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.     

Inhibition of PNA triplex formation by N4-benzoylated cytosine.

The synthesis of N-((N4-(benzoyl)cytosine-1-yl)acetyl)- N -(2-Boc-aminoethyl)glycine (CBz) and the incorporation of this monomer into PNA oligomers are described. A single CBzresidue within a 10mer homopyrimidine PNA is capable of switching the preferred binding mode from a parallel to an antiparallel orientation when targeting a deoxyribonucleotide sequence at neutral pH. The resulting complex has a thermal stability equal to that of the corresponding PNA-DNA duplex, indicative of a strong destabilization of Hoogsteen strand PNA binding due to steric interference by the benzoyl moieties. Accordingly, incorporation of the CBz residue into linked PNAs (bis-PNAs) results in greatly reduced thermal stability of the formed PNA:DNA complexes. Thus, incorporation of the CBz monomer could eliminate the stability bias of triplex-forming sequences in PNA used in hybridization arrays and combinatorial library formats. Furthermore, it is shown that the benzoyl moiety does not severely interfere with Watson-Crick hydrogen bonding, thereby presenting an interesting route for novel cytosine modifications.     

Kinetic sequence discrimination of cationic bis-PNAs upon targeting of double-stranded DNA.

Strand displacement binding kinetics of cationic pseudoisocytosine-containing linked homopyrimidine peptide nucleic acids (bis-PNAs) to fully matched and singly mismatched decapurine targets in double-stranded DNA (dsDNA) are reported. PNA-dsDNA complex formation was monitored by gel mobility shift assay and pseudo-first order kinetics of binding was obeyed in all cases studied. The kinetic specificity of PNA binding to dsDNA, defined as the ratio of the initial rates of binding to matched and mismatched targets, increases with increasing ionic strength, whereas the apparent rate constant for bis-PNA-dsDNA complex formation decreases exponentially. Surprisingly, at very low ionic strength two equally charged bis-PNAs which have the same sequence of nucleobases but different linkers and consequently different locations of three positive charges differ in their specificity of binding by one order of magnitude. Under appropriate experimental conditions the kinetic specificity for bis-PNA targeting of dsDNA is as high as 300. Thus multiply charged cationic bis-PNAs containing pseudoisocytosines (J bases) in the Hoogsteen strand combined with enhanced binding affinity also exhibit very high sequence specificity, thereby making such reagents extremely efficient for sequence-specific targeting of duplex DNA.     

Unique properties of purine/pyrimidine asymmetric PNA.DNA duplexes: differential stabilization of PNA.DNA duplexes by purines in the PNA strand

PNA.DNA duplexes are significantly stabilized by purine nucleobases in the PNA strand. To elucidate and understand the effect of switching the backbone in a nucleic acid duplex, we now report a thermodynamics study along with a solution conformations study of two purine/pyrimidine strand asymmetric duplexes and a strand symmetrical control by comparing the behavior of all four possible PNA/DNA combinations. In essence, we are comparing an identical basepair stack connected by either an aminoethyl glycine PNA or a deoxyribose DNA backbone. We show that the PNA.DNA duplexes containing purine-rich PNA strands are stabilized with regard to the thermal melting temperature and free energy as well as enthalpy (and concomitantly relatively less entropically disfavored). Based on our data, we find it unlikely that differences in counterion binding (identical ionic-strength dependence was observed), hydration (identical and insignificant water release was observed), or single-strand conformation can be responsible for the difference in duplex stability. The only consistent difference observed between the purine-rich PNA versus the pyrimidine-rich PNA in isosequential PNA.DNA duplexes is the significant increase in both binding enthalpy and entropy for the PNA.DNA duplexes containing pyrimidine-rich PNA in organic solvent, which would indicate that these duplexes are relatively enthalpically disfavored in water. Although our results so far do not allow us to identify the origin of the different stabilities of homopurine/homopyrimidine PNA.DNA duplexes, the evidence does point to a significant structural component, which involves enthalpic contributions both within the duplex structure and also from bound water molecules.     

Sequence selective double strand DNA cleavage by peptide nucleic acid (PNA) targeting using nuclease S1.

A novel method for sequence specific double strand DNA cleavage using PNA (peptide nucleic acid) targeting is described. Nuclease S1 digestion of double stranded DNA gives rise to double strand cleavage at an occupied PNA strand displacement binding site, and under optimized conditions complete cleavage can be obtained. The efficiency of this cleavage is more than 10 fold enhanced when a tandem PNA site is targeted, and additionally enhanced if this site is in trans rather than in cis orientation. Thus in effect, the PNA targeting makes the single strand specific nuclease S1 behave like a pseudo restriction endonuclease.     

Towards a circular bis-peptide nucleic acid

En route to a circular bis-PNA molecule, we have synthesized and characterized the DNA binding of several "clamp"-type bis-PNAs. In order to incorporate charge into a circular PNA, a new linker based on the achiral 2-aminoethylglycine has been used.     

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.     

Quinoxaline antibiotics enhance peptide nucleic acid binding to double-stranded DNA

The effects of a wide range of DNA binding drugs on peptide nucleic acid (PNA) binding to double-stranded DNA by strand displacement have been investigated using a gel retardation assay. The bis-PNA [H-(Lys)-TTJTTJTTTT-(eg)(3)-TTTTCTTCTT-Lys-NH(2)] was used together with a 248 bp DNA fragment containing an appropriate target for the PNA. Most of the ligands that were studied, including DNA minor groove binders as well as intercalators and bis-intercalators, either have no effect or strongly inhibit PNA binding to DNA. By contrast, quinoxaline antibiotics facilitate PNA-DNA complex formation. The "PNA-helper" effect of echinomycin was studied in more detail using time and temperature dependence experiments to elucidate the mechanism. PNA binding to DNA follows pseudo-first-order kinetics, but the initial rate of binding is accelerated more than 10-fold in the presence of 10 microM echinomycin. The activation energy for PNA binding to dsDNA is lowered 2-fold by the antibiotic (45 vs 90 kJ/mol in the control). The reasons why quinoxalines promote the binding of PNA to DNA are not entirely clear but may well include distortions (opening) of the double helix that facilitate PNA invasion. This study establishes that the efficacy of DNA-targeted PNA antigene molecules could potentially be enhanced by judiciously adding certain DNA-interactive ligands.     

Increased stability and specificity through combined hybridization of peptide nucleic acid (PNA) and locked nucleic acid (LNA) to supercoiled plasmids for PNA-anchored "Bioplex" formation

Low cellular uptake and poor nuclear transfer hamper the use of non-viral vectors in gene therapy. Addition of functional entities to plasmids using the Bioplex technology has the potential to improve the efficiency of transfer considerably. We have investigated the possibility of stabilizing sequence-specific binding of peptide nucleic acid (PNA) anchored functional peptides to plasmid DNA by hybridizing PNA and locked nucleic acid (LNA) oligomers as "openers" to partially overlapping sites on the opposite DNA strand. The PNA "opener" stabilized the binding of "linear" PNA anchors to mixed-base supercoiled DNA in saline. For higher stability under physiological conditions, bisPNA anchors were used. To reduce nonspecific interactions when hybridizing highly cationic constructs and to accommodate the need for increased amounts of bisPNA when the molecules are uncharged, or negatively charged, we used both PNA and LNA oligomers as "openers" to increase binding kinetics. To our knowledge, this is the first time that LNA has been used together with PNA to facilitate strand invasion. This procedure allows hybridization at reduced PNA-to-plasmid ratios, allowing greater than 80% hybridization even at ratios as low as 2:1. Using significantly lower amounts of PNA-peptides combined with shorter incubation times reduces unspecific binding and facilitates purification.     

Duplex DNA capture

This article describes the sequence-specific isolation and purification of intact double-stranded DNA (dsDNA) by oligonucleotide/PNA-assisted affinity capture (OPAC). The OPAC assay is based on selective tagging of a DNA duplex by biotinylated oligodeoxyribonucleotide (ODN) through formation of a so-called PD-loop. The PD-loop is assembled with the aid of a pair of PNA "openers", which allow sequence-specific targeting with a Watson-Crick complementary ODN probe in the exposed region of the dsDNA. The protocol involves three steps. First, two cationic bis-PNAs locally pry the DNA duplex apart at a predetermined site. Then, the exposed DNA single strand is targeted by a complementary biotinylated ODN to selectively form a stable PD-loop complex. Finally, the capture of dsDNA is performed using streptavidin covered magnetic beads. The OPAC procedure has many advantages in the isolation of highly purified native DNA over other affinity capture and amplification techniques.     

Unwinding of unnatural substrates by a DNA helicase

Helicases separate double-stranded DNA into single-stranded DNA intermediates that are required during replication and recombination. These enzymes are believed to transduce free energy available from ATPase activity to unwind the duplex and translocate along the nucleic acid lattice. The nature of enzyme-substrate interactions between helicases and duplex DNA substrates has not been well-defined. Most helicases require a single-stranded DNA overhang adjacent to duplex DNA in order to initiate unwinding. The strand containing the overhang is referred to as the loading strand whereas the complementary strand is referred to as the displaced strand. We have investigated the interactions between a DNA helicase and the DNA substrate by replacing the displaced strand with a nucleic acid mimic, peptide nucleic acid (PNA). PNA is capable of forming duplex structures with DNA according to Watson-Crick base pairing rules, but contains a N-(2-aminoethyl)glycine backbone in place of the deoxyribose phosphates. The PNA-DNA hybrids had higher melting temperatures than their DNA-DNA counterparts. Dda helicase, from bacteriophage T4, was able to unwind the DNA-PNA substrates at similar rates as DNA-DNA substrates. The results indicate that the rate-limiting step for unwinding is relatively insensitive to the chemical nature of the displaced strand and the thermal stability of oligonucleotide substrates.     

Towards a Circular bis -Peptide Nucleic Acid

Abstract

En route to a circular bis-PNA molecule, we have synthesized and characterized the DNA binding of several “clamp”-type bis-PNAs. In order to incorporate charge into a circular PNA, a new linker based on the achiral 2-aminoethylglycine has been used.     

γPNA一种新型高效的肽核酸

肽核酸(peptide nucleic acid,PNA)是一种人工合成的具有类多肽骨架的DNA类似物,具有与核酸结合特异性强、组织和细胞内生物稳定性好、半衰期长等优点。通过靶向结合DNA/RNA而抑制其复制、转录和翻译过程,进行基因调控。在PNA骨架结构中γ位点引入带手性的官能团,能形成右手螺旋结构,显著提高其与靶DNA/RNA的杂交特性,这种PNA衍生物称之为γPNA。γPNA的溶解性、热稳定性和特异性等化学与生物学特性明显改善,在基因编辑和作为探针检测等方面具有良好的应用前景。通过对γPNA结构、性质及其研究进展进行总结,以期为γPNA反义应用提供理论依据和参考。     

Inducing the replacement of PNA in DNA.PNA duplexes by DNA

The uncharged DNA-analogue peptide nucleic acid (PNA) can invade into dsDNA by displacing the non-complementary DNA strand. The formed strand displacement complexes can create a sterical hindrance to block access of enzymes such as nucleases and polymerases. Due to the high stability of DNA.PNA duplexes it is usually not possible to displace the PNA strand by ssDNA or ssRNA. We herein report that the polycationic, comb-type copolymer alphaPLL-g-Dex can induce such a replacement of PNA in DNA.PNA duplexes by ssDNA. The influence of the copolymer on strand exchange highly depends on the nature of the oligonucleotides. Acceleration has only been observed when both the starting duplex and the single-stranded exchanger strand were negatively charged. The presented approach should allow the withdrawal of PNA induced sterical hindrance of DNA by rehybridisation with ssDNA.     

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 NaPO₄, 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 NaPO₄, 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 ≥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.     

Introduction of chirality into PNA by replacement of the achiral methylene carbonyl linkage to the nucleobase

A novel approach to the introduction of chirality into peptide nucleic acid (PNA) by replacement of the methylene carbonyl linker by an alpha-amino acid derived moiety is described. A monomer compatible with Fmoc-based oligomerization chemistry possessing an L-serine derived linker has been synthesized and incorporated into PNA oligomers. A single, central substitution in a hexathymine PNA strongly destabilized triple helix formation whereas a central substitution in a mixed sequence is much better tolerated. We have investigated the influence of this substitution on the selectivity for strand composition (DNA versus RNA complement) and strand orientation (antiparallel versus parallel) in the context of duplex formation. A PNA 11-mer with a single substitution demonstrates a preference for an antiparallel RNA complement, as judged by thermal denaturation analysis of the complexes.     

Peptide nucleic acid-anthraquinone conjugates: strand invasion and photoinduced cleavage of duplex DNA.

A bis-peptide nucleic acid (PNA)-anthraquinone imide (AQI) conjugate has been synthesized and shown to form strand invasion complexes with a duplex DNA target. The two arms of the bis-PNA each consist of five consecutive thymine residues and are linked by a flexible, hydrophilic spacer. Probing with potassium permanganate reveals that the bis-PNA complexes to duplex DNA at A5.T5sites with local displacement of the T5DNA strand. The 5 bp sequence targeted by the PNA is the shortest strand invasion complex reported to date. Irradiation of the strand invasion complex results in asymmetric cleavage of the displaced strand, with more efficient cleavage at the 3'-end of the loop. This result indicates that the bis-PNA binds to the DNA such that the C-terminal T5sequence forms the strand invasion complex, leaving the N-terminal T5sequence to bind by triplex formation, thereby placing the AQI closer to the 3'-end of the displaced strand, consistent with the observed photocleavage pattern. The ability of the PNA to directly report its binding site by photoinduced cleavage could have significant utility in mapping the secondary and tertiary structure of nucleic acids.     

Role of chirality and optical purity in nucleic acid recognition by PNA and PNA analogs

Peptide nucleic acids are DNA mimics able to form duplexes with complementary DNA or RNA strands of remarkable affinity and selectivity. Oligopyrimidine PNA can displace one strand of dsDNA by forming PNA(2):DNA triplexes of very high stability. Many PNA analogs have been described in recent years, in particular, chiral PNA analogs. In the present article the results obtained recently using PNA derived from N-aminoethylamino acids 7 are illustrated. In particular, the dependence of optical purity on synthetic methodologies and a rationale for the observed effects of chirality on DNA binding ability is proposed. Chirality as a tool for improving sequence selectivity is also described. PNA analogs derived from D- or L-ornithine 8 were also found to be subjected to epimerization during solid phase synthesis. Modification of the coupling conditions or the use of a submonomeric strategy greatly reduced epimerization. The optically pure oligothymine PNAs 8 were found to bind to RNA by forming triplexes of unusual CD spectra. The melting curves of these adducts presented two transitions, suggesting a conformational change followed by melting at high temperature.