Disrupting Protein Expression with Peptide Nucleic Acids Reduces Infection by Obligate Intracellular Rickettsia

Peptide Nucleic Acids (PNAs) are single-stranded synthetic nucleic acids with a pseudopeptide backbone in lieu of the phosphodiester linked sugar and phosphate found in traditional oligos. PNA designed complementary to the bacterial Shine-Dalgarno or start codon regions of mRNA disrupts translation resulting in the transient reduction in protein expression. This study examines the use of PNA technology to interrupt protein expression in obligate intracellular Rickettsia sp. Their historically intractable genetic system limits characterization of protein function. We designed PNA targeting mRNA for rOmpB from Rickettsia typhi and rickA from Rickettsia montanensis, ubiquitous factors important for infection. Using an in vitro translation system and competitive binding assays, we determined that our PNAs bind target regions. Electroporation of R. typhi and R. montanensis with PNA specific to rOmpB and rickA, respectively, reduced the bacteria’s ability to infect host cells. These studies open the possibility of using PNA to suppress protein synthesis in obligate intracellular bacteria.     

Nanomolar cellular antisense activity of peptide nucleic acid (PNA) cholic acid ("umbrella") and cholesterol conjugates delivered by cationic lipids

Limited cellular uptake and low bioavailability of peptide nucleic acids (PNAs) have restricted widespread use of PNAs as antisense/antigene agents for cells in culture and not least for in vivo applications. We now report the synthesis and cellular antisense activity in cultured HeLa pLuc705 cells of cholesterol and cholic acid ("umbrella") derivatives of splice correction antisense PNA oligomers. While the conjugates alone were practically inactive up to 1 μM, their activity was dramatically improved when delivered by a cationic lipid transfection agent (LipofectAMINE2000). In particular, PNAs, conjugated to cholesterol through an ester hemisuccinate linker or to cholic acid, exhibited low nanomolar activity (EC(50) ～ 25 nM). Excellent sequence specificity was retained, as mismatch PNA conjugates did not show any significant antisense activity. Furthermore, we show that increasing the transfection volume improved transfection efficiency, suggesting that accumulation (condensation) of the PNA/lipid complex on the cellular surface is part of the uptake mechanism. These results provide a novel, simple method for very efficient cellular delivery of PNA oligomers, especially using PNA-cholic acid conjugates which, in contrast to PNA-cholesterol conjugates, exhibit sufficient water solubility. The results also question the generality of using cholic acid "umbrella" derivatives as a delivery modality for antisense oligomers.     

Short pyrimidine stretches containing mixed base PNAs are versatile tools to induce translation elongation arrest and truncated protein synthesis

Recently, we showed that antisense peptide nucleic acids (PNA) containing a short pyrimidine stretch (C(4)TC(3)) invade Ha-ras mRNA hairpin structures to form highly stable duplex and triplex complexes that contribute to the arrest of translation elongation. The antisense PNA targeted to codon 74 of Ha-ras was designed to bind in antiparallel configuration (the N-terminal of the PNA faces the 3'-end of target mRNA), as PNA/RNA duplexes are most stable in this configuration. In order to show that different sequences in the coding region could be targeted successfully with antisense PNAs, we extended our study to three other purine-rich targets. We show that the tridecamer PNA (targeted to codon 149) containing a CTC(3)T pyrimidine stretch forms with the complementary oligoribonucleotide (ORN) a stable (PNA)(2)/ORN triplex at neutral pH (T(m) = 50 degrees C) and arrests Ha-ras mRNA translation elongation. Interestingly, the thermal stability of triplexes formed with PNAs designed to bind to the complementary ORN in a parallel orientation (the N-terminal of the PNA faces the 5'-end of target) was higher than that formed with antiparallel oriented PNAs (T(m) = 58 degrees C). Because parallel and antiparallel PNAs form stable triplexes with target sequence, they act as translation elongation blockers. These duplex-forming and partly triplex-forming PNAs targeted to Ha-ras mRNA also arrested translation elongation at specific polypurine sites contained in the mRNA coding for HIV-integrase protein. Furthermore, the tridecamer PNA containing the C(3)TC(4) motif was more active than a bis-PNA in which the Hoogsteen recognizing strand was linked to the Watson-Crick recognizing strand by a flexible linker. Pyrimidine-rich, short PNAs that form very stable duplexes with target Ha-ras mRNA inhibit translation by a mechanism that does not involve ribosome elongation arrest, whereas PNAs forming duplex and triplex structures arrest ribosome elongation. The remarkable efficacy of the tridecamer PNAs in arresting translation elongation of HIV-1 integrase mRNA is explained by their ability to form stable triplexes at neutral pH with short purine sequences.     

Bactericidal antisense effects of peptide-PNA conjugates

Antisense peptide nucleic acids (PNAs) can specifically inhibit Escherichia coli gene expression and growth and hold promise as anti-infective agents and as tools for microbial functional genomics. Here we demonstrate that chemical modification improves the potency of standard PNAs. We show that 9- to 12-mer PNAs, especially when attached to the cell wall/membrane-active peptide KFFKFFKFFK, provide improvements in antisense potency in E. coli amounting to two orders of magnitude while retaining target specificity. Peptide-PNA conjugates targeted to ribosomal RNA (rRNA) and to messenger RNA (mRNA) encoding the essential fatty acid biosynthesis protein Acp prevented cell growth. The anti-acpP PNA at 2 microM concentration cured HeLa cell cultures noninvasively infected with E. coli K12 without any apparent toxicity to the human cells. These results indicate that peptides can be used to carry antisense PNA agents into bacteria. Such peptide-PNA conjugates open exciting possibilities for anti-infective drug development and provide new tools for microbial genetics.     

Intracellular uptake and inhibition of gene expression by PNAs and PNA-peptide conjugates

Peptide nucleic acids (PNAs) offer a distinct option for silencing gene expression in mammalian cells. However, the full value of PNAs has not been realized, and the rules governing the recognition of cellular targets by PNAs remain obscure. Here we examine the uptake of PNAs and PNA-peptide conjugates by immortal and primary human cells and compare peptide-mediated and DNA/lipid-mediated delivery strategies. We find that both peptide-mediated and lipid-mediated delivery strategies promote entry of PNA and PNA-peptide conjugates into cells. Confocal microscopy reveals a punctate distribution of PNA and PNA-peptide conjugates regardless of the delivery strategy used. Peptide D(AAKK)(4) and a peptide containing a nuclear localization sequence (NLS) promote the spontaneous delivery of antisense PNAs into cultured cells. The PNA-D(AAKK)(4) conjugate inhibits expression of human caveolin 1 (hCav-1) in both HeLa and primary endothelial cells. DNA/lipid-mediated delivery requires less PNA, while peptide-mediated delivery is simpler and is less toxic to primary cells. The ability of PNA-peptide conjugates to enter primary and immortal human cells and inhibit gene expression supports the use of PNAs as antisense agents for investigating the roles of proteins in cells. Both DNA/lipid-mediated and peptide-mediated delivery strategies are efficient, but the compartmentalized localization of PNAs suggests that improving the cellular distribution may lead to increased efficacy.     

Development of Peptide Nucleic Acid Probes for Detection of the HER2 Oncogene

Peptide nucleic acids (PNAs) have gained much interest as molecular recognition tools in biology, medicine and chemistry. This is due to high hybridization efficiency to complimentary oligonucleotides and stability of the duplexes with RNA or DNA. We have synthesized 15/16-mer PNA probes to detect the HER2 mRNA. The performance of these probes to detect the HER2 target was evaluated by fluorescence imaging and fluorescence bead assays. The PNA probes have sufficiently discriminated between the wild type HER2 target and the mutant target with single base mismatches. Furthermore, the probes exhibited excellent linear concentration dependence between 0.4 to 400 fmol for the target gene. The results demonstrate potential application of PNAs as diagnostic probes with high specificity for quantitative measurements of amplifications or over-expressions of oncogenes.     

Non-Watson-Crick interactions between PNA and DNA inhibit the ATPase activity of bacteriophage T4 Dda helicase

Peptide nucleic acid (PNA) is a DNA mimic in which the nucleobases are linked by an N-(2-aminoethyl) glycine backbone. Here we report that PNA can interact with single-stranded DNA (ssDNA) in a non-sequence-specific fashion. We observed that a 15mer PNA inhibited the ssDNA-stimulated ATPase activity of a bacteriophage T4 helicase, Dda. Surprisingly, when a fluorescein-labeled 15mer PNA was used in binding studies no interaction was observed between PNA and Dda. However, fluorescence polarization did reveal non-sequence-specific interactions between PNA and ssDNA. Thus, the inhibition of ATPase activity of Dda appears to result from depletion of the available ssDNA due to non-Watson–Crick binding of PNA to ssDNA. Inhibition of the ssDNA-stimulated ATPase activity was observed for several PNAs of varying length and sequence. To study the basis for this phenomenon, we examined self-aggregation by PNAs. The 15mer PNA readily self-aggregates to the point of precipitation. Since PNAs are hydrophobic, they aggregate more than DNA or RNA, making the study of this phenomenon essential for understanding the properties of PNA. Non-sequence-specific interactions between PNA and ssDNA were observed at moderate concentrations of PNA, suggesting that such interactions should be considered for antisense and antigene applications.     

Antisense properties of duplex- and triplex-forming PNAs.

The potential of peptide nucleic acids (PNAs) as specific inhibitors of translation has been studied. PNAs with a mixed purine/pyrimidine sequence form duplexes, while homopyrimidine PNAs form (PNA)2/RNA triplexes with complementary sequences on RNA. We show here that neither of these PNA/RNA structures are substrates for RNase H. Translation experiments in cell-free extracts showed that a 15mer duplex-forming PNA blocked translation in a dose-dependent manner when the target was 5'-proximal to the AUG start codon on the RNA, whereas similar 10-, 15- or 20mer PNAs had no effect when targeted towards sequences in the coding region. Triplex-forming 10mer PNAs were efficient and specific antisense agents with a target overlapping the AUG start codon and caused arrest of ribosome elongation with a target positioned in the coding region of the mRNA. Furthermore, translation could be blocked with a 6mer bisPNA or with a clamp PNA, forming partly a triplex, partly a duplex, with its target sequence in the coding region of the mRNA.     

Peptide nucleic acids as therapeutic agents.

Peptide nucleic acids (PNAs) have been around for more than seven years and it was hoped, at their introduction, that they would quickly enter the fields of antisense and antigene technology and drug development. Despite their extremely favorable hybridization and stability properties, as well as the encouraging antisense and antigene activity of PNA in cell-free systems, progress has been slow and experiments on cells in culture and in animals have been lacking. Judging from the very promising results published within the past year, however, there is every reason to believe that both PNA antisense and, possibly, PNA antigene research will strongly pick up momentum again. Specifically, it has been demonstrated that certain peptide-PNA conjugates are taken up very efficiently by, at least some, eukaryotic cells and that antisense down regulation of target genes in nerve cells in culture is attainable using such PNA conjugates. Perhaps even more exciting is that antisense-compatible effects have been reported using PNAs injected into the brain of rats. Finally, it has been shown that the bacterium Escherichia coli is susceptible to antisense gene regulation using PNA.     

Synthesis and properties of peptide nucleic acid labeled at the N-terminus with HiLyte Fluor 488 fluorescent dye

Fluorescently labeled peptide nucleic acids (PNAs) are important tools in fundamental research and biomedical applications. However, synthesis of labeled PNAs, especially using modern and expensive dyes, is less explored than similar preparations of oligonucleotide dye conjugates. Herein, we present a simple procedure for labeling of the PNA N-terminus with HiLyte Fluor 488 as the last step of solid phase PNA synthesis. A minimum excess of 1.25 equiv of activated carboxylic acid achieved labeling yields close to 90% providing a good compromise between the price of dye and the yield of product and significant improvement over previous literature procedures. The HiLyte Fluor 488-labeled PNAs retained the RNA binding ability and in live cell fluorescence microscopy experiments were brighter and significantly more photostable than PNA labeled with carboxyfluorescein. In contrast to fluorescein-labeled PNA, the fluorescence of PNAs labeled with HiLyte Fluor 488 was independent of pH in the biologically relevant range of 5–8. The potential of HiLyte Fluor 488-labeling for studies of PNA cellular uptake and distribution was demonstrated in several cell lines.     

Cellular antisense activity of peptide nucleic acid (PNAs) targeted to HIV-1 polypurine tract (PPT) containing RNA

DNA and RNA oligomers that contain stretches of guanines can associate to form stable secondary structures including G-quadruplexes. Our study shows that the (UUAAAAGAAAAGGGGGGAU) RNA sequence, from the human immunodeficiency virus type 1 (HIV-1 polypurine tract or PPT sequence) forms in vitro a stable folded structure involving the G-run. We have investigated the ability of pyrimidine peptide nucleic acid (PNA) oligomers targeted to the PPT sequence to invade the folded RNA and exhibit biological activity at the translation level in vitro and in cells. We find that PNAs can form stable complexes even with the structured PPT RNA target at neutral pH. We show that T-rich PNAs, namely the tridecamer-I PNA (C4T4CT4) forms triplex structures whereas the C-rich tridecamer-II PNA (TC6T4CT) likely forms a duplex with the target RNA. Interestingly, we find that both C-rich and T-rich PNAs arrested in vitro translation elongation specifically at the PPT target site. Finally, we show that T-rich and C-rich tridecamer PNAs that have been identified as efficient and specific blockers of translation elongation in vitro, specifically inhibit translation in streptolysin-O permeabilized cells where the PPT target sequence has been introduced upstream the reporter luciferase gene.     

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.     

Peptide nucleic acids (PNAs) antisense effect to bacterial growth and their application potentiality in biotechnology

Peptide nucleic acids (PNAs) are nucleic acid analogs having attractive properties such as quiet stability against nucleases and proteases, and they form strong complexes with complementary strands of DNA or RNA. Because of this attractive nature, PNA is often used in antisense technology to inhibit gene expression and microbial cell growth with high specificity. Many bacterial antisense or antiribosomal studies using PNA oligomers have been reported so far, and parameters to design effective antisense PNAs and to improve PNA cell entry for efficient inhibition of bacterial growth have been presented. However, there are still several obstacles such as low cellular uptake of PNA while applying antisense PNAs to a complex microbial community. On overcoming these problems, the PNA antisense technique might become a very attractive tool not only for controlling the microbial growth but also for further elucidating microbial ecology in complex microbial consortia. Here, we summarize and present recent studies on the development of antimicrobial PNAs targeting mRNAs and rRNAs. In addition, the application potentiality of antisense techniques in nonclinical biotechnology fields is discussed.     

An efficient biodelivery system for antisense polyamide nucleic acid (PNA)

With the aim of developing a general and straightforward procedure for the intracellular delivery of naked peptide nucleic acids (PNAs), we designed an intracellularly biodegradable triphenylphosphonium (TPP) cation based transporter system. In this system, TPP is linked, via a biolabile disulfide bridge, to an activated mercaptoethoxycarbonyl moiety, allowing its direct coupling to the N-terminal extremity of a free PNA through a carbamate bond. We found that such TPP-PNA-carbamate conjugates were highly stable in a cell culture medium containing fetal calf serum. In a glutathione-containing medium mimicking the cytosol, the conjugates were rapidly degraded into an unstable intermediate, which spontaneously decomposed, releasing the free PNA. Using a fluorescence-labeled PNA-TPP conjugate, we demonstrated that conjugates were taken up by cells. Efficient cellular uptake and release of the PNA into the cytosol was further confirmed by the anti-HIV activity measured for the TPP-conjugate of a 16-mer PNA targeting the TAR region of the HIV-1 genome. This conjugate exhibited an IC(50) value of 1 microM, while the free 16-mer PNA did not inhibit replication of HIV in the same cellular test.     

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.