The Lack of Mutagenic Potential of a Guanine-Rich Triplex Forming Oligonucleotide in Physiological Conditions

Saleh, Amer F.; Fellows, Mick D.; Ying, Liming; Gooderham, Nigel J.; Priestley, Catherine

doi:10.1093/toxsci/kfw179

Cited by 2 publications

(11 citation statements)

References 41 publications

(27 reference statements)

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“…We carried out the Triplex-seq experiments in two different buffers: pH 7, and triplex-disfavoring high potassium pH 7, with a TTS (TTS-1; see Table ) that was previously shown using EMSA to form a triplex with a specific TFO. High potassium buffers are triplex-disfavoring, and instead have been shown to stabilize G-quadruplex structures. − After sequencing, we counted the number of normalized reads that were attained for each variant for both the triplex and TFO-only control lane and plotted them in Figure C (left).…”

Section: Resultsmentioning

confidence: 99%

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An Oligo-Library-Based Approach for Mapping DNA–DNA Triplex Interactions In Vitro

et al. 2021

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We present Triplex-seq, a deep-sequencing method that systematically maps the interaction space between an oligo library of ssDNA triplex-forming oligos (TFOs) and a particular dsDNA triplex target site (TTS). We demonstrate the method using a randomized oligo library comprising 67 million variants, with five TTSs that differ in guanine (G) content, at two different buffer conditions, denoted pH 5 and pH 7. Our results show that G-rich triplexes form at both pH 5 and pH 7, with the pH 5 set being more stable, indicating that there is a subset of TFOs that form triplexes only at pH 5. In addition, using information analysis, we identify triplex-forming motifs (TFMs), which correspond to minimal functional TFO sequences. We demonstrate, in single-variant verification experiments, that TFOs with these TFMs indeed form a triplex with G-rich TTSs, and that a single mutation in the TFM motif can alleviate binding. Our results show that deepsequencing platforms can substantially expand our understanding of triplex binding rules and aid in refining the DNA triplex code.

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Section: Resultsmentioning

confidence: 99%

“…Here the “-” denotes Watson–Crick base-pairing between the purine base R and its pyrimidine pair Y, and “*” denotes Hoogstein interaction. TFOs have subsequently been used to identify triplex rules , and have been utilized as biotechnological tools in vitro and in vivo . − …”

Section: Introductionmentioning

confidence: 99%

An Oligo-Library-Based Approach for Mapping DNA–DNA Triplex Interactions In Vitro

et al. 2021

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“…We next sought to evaluate which TFO sequences will be enriched when testing the ~ 270,000,000 large N-TFO library (Figure 3a, top). We used two known TTSs (pH 5: TTS 2) 41 and (pH 7: TTS 1) 24 as our test targets ( Figure 3a, middle and bottom) alongside the N-TFO library to determine the migration pattern of duplexes and triplexes in various buffer conditions. In Figure 3b, we plot the mean nucleotide frequency of the enriched TFO sequences against the triplex reactivities for pH 5 (Figure 3b, left) and pH 7 (Figure 3b, right) and observe a G-increase in the TFO sequences with higher triplex reactivities for both conditions.…”

Section: G-rich Tfos Are Enriched In a Random Tfo Librarymentioning

confidence: 99%

“…In Figure 3b, we plot the mean nucleotide frequency of the enriched TFO sequences against the triplex reactivities for pH 5 (Figure 3b, left) and pH 7 (Figure 3b, right) and observe a G-increase in the TFO sequences with higher triplex reactivities for both conditions. To further characterize the behavior of the N-TFO, we additionally applied the Triplex-Seq platform in a buffer that negatively affects triplex formation due to the presence of monovalent ions ( Figure 3c) 24,42 . In Figure 3d the triplex reactivities of both TTS sequences in the triplex-disfavoring buffer are plotted and we observe again a trend toward Grich sequences with higher triplex reactivities, but this effect is weaker as compared to the conditions lacking potassium ( Figure 3b).…”

Section: G-rich Tfos Are Enriched In a Random Tfo Librarymentioning

confidence: 99%

“…Due to their specificity in targeting dsDNA, TFOs were subsequently used to identify triplex rules 13,14 and applied as biotechnological tools in vitro and in vivo to regulate transcription [15][16][17][18] , control recombination events 19 and induce triplex-directed mutagenesis [20][21][22] . Despite extensive amount of work to establish TFOs as therapeutic agents, triplex formation in vivo mostly was attenuated and the expected biological function was limited 23,24 .…”

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Identifying triplex binding rulesin vitroleads to creation of a new synthetic regulatory toolin vivo

Kaufmann

Willinger

Eden

et al. 2019

Preprint

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Nature provides a rich toolbox of dynamic nucleic acid structures that are widespread in cells and affect multiple biological processes 1 . Recently, non-canonical structures gained renewed scientific and biotechnological interest 2,3 . One particularly intriguing form of such structures are triplexes 4 in which a single-stranded nucleic acid molecule interacts via Hoogsteen bonds with a DNA/RNA double helix 5 . Despite extensive research in vitro 6-9 , the underlying rules for triplex formation remain debated and evidence for triplexes in vivo is circumstantial 10-12 . Here, we demonstrate the development of a deep-sequencing platform termed Triplex-Seq to systematically refine the DNA triplex code and identify high affinity triplex forming oligo (TFO)variants. We identified a preference for short G-rich motifs using an oligo-library with a mix of all four bases. These high-information content motifs formed specific high-affinity triplexes in a pH-independent manner and stability was increased with G-rich double-stranded molecules. We then conjugated one high-affinity and one low-affinity variant to a VP48 peptide and studied these synthetic biomolecules in mammalian cells. Using these peptide-oligo constructs (POCs), we demonstrated possible triplex-induced down-regulation activity in 544 differentially expressed genes. Our results show that deep-sequencing platforms can substantially expand our understanding of triplex binding rules, which in turn has led to the development of a functional non-genetically encoded regulatory tool for in vivo applications.

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The Lack of Mutagenic Potential of a Guanine-Rich Triplex Forming Oligonucleotide in Physiological Conditions

Cited by 2 publications

References 41 publications

An Oligo-Library-Based Approach for Mapping DNA–DNA Triplex Interactions In Vitro

An Oligo-Library-Based Approach for Mapping DNA–DNA Triplex Interactions In Vitro

Identifying triplex binding rulesin vitroleads to creation of a new synthetic regulatory toolin vivo

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