Peptide Nucleic Acid Clamping Research Articles

Medicinal chemistry of plasmid DNA with peptide nucleic acids: A new strategy for gene therapy

In this chapter, we describe an approach using a peptide nucleic acid (PNA) clamp to directly and irreversibly modify plasmid DNA, without affecting either its supercoiled conformation or its ability to be efficiently transcribed. This strategy enables investigators to `functionalize' their gene of interest by direct coupling of ligands (fluorophores, peptide, proteins, sugars or oligonucleotides) to plasmid DNA. This approach provides versatile tools to study the mechanisms of gene delivery and to circumvent some of the main obstacles of synthetic gene delivery systems, such as specific targeting and efficient delivery. The proof-of-principal of PNA-dependent gene chemistry (PDGC) was demonstrated with a fluorescently labeled PNA that allowed generation of a highly fluorescent preparation of plasmid DNA that was functionally and conformationally intact. Fluorescent-PNA/DNA was used to identify critical parameters involved in naked DNA and non-viral gene delivery technology. The greatest potential of PDGC lies in the ability to attach specific ligands (e.g., peptides, proteins) to the plasmid DNA in order to overcome cellular barriers of non-viral gene delivery systems. In this regard, specific examples of ligands coupled to DNA are described and their effect on increasing the efficacy of gene therapy is presented.

Rare Quasispecies in the YMDD Motif of Hepatitis B Virus Detected by Polymerase Chain Reaction with Peptide Nucleic Acid Clamping

The emergence of drug-resistant mutants of hepatitis B virus (HBV) is a serious problem during antiviral therapy of patients with chronic hepatitis B. Lamivudine-resistant mutants with a mutation in the YMDD motif of reverse transcriptase of HBV emerge in approximately one half of the treated patients within 5 years. To date, the detection of YMDD mutants by polymerase chain reaction (PCR) with peptide nucleic acid (PNA) clamping is most sensitive. In this study, the performance of this method was evaluated in various clinical settings. The PCR-PNA method was able to detect the emergence of YMDD mutants 2–3 months earlier than the previously developed method involving restriction fragment length polymorphism. Further, rare quasispecies were detected by PCR-PNA in patients with chronic hepatitis B who were positive for hepatitis B e antigen (HBeAg). Many previously unrecognized mutants, such as those with YLDD and YMED, were found in them. Although precise sequence analyses of 10 patients identified YVDD and YIDD sequences in 6 of them, only 1 patient had a typical YVDD sequence that was identical with that in the reported lamivudine-resistant strain. All HBV mutants with the YIDD sequence accompanied stop codon(s) in the overlapping envelope (S) gene, suggesting that these strains would have no relevance as regards the emergence of lamivudine resistance. These results suggest that it would be difficult to detect lamivudine-resistant mutants before the therapy and that they would have a greater ability to evade the attack of antiviral drugs by frequent nucleotide substitutions than previously expected.

Affinity purification of DNA and RNA from environmental samples with peptide nucleic acid clamps.

Bispeptide nucleic acids (bis-PNAs; PNA clamps), PNA oligomers, and DNA oligonucleotides were evaluated as affinity purification reagents for subfemtomolar 16S ribosomal DNA (rDNA) and rRNA targets in soil, sediment, and industrial air filter nucleic acid extracts. Under low-salt hybridization conditions (10 mM NaPO(4), 5 mM disodium EDTA, and 0.025% sodium dodecyl sulfate [SDS]) a PNA clamp recovered significantly more target DNA than either PNA or DNA oligomers. The efficacy of PNA clamps and oligomers was generally enhanced in the presence of excess nontarget DNA and in a low-salt extraction-hybridization buffer. Under high-salt conditions (200 mM NaPO(4), 100 mM disodium EDTA, and 0.5% SDS), however, capture efficiencies with the DNA oligomer were significantly greater than with the PNA clamp and PNA oligomer. Recovery and detection efficiencies for target DNA concentrations of > or =100 pg were generally >20% but depended upon the specific probe, solution background, and salt condition. The DNA probe had a lower absolute detection limit of 100 fg of target (830 zM [1 zM = 10(-21) M]) in high-salt buffer. In the absence of exogenous DNA (e.g., soil background), neither the bis-PNA nor the PNA oligomer achieved the same absolute detection limit even under a more favorable low-salt hybridization condition. In the presence of a soil background, however, both PNA probes provided more sensitive absolute purification and detection (830 zM) than the DNA oligomer. In varied environmental samples, the rank order for capture probe performance in high-salt buffer was DNA > PNA > clamp. Recovery of 16S rRNA from environmental samples mirrored quantitative results for DNA target recovery, with the DNA oligomer generating more positive results than either the bis-PNA or PNA oligomer, but PNA probes provided a greater incidence of detection from environmental samples that also contained a higher concentration of nontarget DNA and RNA. Significant interactions between probe type and environmental sample indicate that the most efficacious capture system depends upon the particular sample type (and background nucleic acid concentration), target (DNA or RNA), and detection objective.

PNA-dependent gene chemistry: stable coupling of peptides and oligonucleotides to plasmid DNA.

Two approaches are described for stably conjugating peptides, proteins and oligonucleotides onto plasmid DNA. Both methods use a peptide nucleic acid (PNA) clamp, which binds irreversibly and specifically to a binding site cloned into the plasmid. The first approach uses a biotin-conjugated PNA clamp that can be used to introduce functional biotin groups onto the plasmid to which streptavidin can bind. Atomic force microscopy images of linearized plasmid show streptavidin localized at the predicted PNA binding site on the DNA strand. Peptides and oligonucleotides containing free thiol groups were conjugated to maleimide streptavidin, and these streptavidin conjugates were bound to the biotin-PNA-labeled plasmid. In this way, peptides and oligonucleotides could be brought into stable association with the plasmid. A second approach used a maleimide-conjugated PNA clamp. Methods are described for conjugating thiolated peptides and oligonucleotides directly to the maleimide-PNA-DNA hybrid. This straightforward technology offers an easy approach to introduce functional groups onto plasmid DNA without disturbing its transcriptional activity.

Nuclear Import of Plasmid DNA in Digitonin-permeabilized Cells Requires Both Cytoplasmic Factors and Specific DNA Sequences

Although much is known about the mechanisms of signal-mediated protein and RNA nuclear import and export, little is understood concerning the nuclear import of plasmid DNA. Plasmids between 4.2 and 14.4 kilobases were specifically labeled using a fluorescein-conjugated peptide nucleic acid clamp. The resulting substrates were capable of gene expression and nuclear localization in microinjected cells in the absence of cell division. To elucidate the requirements for plasmid nuclear import, a digitonin-permeabilized cell system was adapted to follow the nuclear localization of plasmids. Nuclear import of labeled plasmid was time- and energy-dependent, was inhibited by the lectin wheat germ agglutinin, and showed an absolute requirement for cytoplasmic extract. Addition of nuclear extract alone did not support plasmid nuclear import but in combination with cytoplasm stimulated plasmid nuclear localization. Whereas addition of purified importin alpha, importin beta, and RAN was sufficient to support protein nuclear import, plasmid nuclear import also required the addition of nuclear extract. Finally, nuclear import of plasmid DNA was sequence-specific, requiring a region of the SV40 early promoter and enhancer. Taken together, these results confirm and extend our findings in microinjected cells and support a protein-mediated mechanism for plasmid nuclear import.

An experimental study of mechanism and specificity of peptide nucleic acid (PNA) binding to duplex DNA

We investigated the mechanism and kinetic specificity of binding of peptide nucleic acid clamps (bis-PNAs) to double-stranded DNA (dsDNA). Kinetic specificity is defined as a ratio of initial rates of PNA binding to matched and mismatched targets on dsDNA. Bis-PNAs consist of two homopyrimidine PNA oligomers connected by a flexible linker. While complexing with dsDNA, they are known to form P-loops, which consist of a [PNA]2-DNA triplex and the displaced DNA strand. We report here a very strong pH-dependence, within the neutral pH range, of binding rates and kinetic specificity for a bis-PNA consisting of only C and T bases. The specificity of binding reaches a very sharp and high maximum at pH 6.9. In contrast, if all the cytosine bases in one of the two PNA oligomers within the bis-PNA are replaced by pseudoisocytosine bases (J bases), which do not require protonation to form triplexes, a weak dependence on pH of the rates and specificity of the P-loop formation is observed. A theoretical analysis of the data suggests that for (C+T)-containing bis-PNA the first, intermediate step of PNA binding to dsDNA occurs via Hoogsteen pairing between the duplex target and one oligomer of bis-PNA. After that, the strand invasion occurs via Watson-Crick pairing between the second bis-PNA oligomer and the homopurine strand of the target DNA, thus resulting in the ultimate formation of the P-loop. The data for the (C/J+T)-containing bis-PNA show that its high affinity to dsDNA at neutral pH does not seriously compromise the kinetic specificity of binding. These findings support the earlier expectation that (C/J+T)-containing PNA constructions may be advantageous for use in vivo.

Detection of the Hereditary Hemochromatosis Gene Mutation by Real-Time Fluorescence Polymerase Chain Reaction and Peptide Nucleic Acid Clamping

Hereditary hemochromatosis (HH), an iron overload disease, is the most common known inheritable disease. The most prevalent form of HH is believed to be the result of a single base-pair mutation. We describe a rapid homogeneous mutation analysis method that does not require post-polymerase chain reaction (PCR) manipulations. This method is a marriage of three emerging technologies: rapid cycling PCR thermal cyclers, peptide nucleic acid (PNA) probes, and a new double-stranded DNA-selective fluorescent dye, Sybr Green I. The LightCycler is a rapid thermal cycler that fluorometrically monitors real-time formation of amplicon with Sybr Green I. PNAs are DNA mimics that are more sensitive to mismatches than DNA probes, and will not serve as primers for DNA polymerases. PNA probes were designed to compete with PCR primers hybridizing to the HH mutation site. Fully complemented PNA probes at an 18:1 ratio over DNA primers with a mismatch result in suppression of amplicon formation. Conversely, PNA probes with a mismatch will not impair the binding of a complementary primer, culminating in amplicon formation. A LightCycler-based rapid genetic assay has been developed to distinguish HH patients from HH carriers and normal individuals using PNA clamping technology.

Analysis of the allele-specific PCR method for the detection of neoplastic disease.

PCR assays for the presence of mutant K-ras or p53 sequences are potentially useful as sensitive tests for tumor diagnosis. The technical challenge is to design assays sensitive enough to detect a few molecules of mutant DNA yet sufficiently specific that a false positive signal is not produced by a 10(5)- or 10(6)-fold excess of normal DNA. We determined the detection limit of allele-specific PCR (ASA) as a function of the particular mismatch involved using all 12 possible mismatches in two different DNA sequence contexts (K-ras codon 12 and p53 codon 273). Depending on the identity of the mismatch, mismatched template was amplified 10(2)-10(4)-fold less than perfectly matched template. In other words, a mutant allele could be detected by ASA if it represented > 1-0.01% of the total DNA from that locus. Peptide nucleic acid (PNA) clamping was used to improve the K-ras ASA assay. Selective amplification of mutant sequences was achieved using a PNA complementary to the normal sequence to inhibit the amplification of wild-type DNA. PNA clamping followed by ASA resulted in significant improvement in sensitivity and specificity, permitting the detection of tumor DNA diluted with a 300,000-fold excess of normal human DNA.