2rep[2], is composed of a PPRH motif (HpE6 and HpE2, respectively) designed to target a polypyrimidine/polypurine tract next to the dhfr gene sequence to be repaired, and of a 25 nucleotide single-stranded extension (rep[6] and rep[2], respectively) homologous to the sequence to be repaired (Table 1). In particular we show that HpE2 folds, in potassium, into a stable G4; in the presence of its single-stranded polypyrimidine target sequence, it converts into a reverse-Hoogsteen hairpin and forms a triplex. Besides elucidating the structure of the two repair-PPRH oligonucleotides and of the complexes they form with their targets, our work proves that folding of a PPRH oligonucleotide into a stable G4 does not necessarily impair sequence-specific DNA recognition by triplex formation. We suggest that this kind of conversion might spontaneously occur at particular loci of genomic DNA and be involved in genome dynamics
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