Triplex‐Forming Peptide Nucleic Acids with Extended Backbones

Kumar, Vipin; Brodyagin, Nikita; Rozners, Eriks

doi:10.1002/cbic.202000432

Cited by 11 publications

(10 citation statements)

References 39 publications

(48 reference statements)

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“…We synthesized six PNAs having modified nucleobases with various fluorine substitution patterns (PNAX, Figure 2) ranging from none (X=F0) to fully substituted pentafluorobeznene (X=F5). PNA monomers were synthesized using our previously reported methods starting from commercially available substituted phenylacetic acids (for details, see Supporting Information) [9–10,19] …”

Section: Resultsmentioning

confidence: 99%

“…PNA monomers were synthesized using our previously reported methods starting from commercially available substituted phenylacetic acids (for details, see Supporting Information). [9][10]19] We evaluated the stability and specificity of base triplets involving fluorinated benzenes using UV thermal melting of the triple helices formed between model hairpins and modified PNAs. UV thermal melting is a common technique to measure stability of nucleic acid secondary structures; however, for triple helices the measurements may be complicated by overlap between the triplex to duplex and duplex to single strands transitions.…”

Section: Resultsmentioning

confidence: 99%

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Fluorobenzene Nucleobase Analogues for Triplex‐Forming Peptide Nucleic Acids

Kumar

Rozners

2021

ChemBioChem

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2,4‐Difluorotoluene is a nonpolar isostere of thymidine that has been used as a powerful mechanistic probe to study the role of hydrogen bonding in nucleic acid recognition and interactions with polymerases. In the present study, we evaluated five fluorinated benzenes as nucleobase analogues in peptide nucleic acids designed for triple helical recognition of double helical RNA. We found that analogues having para and ortho fluorine substitution patterns (as in 2,4‐difluorotoluene) selectively stabilized Hoogsteen triplets with U−A base pairs. The results were consistent with attractive electrostatic interactions akin to non‐canonical F to H−N and C−H to N hydrogen bonding. The fluorinated nucleobases were not able to stabilize Hoogsteen‐like triplets with pyrimidines in either G−C or A−U base pairs. Our results illustrate the ability of fluorine to engage in non‐canonical base pairing and provide insights into triple helical recognition of RNA.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Fluorobenzene Nucleobase Analogues for Triplex‐Forming Peptide Nucleic Acids

Kumar

Rozners

2021

ChemBioChem

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“…Not surprisingly, backbone modification has been a major focus of follow up attempts to improve the original PNA design. Early studies showed that maintaining proper distances (number of bonds) along the backbone and be-tween the backbone and nucleobases of PNA was critical for effective nucleic acid binding as extension of either by additional methylene groups strongly decreased the binding affinity of PNA to either single-or double-stranded nucleic acids [46][47][48]. Furthermore, replacing amide linkages connecting the PNA's backbone and the nucleobase with a tertiary amine also destabilized PNA complexes with complementary DNA [49].…”

Section: Pna Backbone Modificationsmentioning

confidence: 99%

Chemical approaches to discover the full potential of peptide nucleic acids in biomedical applications

Brodyagin

Katkevičs

Kotikam

et al. 2021

Beilstein J. Org. Chem.

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Peptide nucleic acid (PNA) is arguably one of the most successful DNA mimics, despite a most dramatic departure from the native structure of DNA. The present review summarizes 30 years of research on PNA’s chemistry, optimization of structure and function, applications as probes and diagnostics, and attempts to develop new PNA therapeutics. The discussion starts with a brief review of PNA’s binding modes and structural features, followed by the most impactful chemical modifications, PNA enabled assays and diagnostics, and discussion of the current state of development of PNA therapeutics. While many modifications have improved on PNA’s binding affinity and specificity, solubility and other biophysical properties, the original PNA is still most frequently used in diagnostic and other in vitro applications. Development of therapeutics and other in vivo applications of PNA has notably lagged behind and is still limited by insufficient bioavailability and difficulties with tissue specific delivery. Relatively high doses are required to overcome poor cellular uptake and endosomal entrapment, which increases the risk of toxicity. These limitations remain unsolved problems waiting for innovative chemistry and biology to unlock the full potential of PNA in biomedical applications.

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“…Binding data suggest that increasing the length of the backbone or the backbone‐base linker significantly weakens the binding of PNAs to dsRNAs, ssRNAs, and dsDNAs. [ 64,71 ] NMR and fluorescence studies suggest that attaching a γ‐(R)‐hydroxymethyl group to PNAs containing bases T, M, and E results in a reduced PNA•dsRNA triplex formation and an enhanced invasion of a dsRNA to form a PNA•RNA‐PNA triplex. [ 55,72 ] Clearly, base modifications (Figures 3–7) combined with backbone/linker modifications (Figure 1) would allow the development of optimized PNA‐based scaffolds for the specific recognition of dsRNAs.…”

Section: Sequence‐specific Recognition Of Dsrnasmentioning

confidence: 99%

Mechanisms and applications of peptide nucleic acids selectively binding to double‐stranded RNA

2021

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RNAs form secondary structures containing double‐stranded base paired regions and single‐stranded regions. Probing, detecting and modulating RNA structures and dynamics requires the development of molecular sensors that can differentiate the sequence and structure of RNAs present in viruses and cells, as well as in extracellular space. In this review, we summarize the recent progress on the development of chemically modified peptide nucleic acids (PNAs) for the selective recognition of double‐stranded RNA (dsRNA) sequences over both single‐stranded RNA (ssRNA) and double‐stranded DNA (dsDNA) sequences. We also briefly discuss the applications of sequence‐specific dsRNA‐binding PNAs in sensing and stabilizing dsRNA structures and inhibiting dsRNA‐protein interactions.

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Triplex‐Forming Peptide Nucleic Acids with Extended Backbones

Cited by 11 publications

References 39 publications

Fluorobenzene Nucleobase Analogues for Triplex‐Forming Peptide Nucleic Acids

Fluorobenzene Nucleobase Analogues for Triplex‐Forming Peptide Nucleic Acids

Chemical approaches to discover the full potential of peptide nucleic acids in biomedical applications

Mechanisms and applications of peptide nucleic acids selectively binding to double‐stranded RNA

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