Non-Watson-Crick interactions between PNA and DNA inhibit the ATPase activity of bacteriophage T4 Dda helicase

Peptide nucleic acid (PNA) is a DNA mimic in which the nucleobases are linked by an N-(2-aminoethyl) glycine backbone. Here we report that PNA can interact with single-stranded DNA (ssDNA) in a non-sequence-specific fashion. We observed that a 15mer PNA inhibited the ssDNA-stimulated ATPase activity of a bacteriophage T4 helicase, Dda. Surprisingly, when a fluorescein-labeled 15mer PNA was used in binding studies no interaction was observed between PNA and Dda. However, fluorescence polarization did reveal non-sequence-specific interactions between PNA and ssDNA. Thus, the inhibition of ATPase activity of Dda appears to result from depletion of the available ssDNA due to non-Watson–Crick binding of PNA to ssDNA. Inhibition of the ssDNA-stimulated ATPase activity was observed for several PNAs of varying length and sequence. To study the basis for this phenomenon, we examined self-aggregation by PNAs. The 15mer PNA readily self-aggregates to the point of precipitation. Since PNAs are hydrophobic, they aggregate more than DNA or RNA, making the study of this phenomenon essential for understanding the properties of PNA. Non-sequence-specific interactions between PNA and ssDNA were observed at moderate concentrations of PNA, suggesting that such interactions should be considered for antisense and antigene applications.     

End invasion of peptide nucleic acids (PNAs) with mixed-base composition into linear DNA duplexes

Peptide nucleic acid (PNA) is a synthetic DNA mimic with valuable properties and a rapidly growing scope of applications. With the exception of recently introduced pseudocomplementary PNAs, binding of common PNA oligomers to target sites located inside linear double-stranded DNAs (dsDNAs) is essentially restricted to homopurine–homopyrimidine sequence motifs, which significantly hampers some of the PNA applications. Here, we suggest an approach to bypass this limitation of common PNAs. We demonstrate that PNA with mixed composition of ordinary nucleobases is capable of sequence-specific targeting of complementary dsDNA sites if they are located at the very termini of DNA duplex. We then show that such targeting makes it possible to perform capturing of designated dsDNA fragments via the DNA-bound biotinylated PNA as well as to signal the presence of a specific dsDNA sequence, in the case a PNA beacon is employed. We also examine the PNA–DNA conjugate and prove that it can initiate the primer-extension reaction starting from the duplex DNA termini when a DNA polymerase with the strand-displacement ability is used. We thus conclude that recognition of duplex DNA by mixed-base PNAs via the end invasion has a promising potential for site-specific and sequence-unrestricted DNA manipulation and detection.     

Conjugates of PNA with naphthalene diimide derivatives having a broad range of DNA affinities

Peptide nucleic acids (PNAs) are neutral DNA analogues, which bind single-stranded DNA (ssDNA) strongly and with high sequence specificity. However, binding efficiency is dependent on the purine content of the PNA strand. This property make more difficult application of PNA as hybridization probes in, e.g., PNA chips, since at a set temperature the hybridization of a fraction of the DNA targets to the PNA probes does not obey Watson-Crick binding rules. The polypurine PNAs, for example, bind the mismatch containing DNA targets stronger, than the pyrimidine rich PNAs their fully complementary targets. Herein we show that PNA-DNA binding efficiency can be finely tuned by the conjugation of derivatives of naphthalene diimide (NADI) to the N-terminus of PNA using polyamide linkers of different lengths. This approach can potentially be used for the design of PNA probes, which bind their DNA targets with similar affinity independently of the PNA sequence.     

Composites of peptide nucleic acids with ttitanium dioxide nanoparticles. I. Construction of nanocomposites containing DNA/PNA duplexes and their delivery into HeLa cells

In order to study the possibility of using titanium dioxide (TiO₂) nanoparticles to deliver peptide nucleic acids (PNA) in eukaryotic cells, a PNA oligomer was synthesized, and a method of PNA immobilization in the form of hybrid DNA/PNA duplexes on the surface of TiO₂ nanoparticles covered with polylysine (PL) was developed. The attachment of a DNA/PNA duplex to TiO₂ · PL nanoparticles occurs due to electrostatic interactions between the negatively charged DNA chain and the positively charged amino groups of PL. The binding of the PNA to the nanocomposite is achieved through noncovalent Watson-Crick interactions between PNA and complementary DNA. The capacity of the obtained TiO₂ · PL · DNA/PNA nano-composites depending on immobilization conditions was 10?C30 nmol PNA per 1 mg of TiO₂ particles, which corresponds to ??1?C3 PNA molecules per one TiO₂ particle with a size of 4?C6 nm. It was shown by confocal laser scanning microscopy that fluorescently-labeled PNA molecules in the TiO₂ · PL · DNA/^FluPNA nano-composites effectively penetrate into HeLa cells without transfection agents, electroporation, or other auxiliary procedures.     

The peptide nucleic acids (PNAs): a new generation of probes for genetic and cytogenetic analyses

Peptide nucleic acids (PNAs) are synthetic homologs of nucleic acids in which the phosphate-sugar polynucleotide backbone is replaced by a flexible pseudo-peptide polymer to which the nucleobases are linked. This structure gives PNAs the capacity to hybridize with high affinity and specificity to complementary sequences of DNA and RNA, and also confers remarkable resistance to DNAses and proteinases. The unique physico-chemical characteristics of PNAs have led to the development of a wide range of biological assays. Several exciting new applications of PNA technology have been published recently in genetics and cytogenetics. Also, PNA-based hybridization technology is developing rapidly within the field of in situ fluorescence hybridization, pointing out the great potential of PNA probes for chromosomal investigations.     

Cooperative strand invasion of supercoiled plasmid DNA by mixed linear PNA and PNA-peptide chimeras

Peptide nucleic acid (PNA) is a DNA analog with broad biotechnical applications, and possibly also treatment applications. Its suggested uses include that of a specific anchor sequence for biologically active peptides to plasmids in a sequence-specific manner. Such complexes, referred to as Bioplex, have already been used to enhance non-viral gene transfer in vitro. To investigate how hybridization of PNAs to supercoiled plasmids would be affected by the binding of multiple PNA-peptides to the same strand of DNA, we have developed a method of quantifying the specific binding of PNA using a PNA labeled with a derivative of the fluorophore thiazole orange (TO). Cooperative effects were found at a distance of up to three bases. With a peptide present at the end of one of the PNAs, steric hindrance occurred, reducing the increase in binding rate when the distance between the two sites was less than two bases. In addition, we found increased binding kinetics when two PNAs binding to overlapping sites on opposite DNA strands were used, without the use of chemically modified bases in the PNAs.     

Development of Peptide Nucleic Acid Probes for Detection of the HER2 Oncogene

Peptide nucleic acids (PNAs) have gained much interest as molecular recognition tools in biology, medicine and chemistry. This is due to high hybridization efficiency to complimentary oligonucleotides and stability of the duplexes with RNA or DNA. We have synthesized 15/16-mer PNA probes to detect the HER2 mRNA. The performance of these probes to detect the HER2 target was evaluated by fluorescence imaging and fluorescence bead assays. The PNA probes have sufficiently discriminated between the wild type HER2 target and the mutant target with single base mismatches. Furthermore, the probes exhibited excellent linear concentration dependence between 0.4 to 400 fmol for the target gene. The results demonstrate potential application of PNAs as diagnostic probes with high specificity for quantitative measurements of amplifications or over-expressions of oncogenes.     

Synthesis of Chiral Heteronucleotide ONA Sequences by a Fmoc/Boc-Based Submonomeric Strategy

Peptide nucleic acid (PNA) is a DNA analog able to form hybridization complexes with complementary DNA or RNA strands. Many PNAs have been described in recent years, particularly chiral PNA analogs. Chiral heteronucleotide ONA (Orn backbone PNA) is an important tool in the antisensing field, but was not been fully explored yet. In the present work, we performed studies toward the synthesis of chiral heteronucleotide ONA sequences by utilizing a Fmoc/Boc-based submonomer approach on solid support. The desired oligomers with different nucleic content and length were obtained in very good yields and high purity. Specific binding to the complimentary ssDNA oligomers was demonstrated.     

Cellular antisense activity of peptide nucleic acid (PNAs) targeted to HIV-1 polypurine tract (PPT) containing RNA

DNA and RNA oligomers that contain stretches of guanines can associate to form stable secondary structures including G-quadruplexes. Our study shows that the (UUAAAAGAAAAGGGGGGAU) RNA sequence, from the human immunodeficiency virus type 1 (HIV-1 polypurine tract or PPT sequence) forms in vitro a stable folded structure involving the G-run. We have investigated the ability of pyrimidine peptide nucleic acid (PNA) oligomers targeted to the PPT sequence to invade the folded RNA and exhibit biological activity at the translation level in vitro and in cells. We find that PNAs can form stable complexes even with the structured PPT RNA target at neutral pH. We show that T-rich PNAs, namely the tridecamer-I PNA (C4T4CT4) forms triplex structures whereas the C-rich tridecamer-II PNA (TC6T4CT) likely forms a duplex with the target RNA. Interestingly, we find that both C-rich and T-rich PNAs arrested in vitro translation elongation specifically at the PPT target site. Finally, we show that T-rich and C-rich tridecamer PNAs that have been identified as efficient and specific blockers of translation elongation in vitro, specifically inhibit translation in streptolysin-O permeabilized cells where the PPT target sequence has been introduced upstream the reporter luciferase gene.     

Specific versus nonspecific binding of cationic PNAs to duplex DNA

Although peptide nucleic acids (PNAs) are neutral by themselves, they are usually appended with positively charged lysine residues to increase their solubility and binding affinity for nucleic acid targets. Thus obtained cationic PNAs very effectively interact with the designated duplex DNA targets in a sequence-specific manner forming strand-invasion complexes. We report on the study of the nonspecific effects in the kinetics of formation of sequence-specific PNA-DNA complexes. We find that in a typical range of salt concentrations used when working with strand-invading PNAs (10-20 mM NaCl) the PNA binding rates essentially do not depend on the presence of nontarget DNA in the reaction mixture. However, at lower salt concentrations (<10 mM NaCl), the rates of PNA binding to DNA targets are significantly slowed down by the excess of unrelated DNA. This effect of nontarget DNA arises from depleting the concentration of free PNA capable of interacting with DNA target due to adhesion of positively charged PNA molecules on the negatively charged DNA duplex. As expected, the nonspecific electrostatic effects are more pronounced for more charged PNAs. We propose a simple model quantitatively describing all major features of the observed phenomenon. This understanding is important for design of and manipulation with the DNA-binding polycationic ligands in general and PNA-based drugs in particular.     

Recognition of Double-Stranded Dna by Peptide Nucleic Acid

Abstract

Peptide nucleic acid (PNA) is an oligonucleotide mimic in which the backbone of DNA has been replaced by a pseudopeptide. We here show that there are distinct variations as to how PNA oligomers interact with double-stranded DNA depending on choice of nucleobases. Thymine-rich homopyrimidine PNA oligomers recognise double-stranded polynucleotides by forming PNA₂-DNA triplexes with the DNA purine strand. By contrast, cytosine-rich homopyrimidine PNAs add to double-stranded polynucleotides as Hoogsteen strands, forming PNA-DNA₂ triplexes, while homopurine, or alternating thymine-guanine, PNA oligomers invade DNA to form PNA-DNA duplexes.     

Hybridization of complementary and homologous peptide nucleic acid oligomers to a guanine quadruplex-forming RNA

Peptide nucleic acid (PNA) oligomers targeted to guanine quadruplex-forming RNAs can be designed in two different ways. First, complementary cytosine-rich PNAs can hybridize by the formation of Watson-Crick base pairs, resulting in hybrid PNA-RNA duplexes. Second, guanine-rich homologous PNAs can hybridize by the formation of G tetrads, resulting in hybrid PNA-RNA quadruplexes. UV thermal denaturation, circular dichroism, and fluorescence spectroscopy experiments were used to compare these two recognition modes and revealed 1:1 duplex formation for the complementary PNA and 2:1 (PNA2-RNA) quadruplex formation for the homologous PNA. Both hybrids were very stable, and hybridization was observed at low nanomolar concentrations. Hybrid quadruplex formation was equally efficient regardless of the PNA strand polarity, indicating a lack of interaction between the loop nucleobases on the PNA and RNA strands. The implications of this finding on sequence specificity as well as methods to improve affinity are also discussed.     

Vitamin B12-peptide nucleic acids use the BtuB receptor to pass through the Escherichia coli outer membrane

Short modified oligonucleotides that bind in a sequence-specific way to messenger RNA essential for bacterial growth could be useful to fight bacterial infections. One such promising oligonucleotide is peptide nucleic acid (PNA), a synthetic DNA analog with a peptide-like backbone. However, the limitation precluding the use of oligonucleotides, including PNA, is that bacteria do not import them from the environment. We have shown that vitamin B₁₂, which most bacteria need to take up for growth, delivers PNAs to Escherichia coli cells when covalently linked with PNAs. Vitamin B₁₂ enters E. coli via a TonB-dependent transport system and is recognized by the outer-membrane vitamin B₁₂-specific BtuB receptor. We engineered the E. coli ΔbtuB mutant and found that transport of the vitamin B₁₂-PNA conjugate requires BtuB. Thus, the conjugate follows the same route through the outer membrane as taken by free vitamin B₁₂. From enhanced sampling all-atom molecular dynamics simulations, we determined the mechanism of conjugate permeation through BtuB. BtuB is a β-barrel occluded by its luminal domain. The potential of mean force shows that conjugate passage is unidirectional and its movement into the BtuB β-barrel is energetically favorable upon luminal domain unfolding. Inside BtuB, PNA extends making its permeation mechanically feasible. BtuB extracellular loops are actively involved in transport through an induced-fit mechanism. We prove that the vitamin B₁₂ transport system can be hijacked to enable PNA delivery to E. coli cells.     

Composites of peptide nucleic acids with titanium dioxide nanoparticles. II. Dissociation of DNA/PNA duplexes within TiO2 · polylysine · DNA/PNA nanocomposites and in solution. Effect of polylysine

When creating effective drugs, it is important not only to transport them into cells, but also allow them to be released from the “transporter” after the delivery. It was shown that the dissociation of peptide nucleic acids (PNA) from TiO₂ · PL · DNA/PNA nanocomposites occurred according to a typical thermal denaturation, and polylysine (PL) in the nanocomposite has almost no effect on the dissociation. These data suggest that the immobilization of PNA in the TiO₂ · PL · DNA/PNA nanocomposite is reversible and PNA can be easily released from TiO₂ carrier into solution. In contrast to that, the dissociation of DNA/DNA and DNA/PNA duplexes in physiological solution in the presence of PL was not observed. PL in solution dramatically influences the dependence of the optical density on temperature and time for DNA/DNA duplexes and to a lesser degree for DNA/PNA duplexes. It has been assumed that PL and DNA/DNA duplexes in physiological solutions form triple polycomplexes (DNA/DNA · PL) _m , which can aggregate and precipitate. PL in solution can also interact with DNA/PNA duplexes to form monocomplexes PL · (DNA/PNA) _n consisting of one PL chain and one or more (n) DNA/PNA duplexes. Although these monocomplexes do not precipitate, the dissociation of DNA/PNA duplexes from them is complicated.     

The peptide nucleic acids (PNAs): introduction to a new class of probes for chromosomal investigation

Peptide nucleic acids (PNAs) are synthetic DNA mimics in which the sugar phosphate backbone is replaced by repeating N-(2-aminoethyl) glycine units linked by an amine bond and to which the nucleobases are fixed. Peptide nucleic acids hybridize with complementary nucleic acids with remarkably high affinity and specificity, essentially because of their uncharged and flexible polyamide backbone. The unique physicochemical properties of PNAs have led to the development of a large variety of biological research assays, and, over the last few years, PNAs have proved their powerful usefulness in genetic and cytogenetic diagnostic procedures. Several sensitive and robust PNA-dependent methods have been designed for modulating polymerase chain reactions, detecting genomic mutation or capturing nucleic acids. The more recent applications of PNA involve their use as molecular hybridization probes. Thus, the in situ detection of several human chromosomes has been reported in various types of tissues.Communicated by E.A. Nigg     

Evidence for (PNA)2/DNA triplex structure upon binding of PNA to dsDNA by strand displacement

The binding of PNA (peptide nucleic acid) T₂CT₂CT₄-LysNH₂ to the double-stranded DNA target 5′ -A₂GA₂GA₄ was studied by KMnO₄ and dimethylsulfate (DMS) probing. It is found that upon sequence-specific strand displacement binding of the PNA to the dsDNA target concomitant protection of the N-7 of guanines within the target takes place. It is furthermore shown that the binding of this PNA is more efficient at pH 5.5 that at pH 6.5 and very inefficient at pH 7.5. These results clearly indicate that C⁺G Hoogsteen base pairing is present and important for binding and that the strand displacement complex therefore involves a PNA·DNA-PNA triplex.