Novel mono- and di-DNA-enzymes targeted to cleave TAT or TAT-REV RNA inhibit HIV-1 gene expression

Multivalent DNAzyme agents for cleaving folded RNA

Multivalent recognition and binding of biological molecules is a natural phenomenon that increases the binding stability (avidity) without decreasing the recognition specificity. In this study, we took advantage of this phenomenon to increase the efficiency and maintain high specificity of RNA cleavage by DNAzymes (Dz). We designed a series of DNA constructs containing two Dz agents, named here bivalent Dz devices (BDD). One BDD increased the cleavage efficiency of a folded RNA fragment up to 17-fold in comparison with the Dz of a conventional design. Such an increase was achieved due to both the improved RNA binding and the increased probability of RNA cleavage by the two catalytic cores. By moderating the degree of Dz agent association in BDD, we achieved excellent selectivity in differentiating single-base mismatched RNA, while maintaining relatively high cleavage rates. Furthermore, a trivalent Dz demonstrated an even greater efficiency than the BDD in cleaving folded RNA. The data suggests that the cooperative action of several RNA-cleaving units can significantly improve the efficiency and maintain high specificity of RNA cleavage, which is important for the development of Dz-based gene knockdown agents.

A promising nucleic acid therapy drug: DNAzymes and its delivery system

Based on the development of nucleic acid therapeutic drugs, DNAzymes obtained through in vitro selection technology in 1994 are gradually being sought. DNAzymes are single-stranded DNA molecules with catalytic function, which specifically cleave RNA under the action of metal ions. Various in vivo and in vitro models have recently demonstrated that DNAzymes can target related genes in cancer, cardiovascular disease, bacterial and viral infection, and central nervous system disease. Compared with other nucleic acid therapy drugs, DNAzymes have gained more attention due to their excellent cutting efficiency, high stability, and low cost. Here, We first briefly reviewed the development and characteristics of DNAzymes, then discussed disease-targeting inhibition model of DNAzymes, hoping to provide new insights and ways for disease treatment. Finally, DNAzymes were still subject to some restrictions in practical applications, including low cell uptake efficiency, nuclease degradation and interference from other biological matrices. We discussed the latest delivery strategy of DNAzymes, among which lipid nanoparticles have recently received widespread attention due to the successful delivery of the COVID-19 mRNA vaccine, which provides the possibility for the subsequent clinical application of DNAzymes. In addition, the future development of DNAzymes was prospected.

Blue-white screening as a new readout for deoxyribozyme activity in bacterial cells

Demonstration of 10–23 deoxyribozyme activity in viable E. coli using blue-white screening as the readout system.

DNA enzymes as potential therapeutics: towards clinical application of 10-23 DNAzymes

INTRODUCTION

Ongoing studies on the inhibition of gene expression at the mRNA level have identified several types of specific inhibitors such as antisense oligonucleotides, small interfering RNA, ribozymes and DNAzymes (Dz). After its discovery in 1997, the 10-23 Dz (which can cleave RNA efficiently and site-specifically, has flexible design, is independent from cell mechanisms, does not require expensive chemical modifications for effective use in vivo) has been employed to downregulate a range of therapeutically important genes. Recently, 10-23 Dzs have taken their first steps into clinical trials.

AREAS COVERED

This review focuses predominantly on Dz applications as potential antiviral, antibacterial, anti-cancer and anti-inflammatory agents as well as for the treatment of cardiovascular disease and diseases of CNS, summarizing results of their clinical trials up to the present day.

EXPERT OPINION

In comparison with antisense oligonucleotides and small interfering RNAs, Dzs do not usually show off-target effects due to their high specificity and lack of immunogenicity in vivo. As more results of clinical trials carried out so far are gradually becoming available, Dzs may turn out to be safe and well-tolerated therapeutics in humans. Therefore, there is a good chance that we may witness a deoxyribozyme drug reaching the clinic in the near future.

Inhibiting the HIV integration process: past, present, and the future

HIV integrase (IN) catalyzes the insertion into the genome of the infected human cell of viral DNA produced by the retrotranscription process. The discovery of raltegravir validated the existence of the IN, which is a new target in the field of anti-HIV drug research. The mechanism of catalysis of IN is depicted, and the characteristics of the inhibitors of the catalytic site of this viral enzyme are reported. The role played by the resistance is elucidated, as well as the possibility of bypassing this problem. New approaches to block the integration process are depicted as future perspectives, such as development of allosteric IN inhibitors, dual inhibitors targeting both IN and other enzymes, inhibitors of enzymes that activate IN, activators of IN activity, as well as a gene therapy approach.

Inhibition of HIV-1 Integrase gene expression by 10-23 DNAzyme

HIV Integrase (IN) is an enzyme that is responsible for the integration of the proviral genome into the human genome, and this integration step is the first step of the virus hijacking the human cell machinery for its propagation and replication. 10-23 DNAzyme has the potential to suppress gene expressions through sequence-specific mRNA cleavage. We have designed three novel DNAzymes, DIN54, DIN116, and DIN152, against HIV-1 Integrase gene using Mfold software and evaluated them for target site cleavage activity on the in vitro transcribed mRNA. All DNAzymes were tested for its inhibition of expression of HIV Integrase protein in the transiently transfected cell lines. DIN116 and DIN152 inhibited IN-EGFP expression by 80 percent and 70 percent respectively.

RNA-Cleaving DNA Enzymes and Their Potential Therapeutic Applications as Antibacterial and Antiviral Agents

DNA catalysts are synthetic single-stranded DNA molecules that have been identified by in vitro selection from random sequence DNA pools. The most prominent representatives of DNA catalysts (also known as DNA enzymes, deoxyribozymes, or DNAzymes) catalyze the site-specific cleavage of RNA substrates. Two distinct groups of RNA-cleaving DNA enzymes are the 10-23 and 8-17 enzymes. A typical RNA-cleaving DNA enzyme consists of a catalytic core and two short binding arms which form Watson–Crick base pairs with the RNA targets. RNA cleavage is usually achieved with the assistance of metal ions such as Mg²⁺, Ca²⁺, Mn²⁺, Pb²⁺, or Zn²⁺, but several chemically modified DNA enzymes can cleave RNA in the absence of divalent metal ions. A number of studies have shown the use of 10-23 DNA enzymes for modest downregulation of therapeutically relevant RNA targets in cultured cells and in whole mammals. Here we focus on mechanistic aspects of RNA-cleaving DNA enzymes and their potential to silence therapeutically appealing viral and bacterial gene targets. We also discuss delivery options and challenges involved in DNA enzyme-based therapeutic strategies.

Nucleic acid therapeutic carriers with on-demand triggered release

Biohybrid platforms such as synthetic polymer networks engineered from artificial and natural materials hold immense potential as drug and gene delivery vehicles. Here, we report the synthesis and characterization of novel polymer networks that release oligonucleotide sequences via enzymatic and physical triggers. Chemical monomers and acrylated oligonucleotides were copolymerized into networks, and phosphoimaging revealed that 70% of the oligonucleotides were incorporated into the networks. We observed that the immobilized oligonucleotides were readily cleaved when the networks were incubated with the type II restriction enzyme BamHI. The diffusion of the cleaved fragments through the macromolecular chains resulted in relatively constant release profiles very close to zero-order. To our knowledge, this is the first study which harnesses the sequence-specificity of restriction endonucleases as triggering agents for the cleavage and release of oligonucleotide sequences from a synthetic polymer network. The polymer networks exhibited an oligonucleotide diffusion coefficient of 5.6 x 10(-8) cm(2)/s and a diffusional exponent of 0.92. Sigmoidal temperature responsive characteristics of the networks matched the theoretical melting temperature of the oligonucleotides and indicated a cooperative melting transition of the oligonucleotides. The networks were also triggered to release a RNA-cleaving deoxyribozyme, which degraded a HIV-1 mRNA transcript in vitro. To tailor release profiles of the oligonucleotides, we controlled the structure of the macromolecular architecture of the networks by varying their cross-linking content. When incubated with DNase I, networks of cross-linking content 0.15%, 0.22%, and 0.45% exhibited oligonucleotide diffusion coefficients of 1.67 x 10(-8), 7.65 x 10(-9), and 2.7 x 10(-9) cm(2)/s, and diffusional exponents of 0.55, 0.8, and 0.8, respectively. The modular nature of our platform promises to open new avenues for the creation and optimization of a rich toolbox of novel drug and gene delivery platforms. We anticipate further inquiry into nucleic acid based programmable on-demand switches and modulatory devices of exquisite sensitivity and control.

Site-specific cleavage of HCV genomic RNA and its cloned core and NS5B genes by DNAzyme

BACKGROUND AND AIMS

The 9600 nt hepatitis C virus (HCV) genomic RNA has only one internal ribosome entry site (IRES) for translation to a single polyprotein. In search of nucleic acid-based antiviral agents, two 10-23 DNAzymes were designed to cleave the RNA in IRES and RNA dependent RNA polymerase (RDRP/NS5B) regions to prevent translation and replication of HCV RNA.

METHODS

In vitro cleavage of HCV RNA by IRES specific DNAzyme, CDz and NS5B specific DNAzyme, NDz was carried out using HCV genomic RNA and in vitro synthesized runoff transcripts of core and NS5B genes. Cleavage of core and NS5B mRNAs by DNAzyme (Dz) in HepG2 cells was assessed by reverse transcription polymerase chain reaction (RT-PCR) using RNA from cells co-transfected with cloned core or NS5B gene and its respective DNAzyme. Suppression of core or NS5B protein expression due to mRNA cleavage by Dz in co-transfected cells was determined by Western blot analysis and fluorescence intensity of fluorescent-tagged expressed protein. Reduction of NS5B protein activity in NDz co-transfected cells was determined by enzymatic assays.

RESULTS

The designed CDz and NDz cleaved HCV genomic RNA and their respective in vitro generated transcripts. Both mRNA and protein expressions of core or NS5B from their cloned genes reduced substantially when co-transfected with respective Dz. Reduction of RDRP expression by NDz was accompanied with its reduced enzyme activity. Increased RNA cleavage, inhibition of protein expression, and reduction of RDRP activity were observed on increasing Dz concentration.

CONCLUSION

Core and NS5B targeted DNAzymes can be used in controlling the replication of HCV RNA.

An efficient RNA-cleaving DNA enzyme can specifically target the 5'-untranslated region of severe acute respiratory syndrome associated coronavirus (SARS-CoV)

Background

The worldwide epidemic of severe acute respiratory syndrome (SARS) in 2003 was caused by a novel coronavirus called SARS‐CoV. We report the use of DNAzyme (catalytic DNA) to target the 5′‐untranslated region (5′UTR) of a highly conserved fragment in the SARS genome as an approach to suppression of SARS‐CoV replication. A mono‐DNA enzyme (Dz‐104) possessing the 10–23 catalytic motif was synthesized and tested both in vitro and in cell culture.

Materials and methods

SARS‐CoV total RNA was isolated, extracted from the SARS‐CoV‐WHU strain and converted into cDNA. We designed a RNA‐cleaving 10–23 DNAzyme targeting at the loop region of the 5′UTR of SARS‐CoV. The designed DNAzyme, Dz‐104, and its mutant version, Dz‐104 (mut), as a control consist of 9 + 9 arm sequences with a 10–23 catalytic core. In vitro cleavage was performed using an in vitro transcribed 5′UTR RNA substrate. A vector containing a fused 5′UTR and enhanced green fluorescent protein (eGFP) was co‐transfected with the DNAzyme into E6 cells and the cells expressing eGFP were visualized with fluorescence microscopy and analyzed by fluorescence‐activated cell sorting (FACS).

Results and conclusions

Our results demonstrated that this DNAzyme could efficiently cleave the SARS‐CoV RNA substrate in vitro and inhibit the expression of the SARS‐CoV 5′UTR‐eGFP fusion RNA in mammalian cells. This work presents a model system to rapidly screen effective DNAzymes targeting SARS and provides a basis for potential therapeutic use of DNA enzymes to combat the SARS infection. Copyright © 2007 John Wiley & Sons, Ltd.

Brothers in arms: DNA enzymes, short interfering RNA, and the emerging wave of small-molecule nucleic acid-based gene-silencing strategies

The past decade has seen the rapid evolution of small-molecule gene-silencing strategies, driven largely by enhanced understanding of gene function in the pathogenesis of disease. Over this time, many genes have been targeted by specifically engineered agents from different classes of nucleic acid-based drugs in experimental models of disease to probe, dissect, and characterize further the complex processes that underpin molecular signaling. Arising from this, a number of molecules have been examined in the setting of clinical trials, and several have recently made the successful transition from the bench to the clinic, heralding an exciting era of gene-specific treatments. This is particularly important because clear inadequacies in present therapies account for significant morbidity, mortality, and cost. The broad umbrella of gene-silencing therapeutics encompasses a range of agents that include DNA enzymes, short interfering RNA, antisense oligonucleotides, decoys, ribozymes, and aptamers. This review tracks current movements in these technologies, focusing mainly on DNA enzymes and short interfering RNA, because these are poised to play an integral role in antigene therapies in the future.

Potent knock down of HIV-1 replication by targeting HIV-1 Tat/Rev RNA sequences synergistically with catalytic RNA and DNA

OBJECTIVE

Ribozymes (Rzs) and DNA-enzymes (Dzs) possess the ability to prevent gene expression by cleaving target RNA in a catalytic and sequence-specific manner. Although Rzs or Dzs have been used earlier for HIV-1 gene suppression, the present study explored the possibility of using catalytic RNA and DNA simultaneously in a synergistic manner with the hope that this novel approach will allow more potent inhibition for a longer duration.

METHODS

In order to achieve long-term inhibition of HIV-1 replication, a novel non-GUX hammerhead Rz was designed by standard recombinant DNA technology and cloned it under the powerful CMV promoter containing expression vector. A 10-23 catalytic motif containing Dz that was targeted against the conserved second exon of HIV-1 Tat/Rev region was also assembled.

RESULTS

Both Rz and Dz possessed sequence-specific cleavage activities individually and simultaneously cleaved target RNA in a synergistic manner under the same in vitro cleavage conditions. These catalytic molecules inhibited HIV-1 replication in macrophages individually and exhibited potent inhibitory effects when used in combination.

CONCLUSIONS

The combination strategy described here can be widely used against any target RNA to achieve more effective gene inhibition that exploits the simultaneous sequence-specific cleavage potentials of catalytic RNA and DNA.

Inhibition of hepatitis B virus X gene expression by 10-23 DNAzymes

The X protein (HBx) of human hepatitis B virus (HBV) is a transcriptional activator protein. The HBx protein plays an important role in viral replication in HBV infected cells and the liver diseases including hepatitis, cirrhosis and hepatocellular carcinoma (HCC). Therefore, the repression of HBx gene expression by 10-23 DNAzymes might be a good way to inhibit HBV replication and counteract HBV-related liver diseases. We designed three 10-23 DNAzymes with different substrate-recognition domains. When each of the 10-23 DNAzymes were cotransfected into human AD293 cells with HBx-EGFP expression plasmid, they could all reduce the level of HBx mRNA as well as the HBx-EGFP protein. These results suggest that the 10-23 DNAzymes might be used for gene therapy of liver diseases caused by HBV.

In vitro selection, characterization, and application of deoxyribozymes that cleave RNA

Over the last decade, many catalytically active DNA molecules (deoxyribozymes; DNA enzymes) have been identified by in vitro selection from random-sequence DNA pools. This article focuses on deoxyribozymes that cleave RNA substrates. The first DNA enzyme was reported in 1994 and cleaves an RNA linkage. Since that time, many other RNA-cleaving deoxyribozymes have been identified. Most but not all of these deoxyribozymes require a divalent metal ion cofactor such as Mg²⁺ to catalyze attack by a specific RNA 2′-hydroxyl group on the adjacent phosphodiester linkage, forming a 2′,3′-cyclic phosphate and a 5′-hydroxyl group. Several deoxyribozymes that cleave RNA have utility for in vitro RNA biochemistry. Some DNA enzymes have been applied in vivo to degrade mRNAs, and others have been engineered into sensors. The practical impact of RNA-cleaving deoxyribozymes should continue to increase as additional applications are developed.

DNAzymes as molecular agents that manipulate Egr-1 gene expression

In recent years, the arsenal of small-molecule synthetic nucleic acids as gene-specific "knock-down" agents has increased in scope and variety. The investigator has the choice of antisense oligonucleotides, ribozymes, siRNA and DNAzymes, each subclass further benefiting from modifications that increase stability and efficiency and decrease toxicity. This review describes our use of DNAzymes in efforts to define the roles of key transcription factor targets, first in cultured vascular cells, then in animal models of neovascularization and arterial thickening.

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.

Identification of cleavage sites in the HIV-1 TAR RNA by 10-23 and 8-17 catalytic motif containing DNA enzymes

A quick identification of a cleavage site in the target RNA molecule to obtain sequence-specific cleavage by either catalytic RNA (ribozymes) or DNA (DNA enzymes) is very important for achieving gene-specific suppression. These molecules could also provide important information on the secondary and tertiary structure of the target RNA molecule. We have exploited the use of two kinds of DNA enzymes, namely, the 10-23 and 8-17 catalytic motif containing DNA enzymes, to achieve these objectives. We identified several DNA enzyme cleavage sites in the human immunodeficiency virus type 1 (HIV-1) transactivation response element (TAR) RNA-a structural feature present at the 5' end of all HIV-1 transcripts. Most of the DNA enzymes that cleaved the TAR RNA were targeted to the regions that were single-stranded in the predicted structure. Regions that were predicted to be base-paired (stem) failed to show any detectable cleavage. The DNA enzyme possessing the 8-17 catalytic motif was extremely efficient in cleaving full length, as well as short, HIV-1 specific transcripts. The efficiency of cleavage of the same target RNA by DNA enzymes that possessed the 10-23 catalytic motif was significantly less in comparison, and they failed to cleave the short transcripts. These molecules, in principle, have the potential to down regulate expression of all HIV-1 transcripts from a wide range of isolates because this region is functionally very well conserved.

Comparison of colorimetric, fluorometric, and visual methods for determining anti-influenza (H1N1 and H3N2) virus activities and toxicities of compounds

Methods have been developed previously for rapid evaluation of compounds for antiviral activity in 96-well microplates, which include visual quantitation of antiviral activity based upon inhibition of virus-induced cytopathic effect (CPE) or by less subjective colorimetric or fluorometric means. In the present studies we compared a number of colorimetric (crystal violet, MTT [3-[4,5-dimethylthiazol-2-yl]-2,5-diphenyltetrazolium bromide], and neutral red) and fluorometric (Alamar Blue, bisbenzimide [Hoechst 33258], fluorescein diacetate, and rhodamine 6G) methods to visual scoring of antiviral activity in influenza A virus infections in Madin Darby canine kidney (MDCK) cells. Toxicity determinations using these same methods were also made for anti-influenza inhibitors and other compounds known to inhibit cell proliferation. Against influenza A/Texas/36/91 (H1N1) and A/Sydney/05/97 (H3N2) viruses, visual scoring and dye or stain methods produced results that were not significantly different from each other in deriving 50% virus-inhibitory concentrations (EC(50) values) for six anti-influenza compounds (amantadine, rimantadine, ribavirin, RWJ-270201 [BCX-1812], oseltamivir carboxylate, and zanamivir), with the exception of Alamar Blue which quantified lower EC(50) values than expected. In uninfected replicating cells, the visual and Alamar Blue methods underestimated the 50% cytotoxic concentrations (IC(50) values) of ribavirin, 1-beta-D-arabinofuranosylcytosine, and 6-azauridine, but more accurately assessed the toxicities of amantadine, rimantadine, and cycloheximide. Visual scoring, coupled with the use of one of these dyes or stains except Alamar Blue, can be used to accurately and rapidly quantify the anti-influenza virus activities and toxicities of potential new influenza virus inhibitors. These methods should also be applicable to evaluating antiviral effects against other lytic virus infections.