Sequence-specific targeting of duplex DNA by peptide nucleic acids via triplex strand invasion

Because of a set of exceptional chemical, physical, and biological properties, polyamide or peptide nucleic acids (PNAs) hold a distinctive position among various synthetic ligands designed for DNA-targeting purposes. Cationic pyrimidine PNAs (cpyPNAs) represent a special group of PNAs, which effectively form strand invasion triplexes with double-stranded DNA (dsDNA) also known as P-loops. Extraordinary stability of the invasion triplexes and high sequence specificity of their formation combined with local opening of the DNA double helix within the P-loops make these complexes very attractive for sequence-specific manipulation with dsDNA. Important for applications is the fact that the discrimination between correct and mismatched binding sites in dsDNA by cpyPNAs is a nonequilibrium, kinetically controlled process. Therefore, a careful choice of experimental conditions that are optimal for the kinetic discrimination of correct versus mismatched cpyPNA binding is crucial for sequence-specific recognition of dsDNA by cpyPNAs. The experimental and theoretical data presented make it possible to select those solution parameters and cpyPNA constructions that are most favorable for sequence specificity without compromising the affinity of dsDNA targeting.     

Kinetic analysis of specificity of duplex DNA targeting by homopyrimidine peptide nucleic acids

A simple theoretical analysis shows that specificity of double-stranded DNA (dsDNA) targeting by homopyrimidine peptide nucleic acids (hpyPNAs) is a kinetically controlled phenomenon. Our computations give the optimum conditions for sequence-specific targeting of dsDNA by hpyPNAs. The analysis shows that, in agreement with the available experimental data, kinetic factors play a crucial role in the selective targeting of dsDNA by hpyPNAs. The selectivity may be completely lost if PNA concentration is too high and/or during prolonged incubation of dsDNA with PNA. However, quantitative estimations show that the experimentally observed differences in the kinetic constants for hpyPNA binding with the correct and mismatched DNA sites are sufficient for sequence-specific targeting of long genomic DNA by hpyPNAs with a high yield under appropriate experimental conditions. Differential dissociation of hpyPNA/dsDNA complexes is shown to enhance the selectivity of DNA targeting by PNA.     

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.     

Inhibiting gene expression with peptide nucleic acid (PNA)--peptide conjugates that target chromosomal DNA

Peptide nucleic acids (PNAs) are nonionic DNA/RNA mimics that can recognize complementary sequences by Watson-Crick base pairing. The neutral PNA backbone facilitates the recognition of duplex DNA by strand invasion, suggesting that antigene PNAs (agPNAs) can be important tools for exploring the structure and function of chromosomal DNA inside cells. However, before agPNAs can enter wide use, it will be necessary to develop straightforward strategies for introducing them into cells. Here, we demonstrate that agPNA-peptide conjugates can target promoter DNA and block progesterone receptor (PR) gene expression inside cells. Thirty-six agPNA-peptide conjugates were synthesized and tested. We observed inhibition of gene expression using cationic peptides containing either arginine or lysine residues, with eight or more cationic amino acids being preferred. Both 13 and 19 base agPNA-peptide conjugates were inhibitory. Inhibition was observed in human cancer cell lines expressing either high or low levels of progesterone receptor. Modification of agPNA-peptide conjugates with hydrophobic amino acids or small molecule hydrophobic moieties yielded improved potency. Inhibition by agPNAs did not require cationic lipid or any other additive, but adding agents to cell growth media that promote endosomal release caused modest increases in agPNA potency. These data demonstrate that chromosomal DNA is accessible to agPNA-peptide conjugates and that chemical modifications can improve potency.     

Imaging gene expression using oligonucleotides and peptide nucleic acids

The development of methods for non-invasive, real-time imaging of gene expression would provide powerful tools for biomedical research and medical diagnostics. A broadly applicable strategy for achieving this goal is the use of complementary oligonucleotide probes for recognition of mRNA. The major challenge for molecular imaging is the development of specific and efficient transducers for signaling probe-target interaction. This review summarizes the strengths and limitations of reported molecular approaches for imaging of mRNA expression and discusses the challenges to development of in vivo methods.     

Inhibition of gene expression by peptide nucleic acids in cultured cells

We have tested in cultured cells the capacity of antisense and antigene PNAs to inhibit, in a sequence specific manner, the expression of oncogenes in leukaemia and pancreatic carcinoma cells. The results observed appeared promising and suggest that PNA may play in the future an important role in targeting disease-related genes.     

Efficient and isoform-selective inhibition of cellular gene expression by peptide nucleic acids

Peptide nucleic acids (PNAs) are a potentially powerful approach for the recognition of cellular mRNA and the inhibition of gene expression. Despite their promise, the rules for using antisense PNAs have remained obscure, and antisense PNAs have been used sparingly in research. Here we investigate the ability of PNAs to be effective antisense agents inside mammalian cells, to inhibit expression of human caveolin-1 (hCav-1), and to discriminate between its alpha and beta isoforms. Many human genes are expressed as isoforms. Isoforms may play different roles within a cell or within different tissues, and defining these roles is a challenge for functional genomics and drug discovery. PNAs targeted to the translation start codons for the alpha and beta isoforms inhibit expression of hCav-1. Inhibition is dependent on PNA length. The potency and duration of inhibition by PNAs are similar to inhibition of gene expression by short interferring RNA (siRNA). Expression of the alpha isoform can be blocked selectively by a PNA. Cell proliferation is halted by inhibition of expression of both hCav-1 isoforms, but not by inhibition of the alpha hCav-1 isoform alone. Efficient antisense inhibition and selective modulation of isoform expression suggest that PNAs are versatile tools for controlling gene expression and dissecting the roles of closely related protein variants. Potent inhibition by PNAs may supply a "knock down" technology that can complement and "cross-check" siRNA and other approaches to antisense gene inhibition that rely on oligomers with phosphate or phosphorothioate backbone linkages.     

Receptor-specific targeting with complementary peptide nucleic acids conjugated to peptide analogs and radionuclides

Genomic sequencing makes it possible to identify all the genes of an organism, now including Homo sapiens. Yet measurement of the expression of each gene of interest still presents a dauntingprospect. Northern blots, RNase protection assays, as well as microarrays and related technologies permit measurement of gene expression in total RNA extracted from cultured cells or tissue samples. It would be most valuable, however, to quantitate gene expression noninvasively in living cells and tissues. Unfortunately,no reliable method has been available to measure levels of specificmRNAs in vivo. Peptide nucleic acids (PNAs) display superior ruggedness and hybridization properties as a diagnostic tool for gene expression, and could be used for this purpose. On the down side, they are negligibly internalized by normal or malignant cells in the absence of conjugated ligands. Nevertheless,we have observed that Tc-99m-peptides can delineate tumors, and PNA-peptides designed to bind to IGF-1 receptors on malignant cellsare taken up specifically and concentrated in nuclei. We have postulated that antisense Tc-99m-PNA-peptides will be taken up by human cancer cells, will hybridize to complementary mRNA targets, and will permit scintigraphic imaging of oncogene mRNAsin human cancer xenografts in a mouse model. The oncogenes cyclinD1, ERBB2, c-MYC, K-RAS, and tumor suppressor p53 are being probed initially. These experimentsprovide a proof-of-principle for noninvasive detection of oncogeneexpression in living cells and tissues. This scintigraphic imaging technique should be applicable to any particular gene of interest in a cell or tissue type with characteristic receptors.     

Receptor-specific targeting with complementary peptide nucleic acids conjugated to peptide analogs and radionuclides

Summary Genomic sequencing makes it possible to identify all the genes of an organism, now including Homo sapiens. Yet measurement of the expression of each gene of interest still presents a daunting prospect. Northern blots, RNase protection assays, as well as microarrays and related technologies permit measurement of gene expression in total RNA extracted from cultured cells or tissue samples. It would be most valuable, however, to quantitate gene expression noninvasively in living cells and tissues. Unfortunately, no reliable method has been available to measure levels of specific mRNAs in vivo. Peptide nucleic acids (PNAs) display superior ruggedness and hybridization properties as a diagnostic tool for gene expression, and could be used for this purpose. On the down side, they are negligibly internalized by normal or malignant cells in the absence of conjugated ligands. Nevertheless, we have observed that Tc-99m-peptides can delineate tumors, and PNA-peptides designed to bind to IGF-1 receptors on malignant cells are taken up specifically and concentrated in nuclei. We have postulated that antisense Tc-99m-PNA-peptides will be taken up by human cancer cells, will hybridize to complementary mRNA targets, and will permit scintigraphic imaging of oncogene mRNAs in human cancer xenografts in a mouse model. The oncogenes cyclin D1, ERBB2, c-MYC, K-RAS, and tumor suppressor p53 are being probed initially. These experiments provide a proof-of-principle for noninvasive detection of oncogene expression in living cells and tissues. This scintigraphic imaging technique should be applicable to any particular gene of interest in a cell or tissue type with characteristic receptors.     

Receptor-specific targeting with complementary peptide nucleic acids conjugated to peptide analogs and radionuclides

Summary Genomic sequencing makes it possible to identify all the genes of an organism, now includingHomo sapiens. Yet measurement of the expression of each gene of interest still presents a daunting prospect. Northern blots, RNase protection assays, as well as microarrays and related technologies permit measurement of gene expression in total RNA extracted from cultured cells or tissue samples. It would be most valuable, however, to quantitate gene expression noninvasively in living cells and tissues. Unfortunately, no reliable method has been available to measure levels of specific mRNAsin vivo. Peptide nucleic acids (PNAs) display superior ruggedness and hybridization properties as a diagnostic tool for gene expression, and could be used for this purpose. On the down side, they are negligibly internalized by normal or malignant cells in the absence of conjugated ligands. Nevertheless, we have observed that Tc-99m-peptides can delineate tumors, and PNA-peptides designed to bind to IGF-1 receptors on malignant cells are taken up specifically and concentrated in nuclei. We have postulated that antisense Tc-99m-PNA-peptides will be taken up by human cancer cells, will hybridize to complementary mRNA targets, and will permit scintigraphic imaging of oncogene mRNAs in human cancer xenografts in a mouse model. The oncogenes cyclin D1,ERBB2, c-MYC, K-RAS, and tumor suppressor p53 are being probed initially. These experiments provide a proof-of-principle for noninvasive detection of oncogene expression in living cells and tissues. This scintigraphic imaging technique should be applicable to any particular gene of interest in a cell or tissue type with characteristic receptors.     

Activating gene expression in mammalian cells with promoter-targeted duplex RNAs

The ability to selectively activate or inhibit gene expression is fundamental to understanding complex cellular systems and developing therapeutics. Recent studies have demonstrated that duplex RNAs complementary to promoters within chromosomal DNA are potent gene silencing agents in mammalian cells. Here we report that chromosome-targeted RNAs also activate gene expression. We have identified multiple duplex RNAs complementary to the progesterone receptor (PR) promoter that increase expression of PR protein and RNA after transfection into cultured T47D or MCF7 human breast cancer cells. Upregulation of PR protein reduced expression of the downstream gene encoding cyclooygenase 2 but did not change concentrations of estrogen receptor, which demonstrates that activating RNAs can predictably manipulate physiologically relevant cellular pathways. Activation decreased over time and was sequence specific. Chromatin immunoprecipitation assays indicated that activation is accompanied by reduced acetylation at histones H3K9 and H3K14 and by increased di- and trimethylation at histone H3K4. These data show that, like proteins, hormones and small molecules, small duplex RNAs interact at promoters and can activate or repress gene expression.     

Inhibition of gene expression and growth of multidrug-resistant Acinetobacter baumannii by antisense peptide nucleic acids

Acinetobacter baumannii causes common and severe community- and hospital-acquired infections. The increasing emergence of multidrug-resistant (MDR) and pan-drug resistant A. baumannii has limited the therapeutic options, highlighting the need for new therapeutic strategies. The goal of this study was to investigate whether antisense peptide nucleic acids (PNAs) could mediate gene-specific inhibition effects in MDR A. baumannii. We described a screening strategy based on computational prediction and dot hybridization for identifying potential inhibitory PNAs, and evaluated the in vitro growth inhibition potency of two PNAs conjugated to the (KFF)₃K peptide (pPNA1 and pPNA2), both of which targeted the growth essential gene gyrA of A. baumannii. Both pPNAs showed strong inhibition effects on bacterial growth and gyrA mRNA expression in a dose-dependent manner. The lowest inhibitory and bactericidal concentration were 5 and 10 μM, respectively. Combination of the two pPNAs showed superimposed effect other than synergistic effect. Control PNAs without (KFF)₃K peptide conjugation or with mismatched antisense sequence had no inhibition effects on bacterial growth or mRNA expression. Our study suggests that anti-gyrA pPNAs can efficiently inhibit gene expression and bacterial growth, and has the potential as a new therapeutic option for MDR A. baumannii.     

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.     

Peptide nucleic acids specifically cause antigene effects in vivo by systemic injection

Peptide nucleic acids (PNAs) are uncharged DNA analogs that hybridize to complementary sequences with high affinity and stability. We previously showed that PNAs, after intraperitoneal injection into rats, are effective antisense compounds in vivo. The present study was designed to test whether PNAs also have antigene effects in vivo. The renin-angiotensin system is critical in the control of blood pressure. We designed and synthesized sense (antigene) PNAs to angiotensinogen, which is the precursor protein that leads to angiotensin I and II. Spontaneously hypertensive rats received intraperitoneal injections of either 20 mg/kg sense-angiotensinogen-PNA, mismatch-angiotensinogen PNA, or saline. Only the sense-angiotensinogen PNA treatment resulted in a significant decrease in plasma angiotensin I, systolic blood pressure, and liver and brain angiotensinogen mRNA levels. Thus, these results demonstrate on the molecular, protein, and physiological levels that antigene PNAs are effective in vivo upon systemic administration.