Increased DNA binding and sequence discrimination of PNA oligomers containing 2,6-diaminopurine.

The synthesis of a diaminopurine PNA monomer, N-[N6-(benzyloxycarbonyl)-2,6-diaminopurine-9-yl] acetyl-N-(2-t-butyloxycarbonylaminoethyl)glycine, and the incorporation of this monomer into PNA oligomers are described. Substitution of adenine by diaminopurine in PNA oligomers increased the T m of duplexes formed with complementary DNA, RNA or PNA by 2.5-6.5 degrees C per diaminopurine. Furthermore, discrimination against mismatches facing the diaminopurine in the hybridizing oligomer is improved. Finally, a homopurine decamer PNA containing six diaminopurines is shown to form a (gel shift) stable strand displacement complex with a target in a 246 bp double-stranded DNA fragment.     

Synthesis of peptide nucleic acid oligomers carrying 5-methylcytosine derivatives by postsynthetic substitution

Summary The preparation of the thymine peptide nucleic acid (PNA) monomer carrying a 2-nitrophenyl group in position 4 is described. This monomer is incorporated into PNA oligomers and reacted with amines to yield PNA oligomers carrying 5-methylcytosine derivatives. During the deprotection-modification step two side reactions were detected: degradation of PNA oligomer from theN-terminal residue and modification ofN ⁴-tert-butylbenzoyl cytosine residue. Protection of theN-terminal position and the use ofN ⁴-acetyl group for the protection of cytosine eliminate these side reactions.     

Synthesis of a new disulfide Fmoc monomer for creating biologically susceptible linkages in peptide nucleic acid oligomers

Peptide nucleic acids (PNA) are one of many synthetic mimics of DNA and RNA that have found applications as biological probes, as nano-scaffold components, and in diagnostics. In an effort to use PNA as constructs for cellular delivery we investigated the possibility of installing a biologically susceptible disulfide bond in the backbone of a PNA oligomer. Here we report the synthesis of a new abasic Fmoc monomer containing a disulfide bond that can be incorporated into a PNA oligomer (DS-PNA) using standard solid phase peptide synthesis. The disulfide bond survives cleavage from the resin and DS-PNA forms duplexes with complementary PNA oligomers. Initial studies aimed at determining if the disulfide bond is cleavable to reducing agents while in a duplex are explored using UV thermal analysis and HPLC.     

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.     

Nuclear antisense effects of neutral, anionic and cationic oligonucleotide analogs

The antisense activity of oligomers with 2'-O-methyl (2'-O-Me) phosphorothioate, 2'-O-methoxyethyl (2'-O-MOE) phosphorothioate, morpholino and peptide nucleic acid (PNA) backbones was investigated using a splicing assay in which the modified oligonucleotides blocked aberrant and restored correct splicing of modified enhanced green fluorescent protein (EGFP) precursor to mRNA (pre-mRNA), generating properly translated EGFP. In this approach, antisense activity of each oligomer was directly proportional to up-regulation of the EGFP reporter. This provided a positive, quantitative readout for sequence-specific antisense effects of the oligomers in the nuclei of individual cells. Nuclear localization of fluorescent labeled oligomers confirmed validity of the functional assay. The results showed that the free uptake and the antisense efficacy of neutral morpholino derivatives and cationic PNA were much higher than that of negatively charged 2'-O-Me and 2'-O-MOE congeners. The effects of the PNA oligomers were observed to be dependent on the number of L-lysine (Lys) residues at the C-terminus. The experiments suggest that the PNA containing Lys was taken up by a mechanism similar to that of cell-penetrating homeodomain proteins and that the Lys tail enhanced intracellular accumulation of PNA oligomer without affecting its ability to reach and hybridize to the target sequence.     

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.     

Synthesis of a monocharged peptide nucleic acid (PNA) analog and its recognition as substrate by DNA polymerases.

The preparation of a novel phosphoramidite monomer based on thyminyl acetic acid coupled to the secondary nitrogen of 2-(2-amino-ethylamino)ethanol is described. This monomer can be used to attach a deoxynucleotide to the carboxy terminus of a PNA oligomer by solid-phase synthesis. The resulting PNA primer is recognized as a substrate by various DNA polymerases.     

SYNTHESIS AND PROPERTIES OF PNA OLIGOMERS CONTAINING OROTIC ACID DERIVATIVES

We have investigated the incorporation of C6-derivatives of uracil into polypyrimidine peptide nucleic acid oligomers (PNA). Starting with orotic acid (uracil-6-carboxylic acid) we have prepared a PNA monomer containing the methyl orotate nucleobase which is compatible with Fmoc-based synthesis. Treatment of the resin-bound oligomers with hydroxide or amines cleanly converted the ester to an orotic acid or orotamide-containing PNA. Alternatively, the methyl orotate-containing PNA was liberated from the resin by standard acidolysis. PNA bearing a modified nucleobase was found to hybridize to both poly(rA) and poly(dA). Complexes with poly(rA) were more stable than those with poly(dA) but both were destabilized relative to an unmodified PNA. Modification of a terminal residue was tolerated better than modification of an internal position. The type of charge provided by the modification affected the complex stability. In the worst case, an internal modification was nearly as detrimental as a base mismatch.     

Synthesis and properties of PNA oligomers containing orotic acid derivatives

We have investigated the incorporation of C6-derivatives of uracil into polypyrimidine peptide nucleic acid oligomers (PNA). Starting with orotic acid (uracil-6-carboxylic acid) we have prepared a PNA monomer containing the methyl orotate nucleobase which is compatible with Fmoc-based synthesis. Treatment of the resin-bound oligomers with hydroxide or amines cleanly converted the ester to an orotic acid or orotamide-containing PNA. Alternatively, the methyl orotate-containing PNA was liberated from the resin by standard acidolysis. PNA bearing a modified nucleobase was found to hybridize to both poly(rA) and poly(dA). Complexes with poly(rA) were more stable than those with poly(dA) but both were destabilized relative to an unmodified PNA. Modification of a terminal residue was tolerated better than modification of an internal position. The type of charge provided by the modification affected the complex stability. In the worst case, an internal modification was nearly as detrimental as a base mismatch.     

Constrained flexibility in PNA: DNA binding studies with bridged aminopropylglycyl PNA

Introduction of methylene bridges in aegPNA and apgPNA molecules give rise to cyclic five and six membered ring structures. Synthesis of a new six membered cyclic PNA monomer, aminopipecolyl PNA (pipPNA) is reported. Incorporation of pipPNA into PNA oligomers and comparative binding with target DNA sequences is studied.     

Evaluation of transfection protocols for unmodified and modified peptide nucleic acid (PNA) oligomers

We have compared the efficacy of different transfection protocols reported for peptide nucleic acid (PNA) oligomers. A precise evaluation of uptake efficacy was achieved by using a positive readout assay based on the ability of a PNA oligomer to correct aberrant splicing of a recombinant luciferase gene. The study comprised transfection of PNA conjugated to acridine, adamantyl, decanoic acid, and porphyrine (acr-PNA, ada-PNA, deca-PNA, and por-RNA, respectively) and unmodified PNA partially hybridized to a DNA oligomer (PNA/DNA cotransfection). Furthermore, the effect of conjugation to a nuclear localization signal (NLS) was evaluated as part of the PNA/DNA cotransfection protocol. Transfection of the tested PNAs was systematically optimized. PNA/DNA cotransfection was found to produce the highest luciferase activity, but only after careful selection of the DNA oligonucleotide. Both a cationic lipid, Lipofectamine, and a nonliposomal cationic polymer, polyethylenimine (PEI, ExGen 500), were efficient transfection reagents for the PNA/DNA complex. However, Lipofectamine, in contrast to PEI, showed severe side effects, such as cytotoxicity. acr-PNA, ada-PNA, and por-PNA were transfectable with efficacies between 5 and 10 times lower than that seen with PNA/DNA cotransfection. Conjugation of PNA to NLS had no effect on PNA/DNA cotransfection efficacy. An important lesson from the study was the finding that because of uncontrollable biologic variations, even optimal transfection conditions differed to a certain extend from experiment to experiment in an unpredictable way.     

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.     

PNA monomers fully compatible with standard Fmoc-based solid-phase synthesis of pseudocomplementary PNA

Here we report the synthesis of new PNA monomers for pseudocomplementary PNA (pcPNA) that are fully compatible with standard Fmoc chemistry. The thiocarbonyl group of the 2-thiouracil (sU) monomer was protected with the 4-methoxy-2-methybenzyl group (MMPM), while the exocyclic amino groups of diaminopurine (D) were protected with Boc groups. The newly synthesized monomers were incorporated into a 10-mer PNA oligomer using standard Fmoc chemistry for solid-phase synthesis. Oligomerization proceeded smoothly and the HPLC and MALDI-TOF MS analyses indicated that there was no remaining MMPM on the sU nucleobase. The new PNA monomers reported here would facilitate a wide range of applications, such as antigene PNAs and DNA nanotechnologies.     

CONSTRAINED FLEXIBILITY IN PNA: DNA BINDING STUDIES WITH BRIDGED AMINOPROPYLGLYCYL PNA

Introduction of methylene bridges in aegPNA and apgPNA molecules give rise to cyclic five and six membered ring structures. Synthesis of a new six membered cyclic PNA monomer, aminopipecolyl PNA (pipPNA) is reported. Incorporation of pipPNA into PNA oligomers and comparative binding with target DNA sequences is studied.     

Systemically delivered antisense oligomers upregulate gene expression in mouse tissues

Systemically injected 2'-O-methoxyethyl (2'-O-MOE)-phosphorothioate and PNA-4K oligomers (peptide nucleic acid with four lysines linked at the C terminus) exhibited sequence-specific antisense activity in a number of mouse organs. Morpholino oligomers were less effective, whereas PNA oligomers with only one lysine (PNA-1K) were completely inactive. The latter result indicates that the four-lysine tail is essential for the antisense activity of PNA oligomers in vivo. These results were obtained in a transgenic mouse model designed as a positive readout test for activity, delivery, and distribution of antisense oligomers. In this model, the expressed gene (EGFP-654) encoding enhanced green fluorescence protein (EGFP) is interrupted by an aberrantly spliced mutated intron of the human beta-globin gene. Aberrant splicing of this intron prevented expression of EGFP-654 in all tissues, whereas in tissues and organs that took up a splice site-targeted antisense oligomer, correct splicing was restored and EGFP-654 expression upregulated. The sequence-specific ability of PNA-4K and the 2'-O-MOE oligomers to upregulate EGFP-654 provides strong evidence that systemically delivered, chemically modified oligonucleotides affect gene expression by sequence-specific true antisense activity, validating their application as potential therapeutics.     

C3′-endo-puckered pyrrolidine containing PNA has favorable geometry for RNA binding: Novel ethano locked PNA (ethano-PNA)

A novel peptide nucleic acid (PNA) analogue is designed with a constraint in the aminoethyl segment of the aegPNA backbone so that the dihedral angle β is restricted within 60–80°, compatible to form PNA:RNA duplexes. The designed monomer is further functionalized with positively charged amino-/guanidino-groups. The appropriately protected monomers were synthesized and incorporated into aegPNA oligomers at predetermined positions and their binding abilities with cDNA and RNA were investigated. A single incorporation of the modified PNA monomer into a 12-mer PNA sequence resulted in stronger binding with complementary RNA over cDNA. No significant changes in the CD signatures of the derived duplexes of modified PNA with complementary RNA were observed.     

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.     

Depolymerization of phospholamban in the presence of calcium pump: a fluorescence energy transfer study

Phospholamban (PLB), a 52-amino acid protein, regulates the Ca-ATPase (calcium pump) in cardiac sarcoplasmic reticulum (SR) through PLB phosphorylation mediated by beta-adrenergic stimulation. The mobility of PLB on SDS-PAGE indicates a homopentamer, and it has been proposed that the pentameric structure of PLB is important for its regulatory function. However, the oligomeric structure of PLB must be determined in its native milieu, a lipid bilayer containing the Ca-ATPase. Here we have used fluorescence energy transfer (FET) to study the oligomeric structure of PLB in SDS and dioleoylphosphatidylcholine (DOPC) lipid bilayers reconstituted in the absence and presence of Ca-ATPase. PLB was labeled, specifically at Lys 3 in the cytoplasmic domain, with amine-reactive fluorescent donor/acceptor pairs. FET between donor- and acceptor-labeled subunits of PLB in SDS solution and DOPC lipid bilayers indicated the presence of PLB oligomers. The dependence of FET efficiency on the fraction of acceptor-labeled PLB in DOPC bilayers indicated that it is predominantly an oligomer having 9-11 subunits, with approximately 10% of the PLB as monomer, and the distance between dyes on adjacent PLB subunits is 0.9 +/- 0.1 nm. When labeled PLB was reconstituted with purified Ca-ATPase, FET indicated the depolymerization of PLB into smaller oligomers having an average of 5 subunits, with a concomitant increase in the fraction of monomer to 30-40% and a doubling of the intersubunit distance. We conclude that PLB exists primarily as an oligomer in membranes, and the Ca-ATPase affects the structure of this oligomer, but the Ca-ATPase binds preferentially to the monomer and/or small oligomers. These results suggest that the active inhibitory species of PLB is a monomer or an oligomer having fewer than 5 subunits.     

Synthesis of peptide nucleic acid oligomers carrying 5-methylcytosine derivatives by postsynthetic substitution

The preparation of the thymine peptide nucleicacid (PNA) monomer carrying a 2-nitrophenyl group in position4 is described. This monomer is incorporated into PNAoligomers and reacted with amines to yield PNA oligomerscarrying 5-methylcytosine derivatives. During thedeprotection-modification step two side reactions weredetected: degradation of PNA oligomer from the N-terminal residue and modification of N ⁴-tert-butylbenzoyl cytosine residue. Protection of the N-terminal position and the use of N ⁴-acetyl group for the protection of cytosine eliminate these side reactions.     

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.