General Recognition of U-G, U-A, and C-G Pairs by Double-Stranded RNA-Binding PNAs Incorporated with an Artificial Nucleobase.

Chemically modified peptide nucleic acids (PNAs) show great promise in the recognition of RNA duplexes by major-groove PNA·RNA-RNA triplex formation. Triplex formation is favored for RNA duplexes with a purine tract within one of the RNA duplex strands, and is severely destabilized if the purine tract is interrupted by pyrimidine residues. Here, we report the synthesis of a PNA monomer incorporated with an artificial nucleobase S, followed by the binding studies of a series of S-modified PNAs. Our data suggest that an S residue incorporated into short 8-mer dsRNA-binding PNAs (dbPNAs) can recognize internal Watson-Crick C-G and U-A, and wobble U-G base pairs (but not G-C, A-U, and G-U pairs) in RNA duplexes. The short S-modified PNAs show no appreciable binding to DNA duplexes or single-stranded RNAs. Interestingly, replacement of the C residue in an S·C-G triple with a 5-methyl C results in the disruption of the triplex, probably due to a steric clash between S and 5-methyl C. Previously reported PNA E base shows recognition of U-A and A-U pairs, but not a U-G pair. Thus, S-modified dbPNAs may be uniquely useful for the general recognition of RNA U-G, U-A, and C-G pairs. Shortening the succinyl linker of our PNA S monomer by one carbon atom to have a malonyl linker causes a severe destabilization of triplex formation. Our experimental and modeling data indicate that part of the succinyl moiety in a PNA S monomer may serve to expand the S base forming stacking interactions with adjacent PNA bases.

[A new toolbox for genome editing]. / Modification ciblée du génome : une nouvelle approche prometteuse - Chroniques génomiques.

A new approach, based on the use of peptide nucleic acid molecules to form triple helices and promote locus-specific recombination, demonstrates potential for in vivo gene correction at clinically significant levels and may provide a promising avenue for gene therapy.

Strand invasion of mixed-sequence, double-helical B-DNA by γ-peptide nucleic acids containing G-clamp nucleobases under physiological conditions.

Peptide nucleic acids (PNAs) make up the only class of nucleic acid mimics developed to date that has been shown to be capable of invading double-helical B-form DNA. Recently, we showed that sequence limitation associated with PNA recognition can be relaxed by utilizing conformationally preorganized γ-peptide nucleic acids (γPNAs). However, like all the previous studies, with the exception of triplex binding, DNA strand invasion was performed at relatively low salt concentrations. When physiological ionic strengths were used, little to no binding was observed. On the basis of this finding, it was not clear whether the lack of binding is due to the lack of base pair opening or the lack of binding free energy, either of which would result in no productive binding. In this work, we show that it is the latter. Under simulated physiological conditions, the DNA double helix is sufficiently dynamic to permit strand invasion by the designer oligonucleotide molecules provided that the required binding free energy can be met. This finding has important implications for the design oligonucleotides for recognition of B-DNA via direct Watson-Crick base pairing.

Characterization of a novel cytotoxic cell-penetrating peptide derived from p14ARF protein.

The tumor suppressor p14ARF is widely deregulated in many types of cancers and is believed to function as a failsafe mechanism, inhibiting proliferation and inducing apoptosis as cellular response to a high oncogene load. We have found that a 22-amino-acid-long peptide derived from the N-terminal part of p14ARF, denoted ARF(1-22), which has previously been shown to mimic the function of p14ARF, has cell-penetrating properties. This peptide is internalized to the same extent as the cell-penetrating peptide (CPP) TP10 and dose-dependently decreases proliferation in MCF-7 and MDA MB 231 cells. Uptake of the ARF(1-22) peptide is associated with low membrane disturbance, measured by deoxyglucose and lactate dehydrogenase (LDH) leakage, as compared to its scrambled peptide. Also, flow cytometric analysis of annexin V/propidium iodide (PI) binding and Hoechst staining of nuclei suggest that ARF(1-22) induces apoptosis, whereas scrambled or inverted peptide sequences have no effect. The ARF(1-22) peptide mainly translocates cells through endocytosis, and is found intact inside cells for at least 3 hours. To our knowledge, this is the first time a CPP having pro-apoptopic activity has been designed from a protein.

[The peptide nucleic acids (PNAs): "high-tech" probes for genetic and molecular cytogenetic investigations]. / Les PNA (peptide nucleic acids) : des sondes high-tech pour l'analyse génétique et cytogénétique moléculaire.

The peptide nucleic acids (PNAs) constitute a remarkable new class of synthetic nucleic acids analogs, in which the sugar phosphate backbone is replaced by repeating N-(2-aminoethyl) glycine units linked by amine bonds and to which the nucleobases are fixed. This structure gives to PNAs the capacity to hybridize with high affinity and specificity to complementary RNA and DNA sequences, and a great resistance to nucleases and proteinases. Originally conceived as ligands for the study of double stranded DNA, the unique physico-chemical properties of PNAs have led to the development of a large variety of research and diagnostic assays, including antigene and antisense therapy and genome mapping. Several sensitive and robust PNA-dependent methods have been designed for modulating polymerase chain reactions, detecting genomic polymorphisms and mutations or capturing nucleic acids. Over the last few years, the use of PNAs has proven its powerful usefulness in cytogenetics for the rapid in situ identification of human chromosomes and the detection of aneuploidies. Recent studies have reported the successful use of chromosome-specific PNA probes on human lymphocytes, amniocytes, spermatozoa as well as on isolated oocytes and blastomeres. Muticolor PNA protocols have been described for the identification of several human chromosomes, indicating that PNAs could become a powerful tool for in situ chromosomal investigation.

Peptide nucleic acid-mediated competitive PCR clamping for detection of rifampin-resistant Mycobacterium tuberculosis.

Peptide nucleic acid-mediated competitive PCR clamping, which can selectively amplify mutant alleles, was developed to detect mutations in four codons (513, 516, 526, and 531) of the rpoB gene in Mycobacterium tuberculosis strains. This simple method successfully identified the mutations in all 40 of the M. tuberculosis strains tested.

PNA targeting the PBS and A-loop sequences of HIV-1 genome destabilizes packaged tRNA3(Lys) in the virions and inhibits HIV-1 replication.

During assembly of the HIV-1 virions, cellular tRNA(Lys)(3) is packaged into the virion particles and is utilized as a primer for the initiation of reverse transcription. The 3'-terminal 18 nucleotides of the cellular tRNA(Lys)(3) are complementary to nucleotides 183-201 of the viral RNA genome, referred to as the primer binding sequence (PBS). Additional sequences (A-Loop) upstream of the PBS are essential for tRNA primer selection. We report here that a PNA targeted to PBS and A-Loop sequence (PNA(PBS)) exhibits high specificity for its target sequence and prevents tRNA(Lys)(3) priming on the viral genome. We also demonstrate that PNA(PBS) is able to invade the duplex region of the tRNA(Lys)(3)-viral RNA complex and destabilize the priming process, thereby inhibiting the in vitro initiation of reverse transcription. The endogenously packaged tRNA(Lys)(3) bound to the PBS region of the viral RNA genome in the HIV-1 virion is efficiently competed out by PNA(PBS), resulting in near complete inhibition of initiation of endogenous reverse transcription. Examination of the effect of PNA(PBS) on HIV-1 production in CEM cells infected with pseudotyped HIV-1 virions carrying luciferase reporter exhibited dramatic reduction of HIV-1 replication by nearly 99%. Analysis of the mechanism of PNA(PBS)-mediated inhibition indicated that PNA(PBS) interferes at the step of reverse transcription. These findings suggest the antiviral efficacy of PNA(PBS) in blocking the process of HIV-1 replication.

Intraperitoneal injection of antisense peptide nucleic acids targeted to the mu receptor decreases response to morphine and receptor protein levels in rat brain.

To determine the effectiveness of peptide nucleic acids (PNAs) in vivo, we designed and synthesized PNAs antisense to the mu receptor, the molecular target of morphine for inducing antinociception. Responsiveness of rats to morphine and the levels of mu receptor expression after treatment was measured. We delivered intraperitoneal injections of antisense PNAs targeted to the mu receptor (AS-MOR), mismatch PNAs (AS-MOR MM), antisense PNAs targeted to the neurotensin receptor subtype 1 (AS-NTR1), or saline and then challenged the rats with 5 mg/kg morphine (intraperitonally) or neurotensin directly into the periaqueductal gray region of the brain. To avoid tolerance, separate groups of animals were tested at 24, 48, and 72 h post-PNA treatment. Only animals treated with the AS-MOR showed a reduction in their antinociceptive response to morphine. The lack of effect of morphine on the AS-MOR rats was profound at 24 and 48 h, but animals tested at 72 h were similar to control groups. At 24 h the AS-MOR rats had a significant 55% decrease in the levels of mu receptor in their periaqueductal gray region, while AS-MOR MM rats showed no significant change. Lastly, the AS-MOR rats continued to show a normal antinociceptive response to neurotensin. This study, therefore, provides additional support for the use of PNAs to target proteins within brain by systemically administered PNAs.