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.     

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.     

Structural diversity of target-specific homopyrimidine peptide nucleic acid-dsDNA complexes

Sequence-selective recognition of double-stranded (ds) DNA by homopyrimidine peptide nucleic acid (PNA) oligomers can occur by major groove triplex binding or by helix invasion via triplex P-loop formation. We have compared the binding of a decamer, a dodecamer and a pentadecamer thymine–cytosine homopyrimidine PNA oligomer to a sequence complementary homopurine target in duplex DNA using gel-shift and chemical probing analyses. We find that all three PNAs form stable triplex invasion complexes, and also conventional triplexes with the dsDNA target. Triplexes form with much faster kinetics than invasion complexes and prevail at lower PNA concentrations and at shorter incubation times. Furthermore, increasing the ionic strength strongly favour triplex formation over invasion as the latter is severely inhibited by cations. Whereas a single triplex invasion complex is formed with the decameric PNA, two structurally different target-specific invasion complexes were characterized for the dodecameric PNA and more than five for the pentadecameric PNA. Finally, it is shown that isolated triplex complexes can be converted to specific invasion complexes without dissociation of the Hoogsteen base-paired triplex PNA. These result demonstrate a clear example of a ‘triplex first’ mechanism for PNA helix invasion.     

Efficient pH-independent sequence-specific DNA binding by pseudoisocytosine-containing bis-PNA.

The synthesis and DNA binding properties of bis-PNA (peptide nucleic acid) are reported. Two PNA segments each of seven nucleobases in length were connected in a continuous synthesis via a flexible linker composed of three 8-amino-3,6-dioxaoctanoic acid units. The sequence of the first strand was TCTCTTT (C- to N-terminal), while the second strand was TTTCTCT or TTTJTJT, where J is pseudoisocytosine. These bis-PNAs form triple-stranded complexes of somewhat higher thermal stability than monomeric PNA with complementary oligonucleotides and the thermal melting transition shows very little hysteresis. When the J base is placed in the strand parallel to the DNA complement ('Hoogsteen strand'), the DNA binding was pH independent. The bis-PNAs were also superior to monomeric PNAs for targeting double-stranded DNA by strand invasion.     

Short pyrimidine stretches containing mixed base PNAs are versatile tools to induce translation elongation arrest and truncated protein synthesis

Recently, we showed that antisense peptide nucleic acids (PNA) containing a short pyrimidine stretch (C(4)TC(3)) invade Ha-ras mRNA hairpin structures to form highly stable duplex and triplex complexes that contribute to the arrest of translation elongation. The antisense PNA targeted to codon 74 of Ha-ras was designed to bind in antiparallel configuration (the N-terminal of the PNA faces the 3'-end of target mRNA), as PNA/RNA duplexes are most stable in this configuration. In order to show that different sequences in the coding region could be targeted successfully with antisense PNAs, we extended our study to three other purine-rich targets. We show that the tridecamer PNA (targeted to codon 149) containing a CTC(3)T pyrimidine stretch forms with the complementary oligoribonucleotide (ORN) a stable (PNA)(2)/ORN triplex at neutral pH (T(m) = 50 degrees C) and arrests Ha-ras mRNA translation elongation. Interestingly, the thermal stability of triplexes formed with PNAs designed to bind to the complementary ORN in a parallel orientation (the N-terminal of the PNA faces the 5'-end of target) was higher than that formed with antiparallel oriented PNAs (T(m) = 58 degrees C). Because parallel and antiparallel PNAs form stable triplexes with target sequence, they act as translation elongation blockers. These duplex-forming and partly triplex-forming PNAs targeted to Ha-ras mRNA also arrested translation elongation at specific polypurine sites contained in the mRNA coding for HIV-integrase protein. Furthermore, the tridecamer PNA containing the C(3)TC(4) motif was more active than a bis-PNA in which the Hoogsteen recognizing strand was linked to the Watson-Crick recognizing strand by a flexible linker. Pyrimidine-rich, short PNAs that form very stable duplexes with target Ha-ras mRNA inhibit translation by a mechanism that does not involve ribosome elongation arrest, whereas PNAs forming duplex and triplex structures arrest ribosome elongation. The remarkable efficacy of the tridecamer PNAs in arresting translation elongation of HIV-1 integrase mRNA is explained by their ability to form stable triplexes at neutral pH with short purine sequences.     

Targeting duplex DNA with DNA‐PNA chimeras? Physico‐chemical characterization of a triplex DNA‐PNA/DNA/DNA

Targeting double-stranded DNA with homopyrimidine PNAs results in strand displacement complexes PNA/DNA/PNA rather than PNA/DNA/DNA triplex structures. Not much is known about the binding properties of DNA-PNA chimeras. A 16-mer 5'-DNA-3'-p-(N)PNA(C) has been investigated for its ability to hybridize a complementary duplex DNA by DSC, CD, and molecular modeling studies. The obtained results showed the formation of a triplex structure having similar, if not slightly higher, stability compared to the same all-DNA complex.     

Effect of temperature and ionic strength on the dissociation kinetics and lifetime of PNA-DNA triplexes

Dissociation kinetics of triplexes formed by molecules of peptide nucleic acid (PNA) and DNA have been studied. The complexes consisted of oligomeric PNA containing 10 thymine bases and the dA(10) target incorporated in single-stranded (ssDNA) or double-stranded DNA (dsDNA). Their dissociation was followed by means of the gel mobility shift assay at various temperatures and sodium ion concentrations. In all experiments, the dissociation kinetics of triplexes were exponential; the effective lifetime of a triplex, tau, depended on temperature in accordance with the Arrhenius law. The tau values for T(10) PNA complexes with ss- and dsDNA were equal within the accuracy of experiments. The activation energy, U, value for T(10) PNA-DNA complexes did not change when the NaCl concentration was increased from 50 to 200 or 600 mM. Conversely, the tau values decreased with the increase in NaCl concentration. The equal lifetimes of the T(10) PNA-DNA triplexes containing ss- and dsDNA suggest that the loop formed in dsDNA does not noticeably affect the triplex structure. The decrease in the triplex lifetime tau with an increase in ionic strength was accounted for by the fact that the PNA backbone is neutral. The lack of relationship between the activation energy of dissociation and salt concentration suggests that the dissociation enthalpy does not depend on the ionic strength. Thus, the effect of ionic strength on the lifetime is entropic by its nature. Contrary to this, for complexes of ssDNA with bis-PNA 1743, which also consists of 10 thymine bases but contains 2 additional positive charges inside the sequence in 1 of the PNA arms, an increase of the dissociation enthalpy at low salt concentration was observed. We suggest that this effect is a result of a direct electrostatic interaction of the positive charges of the PNA with the DNA backbone. Finally, our results allow an estimate of the lifetime of a 10-mer triplex invasion complex in dsDNA at 37 degrees C in excess of several hundred days.     

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.     

Combined triplex/duplex invasion of double-stranded DNA by "tail-clamp" peptide nucleic acid

"Tail-clamp" PNAs composed of a short (hexamer) homopyrimidine triplex forming domain and a (decamer) mixed sequence duplex forming extension have been designed. Tail-clamp PNAs display significantly increased binding to single-stranded DNA compared with PNAs lacking a duplex-forming extension as determined by T(m) measurements. Binding to double-stranded (ds) DNA occurred by combined triplex and duplex invasion as analyzed by permanganate probing. Furthermore, C(50) measurements revealed that tail-clamp PNAs consistently bound the dsDNA target more efficiently, and kinetics experiments revealed that this was due to a dramatically reduced dissociation rate of such complexes. Increasing the PNA net charge also increased binding efficiency, but unexpectedly, this increase was much more pronounced for tailless-clamp PNAs than for tail-clamp PNAs. Finally, shortening the tail-clamp PNA triplex invasion moiety to five residues was feasible, but four bases were not sufficient to yield detectable dsDNA binding. The results validate the tail-clamp PNA concept and expand the applications of the P-loop technology.     

Strand displacement recognition of mixed adenine-cytosine sequences in double stranded DNA by thymine-guanine PNA (peptide nucleic acid).

Mixed pyrimidine-purine peptide nucleic acids (PNAs) composed of thymines and guanines are shown to form a PNA(2)-DNA triplex with Watson-Crick complementary adenine-cytosine oligonucleotides and to bind complementary adenine-cytosine targets in double stranded DNA by helix invasion. These results for the first time demonstrate binding of an unmodified PNA oligomer to a mixed pyrimidine-purine target in double stranded DNA and illustrate a novel binding mode of PNA.     

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.     

Electron microscopy mapping of oligopurine tracts in duplex DNA by peptide nucleic acid targeting.

Biotinylated homopyrimidine decamer peptide nucleic acids (PNAs) are shown to form sequence-specific and stable complexes with complementary oligopurine targets in linear double-stranded DNA. The noncovalent complexes are visualized by electron microscopy (EM) without chemical fixation using streptavidin as an EM marker. The triplex stoichiometry of the PNA-DNA complexes (two PNA molecules presumably binding by Watson-Crick and Hoogsteen pairing with one of the strands of the duplex DNA) is indicated by the appearance of two streptavidin 'beads' per target site in some micrographs, and is also supported by the formation of two retardation bands in a gel shift assay. Quantitative analysis of the positions of the streptavidin 'beads' revealed that under optimized conditions PNA-DNA complexes are preferably formed with the fully complementary target. An increase in either the PNA concentration or the incubation time leads to binding at sites containing one or two mismatches. Our results demonstrate that biotinylated PNAs can be used for EM mapping of short targets in duplex DNA.     

Triplex mediated delivery of a platinum complex to a specific DNA target site

Tethering an ethylene diamine linker to the 5' terminus of an oligothymidine sequence provides a site for complexation with K(2)PtCl(4). Due to the low reactivity of dT toward a platinum source, we chose dT(8) and dT(15) as our initial synthetic targets for platination. Post-synthetic reaction of the platinum reagent with the diamino oligothymidine generates the diamino dichloro platinum-DNA conjugate that can be used for DNA duplex targeting by oligodeoxyncleotide-mediated triplex formation. The dT(8) sequence is not sufficiently long to facilitate triplex formation and Pt-cross-linking, whereas with a dT(15) sequence cross-linking between the third strand and the duplex occurs exclusively with the duplex target strand directly involved in triplex formation. No examples of cross-linking to the complementary target strand, or of cross-linking to both target strands are observed. Most efficient cross-linking occurs when the dinucleotide d(GpG) is present in the target strand and no cross-linking occurs with the corresponding 7-deazaG dinucleotide target. Cross-linking is also observed when dC or dA residues are present in the target strand, or even with a single dG residue, but it is not observed in any cases to dT residues. Triplex formation provides the ability to target specific sequences of double-stranded DNA and the orientational control arising from triplex formation is sufficient to alter the binding preferences of platinum. Conjugates of the type described here offer the potential of delivering a platinum complex to a specific DNA site.     

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.     

Repairing the sickle cell mutation. I. Specific covalent binding of a photoreactive third strand to the mutated base pair.

A DNA third strand with a 3'-psoralen substituent was designed to form a triplex with the sequence downstream of the T.A mutant base pair of the human sickle cell beta-globin gene. Triplex-mediated psoralen modification of the mutant T residue was sought as an approach to gene repair. The 24-nucleotide purine-rich target sequence switches from one strand to the other and has four pyrimidine interruptions. Therefore, a third strand sequence favorable to two triplex motifs was used, one parallel and the other antiparallel to it. To cope with the pyrimidine interruptions, which weaken third strand binding, 5-methylcytosine and 5-propynyluracil were used in the third strand. Further, a six residue "hook" complementary to an overhang of a linear duplex target was added to the 5'-end of the third strand via a T(4) linker. In binding to the overhang by Watson-Crick pairing, the hook facilitates triplex formation. This third strand also binds specifically to the target within a supercoiled plasmid. The psoralen moiety at the 3'-end of the third strand forms photoadducts to the targeted T with high efficiency. Such monoadducts are known to preferentially trigger reversion of the mutation by DNA repair enzymes.