Effects in live cells of a c-myc anti-gene PNA linked to a nuclear localization signal

Sequence-specific inhibition of duck hepatitis B virus reverse transcription by peptide nucleic acids (PNA)

BACKGROUND/AIMS

Peptide nucleic acids (PNAs) appear as promising new antisense agents, that have not yet been examined as hepatitis B virus (HBV) inhibitors. Our aim was to study the ability of PNAs targeting the duck HBV (DHBV) encapsidation signal epsilon to inhibit reverse transcription (RT) and to compare their efficacy with phosphorothioate oligodeoxynucleotides (S-ODNs).

METHODS

The effect of two partly overlapping PNAs targeting epsilon and of analogous S-ODNs was tested in cell-free transcription and translation system for DHBV RT expression. In addition their antiviral effect was investigated in primary duck hepatocytes (PDH).

RESULTS

Both PNAs reproducibly inhibited DHBV RT in a dose-dependent manner with IC(50) of 10nM, whereas up to 600-fold higher concentration of S-ODNs was required for similar inhibition. The PNA targeting the bulge and upper stem of epsilon appeared as more efficient RT inhibitor than the PNA targeting only the bulge. Importantly, the inhibition was highly sequence-specific since double-mismatched PNA had no effect on the RT reaction. Moreover, in PDH the PNA coupled to Arg(7) cationic delivery peptide decreased DHBV replication.

CONCLUSIONS

We provide the first evidence that PNAs targeting the bulge and upper stem of epsilon can efficiently and in a sequence-specific manner inhibit DHBV RT.

Delivery of bioactive molecules into the cell: the Trojan horse approach

In recent years, vast amounts of data on the mechanisms of neural de- and regeneration have accumulated. However, only in disproportionally few cases has this led to efficient therapies for human patients. Part of the problem is to deliver cell death-averting genes or gene products across the blood-brain barrier (BBB) and cellular membranes. The discovery of Antennapedia (Antp)-mediated transduction of heterologous proteins into cells in 1992 and other "Trojan horse peptides" raised hopes that often-frustrating attempts to deliver proteins would now be history. The demonstration that proteins fused to the Tat protein transduction domain (PTD) are capable of crossing the BBB may revolutionize molecular research and neurobiological therapy. However, it was only recently that PTD-mediated delivery of proteins with therapeutic potential has been achieved in models of neural degeneration in nerve trauma and ischemia. Several groups have published the first positive results using protein transduction domains for the delivery of therapeutic proteins in relevant animal models of human neurological disorders. Here, we give an extensive review of peptide-mediated protein transduction from its early beginnings to new advances, discuss their application, with particular focus on a critical evaluation of the limitations of the method, as well as alternative approaches. Besides applications in neurobiology, a large number of reports using PTD in other systems are included as well. Because each protein requires an individual purification scheme that yields sufficient quantities of soluble, transducible material, the neurobiologist will benefit from the experiences of other researchers in the growing field of protein transduction.

Synthesis, cellular uptake and HIV-1 Tat-dependent trans-activation inhibition activity of oligonucleotide analogues disulphide-conjugated to cell-penetrating peptides

Oligonucleotides composed of 2′-O-methyl and locked nucleic acid residues complementary to HIV-1 trans-activation responsive element TAR block Tat-dependent trans-activation in a HeLa cell assay when delivered by cationic lipids. We describe an improved procedure for synthesis and purification under highly denaturing conditions of 5′-disulphide-linked conjugates of 3′-fluorescein labelled oligonucleotides with a range of cell-penetrating peptides and investigate their abilities to enter HeLa cells and block trans-activation. Free uptake of 12mer OMe/LNA oligonucleotide conjugates to Tat (48–58), Penetratin and R₉F₂ was observed in cytosolic compartments of HeLa cells. Uptake of the Tat conjugate was enhanced by N-terminal addition of four Lys or Arg residues or a second Tat peptide. None of the conjugates entered the nucleus or inhibited trans-activation when freely delivered, but inhibition was obtained in the presence of cationic lipids. Nuclear exclusion was seen for free delivery of Tat (48–58), Penetratin and R₉ conjugates of 16mer phosphorothioate OMe oligonucleotide. Uptake into human fibroblast cytosolic compartments was seen for Tat, Penetratin, R₉F₂ and Transportan conjugates. Large enhancements of HeLa cell uptake into cytosolic compartments were seen when free Tat peptide was added to Tat conjugate of 12mer OMe/LNA oligonucleotide or Penetratin peptide to Penetratin conjugate of the same oligonucleotide.

Peptide nucleic acid (PNA) binding-mediated gene regulation

Peptide nucleic acids (PNAs) are synthetic oligonucleotides with chemically modified backbones. PNAs can bind to both DNA and RNA targets in a sequence-specific manner to form PNA/DNA and PNA/RNA duplex structures. When bound to double-stranded DNA (dsDNA) targets, the PNA molecule replaces one DNA strand in the duplex by strand invasion to form a PNA/DNA/PNA [or (PNA)2/DNA] triplex structure and the displaced DNA strand exists as a single-stranded D-loop. PNA has been used in many studies as research tools for gene regulation and gene targeting. The D-loops generated from the PNA binding have also been demonstrated for its potential in initiating transcription and inducing gene expression. PNA provides a powerful tool to study the mechanism of transcription and an innovative strategy to regulate target gene expression. An understanding of the PNA-mediated gene regulation will have important clinical implications in treatment of many human diseases including genetic, cancerous, and age-related diseases.

Pharmacologically selective block of mu opioid antinociception by peptide nucleic acid antisense in absence of detectable ex vivo knockdown

The goal of this study was to determine the neuroanatomical extent of mu opioid receptor knockdown in central nervous system (CNS) following intracerebroventricular (i.c.v.) administration of peptide nucleic acid antisense. Rats received subchronic i.c.v. injections of anti-mu opioid receptor antisense, mismatch or vehicle, and were tested for paw pressure latency following i.c.v. mu opioid receptor agonist ([D-Ala2, N-Me-Phe4, Gly-ol5]-enkephalin; DAMGO) or delta opioid receptor agonist ((+)-4-[(aR)-a-((2S,5R)-4-allyl-2,5-dimethyl-1-piperazinyl)-3-methoxybenzyl]-N,N-diethylbenzamide; SNC80). The anti-mu opioid receptor antisense (but not mismatch) sequence abolished DAMGO-induced antinociception with no reduction in the delta opioid receptor-mediated response. In contrast, postmortem receptor autoradiographic analysis of CNS areas revealed no change in mu opioid receptor functional response ([35S]GTPgammaS assay) or receptor labelling ([125I]FK-33824 and mu opioid receptor immunoautoradiography). These results provide further evidence for antisense-induced knockdown at the behavioural level in the absence of clear changes at the tissue level.

PNA Technology

Peptide nucleic acids (PNA) are deoxyribonucleic acid (DNA) mimics with a pseudopeptide backbone. PNA is an extremely good structural mimic of DNA (or of ribonucleic acid [RNA]), and PNA oligomers are able to form very stable duplex structures with Watson-Crick complementary DNA and RNA (or PNA) oligomers, and they can also bind to targets in duplex DNA by helix invasion. Therefore, these molecules are of interest in many areas of chemistry, biology, and medicine, including drug discovery, genetic diagnostics, molecular recognition, and the origin of life. Recent progress in studies of PNA properties and applications is reviewed.

Ligand-mediated transcription elongation control using triplex-based padlock oligonucleotides

Triplex-forming oligonucleotides (TFOs) provide useful tools for the artificial regulation of gene expression at the transcriptional level. They can become topologically linked to their DNA target upon circularization, thereby forming very stable triple helical structures. These "padlock oligonucleotides" are able to interfere with transcription elongation when their target site is located in the transcribed region of a gene. In vitro transcription experiments showed that a bacterial RNA polymerase was stopped at the site of triple-helix formation, whereas expression of a reporter gene was inhibited in live cells. In both cases, the padlock oligonucleotide was more efficient at inhibiting transcription elongation than a linear TFO, and the inhibition was observed only in the presence of a triplex stabilizing agent. These results provide new insights into the ligand-modulated locking of padlock oligonucleotides around their DNA target.

A peptide nucleic acid-neamine conjugate that targets and cleaves HIV-1 TAR RNA inhibits viral replication

The neamine part of the aminoglycoside antibiotic neomycin B was conjugated to a 16 mer peptide nucleic acid (PNA) targeting HIV-1 TAR RNA. Attachment of the neamine core allows cellular uptake of the PNA and results in potent inhibition of HIV-1 replication. The polycationic neamine moiety imparts greater solubility to the PNA and also confers a unique RNA cleavage property to the conjugate which is specific to its target site and functional at physiological concentrations of Mg(2+). These properties suggest a potential therapeutic application for this class of compounds.

Recent advances in the development of peptide nucleic acid as a gene-targeted drug

Peptide nucleic acid (PNA) is a non-ionic mimic of DNA that binds to complementary DNA and RNA sequences with high affinity and selectivity. Targeting of single-stranded RNA leads to antisense effects, whereas PNAs directed toward double-stranded DNA exhibit antigene properties. Recent advances in cell uptake and in antisense and antigene effects in biological systems are summarised in this review. In addition to traditional targets, namely genomic DNA and messenger RNA, applications for PNA as a bacteriocidal antibiotic, for regulating splice site selection and as a telomerase inhibitor are described.

Enhancement of intracellular concentration and biological activity of PNA after conjugation with a cell-penetrating synthetic model peptide

In order to evaluate the ability of the cell-penetrating alpha-helical amphipathic model peptide KLALKLALKALKAALKLA-NH(2) (MAP) to deliver peptide nucleic acids (PNAs) into mammalian cells, MAP was covalently linked to the 12-mer PNA 5'-GGAGCAGGAAAG-3' directed against the mRNA of the nociceptin/orphanin FQ receptor. The cellular uptake of both the naked PNA and its MAP-conjugate was studied by means of capillary electrophoresis combined with laser-induced fluorescence detection, confocal laser scanning microscopy and fluorescence-activated cell sorting. Incubation with the fluorescein-labelled PNA-peptide conjugate led to three- and eightfold higher intracellular concentrations in neonatal rat cardiomyocytes and CHO cells, respectively, than found after exposure of the cells to the naked PNA. Correspondingly, pretreatment of spontaneously-beating neonatal rat cardiomyocytes with the PNA-peptide conjugate and the naked PNA slowed down the positive chronotropic effect elicited by the neuropeptide nociceptin by 10- and twofold, respectively. The main reasons for the higher bioavailability of the PNA-peptide conjugate were found to be a more rapid cellular uptake in combination with a lowered re-export and resistance against influences of serum.

Combination of a new generation of PNAs with a peptide-based carrier enables efficient targeting of cell cycle progression

The design of potent systems for the delivery of charged and noncharged molecules that target genes of interest remains a challenge. We describe a novel technology that combines a new generation of peptide nucleic acids (PNAs), or HypNA-pPNAs, with a new noncovalent peptide-based delivery system, Pep-2, which promotes efficient delivery of PNAs into several cell lines. We have validated the potential of this technology by showing that Pep2-mediated delivery of an antisense HypNA-pPNA chimera directed specifically against cyclin B1 induces rapid and robust downregulation of its protein levels and efficiently blocks cell cycle progression of several cell lines, as well as proliferation of cells derived from a breast cancer. Pep-2-based delivery system was shown to be 100-fold more efficient in delivering HypNA-pPNAs than classical cationic lipid-based methods. Whereas Pep-2 is essential for improving the bioavailability of PNAs and HypNA-pPNAs, the latter contribute significantly to the efficiency and specificity of the biological response. We have found that Pep-2/HypNA-pPNA strategy promotes potent antisense effects, which are approximately 25-fold greater than with classical antisense oligonucleotide directed specifically against the same cyclin B1 target. Taken together, these data demonstrate that peptide-mediated delivery of HypNA-pPNAs constitutes a very promising technology for therapeutic applications.

The peptide nucleic acids (PNAs): introduction to a new class of probes for chromosomal investigation

Peptide nucleic acids (PNAs) are synthetic DNA mimics in which the sugar phosphate backbone is replaced by repeating N-(2-aminoethyl) glycine units linked by an amine bond and to which the nucleobases are fixed. Peptide nucleic acids hybridize with complementary nucleic acids with remarkably high affinity and specificity, essentially because of their uncharged and flexible polyamide backbone. The unique physicochemical properties of PNAs have led to the development of a large variety of biological research assays, and, over the last few years, PNAs have proved their powerful usefulness in genetic and cytogenetic diagnostic procedures. Several sensitive and robust PNA-dependent methods have been designed for modulating polymerase chain reactions, detecting genomic mutation or capturing nucleic acids. The more recent applications of PNA involve their use as molecular hybridization probes. Thus, the in situ detection of several human chromosomes has been reported in various types of tissues.

Imaging oncogene expression

In 2003, approximately 39,800 women in the US will die from breast cancer. Mammography and physical examination miss up to 40% of early breast cancers. Moreover, if an abnormality is found, an invasive diagnostic procedure must still be performed to determine if the breast contains atypia or cancer, even though approximately 85% of abnormalities are benign. Scintigraphic imaging of gene expression in vivo by noninvasive means could direct physicians to appropriate targets for intervention at the onset of disease and thereby significantly impact patient management. Until now, no method has been available to image specific overexpressed oncogene mRNAs in vivo by scintigraphic imaging. We hypothesize that gamma-emitting Tc-99m-PNA-peptides can be taken up by human ER+ and ER- breast cancer xenografts, hybridize to complementary mRNA targets in those cells, and concentrate sufficiently in tumor tissue to allow noninvasive imaging of oncogene overexpression. To prepare the probes, peptide analogs of insulin-like growth factor 1 (IGF1) were extended from a solid support by Fmoc coupling. Peptide nucleic acid (PNA) dodecamers antisense to CCND1 and MYC mRNAs were then extended from the N-terminus of IGF1, followed by a chelator peptide, using Fmoc coupling for all residues. The cysteine thiols were cyclized on the solid support, either before or after PNA extension. This simplified synthetic approach allows preparation of a variety of multipeptide disulfide-bridged PNA chimeras. A chelating peptide-PNA chimera antisense to MYC mRNA was then labeled efficiently with Tc-99m, yielding a single product. Tissue distribution studies of antisense and mismatch chimeras at 4 h and 24 h after administration displayed modest accumulation in the liver and kidneys, with appreciable levels in tumors. This result enables testing of Tc-99m-peptide-PNA probes to image gene expression in tumors.

Antigenic epitopes fused to cationic peptide bound to oligonucleotides facilitate Toll-like receptor 9-dependent, but CD4+ T cell help-independent, priming of CD8+ T cells

A priority in current vaccine research is the development of adjuvants that support the efficient priming of long-lasting, CD4(+) T cell help-independent CD8(+) T cell immunity. Oligodeoxynucleotides (ODN) with immune-stimulating sequences (ISS) containing CpG motifs facilitate the priming of MHC class I-restricted CD8(+) T cell responses to proteins or peptides. We show that the adjuvant effect of ISS(+) ODN on CD8(+) T cell priming to large, recombinant Ag is enhanced by binding them to short, cationic (arginine-rich) peptides that themselves have no adjuvant activity in CD8(+) T cell priming. Fusing antigenic epitopes to cationic (8- to 10-mer) peptides bound to immune-stimulating ISS(+) ODN or nonstimulating NSS(+) ODN (without CpG-containing sequences) generated immunogens that efficiently primed long-lasting, specific CD8(+) T cell immunity of high magnitude. Different MHC class I-binding epitopes fused to short cationic peptides of different origins showed this adjuvant activity. Quantitative ODN binding to cationic peptides strikingly reduced the toxicity of the latter, suggesting that it improves the safety profile of the adjuvant. CD8(+) T cell priming supported by this adjuvant was Toll-like receptor 9 dependent, but required no CD4(+) T cell help. ODN (with or without CpG-containing sequences) are thus potent Th1-promoting adjuvants when bound to cationic peptides covalently linked to antigenic epitopes, a mode of Ag delivery prevailing in many viral nucleocapsids.

Down-regulation of MDM2 and activation of p53 in human cancer cells by antisense 9-aminoacridine-PNA (peptide nucleic acid) conjugates

A series of peptide nucleic acid (PNA) oligomers targeting the mdm2 oncogene mRNA has been tested for the ability to inhibit the growth of JAR cells. The effect of these PNAs on the cells was also reflected in reduced levels of the MDM2 protein and increased levels of the p53 tumor suppressor protein, which is negatively regulated by MDM2. Initially, PNA oligomers were delivered as DNA complexes with lipofectamine, but it was discovered that PNA conjugated to the DNA intercalator 9-aminoacridine (Acr) (Acr-PNA) could be effectively delivered to JAR cells (as well as to HeLa pLuc705 cells) even in the absence of a DNA carrier. Using such lipofectamine-delivered Acr-PNA conjugates, one PNA targeting a cryptic AUG initiation site was identified that at a concentration of 2 microM caused a reduction of MDM2 levels to approximately 20% (but no reduction in mdm2 mRNA levels) and a 3-fold increase in p53 levels, whereas a 2-base mismatch control had no such effects. Furthermore, transcriptional activation by p53 was also increased (6-fold), and cell viability was reduced to 80%. Finally, this PNA acted cooperatively with camptothecin treatment both with regard to p53 activity induction as well as cell viability. Using this novel cell delivery system, we have identified a target on the mdm2 mRNA that appears sensitive to antisense inhibition by PNA and therefore could be used as a lead for further development of mdm2-targeted antisense (PNA and other) gene therapeutic anticancer drugs.

Peptide nucleic acids targeted to the amyloid precursor protein

The depositing in brain of amyloid beta peptide (Abeta), which is formed by the cleavage of amyloid precursor protein (APP), is likely an etiologic factor in Alzheimer's disease (AD). Of the different forms of Abeta, Abeta(1-42) causes fibril formation and increases aggregation at elevated levels, which can lead to neuronal death. It is hypothesized that if the levels of Abeta, particularly Abeta(1-42), were reduced, then the onset of AD would be slowed or possibly prevented. Therefore, we are using peptide nucleic acids (PNAs) targeted to APP, as well as other key proteins, to try to decrease plasma and brain levels of Abeta(1-40) and Abeta(1-42). This research project was designed to utilize the expertise of our laboratory in the use of PNAs, a third-generation antisense or antigene molecule, to knock down proteins in brain. Antisense compounds specifically knock down the expression of a particular protein by inhibiting translation at the level of mRNA. On the other hand, antigene compounds knock down expression at the level of transcription. For experiments involving antisense strategies, there are several advantages to using PNAs as opposed to the traditional oligonucleotide molecules. We report here the ongoing studies with mice and rats with PNAs targeting APP, as well as BACE.

Oligonucleotides and derivatives as gene-specific control agents

The current achievement of genome sequence projects of a dozen eukaryote organisms (including human genome) and the development of functional genomics are providing the basic knowledge required to utilize gene-specific reagents for both basic understanding of cell physiology and therapeutical development. The field of chemical genomics has the ambitious goal of designing molecules that could act selectively on every single gene or gene product in a cell and in vivo. The progress in oligonucleotide-based approaches will be the topic of this review, however, other nucleic acid- and SELEX-based approaches as well as high sequence-specific low molecular weight DNA-specific ligands will also be discussed.

Insights into peptide nucleic acid (PNA) structural features: the crystal structure of a D-lysine-based chiral PNA-DNA duplex

Peptide nucleic acids (PNAs) are oligonucleotide analogues in which the sugar-phosphate backbone has been replaced by a pseudopeptide skeleton. They bind DNA and RNA with high specificity and selectivity, leading to PNA-RNA and PNA-DNA hybrids more stable than the corresponding nucleic acid complexes. The binding affinity and selectivity of PNAs for nucleic acids can be modified by the introduction of stereogenic centers (such as D-Lys-based units) into the PNA backbone. To investigate the structural features of chiral PNAs, the structure of a PNA decamer containing three D-Lys-based monomers (namely H-GpnTpnApnGpnAdlTdlCdlApnCpnTpn-NH2, in which pn represents a pseudopeptide link and dl represents a D-Lys analogue) hybridized with its complementary antiparallel DNA has been solved at a 1.66-A resolution by means of a single-wavelength anomalous diffraction experiment on a brominated derivative. The D-Lys-based chiral PNA-DNA (LPD) heteroduplex adopts the so-called P-helix conformation. From the substantial similarity between the PNA conformation in LPD and the conformations observed in other PNA structures, it can be concluded that PNAs possess intrinsic conformational preferences for the P-helix, and that their flexibility is rather restricted. The conformational rigidity of PNAs is enhanced by the presence of the chiral centers, limiting the ability of PNA strands to adopt other conformations and, ultimately, increasing the selectivity in molecular recognition.

99mTc-peptide-peptide nucleic acid probes for imaging oncogene mRNAs in tumours

Imaging oncogene mRNA in tumours would provide a powerful tool for the early detection of occult malignant lesions. The goal was to prepare a chimera consisting of a dodecamer antisense peptide nucleic acid (PNA) specific for c-MYC oncogene overexpressed in human breast cancer cells and a chelating moiety that facilitates quantitative radiolabelling with 99mTc and evaluate it for hybridization and tissue distribution in laboratory animals. The pentapeptide chelator-PNA dodecamer specific for c-MYC mRNA was extended from a solid support by 9-fluorenylmethyloxycarbonyl (Fmoc) coupling. Similarly, a chelator-PNA chimera with four central mismatches was also prepared which served as a control. The chimeras were purified, characterized and evaluated for hybridization to c-MYC mRNA by fluorescent, real-time polymerase chain reaction (RT-PCR). The chimeras were labelled with 99mTc and their tissue distribution was examined in athymic nude mice bearing experimental human breast tumours. 99mTc radiolabelling was quantitative and presented a single peak in reversed phase liquid chromatography. Fluorescent real-time polymerase chain reactions using primer and fluorescent probe sets previously calculated for c-MYC mRNA demonstrated inhibition of reverse transcription by the c-MYC specific chimera as compared to that of the control. Tissue distribution studies of antisense and mismatch chimeras at 4 h and 24 h after administration displayed modest accumulation in the liver, and appreciable levels in tumours. These observations suggest that 99mTc-peptide-PNA probes might be useful for imaging gene expression in tumours, and the approach is worthy of further investigation.

The interaction of peptide-tethered platinum(II) complexes with DNA

The sequence specificity and intensity of DNA damage induced by six peptide-tethered platinum complexes was compared to cisplatin and Pt(en)Cl(2). DNA damage was investigated in pUC19 plasmid and in intact HeLa cells, and quantitatively analyzed using a Taq DNA polymerase/linear amplification assay. The DNA sequence specificity of the peptide-platinum compounds was found to be very similar to cisplatin and Pt(en)Cl(2), with runs of consecutive guanines being the most intensely damaged sites. The observed reactivity of the peptide-platinum complexes towards plasmid DNA was lower compared to cisplatin and Pt(en)Cl(2), with the glycine-tethered complex 3 and the phenylalanine-tethered complex 4 producing the highest relative damage intensity, followed by (in decreasing order) lysine-tethered (5), arginine-tethered (6), serine-tethered (7) and glutamate-tethered (8). The reactivity of the peptide-platinum complexes towards cellular DNA was also lower compared to cisplatin and Pt(en)Cl(2). For most investigated complexes, the relative damage intensities were found to be similar in cells compared to plasmid DNA, but were greatly reduced for 3 and 4. The lysine-tethered 5 complex produced the highest DNA damage intensity in cells followed by (in decreasing order) 6, 7, 3, 4 and 8.

Novel binding and efficient cellular uptake of guanidine-based peptide nucleic acids (GPNA)

Incorporation of a guanidine functional group into the PNA backbone facilitates cellular uptake of PNA into mammalian cells with efficiency comparable to that of the TAT transduction domain. The modified PNA recognizes and binds to the complementary DNA strand in accordance with Watson-Crick recognition rules. However, unlike polypyrimidine PNA which binds to DNA in 2:1 stoichiometry, the modified PNA binds to complementary DNA in a 1:1 ratio to form a highly stable duplex.

Cellular delivery of peptide nucleic acid (PNA)

Peptide nucleic acid (PNA) is a DNA mimic having a pseudopeptide backbone that makes it extremely stable in biological fluids. PNA binds complementary RNA and DNA with high affinity and specificity. These qualities make PNA a leading agent among "third generation" antisense and antigene agents. Unfortunately, fast progress in the exploration of PNA as an experimental and therapeutical regulator of gene expression has been hampered by the poor cellular uptake of PNA. However, a number of transfection protocols for PNA have now been established. These include microinjection, electroporation, co-transfection with DNA, conjugation to lipophilic moieties, conjugation to peptides, etc. Here we give a short introduction to the basic findings on PNA as an antisense and antigene agent in cell-free in vitro systems. This is followed by a comprehensive evaluation of the most interesting literature concerning cellular delivery and the intracellular effect of PNA. Also the current progress as regards using PNA as co-factor in DNA delivery is reviewed.

NLS bioconjugates for targeting therapeutic genes to the nucleus

One of the major steps limiting non-viral gene transfer efficiency is the entry of plasmid DNA from the cytoplasm into the nucleus of transfected cells. Trafficking of nuclear proteins from the cytoplasm into the nucleus through nuclear pore complexes is mediated by the presence of nuclear localization sequences (NLS) on proteins. Viral DNA and RNA also require interaction with cellular machinery for efficient nuclear import. In this article, we review the various strategies used to provide plasmid DNA with nuclear localization sequences, and discuss the possibility of developing efficient gene delivery systems based on these strategies.

Peptide nucleic acid antisense prolongs skin allograft survival by means of blockade of CXCR3 expression directing T cells into graft

CXCR3, predominantly expressed on memory/activated T cells, is a receptor for both IFN-gamma-inducible protein 10/CXC chemokine ligand (CXCL)10 and monokine induced by IFN-gamma/CXCL9. It was reported that CXC chemokines IFN-gamma-inducible protein 10/CXCL10 and monokine induced by IFN-gamma/CXCL9 play a critical role in the allograft rejection. We report that CXCR3 is a dominant factor directing T cells into mouse skin allograft, and that peptide nucleic acid (PNA) CXCR3 antisense significantly prolongs skin allograft survival by means of blockade of CXCR3 expression directing T cells into allografts in mice. We found that CXCR3 is highly up-regulated in spleen T cells and allografts from BALB/c recipients by day 7 of receiving transplantation, whereas CCR5 expression is moderately increased. We designed PNA CCR5 and PNA CXCR3 antisenses, and i.v. treated mice that received skin allograft transplantations. The PNA CXCR3 at a dosage of 10 mg/kg/day significantly prolonged mouse skin allograft survival (17.1 +/- 2.4 days) compared with physiological saline treatment (7.5 +/- 0.7 days), whereas PNA CCR5 (10 mg/kg/day) marginally prolonged skin allograft survival (10.7 +/- 1.1 days). The mechanism of prolongation of skin allograft survival is that PNA CXCR3 directly blocks the CXCR3 expression in T cells, which is responsible for directing T cells into skin allograft to induce acute rejection, without interfering with other functions of the T cells. These results were obtained at mRNA and protein levels by flow cytometry and real-time quantitative RT-PCR technique, and confirmed by chemotaxis, Northern and Western blot assays, and histological evaluation of skin grafts. The present study indicates the therapeutic potential of PNA CXCR3 to prevent acute transplantation rejection.

Modular design of artificial transcription factors

Eukaryotic transcription factors are composed of interchangeable modules. This has led to the design of a wide variety of modular artificial transcription factors (ATFs) that can stimulate or inhibit the expression of targeted genes. The ability to regulate the expression of any targeted gene using a 'programmable' ATF offers a powerful tool for functional genomics and bears tremendous promise in developing the field of transcription-based therapeutics.

Continuous solid-phase synthesis and disulfide cyclization of peptide-PNA-peptide chimeras

Chelator peptides were extended from the N-terminus of peptide nucleic acid (PNA) dodecamers, which in turn were extended from the N-termini of disulfide-bridged peptide ligand analogues, using Fmoc coupling for all residues. The cysteine thiols were cyclized on a solid support, either before or after PNA extension. This simplified synthetic approach might allow preparation of a variety of multipeptide disulfide-bridged PNA chimeras. [structure: see text]

Antiproliferative effect in chronic myeloid leukaemia cells by antisense peptide nucleic acids

Peptide nucleic acid (PNA) is a synthetic DNA analogue that is resistant to nucleases and proteases and binds with exceptional affinity to RNA. Because of these properties PNA has the potential to become a powerful therapeutic agent to be used in vivo. Until now, however, the use of PNA in vivo has not been much investigated. Here, we have attempted to reduce the expression of the bcr/abl oncogene in chronic myeloid leukaemia KYO-1 cells using a 13mer PNA sequence (asPNA) designed to hybridise to the b2a2 junction of bcr/abl mRNA. To enhance cellular uptake asPNA was covalently linked to the basic peptide VKRKKKP (NLS-asPNA). Moreover, to investigate the cellular uptake by confocal microscopy, both PNAs were linked by their N-terminus to fluorescein (FL). Studies of uptake, carried out at 4 and 37 degrees C on living KYO-1 cells stained with hexidium iodide, showed that both NLS-asPNA-FL and asPNA-FL were taken up by the cells, through a receptor-independent mechanism. The intracellular amount of NLS-asPNA-FL was about two to three times higher than that of asPNA-FL. Using a semi-quantitative RT- PCR technique we found that 10 micro M asPNA and NLS-asPNA reduced the level of b2a2 mRNA in KYO-1 cells to 20 +/- 5% and 60 +/- 10% of the control, respectively. Western blot analysis showed that asPNA promoted a significant inhibition of p210(BCR/ABL) protein: residual protein measured in cells exposed for 48 h to asPNA was approximately 35% of the control. Additionally, asPNA impaired cell growth to 50 +/- 5% of the control and inhibited completion of the cell cycle. In summary, these results demonstrate that a PNA 13mer is taken up by KYO-1 cells and is capable of producing a significant and specific down-regulation of the bcr/abl oncogene involved in leukaemogenesis.

Antisense peptide nucleic acids conjugated to somatostatin analogs and targeted at the n-myc oncogene display enhanced cytotoxity to human neuroblastoma IMR32 cells expressing somatostatin receptors

Peptide nucleic acid (PNA) sequences are synthetic versions of naturally occurring oligonucleotides which display improved binding properties to DNA and RNA, but are still poorly internalized across cell membranes. In an effort to employ the rapid binding/internalization properties of somatostatin agonist analogs and the over-expression of somatostatin receptors on many types of tumor cells, PNAs complementary to target sites throughout 5'-UTR, translation start site and coding region of the n-myc oncogene were conjugated to a somatostatin analog (SSA) with retention of high somatostatin biological potency. IMR32 cells, which over-express somatostatin receptor type 2 (SSTR2) and contain the n-myc oncogene, were treated with these PNA-SSA conjugates. The results show that PNA conjugates targeted to the 5'-UTR terminus and to regions at or close to the translation start site could effectively inhibit n-myc gene expression and cell growth, whereas the non-conjugate PNAs were without effect at similar doses. The most potent inhibition of cell growth was achieved with PNAs binding to the translation start site, but those complementary to the middle coding region or middle upstream site between 5'-UTR and translation start site displayed no inhibition of gene expression. These observations were extended to four other cell lines: GH3 cells which express SSTRs with the n-myc gene, SKNSH cells containing a silent n-myc gene without SSTR2, HT-29 cells carrying the c-myc but no n-myc gene, and CHO-K1 cells lacking SSTR2 with n-myc gene. The results show that there was almost no effect on these four cell lines. Our study indicates that PNAs conjugated to SSA exhibited improved inhibition of gene expression possibly due to facilitated cellular uptake of the PNAs. These conjugates were mRNA sequence- and SSTR2-specific suggesting that many other genes associated with tumor growth could be targeted using this approach and that SSA could be a novel and effective transportation vector for the PNA antisense strategy.

Using peptide nucleic acids as gene-expression modifiers to reduce beta-amyloid levels

The deposition of amyloid beta peptide (A beta) is an early and critical aspect of Alzheimer's disease. A beta is formed by the cleavage of amyloid precursor protein (APP). Studies of familial forms of Alzheimer's disease indicate that elevated secretion of A beta, particularly A beta(1-42), is likely to be an etiologic agent in the disease. A beta(1-42) is known to cause fibril formation and at elevated levels increases aggregation, which can lead to neuronal death. It has, therefore, been hypothesized that if the levels of A betaB, particularly A beta(1-42), could be reduced that onset of Alzheimer's disease could be slowed or possibly prevented. We, therefore, propose using PNAs targeted to APP to decrease plasma and brain levels of A beta(1-40) and A beta(1-42). This research project is designed to expand upon the discovery in our laboratory that systemic administration of antisense or antigene treatments utilizing peptide nucleic acids (PNAs) can be used to target and shut down proteins. Antisense strategies are methods of specifically targeting a particular protein by inhibiting translation by complementary binding to mRNA, while antigene methods inhibit transcription by complementary binding to DNA. For experiments involving antisense strategies, there are several advantages to using PNAs as opposed to the traditional oligonucleotide approaches. We initially preformed our studies in rats and identified a PNA sequence that was able to significantly reduce the levels of A beta(1-41) in rat brain compared to vehicle control rats. We have switched to mice so that we can prepare to perform our experiments in a transgenic animal model of Alzheimer's disease. We have, however, run into several technical difficulties with using mice compared to rats. In spite of this, we have identified one PNA sequence that specifically lowers mouse brain A beta(1-40) A beta(1-42) by 37% and 47%, respectively.

Cellular uptake of antisense oligonucleotides after complexing or conjugation with cell-penetrating model peptides

The uptake by mammalian cells of phosphorothioate oligonucleotides was compared with that of their respective complexes or conjugates with cationic, cell-penetrating model peptides of varying helix-forming propensity and amphipathicity. An HPLC-based protocol for the synthesis and purification of disulfide bridged conjugates in the 10-100 nmol range was developed. Confocal laser scanning microscopy (CLSM) in combination with gel-capillary electrophoresis and laser induced fluorescence detection (GCE-LIF) revealed cytoplasmic and nuclear accumulationin all cases. The uptake differences between naked oligonucleotides and their respective peptide complexes or conjugates were generally confined to one order of magnitude. No significant influence of the structural properties of the peptide components upon cellular uptake was found. Our results question the common belief that the increased biological activity of oligonucleotides after derivatization with membrane permeable peptides may be primarily due to improved membrane translocation.

Role of chirality and optical purity in nucleic acid recognition by PNA and PNA analogs

Peptide nucleic acids are DNA mimics able to form duplexes with complementary DNA or RNA strands of remarkable affinity and selectivity. Oligopyrimidine PNA can displace one strand of dsDNA by forming PNA(2):DNA triplexes of very high stability. Many PNA analogs have been described in recent years, in particular, chiral PNA analogs. In the present article the results obtained recently using PNA derived from N-aminoethylamino acids 7 are illustrated. In particular, the dependence of optical purity on synthetic methodologies and a rationale for the observed effects of chirality on DNA binding ability is proposed. Chirality as a tool for improving sequence selectivity is also described. PNA analogs derived from D- or L-ornithine 8 were also found to be subjected to epimerization during solid phase synthesis. Modification of the coupling conditions or the use of a submonomeric strategy greatly reduced epimerization. The optically pure oligothymine PNAs 8 were found to bind to RNA by forming triplexes of unusual CD spectra. The melting curves of these adducts presented two transitions, suggesting a conformational change followed by melting at high temperature.

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.

CD10 is a marker for cycling cells with propensity to apoptosis in childhood ALL

CD10 constitutes a favourable prognostic marker for childhood acute lymphoblastic leukaemia. Since correlations between CD10, cell cycle and apoptotic abilities were demonstrated in various cell types, we investigated whether differences existed in the cycling/apoptotic abilities of CD10-positive and CD10-negative B acute lymphoblastic leukaemia cells. Twenty-eight cases of childhood acute lymphoblastic leukaemia (mean age of 6.8 years) were subdivided into two groups according to high (17 cases, 93.2+/-4.5%, MRFI 211+/-82 CD10-positive cells) or low (11 cases, 11.5+/-6.2%, MRFI 10+/-7 CD10-negative cells) expression of CD10. CD10-positive acute lymphoblastic leukaemia cells were cycling cells with elevated c-myc levels and propensity to apoptosis, whereas CD10-negative acute lymphoblastic leukaemia cells had lower cycling capacities and c-myc levels, and were resistant to apoptosis in vitro. A close correlation between all these properties was demonstrated by the observations that the few CD10-positive cells found in the CD10-negative acute lymphoblastic leukaemia group displayed elevated c-myc and cycling capacities and were apoptosis prone. Moreover, exposure of CD10-positive acute lymphoblastic leukaemia B cells to a peptide nucleic acid anti-gene specific for the second exon of c-myc caused inhibition of c-myc expression and reduced cell cycling and apoptotic abilities as well as decreased CD10 expression.