A novel single-stranded DNA expression vector

Generation of DNA Aptamers with Functional Activity in Mammalian Cells by Mimicking Retroviruses

DNA aptamers are single-stranded DNA oligonucleotide sequences that bind to specific targets with high affinity. Currently, DNA aptamers can be produced only by in vitro synthesis. It is difficult for DNA aptamers to have a sustained impact on intracellular protein activity, which limits their clinical application. In this study, we developed a DNA aptamer expression system to generate DNA aptamers with functional activity in mammalian cells by mimicking retroviruses. Using this system, DNA aptamers targeting intracellular Ras (Ra1) and membrane-bound CD71 (XQ2) were successfully generated in cells. In particular, the expressed Ra1 not only specifically bound to the intracellular Ras protein but also inhibited the phosphorylation of downstream ERK1/2 and AKT. Furthermore, by inserting the DNA aptamer expression system for Ra1 into a lentivirus vector, the system can be delivered into cells and stably produce Ra1 over time, resulting in the inhibition of lung cancer cell proliferation. Therefore, our study provides a novel strategy for the intracellular generation of DNA aptamers with functional activity and opens a new avenue for the clinical application of intracellular DNA aptamers in disease treatment.

Delivery of therapeutic RNA-cleaving oligodeoxyribonucleotides (deoxyribozymes): from cell culture studies to clinical trials

INTRODUCTION

Development of efficient in vivo delivery systems remains a major challenge en route to clinical application of antisense technology, including RNA-cleaving molecules such as deoxyribozymes (DNAzymes). The mechanisms of oligonucleotide uptake and trafficking are clearly dependent on cell type and the type of oligonucleotide analogue. It appears likely that each particular disease target would pose its own specific requirements for a delivery method. Areas covered. In this review we will discuss the available options for DNAzyme delivery in vitro and in vivo, outline various exogenous and endogenous strategies that have been, or are still being, developed and ascertain their applicability with emphasis on those methods that are currently being used in clinical trials. Expert opinion. The available information suggests that a practical system for in vivo delivery has to be biodegradable, as to minimize concerns over long-term toxicity, it should not accumulate in the organism. Extracellular vesicles may offer the most organic way for drug delivery especially as they can be fused with artificial liposomes to produce hybrid nanoparticles. Chemical modification of DNAzymes holds great potential to apply oligonucleotide analogs that would not only be resistant to nuclease digestion, but also able to penetrate cells without external delivery agents.

Hitting bacteria at the heart of the central dogma: sequence-specific inhibition

An important objective in developing new drugs is the achievement of high specificity to maximize curing effect and minimize side-effects, and high specificity is an integral part of the antisense approach. The antisense techniques have been extensively developed from the application of simple long, regular antisense RNA (asRNA) molecules to highly modified versions conferring resistance to nucleases, stability of hybrid formation and other beneficial characteristics, though still preserving the specificity of the original nucleic acids. These new and improved second- and third-generation antisense molecules have shown promising results. The first antisense drug has been approved and more are in clinical trials. However, these antisense drugs are mainly designed for the treatment of different human cancers and other human diseases. Applying antisense gene silencing and exploiting RNA interference (RNAi) are highly developed approaches in many eukaryotic systems. But in bacteria RNAi is absent, and gene silencing by antisense compounds is not nearly as well developed, despite its great potential and the intriguing possibility of applying antisense molecules in the fight against multiresistant bacteria. Recent breakthrough and current status on the development of antisense gene silencing in bacteria including especially phosphorothioate oligonucleotides (PS-ODNs), peptide nucleic acids (PNAs) and phosphorodiamidate morpholino oligomers (PMOs) will be presented in this review.

Sequence-specific cleavage activities of DNA enzymes targeted against HIV-1 Gag and Nef regions

The genome of HIV-1 is known to accumulate nucleotide changes throughout the course of disease that result in generation of escape mutants. Therefore, any nucleic acid-based antiviral approach should be targeted against multiple regions of the HIV-1 genome that might significantly delay the appearance of such mutants. We designed several DNA enzymes against the most conserved p24 Gag and the Nef regions in the HIV-1 genome. Sequence-specific cleavage activity was observed for all the DNA enzymes tested. Gag DNA enzyme, which cleaved the target RNA more efficiently in the presence of low levels or physiologic levels of Mg(2+), interfered more effectively with HIV-1 gene expression in virus challenge experiments. The two Nef DNA enzymes, as observed with Gag DNA enzymes, showed significant variation in their cleavage activities in the presence of varying concentration of Mg(2+) and, as expected, did not interfere with the replication of a laboratory-adapted HIV-1 isolate under in vitro culture conditions. The Gag DNA enzymes could be exploited in combination with other promising antiviral approaches.

Antiproliferative activity of G-quartet-containing oligonucleotides generated by a novel single-stranded DNA expression system

Recently, a novel single-stranded DNA (ssDNA) expression system that can generate intracellularly ssDNA or oligodeoxynucleotide (ODN) molecules has been developed. Previous studies showed that this ssDNA expression system is capable of generating DNA enzyme ODNs and triplex-forming oligodeoxynucleotides (TFOs) in cells. In this study, we constructed an ssDNA expression vector that can generate a G-quartet-containing ODNs, GRO29A, in cells. Similar to synthetic ODNs, vector-generated GRO29As were shown to have significant antiproliferative activities in a number of cancer cell lines. These results further demonstrate the potential application of ssDNA expression system in gene target validation and drug development.

Inhibition of HIV-1 gene expression by novel DNA enzymes targeted to cleave HIV-1 TAR RNA: potential effectiveness against all HIV-1 isolates

Nucleic acid-based antiviral approaches have been tried against multiple HIV-1 genes with the purpose of down-regulating its replication. A unique stem-loop structure called TAR is present at the 5'-end of all HIV-1 transcripts; Tat and other cellular proteins bind to TAR and thus govern transcription. Therefore, HIV-1 TAR is an attractive target against which various antiviral approaches could be tried. We screened several DNA enzymes (Dz's) containing the 10-23 catalytic motif and a single Dz containing the 8-17 catalytic motif against the HIV-1 TAR RNA. Dz's directed against the predicted single-stranded bulge regions showed sequence-specific cleavage activities. One of the two Dz's, namely Dz-475, showed moderate cleavage activity in complete absence of Mg(2+). Addition of unrelated sequences at the 5'-end of the HIV-1 TAR RNA rendered it susceptible to four additional Dz-mediated cleavages. Both Dz's (470 and 475) showed significant intracellular reduction of HIV-1 gene expression. Dz-475-treated cells showed significant protection against T-tropic and macrophage-tropic HIV-1 challenge. Dz-475-transfected T-lymphocytes, human PBMCs, or chronically infected cell lines showed marked viral resistance. Unique features of this antiviral strategy with respect to HIV-1 gene inhibition are discussed.