Peptide nucleic acid-metal complex conjugates: facile modulation of PNA-DNA duplex stability

Conjugates of peptide nucleic acids (PNA) and metal binding ligands were prepared using solid-phase synthesis. Stability of duplexes of bis-picolylamine-PNA conjugates and DNA was found to be modulated by equimolar concentrations of bioavailable metal ions: Ni(2+), Zn(2+)>Cu(2+). Sequence specificity of PNA was not compromised in the presence of these metal ions.     

Chiral introduction of positive charges to PNA for double-duplex invasion to versatile sequences

Invasion of two PNA strands to double-stranded DNA is one of the most promising methods to recognize a predetermined site in double-stranded DNA (PNA = peptide nucleic acid). In order to facilitate this 'double-duplex invasion', a new type of PNA was prepared by using chiral PNA monomers in which a nucleobase was bound to the alpha-nitrogen of N-(2-aminoethyl)-d-lysine. These positively charged monomer units, introduced to defined positions in Nielsen's PNAs (poly[N-(2-aminoethyl)glycine] derivatives), promoted the invasion without impairing mismatch-recognizing activity. When pseudo-complementary nucleobases 2,6-diaminopurine and 2-thiouracil were bound to N-(2-aminoethyl)-d-lysine, the invasion successfully occurred even at highly G-C-rich regions [e.g. (G/C)7(A/T)3 and (G/C)8(A/T)2] which were otherwise hardly targeted. Thus, the scope of sequences available as the target site has been greatly expanded. In contrast with the promotion by the chiral PNA monomers derived from N-(2-aminoethyl)-d-lysine, their l-isomers hardly invaded, showing crucial importance of the d-chirality. The promotion of double-duplex invasion by the chiral (d) PNA monomer units was ascribed to both destabilization of PNA/PNA duplex and stabilization of PNA/DNA duplexes.     

The interaction of native DNA with Zn(II) and Cu(II) complexes of 5-triethyl ammonium methyl salicylidene orto-phenylendiimine

The interaction of native calf thymus DNA with the Zn(II) and Cu(II) complexes of 5-triethyl ammonium methyl salicylidene orto-phenylendiimine (ZnL(2+) and CuL(2+)), in 1 mM Tris-HCl aqueous solutions at neutral pH, has been monitored as a function of the metal complex-DNA molar ratio by UV absorption spectrophotometry, circular dichroism (CD) and fluorescence spectroscopy. The results support for an intercalative interaction of both ZnL(2+) and CuL(2+) with DNA, showing CuL(2+) an affinity of approximately 10 times higher than ZnL(2+). In particular, the values of the binding constant, determined by UV spectrophotometric titration, equal to 7.3x10(4) and 1.3x10(6)M(-1), for ZnL(2+) and CuL(2+), respectively, indicate the occurrence of a marked interaction with a binding size of about 0.7 in base pairs. The temperature dependence of the absorbance at 258 nm suggests that both complexes strongly increase the DNA melting temperature (Tm) already at metal complex-DNA molar ratios equal to 0.1. As evidenced by the quenching of the fluorescence of ethidium bromide-DNA solutions in the presence of increasing amounts of metal complex, ZnL(2+) and CuL(2+) are able to displace the ethidium cation intercalated into DNA. A tight ZnL(2+)-DNA and CuL(2+)-DNA binding has been also proven by the appearance, in both metal complex-DNA solutions, of a broad induced CD band in the range 350-450 nm. In the case of the CuL(2+)-DNA system, the shape of the CD spectrum, at high CuL(2+) content, is similar to that observed for psi-DNA solutions. Such result allowed us to hypothesize that CuL(2+) induces the formation of supramolecular aggregates of DNA in aqueous solutions.     

Evaluating the Effect of Ionic Strength on Duplex Stability for PNA Having Negatively or Positively Charged Side Chains

The enhanced thermodynamic stability of PNA:DNA and PNA:RNA duplexes compared with DNA:DNA and DNA:RNA duplexes has been attributed in part to the lack of electrostatic repulsion between the uncharged PNA backbone and negatively charged DNA or RNA backbone. However, there are no previously reported studies that systematically evaluate the effect of ionic strength on duplex stability for PNA having a charged backbone. Here we investigate the role of charge repulsion in PNA binding by synthesizing PNA strands having negatively or positively charged side chains, then measuring their duplex stability with DNA or RNA at varying salt concentrations. At low salt concentrations, positively charged PNA binds more strongly to DNA and RNA than does negatively charged PNA. However, at medium to high salt concentrations, this trend is reversed, and negatively charged PNA shows higher affinity for DNA and RNA than does positively charged PNA. These results show that charge screening by counterions in solution enables negatively charged side chains to be incorporated into the PNA backbone without reducing duplex stability with DNA and RNA. This research provides new insight into the role of electrostatics in PNA binding, and demonstrates that introduction of negatively charged side chains is not significantly detrimental to PNA binding affinity at physiological ionic strength. The ability to incorporate negative charge without sacrificing binding affinity is anticipated to enable the development of PNA therapeutics that take advantage of both the inherent benefits of PNA and the multitude of charge-based delivery technologies currently being developed for DNA and RNA.     

Peptide nucleic acid (PNA)/DNA hybrid duplexes: intercalation by an internally linked anthraquinone.

Peptide nucleic acids (PNA) mimic DNA and RNA by forming complementary duplex structures following Watson-Crick base pairing. A set of reporter compounds that bind to DNA by intercalation are known, but these compounds do not intercalate in PNA/DNA hybrid duplexes. Analysis of the hybrid PNA duplexes requires development of reporter compounds that probe their chemical and physical properties. We prepared a series of anthraquinone (AQ) derivatives that are linked to internal positions of a PNA oligomer. These are the first non-nucleobase functional groups that have been incorporated into a PNA. The resulting PNA(AQ) conjugates form stable hybrids with complementary DNA oligomers. We find that when the AQ groups are covalently bound to PNA that they stabilize the hybrid duplex and are, at least partially, intercalated.     

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.     

Comparison of thermodynamic stabilities between PNA (peptide nucleic acid)/DNA hybrid duplexes and DNA/DNA duplexes.

We have examined quantitatively stabilities of PNA/DNA hybrid duplexes with identical nearest-neighbor base pairs and compared stabilities between PNA/DNA and DNA/DNA. The average difference of stabilization energy of the short PNA/DNA was 0.9 kcal mol(-1), which suggests that the stability of the hybrids with identical nearest-neighbor base pairs can be predicted with the nearest-neighbor model as well as those of nucleic acid duplexes.     

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.     

Stabilization factors affecting duplex formation of peptide nucleic acid with DNA.

Peptide nucleic acid (PNA) is an oligonucleotide analogue in which the sugar-phosphate backbone is replaced by an N-(2-aminoethyl)glycine unit to which the nucleobases are attached. We investigated the thermodynamic behavior of PNA/DNA hybrid duplexes with identical nearest neighbors but with different sequences and chain lengths (5, 6, 7, 8, 10, 12, and 16 mers) to reveal whether the nearest-neighbor model is valid for the PNA/DNA duplex stability. CD spectra of 6, 7, and 8 mer PNA/DNA duplexes showed similar signal, while 10, 12, and 16 mer duplexes did not. The average difference in Delta G degrees (37) for short PNA/DNA duplexes with identical nearest-neighbor pairs was only 3.5%, whereas that of longer duplexes (10, 12, and 16 mers) was 16.4%. Therefore, the nearest-neighbor model seems to be useful at least for the short PNA/DNA duplexes. Thermodynamics of PNA/DNA duplexes containing 1--3 bulge residues were also studied. While the stability of the 12 mer DNA/DNA duplex decreased as the number of bulge bases increases, the number of bulge bases in PNA/DNA unchanged the duplex stability. Thus, the influence of bulge insertion in the PNA/DNA duplexes is different from that of a DNA/DNA duplex. This might be due to the different base geometry in a helix which may potentially make hydrogen bonds in a base pair and stacking interaction unfavorable compared with DNA/DNA duplexes.     

Insertion of an internal dipeptide into PNA oligomers: thermal melting studies and further functionalization

The solid phase synthesis of PNA oligomers with the internal dipeptide Gly-Phe is presented and the interaction with complementary DNA investigated. UV absorbance melting experiments with different but complementary DNA sequences show that stable PNA x DNA duplexes are only obtained when there is no DNA base opposite the dipeptide unit. Instead, the dipeptide spacer forms a loop-like structure within the duplex. Further functionalization with N-heterocyclic ligands is described. p-Nitro-phenylalanine is introduced in place of Phe during solid phase synthesis and subsequently reduced to p-amino-phenylalanine. Reaction with activated acids provides the ligand conjugates in high yield and purity. This strategy opens a universal route to a large number of internal substitutions in PNA chemistry.     

Raman and IR spectroscopic investigation of zinc(II)-carnosine complexes

The zinc(II)-L-carnosine system was investigated at different pH and metal/ligand ratios by Raman and IR spectroscopy. The Raman and IR spectra present some marker bands useful to identify the sites involved in metal chelation at a specific pH value. In particular, the neutral imidazole group gives rise to some Raman bands, such as the nu C(4)===C(5) band, that change in wave number, depending on whether the imidazole ring takes the tautomeric form I or II. Even if tautomer I is predominant in the free ligand, metal coordination can upset tautomeric preference and N(tau)- and N(pi)-ligated complexes can be identified. Although weak compared to those of aromatic residues, these Raman marker bands may be useful in analyzing metal-histidine interaction in peptides and proteins. On the basis of the vibrational results, conclusions can be drawn on the species existing in the system. Depending on the available nitrogen atoms, various complexes can be formed and the prevalent form of the species depends mainly on the pH. At basic pH carnosine gives rise to two different neutral complexes: a water-insoluble polymeric species, [ZnH(-1)L](0)(n), and a dimer, [Zn(2)H(-2)L(2)](0). The first is predominant and involves the tautomeric I form of the imidazole ring in metal chelation; the second contains tautomer II and increases its percentage by going from a 2 to 0.25 metal/ligand ratio. Conversely, the dimeric species dominates at pH 7, whereas two charged species, [ZnHL](2+) and [ZnL](+), are formed under slightly acidic conditions. In the [ZnHL](2+) complex the imidazole ring takes part in the Zn(II) coordination in the tautomeric I form, whereas in [ZnL](+) the ring is protonated and not bound to the Zn(II) ion. In addition, the curve fitting analysis of the 1700-1530 cm(-1) Raman region was helpful in indicating the predominant species at each pH.     

Synthesis of metallointercalator-DNA conjugates on a solid support

Metallointercalator-DNA conjugates were prepared by amide bond formation between active esters on the nonintercalating ligands of transition metal complexes and primary amines presented at the 5' or the 3' termini of oligonucleotides attached to solid supports. The conjugates were liberated from the support by aminolysis and purified by HPLC on C18 or C4 stationary phases, which separates the two diastereomeric forms of the conjugates containing either the Lambda or the Delta enantiomer of the octahedral metal complex. The coupling reaction proceeds with approximately 75% conversion of the amino-terminated oligonucleotide into the conjugate; the isolated yield is approximately 200 nmol for syntheses initiated on DNA-synthesis columns with a loading of 2 micromol. The conjugates were characterized by ultraviolet-visible and circular dichorism absorption spectroscopy, electrospray ionization mass spectrometry, enzymatic digestion, and polyacrylamide gel electrophoresis (PAGE). Oligonucleotides bearing [Rh(phi)(2)(bpy')](3+) (phi = 9, 10-phenanthrene quinone diimine; bpy' = 4-butyric acid-4'-methyl bipyridyl) form 1:1 duplexes with the complementary strand, and the electrophoretic mobility under nondenaturating PAGE of duplexes containing Delta-Rh is notably different from duplexes containing Lambda-Rh. High-resolution PAGE of DNA photocleavage reactions initiated by irradiation of the tethered Rh complexes reveal intercalation of the complex only near the tethered end of the duplex. Analogous DNA-binding properties were observed with [Rh(phi)(2)(bpy')](3+) tethered to the 3' terminus. By combining the 3' and 5' modification strategies, a mixed-metal DNA conjugate containing both [Os(phen)(bpy')(Me(2)-dppz)](2+) (Me(2)-dppz = 7, 8-dimethyldipyridophenazine) on the 3' terminus and [Rh(phi)(2)(bpy')](3+) on the 5' terminus was prepared and isolated. Taken together, these strategies for preparing metallointercalator-DNA conjugates offer a useful approach to generate chemical assemblies to probe long-range DNA-mediated charge transfer where the redox initiator is confined to and intercalated in a well-defined binding site.     

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.     

Composites of peptide nucleic acids with titanium dioxide nanoparticles. III. Kinetics of PNA dissociation from nanocomposites containing DNA/PNA duplexes

When delivering peptide nucleic acids (PNA) into cells in the TiO₂ · PL · DNA/PNA nanocomposites consisting of titanium dioxide nanoparticles coated with polylysine (PL) and immobilized DNA/PNA duplexes, it is important to control the rate of the release of PNA from the carrier due to dissociation of the immobilized DNA/PNA duplex, followed by the desorption of PNA to solution while the DNA remains on the carrier. It was found that the rate constant of dissociation of the DNA/PNA duplex in the TiO₂ · PL · DNA/PNA nanocomposites depended on the number of complementary bases in the duplex. The half-retention time values for PNA in the studied nanocomposites containing the duplexes with 10, 12, 14, and 16 overlapping complementary base pairs were 10, 14, 22, and 70 min, respectively. Thus, it was shown that the rate of the release of PNA from the proposed nanocomposites can be controlled by varying the number of overlapping complementary base pairs in the immobilized DNA/PNA duplex. The method of the PNA immobilization may be used for designing nanocomposites having the optimum time value of the PNA release. The proposed TiO₂ · PL · DNA/PNA nanocomposites can be used to efficiently deliver therapeutically significant PNA drugs for their selective effect on pathogenic nucleic acids in cells.     

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.     

The width of the minor groove affects the binding of the bisquaternary heterocycle SN-6999 to duplex DNA.

A complex between d(GGGAAAAACGG).d(CCGTTTTTCCC) and the minor groove binding drug SN-6999 has been studied by 1H nuclear magnetic resonance spectroscopy. The drug is found to bind in the d(A)5 tract, but with interactions extending one residue in the 3'-direction along each strand. Doubling of resonances in the complex indicates slow to intermediate exchange between two binding modes. An orientational preference (7:3) is found, the first such example in an SN-6999 complex. Furthermore, the upper limit of the lifetime for the major species is longer than was found for SN-6999 with other DNA duplexes. The preferred orientation of SN-6999 has the pyridinium ring near the 5'-end of the (+) strand; the minor binding mode has the reverse orientation. The orientational preference and slower exchange rate relative to other SN-6999 complexes is attributed to increased stabilization from van der Waals interactions due to better shape complementarity between the DNA duplex and ligand. The comparison of these results with studies of SN-6999 complexed to other DNA duplexes reveals the sensitivity of the binding properties to the delicate interplay between the molecular structure of the ligand and the specific characteristics of the DNA minor groove.     

Fast and easy colorimetric tests for single mismatch recognition by PNA–DNA duplexes with the diethylthiadicarbocyanine dye and succinyl-β-cyclodextrin

The 3,3′-diethylthiacarbocyanine (DiSC₂(5)) dye is able to aggregate on full matched PNA–DNA duplexes by changing its absorption properties, which are manifested by an instantaneous colour shift from blue to purple. However the spontaneous aggregation of the dye also on mismatched duplexes and even on free PNA strands makes the test quite aspecific. Here it is demonstrated that the addition of succinyl-β-cyclodextrin (Succ-β-CyD) to the solutions containing PNA–DNA duplexes and the dye strongly enhances the specificity of the colour shift, allowing for a fast, very specific and extremely sensitive visual recognition of mismatches in DNA strands by using PNA probes in combination with the DiSC₂(5) dye. The phenomenon has been studied by CD and NMR spectroscopies. The method has been optimized and preliminarily applied for the recognition of an apoE gene mutation in human DNA samples.