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.     

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.     

Synthesis and DNA binding properties of terminally modified peptide nucleic acids

PNAs with terminal modifications of varying structure and charge were synthesized and their binding to DNA was studied. A variation in thermal stability of 19. 8 degrees C has been observed between the least and the most stable PNA-DNA duplexes. The most stable duplex melts 7.7 degrees C higher than the duplex of the corresponding non-modified PNA and complementary DNA. It has been shown that sequence fidelity of the PNA conjugate having the highest DNA affinity is significantly better than that of non-modified PNA. The results obtained can be used for the design of PNA probes, whose binding to DNA is sequence independent.     

Peptide nucleic acid (PNA) amphiphiles: synthesis, self-assembly, and duplex stability

Peptide amphiphiles comprising a class of conjugates of peptide nucleic acid (PNA), natural amino acids, and n-alkanes were synthesized and studied. These PNA amphiphiles (PNAA) self-assemble at concentrations between 10 and 50 muM and exhibit water solubilities above 500 muM. The highly specific, stable DNA binding properties of PNAs are preserved by these modifications, with no significant differences between the thermodynamics of DNA binding of the PNA peptide and the PNA amphiphile. Proper solubilization of the PNAA required the attachment of (Lys)(2) and (Glu)(4) peptides to PNAs, which affected the PNAA-DNA duplex stability by electrostatic interactions between these charged amino acids and the negatively charged DNA backbone. These electrostatic effects did not affect the specificity of DNA binding, however. Electrostatic effects are screened with added salt, in a manner consistent with previous studies of PNA-DNA duplex stability and predictions from a charged-cylinder model for the duplex.     

Unconventional method based on circular dichroism to detect peanut DNA in food by means of a PNA probe and a cyanine dye

In this paper we report an innovative and unconventional method based on circular dichroism for the identification of peanut DNA in food, which can be detected after PCR amplification at the nanomolar level by using an achiral PNA probe complementary to a tract of the peanut Ara h 2 gene and an achiral 3,3'-diethylthiadicarbocyanine dye [DiSC(2)(5)]. Peanuts are one of the most common causes of severe allergic reactions to foods and are particularly dangerous when they are "hidden" (undeclared) in food. For better protection of consumers, detection methods are required to specifically detect the presence of hidden allergens in a wide variety of food items. Alternative to the detection of the proteins is the determination of species-specific DNA, which is more resistant to technological treatments. PNAs are very specific probes able to recognize DNA sequences with high affinity and evidence for the binding can be obtained by using the DiSC(2)(5) dye, which aggregates onto the PNA-DNA duplex giving rise to a characteristic visibile band at 540 nm. Because the PNA-DNA duplex is in a right-handed helical conformation, the aggregation of the dye to the duplex gives also rise to a strong CD signal in the 500-600 nm region with a strong exciton coupling due to the formation of multimeric species, since the handedness of the helix is transferred to the dye aggregate. The dye does not interact with the free single-stranded DNA and although aggregating on the achiral PNA, this interaction is obviously not detectable by circular dichroism. Thus, only the formation of the PNA-DNA duplex, which takes place only upon specific Watson-Crick hydrogen binding between the PNA and the DNA bases, is detected, ensuring a very high specificity and sensitivity. The method has been optimized in a model system by using a synthetic oligonucleotide complementary to the PNA probe, showing that the intensity of the signal is linearly related to the amount of the DNA. The optimized method has been applied to the identification and quantitation of DNA extracted and amplified by PCR from peanuts and from peanut-containing foods, allowing for a very sensitive detection at a very low level (few pmol).     

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.     

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.     

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.     

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.     

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.     

RNA hairpin invasion and ribosome elongation arrest by mixed base PNA oligomer

Recently, we have shown that peptide nucleic acid (PNA) tridecamers targeted to the codon 74, 128 and 149 regions of Ha-ras mRNA arrested translation elongation in vitro. Our data demonstrated for the first time that PNAs with mixed base sequence targeted to the coding region of a messenger RNA could arrest the translation machinery and polypeptide chain elongation. The peculiarity of the complexes formed with PNA tridecamers and Ha-ras mRNA rests upon the stability of PNA-mRNA hybrids, which are not dissociated by cellular proteins or multiple denaturing conditions. In the present study, we show that shorter PNAs such as a dodecamer or an undecamer targeted to the codon 74 region arrest translation elongation in vitro. The 13, 12, and 11-mer PNAs contain eight and the 10-mer PNA seven contiguous pyrimidine residues. Upon binding with parallel Hoogsteen base-pairing to the PNA-RNA duplex, six of the cytosine bases and one thymine base of a second PNA can form C.G*C(+) and T.A*T triplets. Melting experiments show two well-resolved transitions corresponding to the dissociation of the third strand from the core duplex and to melting of duplex at higher temperature. The enzymatic structure mapping of a target 27-mer RNA revealed a hairpin structure that is disrupted upon binding of tri-, dodeca-, undeca- and decamer PNAs. We show that the non-bonded nucleobase overhangs on the RNA stabilize the PNA-RNA hybrids and probably assist the PNA in overcoming the stable secondary structure of the RNA target. The great stability of PNA-RNA duplex and triplex structures allowed us to identify both 1:1 and 2:1 PNA-RNA complexes using matrix-assisted laser desorption/ionization time-of -flight mass spectrometry. Therefore, it is possible to successfully target mixed sequences in structured regions of messenger RNA with short PNA oligonucleotides that form duplex and triplex structures that can arrest elongating ribosomes.     

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.     

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.     

Interactions of DNA binding ligands with PNA-DNA hybrids.

The interactions of two representative mixed-sequence (one with an AT-stretch) PNA-DNA duplexes (10 or 15 base-pairs) and a PNA2/DNA triplex with the DNA binding reagents distamycin A, 4',6-diamidino-2-phenylindole (DAPI), ethidium bromide, 8-methoxy-psoralen and the delta and lambda enantiomers of Ru(phen)2-dppz2+ have been investigated using optical spectroscopic methods. The behaviour of these reagents versus two PNA-PNA duplexes has also been investigated. With triple helical poly(dA)/(H-T10-Lys-NH2)2 no significant intercalative binding was detected for any of the DNA intercalators, whereas DAPI, a DNA minor groove binder, was found to exhibit a circular dichroism with a positive sign and amplitude consistent with minor groove binding. Similarly, a PNA-DNA duplex containing a central AATA motif, a typical minor groove binding site for the DNA minor groove binders distamycin A and DAPI, showed binding for both of these drugs, though with strongly reduced affinity. No important interactions were found for any of the ligands with a PNA-DNA duplex consisting of a ten base-pair mixed purine-pyrimidine sequence with only two AT base-pairs in the centre. Nor did any of the ligands show any detectable binding to the PNA-PNA duplexes (one containing an AATT motif). Various PNA derivatives with extentions of the backbone, believed to increase the flexibility of the duplex to opening of an intercalation slot, were tested for intercalation of ethidium bromide or 8-methoxypsoralen into the mixed sequence PNA-DNA duplex, however, without any observation of improved binding. The importance of the ionic contribution of the deoxyribose phosphate backbone, versus interactions with the nucleobases, for drug binding to DNA is discussed in the light of these findings.