Cellular uptake of 2‐aminopyridine‐modified peptide nucleic acids conjugated with cell‐penetrating peptides

Brodyagin, Nikita; Kataoka, Yuka; Kumpiņa, Ilze; McGee, Dennis W.; Rozners, Eriks

doi:10.1002/bip.23484

Cited by 7 publications

(8 citation statements)

References 53 publications

(98 reference statements)

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“…Thus, substituting the nucleic acid bases with identical aminothiazole moieties enabled cellular uptake of the PNA like Thz-3 ligand. Such observations are consistent with previous reports (only a few) on enhanced cellular permeability of base-modified PNAs compared to unmodified ones. ,, …”

Section: Resultssupporting

confidence: 94%

“…Such observations are consistent with previous reports (only a few) on enhanced cellular permeability of base-modified PNAs compared to unmodified ones. 18,45,46 Thz-3 Mediated Downregulation of c-MYC Expression. The transcriptional arrest by ligands Thz-2 and Thz-3 was investigated in HeLa cells (Figures 3b and S20).…”

Section: ■ Results and Discussionmentioning

confidence: 99%

“…For instance, introduction of 2-aminopyridine as the nucleobase in triplex-forming PNAs or incorporation of guanidine groups to the PNA backbone led to increased stability as well as cellular permeation . It has been shown that conjugation of cell-penetrating peptides like Tat peptides or addition of arginine or lysine side chains to PNAs stimulated their cellular permeation like naturally occurring proteins . However, there is evidence of accumulation of peptide conjugated PNAs in the endosomes resulting in decreased functional activities …”

Section: Introductionmentioning

confidence: 99%

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Thiazole Containing PNA Mimic Regulates c-MYC Gene Expression through DNA G-Quadruplex

et al. 2022

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Peptide nucleic acids (PNAs), besides hybridizing to complementary DNA and RNAs, bind and stabilize DNA secondary structures. Herein, we illustrate the design and synthesis of PNA-like scaffolds by incorporating five-membered thiazole rings as modified bases instead of nucleobases and their subsequent effects on gene regulation by biophysical and in vitro assays. A thiazole-modified PNA trimer selectively recognizes c-MYC G-quadruplex (G4) DNA over other G4s and duplex DNA.It displays a high stabilization potential for the c-MYC G4 DNA and shows remarkable fluorescence enhancement with the c-MYC G4. It is flexible enough to bind at 5′ and 3′ ends as well as in the groove region of c-MYC G4. Furthermore, the PNA trimer easily permeates the cellular membrane and suppresses c-MYC mRNA expression in HeLa cells by targeting the promoter G4. This study illuminates modified PNAs as flexible molecular tools for selective targeting of noncanonical nucleic acids and modulating gene function.

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Section: Resultssupporting

confidence: 94%

Section: ■ Results and Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Thiazole Containing PNA Mimic Regulates c-MYC Gene Expression through DNA G-Quadruplex

et al. 2022

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“…Similar to L, M did not form Watson–Crick base pairs with any of the natural nucleobases minimizing off-target binding to single stranded nucleic acids . Moreover, the partial charge improves cellular uptake of M-modified PNAs, most likely due to resemblance of arginine structure that stimulates endocytosis and may be enhancing endosomal escape through a proton sponge mechanism . M-modified triplex forming PNAs are easy to synthesize and have already been used by us and others to direct RNA-specific templated reactions, suppress mRNA translation, inhibit microRNA maturation, and control conformation of dynamic structures of RNA bulges .…”

Section: Introductionmentioning

confidence: 99%

“…21 Moreover, the partial charge improves cellular uptake of M-modified PNAs, 22 most likely due to resemblance of arginine structure that stimulates endocytosis and may be enhancing endosomal escape through a proton sponge mechanism. 23 M-modified triplex forming PNAs are easy to synthesize 24 and have already been used by us and others to direct RNA-specific templated reactions, 25 suppress mRNA translation, 26 inhibit microRNA maturation, 27 and control conformation of dynamic structures of RNA bulges. 28 In our hands, M has become the most impactful PNA modification that both enables strong and selective binding to dsRNA and improves the cellular uptake of triplex-forming PNAs.…”

Section: ■ Introductionmentioning

confidence: 99%

Comparison of 2-Aminopyridine and 4-Thiopseudisocytosine PNA Nucleobases for Hoogsteen Recognition of Guanosine in RNA

Kumpina,

Loubidi,

Rozners

2024

ACS Omega

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Peptide nucleic acid (PNA) is emerging as a promising ligand for triple-helical recognition of folded biologically relevant RNA. Chemical modifications are actively being developed to achieve high affinity and sequence specificity under physiological conditions. In this study, we compared two modified PNA nucleobases, 2-aminopyridine (M) and 4-thiopseudisocytosine (L), as alternatives to protonated cytosine (unfavorable under physiological conditions), to form more stable triplets than C+·G-C. Both nucleobases formed M+·G-C and L·G-C triplets of similar stability; however, the L-modified PNAs showed somewhat reduced sequence specificity. In conclusion, M and L represent two alternative solutions to the problem of cytosine protonation in triple-helical recognition of RNA. In M, the pK a is increased to favor partial protonation, which improves solubility and cellular uptake of M-modified PNAs. In L, the sulfur substitution enhances favorable hydrophobic interactions, which may have advantages in avoiding off-target effects that may be caused by cationic modifications. However, our results showed that substituting Ms with Ls did not restore the sequence specificity of a PNA containing cationic groups.

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Peptide Nucleic Acids: From Origami to Editing

Carson,

Watson

2024

ChemPlusChem

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Peptide nucleic acids (PNAs) combine the programmability of native nucleic acids with the robustness and ease of synthesis of a peptide backbone. These designer biomolecules have demonstrated tremendous utility across a broad range of applications, from the formation of bespoke biosupramolecular architectures to biosensing and gene regulation. Herein, we explore some of the key developments in the application of PNA in chemical biology and biotechnology in the last 5 years and present anticipated key areas of future development.

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Cellular uptake of 2‐aminopyridine‐modified peptide nucleic acids conjugated with cell‐penetrating peptides

Cited by 7 publications

References 53 publications

Thiazole Containing PNA Mimic Regulates c-MYC Gene Expression through DNA G-Quadruplex

Thiazole Containing PNA Mimic Regulates c-MYC Gene Expression through DNA G-Quadruplex

Comparison of 2-Aminopyridine and 4-Thiopseudisocytosine PNA Nucleobases for Hoogsteen Recognition of Guanosine in RNA

Peptide Nucleic Acids: From Origami to Editing

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