Characterization of nuclease-resistant ribozymes directed against hepatitis B virus RNA

Effects of IFN monotherapy versus combined therapy on HBeAg seroconversion or seroclearance in HBeAg-positive chronic hepatitis B patients: A meta-analysis

BACKGROUND AND AIMS

Recent available treatment guidelines are pointing up clearance or seroconversion of hepatitis B e-antigen (HBeAg) as a valuable endpoint in treating HBeAg-positive chronic hepatitis B (CHB) patients. To evaluate the effect of combination therapy [interferon (IFN) plus nucleos(t)ide analogues (NAs)] versus IFN monotherapy on HBeAg seroconversion or seroclearance in HBeAg-positive CHB patients.

METHODS

All available controlled clinical studies, published from Jan 2000 to Sep 2018, with CHB receiving IFN and NA combination therapy or IFN monotherapy were included. Risk ratio (RR) and their 95% confidence intervals (CIs) was estimated with a fixed-effects model when I² <50% for the test for heterogeneity. Publication bias was measured using Egger's test.

RESULTS

Twelve studies were included. Our meta-analysis demonstrated that IFN and NA combination therapy had a superior HBeAg seroconversion rate or clearance rate compared with IFN monotherapy at the end of treatment (EOT). Sub-analysis showed IFN plus adefovir dipivoxi (ADV) therapy had a better HBeAg seroconversion or seroclearance rate at EOT or at the end of follow-up (EOF).

CONCLUSION

Compared with IFN monotherapy, the combined therapy had a higher e-antigen serological response at EOT, but failed to improve the sustained response at EOF. Only combination therapy with IFN and ADV is superior to IFN monotherapy at the EOT or EOF for HBeAg seroconversion or seroclearance in HBeAg-positive CHB patients. The effect of other combination therapies is not superior to IFN monotherapy.

Therapeutic Potential of Ribozymes

Recent advances in RNA engineering during the last two decades have supported the development of RNA-based therapeutics targeting a variety of human diseases. The broad scope of these emerging drugs clearly demonstrates the versatility of RNA. Ribozymes have been seen as promising candidates in this area. However, efficient intracellular application of ribozymes remains challenging, and other strategies appear to have outperformed ribozymes as molecular drugs. Nevertheless, trans-cleaving ribozymes have been applied for specific cleavage of target mRNAs in order to inhibit undesired gene expression. Furthermore, ribozymes have been engineered to allow site-directed RNA sequence alterations, enabling the correction of genetic misinformation at the RNA level. This chapter provides an overview of ribozyme-based strategies, highlighting the promises and pitfalls for potential therapeutic applications.

Drug Delivery Strategies for Antivirals against Hepatitis B Virus

Chronic hepatitis B virus (HBV) infection poses a significant health challenge due to associated morbidity and mortality from cirrhosis and hepatocellular cancer that eventually results in the breakdown of liver functionality. Nanotechnology has the potential to play a pivotal role in reducing viral load levels and drug-resistant HBV through drug targeting, thus reducing the rate of evolution of the disease. Apart from tissue targeting, intracellular delivery of a wide range of drugs is necessary to exert a therapeutic action in the affected organelles. This review encompasses the strategies and techniques that have been utilized to target the HBV-infected nuclei in liver hepatocytes, with a significant look at the new insights and most recent advances in drug carriers and their role in anti-HBV therapy.

Progress and Prospects of Anti-HBV Gene Therapy Development

Despite the availability of an effective vaccine against hepatitis B virus (HBV), chronic infection with the virus remains a major global health concern. Current drugs against HBV infection are limited by emergence of resistance and rarely achieve complete viral clearance. This has prompted vigorous research on developing better drugs against chronic HBV infection. Advances in understanding the life cycle of HBV and improvements in gene-disabling technologies have been impressive. This has led to development of better HBV infection models and discovery of new drug candidates. Ideally, a regimen against chronic HBV infection should completely eliminate all viral replicative intermediates, especially covalently closed circular DNA (cccDNA). For the past few decades, nucleic acid-based therapy has emerged as an attractive alternative that may result in complete clearance of HBV in infected patients. Several genetic anti-HBV strategies have been developed. The most studied approaches include the use of antisense oligonucleotides, ribozymes, RNA interference effectors and gene editing tools. This review will summarize recent developments and progress made in the use of gene therapy against HBV.

Efficient knockdown of human prnp mRNA expression levels using hybrid hammerhead ribozymes

Prion diseases are invariably fatal infectious diseases of the central nervous system. The prion protein has been identified as the underlying causative agent as PrP knockout mice (prnp(0/0)) are resistant to infection. This suggests that a significant reduction in the expression levels of PrP(c) should interrupt disease progression. Accomplishing this in vivo, upon presentation of symptoms, requires a mechanism that significantly reduces prnp mRNA levels while lacking potential side effects that may be cytotoxic or lethal to the host. Hybrid hammerhead ribozymes (HyHamRzs) include both a helicase recruitment signal and a tRNA(Val) promoter. HyHamRzs offer a means of highly specific and significant mRNA cleavage. In this study, data demonstrate increased activity granted to HamRzs by the addition of the helicase recruitment signal. Results show that three different HyHamRzs, targeting different locations along the full length prnp mRNA, reduced expression levels by greater than 95% relative to the control. It is postulated that HyHamRzs, modified to enhance serum stability and delivered intravenously to neurons by forming a complex with the modified rabies virus G protein (RVG), may offer a potential gene therapy strategy.

Efficacy of cationic lipid-DNA complexes (CLDC) on hepatitis B virus in transgenic mice

Cationic lipid-DNA (non-coding) complexes (CLDC) are activators of the innate immune response that increase survival of rodents with some acute viral infections and cancers. CLDC were evaluated for their ability to impact viral DNA levels in transgenic mice carrying an infectious clone of hepatitis B virus (HBV). Mice used in the studies were diet-restricted as nursing pups from solid food, because the expression of HBV DNA in the liver was increased above background levels in some mice with this restriction. Survival surgery was performed on these mice to obtain liver biopsies from which to select animals with suitable levels of liver HBV DNA for entry into the experimental protocols. Intravenous administration of 5 microg/mouse of CLDC on days 1, 7 and 13 reduced liver HBV DNA to similar low levels achieved with the positive control, adefovir dipivoxil. In a subsequent experiment, the same treatment schedule was used to determine that the minimal effective CLDC dose was between 0.5 and 0.05 microg/mouse. Selective cytokines were increased in the livers of CLDC-treated compared to placebo-treated mice in a dose-responsive manner. CLDC were effective in reducing liver HBV DNA and could be considered for further evaluation in other hepatitis models.

Future therapy for hepatitis B

Therapy for hepatitis B virus (HBV) infection, the most common worldwide cause of viremia and chronic liver disease, is currently limited to interferon preparations and nucleoside or nucleotide analogs. Although these treatments result in suppression of HBV replication, virologic rebounds are common when treatment is ended or when viral resistance emerges. This review considers novel approaches targeting viral or host factors involved in the HBV lifecycle, as well as immunomodulatory strategies that are likely to be used concomitantly with antiviral drugs in future research.

Gene therapy for viral hepatitis

Hepatitis B and C infections are two of the most prevalent viral diseases in the world. Existing therapies against chronic viral hepatitis are far from satisfactory due to low response rates, undesirable side effects and selection of resistant viral strains. Therefore, new therapeutic approaches are urgently needed. This review, after briefly summarising the in vitro and in vivo systems for the study of both diseases and the genetic vehicles commonly used for liver gene transfer, examines the existing status of gene therapy-based antiviral strategies that have been employed to prevent, eliminate or reduce viral infection. In particular, the authors focus on the results obtained in clinical trials and experimental clinically relevant animal models.

New targets and inhibitors of HBV replication to combat drug resistance

All the approved chemotherapeutic drugs for the treatment of HBV hepatitis are nucleoside analogs targeting on HBV DNA polymerase. Drugs targeting on other viral unique targets are needed. A new class of chemicals with novel action against HBV replication was discovered. A brief description of their mode of action is given.

Inhibition of hepatitis B virus gene expression and replication by helioxanthin and its derivative

Chronic hepatitis B virus (HBV) infection continues to be an important worldwide cause of morbidity and mortality. All the currently approved therapeutic drugs have their limitations: interferon-alpha (IFN-alpha) has limited efficacy and a high incidence of adverse effects; nucleoside analogues are very efficient HBV DNA inhibitors, but resistance occurs eventually. Therefore, it is important to develop new non-nucleoside/nucleotide agents with different modes of action that can be used for antiviral combination therapy. Here, we report on a novel class of compounds, helioxanthin and its derivative 5-4-2, which had potent anti-HBV activities in HepG2.2.15 cells, with the EC50s of 1 and 0.08 microM, respectively. The lamivudine-resistant HBV, L526M/M550V double mutant strain, was also sensitive to helioxanthin and 5-4-2. This class of compounds not only inhibited HBV DNA, but also decreased HBV mRNA and HBV protein expression. The EC50 of HBV DNA inhibition was consistent with the EC50 of HBV 3.5 Kb transcript inhibition, which was 1 and 0.09 microM for helioxanthin and 5-4-2 respectively. Western blot analysis of cell lysate from HepG2.2.15 cells showed that the core protein expression decreased in a dose-dependent manner after drug treatment. In conclusion, helioxanthin and 5-4-2 are potentially unique new anti-HBV agents, which possess a different mechanism of action from existing therapeutic drugs. Both compounds inhibited HBV RNA and protein expression in addition to inhibiting HBV DNA.

Advances in the development of therapeutic nucleic acids against cervical cancer

Cervical cancer is the second most common neoplastic disease affecting women worldwide. Basic, clinical and epidemiological analyses indicate that expression of high-risk human papillomaviruses (HPVs) E6/E7 genes is the primary cause of cervical cancer and represent ideal targets for the application of therapeutic nucleic acids (TNAs). Antisense oligodeoxyribonucleotides (AS-ODNs) and ribozymes (RZs) are the most effective TNAs able to inhibit in vivo tumour growth by eliminating HPV-16 and HPV-18 E6/E7 transcripts. Expression of multiple RZs directed against alternative target sites by triplex expression systems may result in the abrogation of highly variable HPVs. More recently, RNA interference (RNAi) gene knockdown phenomenon, induced by small interfering RNA (siRNA), has demonstrated its potential value as an effective TNA for cervical cancer. siRNA and aptamers as TNAs will have a place in the armament for cervical cancer. TNAs against cervical cancer is in a dynamic state, and clinical trials will define the TNAs in preventive and therapeutic roles to control tumour growth, debulk tumour mass, prevent metastasis and facilitate immune interaction.

Effective inhibition of expression of hepatitis B virus genes by DNAzymes

AIM: To evaluate the inhibitory effects of DNAzymes on the expressions of hepatitis B virus (HBV) s (HBsAg) and e (HBeAg) in 2.2.15 cells, and to explore the potential therapeutic effects of DNAzymes on replication of HBV genome.

METHODS: DNAzymes DrzBS and DrzBC specific to HBV (ayw subtype) s gene ORF A¹⁵⁷UG and e gene ORF A¹⁸¹⁶UG, were designed and synthesized. Inhibitory effects of DrzBS or DrzBC on the expressions of HBV s and e genes as well as HBV DNA levels in culture supernatants were observed in 2.2.15 cells.

RESULTS: After being treated with DrzBS or DrzBC, the expression of HBV s or e genes in 2.2.15 cells was depressed dramatically. The maximum inhibition rate was 94.2% and 91.8% for DrzBS and DrzBC, respectively. The concentration for effective inhibition of both DrzBS and DrzBC was within 0.1-2.5 µmol/L, showing a dose-dependence. The efficiency of inhibiting HBsAg, HBeAg in 2.2.15 cells by DrzBS or DrzBC was higher than that of the same target genes by antisense oligonucleotides (ASON). The concentration for effective inhibition of DNAzymes was at least 10-fold lower compared with ASON controls. Neither inhibition on the replication of HBV DNA nor toxicity to 2.2.15 cells was observed.

CONCLUSION: DrzBS and DrzBC can block the expression of HBV s- and e-genes in 2.2.15 cells and provide a specific and effective anti-HBV gene therapeutic means.

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Lethiferous effects of a recombinant vector carrying thymidine kinase suicide gene on 2.2.15 cells via a self-modulating mechanism

AIM: To determine the lethiferous effects of a recombinant vector carrying thymidine kinase (TK) suicide gene on 2.2.15 cells and the possible self-modulating mechanism.

METHODS: A self-modulated expressive plasmid pcDNA3-SCITK was constructed by inserting the fragments carrying hepatitis B virus antisense-S (HBV-anti-S) gene, hepatitis C virus core (HCV-C) gene, internal ribosome entry site (IRES) element of HCV and TK gene into the eukaryotic vector pcDNA3, in which the expression of TK suicide gene was controlled by the HBV S gene transcription. 2.2.15 cells that carry the full HBV genome and stably express series of HBV antigen were transfected with pcDNA₃-SCITK or vector pcDNA₃-SCI which was used as the mock plasmid. The HepG2 cells transfected with pcDNA₃-SCITK were functioned as the negative control. All the transfected cells were incubated in DMEM medium supplemented with 10 μg/mL. of ganciclovir (GCV). The HBsAg levels in the supernatant of cell culture were detected by ELISA on the 1^st, 3^rd and 6^th day post-transfection. Meanwhile, the morphology of tranfected cells was recorded by the photograph and the survival cell ratio was assessed by the trypan blue exclusion test on the 6^th day post-transfection.

RESULTS: The structural accuracy of pcDNA₃-SCITK was confirmed by restriction endonuclease digestion, PCR with specific primers and DNA sequencing. The HBsAg levels in the supernatant of transfected 2.2.15 cell culture were significantly decreased on the 6^th day post-transfection as compared with that of the mock control (P < 0.05). The lethiferous effect of pcDNA₃-SCITK expression on 2.2.15 cells was initially noted on the 3^rd day after transfection and aggravated on the 6^th day post transfection, in which the majority of transfected 2.2.15 cells were observed shrunken, round in shape and even dead. With assessment by the trypan blue exclusion test, the survival cell ratio on the 6^th day post transfection was 95% in the negative control and only 11% in the experimental group.

CONCLUSION: The results indicate that suicide gene expression of pcDNA₃-SCITK can only respond to HBV-S gene transcription, which may be potentially useful in the treatment of HBV infection and its related liver malignancies.

Applications of gene therapy to kidney disease

PURPOSE OF REVIEW

This review summarizes recent applications of somatic cell gene therapy to the treatment of monogenetic renal diseases, renal cell carcinoma, and for the induction of tolerance in solid organ transplantation. In addition, several new gene therapy techniques will be discussed including gene and messenger RNA repair strategies, as well as methods designed to modify the expression of normal genes that may have application in the treatment of multigenetic disorders.

RECENT FINDINGS

Animal studies have demonstrated prolonged graft survival after the successful induction of tolerance to alloantigens via hematopoietic molecular chimerism. Ongoing clinical trials for renal cell carcinoma are encouraging, in that IL-2 gene therapy using non-viral vector systems can reduce the tumor burden. However, limited progress has been made towards applying gene therapy for the most common genetic disorders of the kidney, autosomal dominant polycystic kidney disease and Alport syndrome. Basic research on novel gene repair and expression modulation techniques provide additional gene therapy options for the treatment of viral infections such as HIV-1 and monogenetic disorders.

SUMMARY

Gene therapy holds enormous potential for the treatment of genetic and acquired diseases. Current pre-clinical studies and clinical trials provide encouraging results that gene therapy can become a useful treatment option. However, before gene therapy has widespread application, technical progress must be made in all aspects of treatment design, including optimizing vector and delivery systems and the ability to modify long-term cell populations such as stem cells.

Advances in the Development of Ribozymes and Antisense Oligodeoxynucleotides as Antiviral Agents for Human Papillomaviruses

Urogenital human papillomavirus (HPV) infections are the most common viral sexually transmitted disease in women. On a worldwide basis cervical cancer is the second most prevalent cancer of women. Although HPV infection is not sufficient to induce cancer, the causal relation between high-risk HPV infection and cervical cancer is well established. Over 99% of cervical cancers are positive for high-risk HPV. Therefore, there is a need for newer approaches to treat HPV infection. Two novel approaches for inactivating gene expression involve ribozymes and oligonucleotides. Methods for identification of target genes involved in neoplastic transformation and tumour growth have been established, and these will lead to therapeutic approaches without any damage to normal cellular RNA molecules, which is often associated with conventional therapeutics. Ribozymes and oligonucleotides represent rational antiviral approaches for inhibiting the growth of cervical lesions and carcinomas by interfering with E6/E7 RNA production. The E6 and E7 genes of high-risk HPVs cooperate to immortalize primary epithelial cells and because they are found in cervical cancer are considered the hallmark of cervical cancer. The use and modification of ribozymes and antisense oligodeoxynucleotides can inhibit the growth of HPV-16 and HPV-18 immortalized cells, and tumour cells by eliminating E6/E7 transcript. Hammerhead and hairpin ribozymes have been widely studied because of their potential use for gene therapy and their place as therapeutic tools for cervical cancer is being evaluated. Although antiviral ribozymes and anti-sense molecules have been effective as in vitro or in vivo inhibitors of high-risk HPV-positive cells, none is currently in clinical trial. There are, however, a number of other antisense therapies in Phase I–III clinical trial for several oncogenes.