Uptake Of Peptide Nucleic Acids Research Articles

Variation of Tetrahydrofurans in Thyclotides Enhances Oligonucleotide Binding and Cellular Uptake of Peptide Nucleic Acids.

Selective incorporation of conformational constraints into thyclotides can be used to modulate their binding to complementary oligonucleotides, increase polarity, and optimize uptake into HCT116 cells without assistance from moieties known to promote cell uptake. The X-ray structure and biophysical studies of a thyclotide-DNA duplex reveal that incorporation of tetrahydrofurans into an aegPNA backbone promotes a helical conformation that enhances binding to complementary DNA and RNA. Selective incorporation of tetrahydrofurans into the aegPNA backbone allows polarity to be increased incrementally so that uptake into HCT116 cells can be optimized. The enhanced binding, polarity, and cellular uptake properties of thyclotides were used to demonstrate effective inhibition of microRNA-21 in HCT116 cells.

Cellular uptake of 2-aminopyridine-modified peptide nucleic acids conjugated with cell-penetrating peptides.

Cell-penetrating peptides (CPPs) have been extensively used to deliver peptide nucleic acid (PNA) in cells. We have previously found that replacement of cytosine in triplex-forming PNAs with 2-aminopyridine (M) not only enhanced RNA binding, but also improved cellular uptake of PNAs. In this study, we used confocal fluorescence microscopy to evaluate the ability of CPPs to further improve cellular uptake of M-modified PNAs. We found that PNAs conjugated with Tat and octa-arginine peptides were effectively taken up in MCF7 cells when supplied in cell media at 1μM. Remarkably, M-modified PNA without any CPP conjugation also showed strong uptake when the concentration was increased to 5μM. Majority of PNA conjugates remained localized in distinct cytoplasmic vesicles, as judged by dot-like fluorescence patterns. However, M-modified PNAs conjugated with Tat, octa-arginine, and even a simple tri-lysine peptide also showed dispersed fluorescence in cytoplasm and were taken up in nuclei where they localized in larger vesicles, most likely nucleoli. Endosomolytic peptides or chemicals (chloroquine and CaCl2 ) did not release the conjugates from cytosolic vesicles, which suggested that the PNAs were not entrapped in endosomes. We hypothesize that M-modified PNAs escape endosomes and accumulate in cellular compartments rich in RNA, such as nucleoli, stress granules, and P-bodies.

Tuning the Loading and Release Properties of MicroRNA-Silencing Porous Silicon Nanoparticles by Using Chemically Diverse Peptide Nucleic Acid Payloads.

Peptide nucleic acids (PNAs) are a class of artificial oligonucleotide mimics that have garnered much attention as precision biotherapeutics for their efficient hybridization properties and their exceptional biological and chemical stability. However, the poor cellular uptake of PNA is a limiting factor to its more extensive use in biomedicine; encapsulation in nanoparticle carriers has therefore emerged as a strategy for internalization and delivery of PNA in cells. In this study, we demonstrate that PNA can be readily loaded into porous silicon nanoparticles (pSiNPs) following a simple salt-based trapping procedure thus far employed only for negatively charged synthetic oligonucleotides. We show that the ease and versatility of PNA chemistry also allows for producing PNAs with different net charge, from positive to negative, and that the use of differently charged PNAs enables optimization of loading into pSiNPs. Differently charged PNA payloads determine different release kinetics and allow modulation of the temporal profile of the delivery process. In vitro silencing of a set of specific microRNAs using a pSiNP-PNA delivery platform demonstrates the potential for biomedical applications.

Extracellular vesicles mediated exocytosis of antisense peptide nucleic acids

Peptide nucleic acids (PNAs), a synthetic DNA mimic, have been extensively utilized for antisense- and antigene-based biomedical applications. Significant efforts have been made to increase the cellular uptake of PNAs, but here we examined relatively unexplored aspects of intracellular trafficking and endocytic recycling of PNAs. For proof-of-concept, we used anti-microRNA (miR) PNA targeting miR-155. The sub-cellular localization of PNA was studied via confocal and flow-cytometry-based assays in HeLa cells. A comprehensive characterization of PNA-containing extracellular vesicles revealed spherical morphology, negative surface charge density, and the presence of tetraspanin markers. Most importantly, we investigated rab11a and rab27b GTPases’ role in regulating the exocytosis of PNAs. Organelle staining, followed by confocal imaging, showed higher localization of PNA in lysosomes. Gene-expression analysis established the enhanced functional activity of PNA after inhibition of endocytic recycling. Multiple studies report the exocytosis of single-stranded oligonucleotides, short interfering RNAs (siRNAs), and nanocarriers. To our knowledge, this is the first mechanistic study to establish that PNA undergoes endocytic recycling and exocytosis out of tumor cells. The results presented here can serve as a platform to develop and optimize strategies for improving the therapeutic efficacy of PNAs by avoiding the recycling pathways.

Recent Advances in Peptide Nucleic Acids for Rapid Detection of Foodborne Pathogens

Peptide nucleic acids (PNAs) are DNA/RNA analogs in which sugar-phosphate backbone is replaced by N-2-aminoethylglycine repeating units. Since PNA contains a neutral skeleton, there is no electrostatic repulsion, resulting in significant stability of its hybrid structure with complementary oligonucleotides. At present, PNA has taken the place of DNA probe in many studies. There are several disadvantages of cellular uptake of PNA, so modifications in PNA backbone or covalent coupling with cell-penetrating peptides are necessary to improve its delivery inside the cells. In recent years, PNA has been extensively used in the rapid detection of microorganisms, such as fluorescence in situ hybridization, PCR amplification, biosensor, and gene chip. The structure and characteristics of PNA probe, the hybridization method, and the design principle of PNA probes are introduced in this review, and the application progress of PNA probes in the rapid detection of foodborne pathogens is summarized. On this basis, the advantages and disadvantages of PNA probes are analyzed, and the future development trend is prospected.

Caprin‐1 Promotes Cellular Uptake of Nucleic Acids with Backbone and Sequence Discrimination

AbstractThe cellular delivery of oligonucleotides has been a major obstacle in the development of therapeutic antisense agents. PNAs (Peptide Nucleic Acid) are unique in providing a modular peptidic backbone that is amenable to structural and charge modulation. While cationic PNAs have been shown to be taken up by cells more efficiently than neutral PNAs, the generality of uptake across different nucleobase sequences has never been tested. Herein, we quantified the relative uptake of PNAs across a library of 10 000 sequences for two different PNA backbones (cationic and neutral) and identified sequences with high uptake and low uptake. We used the high uptake sequence as a bait for target identification, leading to the discovery that a protein, caprin‐1, binds to PNA with backbone and sequence discrimination. We further showed that purified caprin‐1 added to cell cultures enhanced the cellular uptake of PNA as well as DNA and RNA.

Influence of Different Cell-Penetrating Peptides on the Antimicrobial Efficiency of PNAs in Streptococcus pyogenes

Streptococcus pyogenes is an exclusively human pathogen causing a wide range of clinical manifestations from mild superficial infections to severe, life-threatening, invasive diseases. S. pyogenes is consistently susceptible toward penicillin, but therapeutic failure of penicillin treatment has been reported frequently. At the same time, streptococcal resistance to alternative antibiotics, e.g., macrolides, is common. To reduce the application of antibiotics for treatment of S. pyogenes infections, it is mandatory to develop novel therapeutic strategies. Antisense peptide nucleic acids (PNAs) are synthetic DNA derivatives widely applied for hybridization-based microbial diagnostics. They have a high potential as therapeutic agents, because PNA antisense targeting of essential genes was shown to reduce growth of several pathogenic bacterial species. Spontaneous cellular uptake of PNAs is restricted in eukaryotes and in bacteria. To overcome this problem, PNAs can be coupled to cell-penetrating peptides (CPPs) that support PNA translocation over the cell membrane. In bacteria, the efficiency of CPP-mediated PNA uptake is species specific. Previously, HIV-1 transactivator of transcription (HIV-1 TAT) peptide-coupled anti-gyrA PNA was shown to inhibit growth of S. pyogenes. Here, we investigate the effect of 18 CPP-coupled anti-gyrA PNAs on S. pyogenes growth and virulence. HIV-1 TAT, oligolysine (K8), and (RXR)4XB peptide-coupled anti-gyrA PNAs efficiently abolished bacterial growth in vitro. Consistently, treatment with these three CPP-PNAs increased survival of larvae in a Galleria mellonella infection model.

AntimiR-155 Cyclic Peptide-PNA Conjugate: Synthesis, Cellular Uptake, and Biological Activity.

Efficient delivery of nucleic acids into cells still remains a great challenge. Peptide nucleic acids (PNAs) are DNA analogues with a neutral backbone and are synthesized by solid phase peptide chemistry. This allows a straightforward synthetic route to introduce a linear short peptide (a.k.a. cell-penetrating peptide) to the PNA molecule as a means of facilitating cellular uptake of PNAs. Herein, we have devised a synthetic route in which a cyclic peptide is prepared on a solid support and is extended with the PNA molecule, where all syntheses are accomplished on the solid phase. This allows the conjugation of the cyclic peptide to the PNA molecule with the need of only one purification step after the cyclic peptide–PNA conjugate (C9–PNA) is cleaved from the solid support. The PNA sequence chosen is an antimiR-155 molecule that is complementary to mature miR-155, a well-established oncogenic miRNA. By labeling C9–PNA with fluorescein isothiocyanate, we observe efficient cellular uptake into glioblastoma cells (U87MG) at a low concentration (0.5 μM), as corroborated by fluorescence-activated cell sorting (FACS) analysis and confocal microscopy. FACS analysis also suggests an uptake mechanism that is energy-dependent. Finally, the antimiR activity of C9–PNA was shown by analyzing miR155 levels by quantitative reverse transcription polymerase chain reaction and by observing a reduction in cell viability and proliferation in U87MG cells, as corroborated by XTT and colony formation assays. Given the added biological stability of cyclic versus linear peptides, this synthetic approach may be a useful and straightforward approach to synthesize cyclic peptide–PNA conjugates.

Antimicrobial synergy between mRNA targeted peptide nucleic acid and antibiotics in E. coli

A combination of antibacterial agents should make the emergence of resistance in bacteria less probable. Thus we have analyzed the synergistic effects between antibacterial antisense peptide nucleic acids (PNA) and conventional antibiotics against Escherichia coli AS19 (lipopolysaccharide defective) strain and a derivative of a pathogenic strain E. coli O157:H7. PNAs were designed to target mRNA transcripts encoding the essential acyl carrier protein (gene acpP) and conjugated to the cell-penetrating peptide (KFF)3K for cellular uptake. Antibiotics included aminoglycosides, aminopenicillins, polymyxins, rifamycins, sulfonamides and trimethoprim. Synergies were evaluated using the checkerboard technique. Fractional Inhibitory Concentration indices (FICi) were calculated for all combinations based on the minimal inhibitory concentration of each individual agent. The results demonstrate two novel synergistic combinations of antimicrobial agents, namely, (KFF)3K-PNA anti-acpP with polymyxin B and (KFF)3K-PNA anti-acpP with trimethoprim (both with FICi = 0.38). Polymyxin B’s synergy postulates cell wall targeted antibiotics as attractive agents to improve the uptake of PNA while trimethoprim’s interaction with PNA my reveal a new inhibitory mechanism.

Self-assembled nanoparticles for cellular delivery of peptide nucleic acid using amphiphilic N,N,N-trimethyl-O-alkyl chitosan derivatives.

Peptide nucleic acid (PNA) holds enormous potentials as antisense/antigenic drug due to its specific binding ability and biostability with DNA or RNA. However, the poor cellular delivery is the key obstacle in development of PNA therapy. To overcome this difficulty, we developed self-assembled nanoparticles (NPs) for delivery of PNA to living cells using amphiphilic CS derivatives. A series of N,N,N-trimethyl-O-alkyl chitosans (TMACs) with different lengths of alkyl chains were synthesized. The structures of these synthesized chemicals were characterized with FT-IR and 1H NMR. We found that the TMACs were all able to self-assemble in aqueous condition to form nano-size NPs. These nano-size NPs are spherical shape with a size range of around 100 nm and a zeta potential above +30 mV. PNA was easily encapsulated into chitosan derivative NPs by an ultrasonic method with entrapment efficiency up to 75%. The PNA-loaded TMAC NPs released the drug in a sustained manner in PBS (pH 7.4) at 37 °C. N,N,N-trimethyl-O-cetyl chitosan (TMCC) showed the best in vitro hemocompatibility and cell viability. These TMCC based NPs were able to dramatically increase the cellular uptake of PNA, specifically, 66-fold higher compared to without using these nanoparticles. The results suggest that the designed TMCC NPs might be a promising solution for improving cellular delivery of PNA.

Sequence-selective recognition of double-stranded RNA and enhanced cellular uptake of cationic nucleobase and backbone-modified peptide nucleic acids.

Sequence-selective recognition of complex RNAs in live cells could find broad applications in biology, biomedical research, and biotechnology. However, specific recognition of structured RNA is challenging, and generally applicable and effective methods are lacking. Recently, we found that peptide nucleic acids (PNAs) were unusually well-suited ligands for recognition of double-stranded RNAs. Herein, we report that 2-aminopyridine (M) modified PNAs and their conjugates with lysine and arginine tripeptides form strong (Ka = 9.4 to 17 × 107 M−1) and sequence-selective triple helices with RNA hairpins at physiological pH and salt concentration. The affinity of PNA–peptide conjugates for the matched RNA hairpins was unusually high compared to the much lower affinity for DNA hairpins of the same sequence (Ka = 0.05 to 1.1 × 107 M−1). The binding of double-stranded RNA by M-modified PNA–peptide conjugates was a relatively fast process (kon = 2.9 × 104 M−1 sec−1) compared to the notoriously slow triple helix formation by oligodeoxynucleotides (kon ∼ 103 M−1 sec−1). M-modified PNA–peptide conjugates were not cytotoxic and were efficiently delivered in the cytosol of HEK293 cells at 10 µM. Surprisingly, M-modified PNAs without peptide conjugation were also taken up by HEK293 cells, which, to the best of our knowledge, is the first example of heterocyclic base modification that enhances the cellular uptake of PNA. Our results suggest that M-modified PNA–peptide conjugates are promising probes for sequence-selective recognition of double-stranded RNA in live cells and other biological systems.

Role of SbmA in the uptake of peptide nucleic acid (PNA)-peptide conjugates in E. coli.

Antisense PNA oligomers targeting essential genes (acpP or ftsZ) and conjugated to the delivery peptide L((KFF)(3)K) show complete growth inhibition of wild type E. coli strain (MG1655) with submicromolar MIC. In this study we show that resistant mutants generated against such PNA-peptide conjugates had disruptions in the region of sbmA, a gene encoding an inner membrane peptide transporter. The wild type sensitivity to the PNA conjugates was re-established in the resistance mutants by complementation with sbmA. Furthermore, deletion of sbmA in E. coli AS19, a strain that is sensitive to unmodified PNA, resulted in resistance to PNA. Finally, PNA conjugated with the corresponding non-biological H-D((KFF)(3)K) peptide retained antibacterial activity in sbmA deletion strains, whereas the same conjugate with a protease-sensitive linker did not. These results clearly identify SbmA as a carrier of naked PNA over the inner bacterial membrane and thereby infer that the peptide is transporting the PNA conjugates over the outer membrane. Strains lacking SbmA were used to screen novel peptide-PNA carriers that were SbmA-independent. Four such PNA-peptide conjugates, H-D((KFF)(3)K), H-(RFR)(4)-Ahx-βAla, H-(R-Ahx-R)(4)-Ahx-βAla, and H-(R-Ahx)(6)-βAla, were identified that utilize an alternative uptake mechanism but retain their antimicrobial potency. In addition SbmA is the first protein identified to recognize PNA.

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.

A Novel Cell-penetrating Peptide, M918, for Efficient Delivery of Proteins and Peptide Nucleic Acids

Cell-penetrating peptides (CPPs) have attracted increasing attention in the past decade as a result of their high potential to convey various, otherwise impermeable, bioactive agents across cellular plasma membranes. Albeit different CPPs have proven potent in delivery of different cargoes, there is generally a correlation between high efficacy and cytotoxicity for these peptides. Hence, it is of great importance to find new, non-toxic CPPs with more widespread delivery properties. We present a novel CPP, M918, that efficiently translocates various cells in a non-toxic fashion. In line with most other CPPs, the peptide is internalized mainly via endocytosis, and in particular macropinocytosis, but independent of glycosaminoglycans on the cell surface. In addition, in a splice correction assay using antisense peptide nucleic acid (PNA) conjugated via a disulphide bridge to M918 (M918-PNA), we observed a dose-dependent increase in correct splicing, exceeding the effect of other CPPs. Our data demonstrate that M918 is a novel CPP that can be used to translocate different cargoes inside various cells efficiently.

261 LABELING SEX-SPECIFIC DNA SEQUENCES IN MAMMALIAN SPERM

While flow cytometric separation of X- andY-chromosome- bearing sperm has advanced to the point of acceptance in the commercial production of sex-preselected cattle, it is important to continue researching this area to improve efficiencies. For example, the difference in DNA sequence between the X- andY-chromosomes has merit as a foundation for an alternative sperm sexing approach that could enable the complete separation and use of an entire ejaculate. We used synthetic DNA mimics conjugated to a fluorescent dye for in situ detection of Y-chromosomes in metaphase preparations of porcine somatic cells and spermatozoa. Peptide nucleic acids (PNA) are synthetic compounds with higher affinity and stability than conventional DNA probes and are used as specific hybridization probes to complementary DNA. The application of PNA probes was demonstrated previously in telomere analysis studies, and we confirmed their efficacy using a CY3-(CCCTAA)3 PNA to probe bull and boar sperm telomeric sequences. Using male porcine somatic cells and theY-chromosome as a template, we arranged for the synthesis of a CY3-conjugated PNA to bind 13-15 base pairs of unique, Y-chromosome sequence. By testing different labeling conditions, we found that brief incubation of metaphase chromosomes with the PNA produced a localized signal on theY-chromosome. No signals were present when chromosomes of porcine female somatic cells were incubated with the PNA probes. Because chromosomes occupy non-random territories in all cell nuclei including those in sperm, we expected to find centrally located signals in 50% of fixed boar sperm when these were treated with the same PNA as used for the somatic cells. We found the signals present in 161 of 302 (53.3%) sperm to consist of a single, centrally located, round fluorescent dot in the sperm head. Further research is required to establish the uptake of PNA in live sperm toward evaluation of this approach for sperm sexing.

Enhanced delivery of cell-penetrating peptide–peptide nucleic acid conjugates by endosomal disruption

Improvement of cellular uptake and cellular localization is still one of the main obstacles to the development of antisense-antigene therapeutics, including peptide nucleic acid (PNA). Cell-penetrating peptides (CPPs) such as Tat peptide and polyarginine have been widely used to improve the cellular uptake of PNA and other antisense agents. Cellular uptake of most CPP conjugates occurs mainly through endocytotic pathways, and most CPP conjugate is retained in the endosomal compartments of the cell. Several methods to induce endosome disruption have been shown to improve the bioavailability of CPP conjugates to the cytosol and/or nucleus by facilitating escape from the endosomal compartments. Here we describe protocols for the delivery of CPP-PNA conjugates to adherent cultured cells using photodynamic treatment (photochemical internalization), Ca2+ treatment or chloroquine treatment to potentiate the antisense effects of CPP-PNA conjugates through increased release of CPP conjugates into the cytoplasm. This protocol, consisting of CPP-mediated delivery assisted by an endosome-disruption agent, allows the delivery of the CPP-PNA conjugates to the nucleus and/or cytosol of cultured cells. The endosome-disruption treatment improves the nuclear antisense effects of CPP-PNA conjugates by up to two orders of magnitude using 24-hour delivery.

Cellular Uptake of PNA−Terpyridine Conjugates and Its Enhancement by Zn2+ Ions

Conjugation of usually impermeable peptide nucleic acids (PNA) to the chelator 2,2':6',2' '-terpyridine strongly promotes cellular and nuclear uptake by cultured HeLa cells. Cellular accumulation is further enhanced in the presence of extracellular Zn2+.

Calcium Liberates PNAs from Endosomes

Many peptides are reported to enhance cellular uptake of peptide nucleic acids and other macromolecules. Cellular uptake, however, is not synonymous with cellular activity. In this issue of Chemistry and Biology, Nielsen and colleagues examine the traffic of PNAs and investigate protocols for improving recognition of target mRNA inside cells.

Uptake of cell-penetrating peptides is dependent on peptide-to-cell ratio rather than on peptide concentration

The influence of the peptide-to-cell ratio and energy depletion on uptake and degradation of the cell-penetrating peptides (CPPs) MAP (model amphipathic peptide) was investigated. The intracellular concentration of the CPPs, MAP and penetratin was monitored while varying the number of cells at fixed peptide concentration and incubation volume, or changing the concentration and incubation volume at fixed cell number. The uptake of CPPs was shown to be dependent on the peptide/cell ratio. At given peptide concentration and incubation volume, the intracellular concentration of peptide increased with lower cell number. At given cell number, doubling of the incubation volume increased intracellular peptide concentration to a similar extent as the doubling in incubation concentration. From a practical view, this means that the peptide/cell ratio has at least the same importance for the uptake of CPPs as the used peptide concentration. No influence of the peptide/cell ratio was found for the cellular uptake of peptide nucleic acid (PNA), or a non-amphipathic MAP analogue, investigated in parallel for comparison purposes. Energy depletion resulted in significantly reduced quantities of intracellular fluorescence label. Moreover, we show that this difference is mainly due to a membrane-impermeable fluorescent-labelled degradation product, which is lacking in energy-depleted cells. The mechanism of its generation is not likely to be endosomal degradation of endocytosed material, as it is not chloroquine- or brefeldin-sensitive.

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.