Telomerase as a possible target for anticancer therapy

Telomeres, the termini of chromosomes, provide essential stability to linear eukaryotic chromosomes. The enzyme telomerase is one mechanism that maintains telomeres, and is activated in 85% of human cancer cells. New studies on peptide nucleic acids (PNAs) that inhibit telomerase have demonstrated that unexpected regions of the enzyme can serve as targets for inhibitors. The novel delivery method used expands the utility of PNAs.     

PNA: Synthetic Polyamide Nucleic Acids with Unusual Binding Properties

The astonishing discovery that peptide nucleic acids (PNAs, B=nucleobase), in spite of their drastic structural difference to natural DNA, are better nucleic acid mimetics than many other oligonucleotides has resulted in an explosion of research into this class of compounds. The synthesis, physical properties, and biological interactions of PNAs as well as their chimeras with DNA and RNA are summarized here.     

Recognition of chromosomal DNA by PNAs

The recognition of cellular nucleic acids by synthetic oligonucleotides is a versatile strategy for regulating biological processes. The vast majority of published studies have focused on antisense oligonucleotides that target mRNA, but it is also possible to design antigene oligonucleotides that are complementary to chromosomal DNA. Antigene oligomers could be used to inhibit the expression of any gene or analyze promoter structure and the mechanisms governing gene regulation. Other potential applications of antigene oligomers include activation of expression of chosen genes or the introduction of mutations to correct genetic disease. Peptide nucleic acid (PNA) is a nonionic DNA/RNA mimic that possesses outstanding potential for recognition of duplex DNA. Here we describe properties of PNAs and the challenges for their development as robust antigene agents.     

From Prebiotic Chemistry to Supramolecular Biomedical Materials: Exploring the Properties of Self-Assembling Nucleobase-Containing Peptides

Peptides and their synthetic analogs are a class of molecules with enormous relevance as therapeutics for their ability to interact with biomacromolecules like nucleic acids and proteins, potentially interfering with biological pathways often involved in the onset and progression of pathologies of high social impact. Nucleobase-bearing peptides (nucleopeptides) and pseudopeptides (PNAs) offer further interesting possibilities related to their nucleobase-decorated nature for diagnostic and therapeutic applications, thanks to their reported ability to target complementary DNA and RNA strands. In addition, these chimeric compounds are endowed with intriguing self-assembling properties, which are at the heart of their investigation as self-replicating materials in prebiotic chemistry, as well as their application as constituents of innovative drug delivery systems and, more generally, as novel nanomaterials to be employed in biomedicine. Herein we describe the properties of nucleopeptides, PNAs and related supramolecular systems, and summarize some of the most relevant applications of these systems.     

Studying the mechanism of RNA separations using RNA chromatography and its application in the analysis of ribosomal RNA and RNA:RNA interactions

DNA/RNA chromatography presents a versatile platform for the analysis of nucleic acids. Although the mechanism of separation of double stranded (ds) DNA fragments is largely understood, the mechanism by which RNA is separated appears more complicated. To further understand the separation mechanisms of RNA using ion pair reverse phase liquid chromatography, we have analysed a number of dsRNA and single stranded (ss) RNA fragments. The high-resolution separation of dsRNA was observed, in a similar manner to dsDNA under non-denaturing conditions. Moreover, the high-resolution separation of ssRNA was observed at high temperatures (75 °C) in contrast to ssDNA. It is proposed that the presence of duplex regions/secondary structures within the RNA remain at such temperatures, resulting in high-resolution RNA separations. The retention time of the nucleic acids reflects the relative hydrophobicity, through contributions of the nucleic sequence and the degree of secondary structure present. In addition, the analysis of RNA using such approaches was extended to enable the discrimination of bacterial 16S rRNA fragments and as an aid to conformational analysis of RNA. RNA:RNA interactions of the human telomerase RNA component (hTR) were analysed in conjunction with the incorporation of Mg²⁺ during chromatography. This novel chromatographic procedure permits analysis of the temperature dependent formation of dimeric RNA species.     

PNA-DNA duplexes, triplexes, and quadruplexes are stabilized with trans-cyclopentane units

Peptide nucleic acids (PNAs) are non-natural nucleic acid mimics that bind to complementary DNA and RNA with high affinity and selectivity. PNA can bind to nucleic acids in a number of different ways. Currently, the formation of PNA-oligonucleotide duplex, triplex, and quadruplex structures have been reported. PNAs have been used in numerous biomedicial applications, but there are few strategies to predictably improve the binding properties of PNAs by backbone modification. We have been studying the benefits of incorporating (S,S)-trans-cyclopentane diamine units (tcyp) into the PNA backbone. In this Communication, we report the improvement in stability associated with tcyp incorporation into PNA-DNA duplexes, triplexes, and quadruplexes. The broad utility of this modification across multiple types of PNA structures is unique and should prove useful in the development of applications that rely on PNA.     

An experimental and theoretical study of the gas-phase decomposition of monoprotonated peptide nucleic acids

Peptide nucleic acids (PNAs) are DNA/RNA mimics which have recently generated considerable interest due to their potential use as antisense and antigene therapeutics and as diagnostic and molecular biology tools. These synthetic biomolecules were designed with improved properties over corresponding oligonucleotides such as greater binding affinity to complementary nucleic acids, enhanced cellular uptake, and greater stability in biological systems. Because of the stability and unique structure of PNAs, traditional sequence confirmation methods are not effective. Alternatively, electrospray ionization coupled with Fourier transform ion cyclotron resonance mass spectrometry shows great potential as a tool for the characterization and structural elucidation of these oligonucleotide analogs. Extensive gas-phase fragmentation studies of a mixed nucleobase 4-mer (AACT) and a mixed nucleobase 4-mer with an acetylated N-terminus (N-acetylated AACT) have been performed. Gas-phase collision-induced dissociation of PNAs resulted in water loss, cleavage of the methylene carbonyl linker containing a nucleobase, cleavage of the peptide bond, and the loss of nucleobases. These studies show that the fragmentation behavior of PNAs resembles that of both peptides and oligonucleotides. Molecular mechanics (MM+), semiempirical (AM1), and ab initio (STO-3G) calculations were used to investigate the site of protonation and determine potential low energy conformations. Computational methods were also employed to study prospective intramolecular interactions and provide insight into potential fragmentation mechanisms.     

High-affinity peptide nucleic acid oligomers containing tricyclic cytosine analogues

[structure: see text] Peptide nucleic acid (PNA) monomers containing the tricyclic cytosine analogues phenoxazine, 9-(2-aminoethoxy)phenoxazine (G-clamp), and 9-(3-aminopropoxy)phenoxazine (propyl-G-clamp) have been synthesized. The modified nucleobases were incorporated into PNA oligomers using Boc-chemistry for solid-phase synthesis. PNAs containing single G-clamp modifications exhibit significantly enhanced affinity toward RNA and DNA targets relative to unmodified PNA while maintaining mismatch discrimination. These PNA G-clamp modifications exhibit the highest increase in affinity toward nucleic acid targets reported so far for PNA modifications.     

Nucleobase‐Modified PNA Suppresses Translation by Forming a Triple Helix with a Hairpin Structure in mRNA In Vitro and in Cells

Compounds that bind specifically to double‐stranded regions of RNA have potential as regulators of structure‐based RNA function; however, sequence‐selective recognition of double‐stranded RNA is challenging. The modification of peptide nucleic acid (PNA) with unnatural nucleobases enables the formation of PNA–RNA triplexes. Herein, we demonstrate that a 9‐mer PNA forms a sequence‐specific PNA–RNA triplex with a dissociation constant of less than 1 nm at physiological pH. The triplex formed within the 5′ untranslated region of an mRNA reduces the protein expression levels both in vitro and in cells. A single triplet mismatch destabilizes the complex, and in this case, no translation suppression is observed. The triplex‐forming PNAs are unique and potent compounds that hold promise as inhibitors of cellular functions that are controlled by double‐stranded RNAs, such as RNA interference, RNA editing, and RNA localization mediated by protein–RNA interactions.     

Site-specific cleavage of human telomerase RNA using PNA-neocuproine.Zn(II) derivatives

Here we report the synthesis of a novel PNA based neocuproine.Zn RNA cleaving agent; we demonstrate that such agents sequence specifically cleave a synthetic RNA target and in particular the RNA component of human telomerase.     

The alpha-helical peptide nucleic acid concept: merger of peptide secondary structure and codified nucleic acid recognition

A novel platform for nucleic acid recognition that integrates the alpha-helix secondary structure of peptides with the codified base-pairing capability of nucleic acids is reported. The resulting alpha-helical peptide nucleic acids (alpha PNAs) are composed of a repeating tetrapeptidyl unit, aa(1)-aa(2)-aa(3)-Ser(B), where aa(1) through aa(3) represent generic ancillary amino acids and B = nucleobases linked to Ser via a methylene bridge. Effective syntheses of constituent Fmoc-protected nucleoamino acids (Fmoc-Ser(B)-OH, where B = thymine, cytosine, and uracil) are described along with a protocol for the solid-phase synthesis of 21mer alpha PNAs containing five such nucleobases. By varying the ancillary amino acids, two distinct classes of alpha PNAs were constructed, having a net charge of -1 or +6, respectively, at physiological pH. The modular nature of the alpha PNA platform was illustrated by the synthesis of symmetrical disulfide-bridged alpha PNA dimers containing 10 nucleobases. Hybridization of these alpha PNAs with ssDNA has been examined by thermal denaturation, gel electrophoresis, and circular dichroism (CD) and the data indicated that alpha PNA binds to ssDNA in a cooperative manner with high affinity and sequence specificity. In general, b2 alpha PNAs bind faster and more strongly with ssDNA than do the corresponding b1 alpha PNAs. Parallel alpha PNA-DNA complexes are more stable than their antiparallel counterparts. CD studies also revealed that the hybridization event involves the folding of both species into their helical conformations. Finally, NMR experiments provided conclusive evidence of Watson-Crick base pairing in alpha PNA-ssDNA hybrids.     

A Nucleic Acid Dependent Chemical Photocatalysis in Live Human Cells

Only two nucleic acid directed chemical reactions that are compatible with live cells have been reported to date. Neither of these processes generate toxic species from nontoxic starting materials. Reactions of the latter type could be applied as gene‐specific drugs, for example, in the treatment of cancer. We report here the first example of a chemical reaction that generates a cytotoxic drug from a nontoxic prodrug in the presence of a specific endogeneous ribonucleic acid in live mammalian cells. In this case, the prodrug is triplet oxygen and the drug is singlet oxygen. The key component of this reaction is an inert molecule (InP–2′‐OMe‐RNA/Q–2′‐OMe‐RNA; P: photosensitizer; Q: quencher), which becomes an active photosensitizer (InP–2′‐OMe‐RNA) in the presence of single‐stranded nucleic acid targets. Upon irradiation with red light, the photosensitizer produces over 6000 equivalents of toxic singlet oxygen per nucleic acid target. This reaction is highly sequence specific. To detect the generation of singlet oxygen in live cells, we prepared a membrane‐permeable and water‐soluble fluorescent scavenger, a derivative of 2,5‐diphenylisobenzofurane. The scavenger decomposes upon reaction with singlet oxygen and this is manifested in a decrease in the fluorescence intensity. This effect can be conveniently monitored by flow cytometry.     

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

The 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.     

Cyclohexanyl peptide nucleic acids (chPNAs) for preferential RNA binding: effective tuning of dihedral angle beta in PNAs for DNA/RNA discrimination

[structures: see text] A serious drawback of peptide nucleic acids (PNAs) from an application perspective that has not been adequately dealt with is nondiscrimination of identical DNA and RNA sequences. An analysis of the available X-ray and NMR solution structures of PNA complexes with DNA and RNA suggested that it might be possible to rationally impart DNA/RNA duplex binding selectivity by tuning the dihedral angle beta of the flexible ethylenediamine part of the PNA backbone (II) via suitable chemical modifications. Cyclohexanyl PNAs (chPNAs) with beta approximately = 65 degrees were designed on the basis of this rationale. The chPNAs introduced remarkable differences in duplex stabilities among their DNA and RNA complexes, with melting temperatures (deltaTm(RNA-DNA) = +16-50 degrees C) depending on the number of modifications and the stereochemistry. This is a highly significant, exceptional binding selectivity of a mix sequence of PNA to RNA over the same DNA sequence as that seen to date. In contrast, cyclopentanyl PNAs (cpPNAs) with beta approximately = 25 degrees hybridize to DNA/RNA strongly without discrimination because of the ring puckering of the cyclopentane ring. The high affinity of chPNAs to bind to RNA without losing base specificity will have immediate implications in designing improved PNAs for therapeutic and diagnostic applications.     

Inhibition of translation by small RNA-stabilized mRNA structures in human cells

RNA-mediated gene regulation and expression are critically dependent on both nucleic acid architecture and recognition. We present a novel mechanism for the regulation of gene expression through direct RNA-RNA interactions between small RNA and mRNA in human cells. Using mRNA reporters containing G-rich sequences in the 5'-untranslated region (5'-UTR), in the coding region, or both, we showed that G-rich small RNAs bind to the reporter mRNAs and form an intermolecular RNA G-quadruplex that can inhibit gene translation in living cells. Using a combination of circular dichroism (CD) and RNase footprinting in vitro, we found that the intermolecular G-quadruplexes show a parallel G-quadruplex structure. We next investigated whether the intermolecular G-quadruplex is present in living cells. Employing the fluorophore-labeled probes, we found that two G-rich RNA molecules form an intermolecular G-quadruplex structure in living cells. These results extend the concept of small RNA-mediated expression and suggest an important role for such RNA structures in the inhibition of mRNA translation.     

Targeted disruption of the CCR5 gene in human hematopoietic stem cells stimulated by peptide nucleic acids

Peptide nucleic acids (PNAs) bind duplex DNA in a sequence-specific manner, creating triplex structures that can provoke DNA repair and produce genome modification. CCR5 encodes a chemokine receptor required for HIV-1 entry into human cells, and individuals carrying mutations in this gene are resistant to HIV-1 infection. Transfection of human cells with PNAs targeted to the CCR5 gene, plus donor DNAs designed to introduce stop codons mimicking the naturally occurring CCR5-delta32 mutation, produced 2.46% targeted gene modification. CCR5 modification was confirmed at the DNA, RNA, and protein levels and was shown to confer resistance to infection with HIV-1. Targeting of CCR5 was achieved in human CD34(+) hematopoietic stem cells (HSCs) with subsequent engraftment into mice and persistence of the gene modification more than four months posttransplantation. This work suggests a therapeutic strategy for CCR5 knockout in HSCs from HIV-1-infected individuals, rendering cells resistant to HIV-1 and preserving immune system function.     

Gene sensors based on peptide nucleic acid (PNA) probes: relationship between sensor sensitivity and probe/target duplex stability

Gene sensors based on peptide nucleic acid (PNA) probes were prepared and the relationship between sensor sensitivity and the duplex stability of the probe PNAs and target complementary DNAs was studied using five synthesized PNAs (10-, 15-, 17-, 20-, and 22-mers). It was found that the association constants for the probe PNA/target DNA pairs depend not only on the length but also on the base pair sequence, and that the trend in the sensor responses was the same as that in the association constants for the corresponding pairs. In addition, by using two kinds of probe PNAs with different lengths, it was demonstrated that fabrication of sensors based on probe PNAs with comparable association constants yielded similar response curves and sensor sensitivities.     

Telomere and Telomerase as Targets for Cancer Therapy

Telomere maintenance and telomerase reactivation is essential for the transformation of most human cancer cells. Telomere shortening to the threshold length, mutations of the telomere-associated proteins, and/or telomerase RNA lead to telomeric dysfunction and therefore genomic instability. Telomerase up-regulation in 85% of human cancer cells has become a hallmark of cancers, hence a promising target for anticancer therapy. In this review, we discuss the mechanism of cancer due to telomere dysfunction and the resulting biological effects, the control of telomerase activity, and the new developments in cancer therapies targeting telomere and telomerase.     

Nucleic acid encoding to program self-assembly in chemical biology

This tutorial review serves as an introduction to the use of oligonucleotides and in particular peptide nucleic acids (PNAs) to encode function beyond heredity. Applications in chemical biology are reviewed starting with the use of nucleic acid tags to program self-assembled microarrays of small and macromolecules, followed by the use of nucleic acid templated reactions for the purpose of DNA or RNA sensing and finally, the use of nucleic acid templates to display ligands.