Long-term RNase P-mediated inhibition of HIV-1 replication and pathogenesis

Advances in genetic analysis and a greater understanding of human immunodeficiency virus (HIV) molecular pathogenesis have identified critical viral targets for gene interference strategies. RNase P molecules have been proposed as a novel approach for gene targeting based upon their potent catalytic activity, as well as versatile external guide sequence (EGS) which can be modified to specifically recognize almost any target mRNA. We designed a truncated EGS to specifically recognize the highly conserved U5 region of HIV-1 mRNA and mediate subsequent cleavage of hybridized mRNA by the RNase P enzyme component. The active U5-EGS (560), as well as a disabled U5 EGS (560D) control, were cloned into plasmids containing proviral constructs and transfected into a CD4(+) T cell line that was thereafter infected with HIV-1 MN. CD4(+) T cells treated with the active U5 EGS (560) were observed to maintain CD4(+) expression and did not produce HIV p24 gag antigen, form syncytia or undergo apoptosis up to 30 days after infection. Identical cells expressing the inactivated form of the U5 RNase P EGS completely down-regulated CD4 expression, produced elevated levels of HIV-1, formed large syncytia and underwent apoptosis similar to untreated cells. HIV-1 replication and related cytopathology can be effectively inhibited in CD4(+) T cells expressing a protective U5 EGS (560).     

Short-term Correction of Arginase Deficiency in a Neonatal Murine Model With a Helper-dependent Adenoviral Vector

Neonatal gene therapy has the potential to ameliorate abnormalities before disease onset. Our gene knockout of arginase I (AI) deficiency is characterized by increasing hyperammonemia, neurological deterioration, and early death. We constructed a helper-dependent adenoviral vector (HDV) carrying AI and examined for correction of this defect. Neonates were administered 5 × 10⁹ viral particles/g and analyzed for survival, arginase activity, and ammonia and amino acids levels. The life expectancy of arg^−/− mice increased to 27 days while controls died at 14 days with hyperammonemia and in extremis. Death correlated with a decrease in viral DNA/RNA per cell as liver mass increased. Arginase assays demonstrated that vector-injected hepatocytes had ~20% activity of heterozygotes at 2 weeks of age. Hepatic arginine and ornithine in treated mice were similar to those of saline-injected heterozygotes at 2 weeks, whereas ammonia was normal. By 26 days, arginase activity in the treated arg^−/− livers declined to <10%, and arginine and ornithine increased. Ammonia levels began increasing by day 25, suggesting the cause of death to be similar to that of uninjected arg^−/− mice, albeit at a later time. These studies demonstrate that the AI deficient newborn mouse can be temporarily corrected and rescued using a HDV.     

Zinc-finger Nucleases as a Novel Therapeutic Strategy for Targeting Hepatitis B Virus DNAs

Hepatitis B virus (HBV) chronically infects 350–400 million people worldwide and causes >1 million deaths yearly. Current therapies prevent new viral genome formation, but do not target pre-existing viral genomic DNA, thus curing only ~1/2 of patients. We targeted HBV DNA for cleavage using zinc-finger nucleases (ZFNs), which cleave as dimers. Co-transfection of our ZFN pair with a target plasmid containing the HBV genome resulted in specific cleavage. After 3 days in culture, 26% of the target remained linear, whereas ~10% was cleaved and misjoined tail-to-tail. Notably, ZFN treatment decreased levels of the hepatitis C virus pregenomic RNA by 29%. A portion of cleaved plasmids are repaired in cells, often with deletions and insertions. To track misrepair, we introduced an XbaI restriction site in the spacer between the ZFN sites. Targeted cleavage and misrepair destroys the XbaI site. After 3 days in culture, ~6% of plasmids were XbaI-resistant. Thirteen of 16 clones sequenced contained frameshift mutations that would lead to truncations of the viral core protein. These results demonstrate, for the first time, the possibility of targeting episomal viral DNA genomes using ZFNs.     

PiggyBac Transposon-based Inducible Gene Expression In Vivo After Somatic Cell Gene Transfer

Somatic cell gene transfer has permitted inducible gene expression in vivo through coinfection of multiple viruses. We hypothesized that the highly efficient plasmid-based piggyBac transposon system would enable long-term inducible gene expression in mice in vivo. We used a multiple-transposon delivery strategy to create a tetracycline-inducible expression system in vitro in human cells by delivering the two genes on separate transposons for inducible reporter gene expression along with a separate selectable transposon marker. Evaluation of stable cell lines revealed 100% of selected clones exhibited inducible expression via stable expression from three separate transposons simultaneously. We next tested and found that piggyBac-mediated gene transfer to liver or lung could achieve stable reporter gene expression in mice in vivo in either immunocompetent or immune deficient animals. A single injection of piggyBac transposons could achieve long-term inducible gene expression in the livers of mice in vivo, confirming our multiple-transposon strategy used in cultured cells. The plasmid-based piggyBac transposon system enables constitutive or inducible gene expression in vivo for potential therapeutic and biological applications without using viral vectors.     

靶向C区基因的M1GS RNA核酶胞内抗乙型肝炎病毒的实验研究

目的探讨靶向作用于乙型肝炎病毒C区基因的M1GS RNA核酶胞内抗乙型肝炎病毒的作用。方法设计并应用PCR技术合成M1RNA核酶，应用pEGFP-C1载体构建M1GSRNA核酶的真核表达质粒，应用脂质体Lipofectamine TM 2000转染HepG2．2．15细胞，以ELISA法检测细胞培养液中病毒抗原，以反转录-聚合酶链反应法（RT-PCR）检测细胞内病毒mRNA，以荧光定量PCR法检测分泌入培养液的HBVDNA含量，用MTT法检测核酶对细胞增殖活性的影响。结果质粒载体表达的M1GS RNA核酶能明显抑制细胞培养液中HBeAg的表达及病毒mRNA的表达，抑制率分别为31．58％，32．5％。但M1GS RNA核酶对培养液中的HBV DNA含量无明显影响，亦不影响HepG2．2．15细胞的增殖活性。结论M1GS RNA核酶能特异性抑制HepG2．2．15细胞内HBV C区基因表达，是一种很有潜力的抗HBV基因治疗方法。     

Preclinical Safety Validation of a Stabilized Viral Vector Direct Injection Approach to the Cervical Spinal Cord

The current lack of a validated intraspinal delivery approach precludes translation of promising cell or viral‐based therapeutics for treatment of varied spinal cord afflictions. We have developed a stabilized cervical microinjection platform with the intent of precise delivery to intraspinal sites of interest. Nine 30–40 kg female swine underwent coordinate‐based microinjection AAV2‐GFP at three injected volumes (10, 25, and 50 μL (n= 3/group)) and matched infusion rates (1.0, 2.5, and 5.0 μL/min) over a period (t= 10 minutes). Preliminary validation is provided by behavioral and targeting data demonstrating safe delivery of a viral vector carrying a fluorescent reporter gene to the cervical spinal cord ventral horn.     

靶向X区的siRNA抑制乙型肝炎病毒基因的表达和复制

目的构建针对乙型肝炎病毒（HBV）X基因的siRNA表达载体，观察其对HBV基因表达和复制的影响。方法设计并合成针对HBVX区基因的siRNA寡核苷酸，经退火形成双链后克隆人pSUPER载体，构建成功的siRNA表达载体与pTK-Hyg质粒共转染稳定表达HBV的HepG22．2．15细胞，潮霉素抗性筛选获得稳定细胞克隆，对所得细胞培养上清液中的HBsAg和HBeAg进行定量检测，逆转录-聚合酶链反应（RT-PCR）检测靶基因mRNA的抑制效果，荧光定量PCR检测HBVDNA。结果成功构建了针对HBVX基因的siRNA表达载体pSUPER-X1和pSUPER-X2，两种siRNA均能明显抑制HepG22．2．15细胞的HBsAg和HBeAg分泌，抑制率分别为97％和88％，RT-PCR结果显示HBV的mRNA表达降低，荧光定量PCR结果证实siRNA能降低HBVDNA拷贝数2个数量级。结论载体产生的针对HBVX基因的siRNA能高效、特异地抑制HBV基因的表达和复制。     

Hepatitis B virus S gene therapy with 10-23 DNAzyme delivered by chitosan-g-stearic acid micelles

DNAzymes have the potential to suppress gene expression through sequence-specific mRNA cleavage and can therefore play an important role in various gene therapies. Hepatitis B virus (HBV) is still one of the most serious liver infections in people around the world and is difficult to treat. We previously designed a 10-23 DNAzyme called DrzBS, which targets HBV S gene expression, but this enzyme depends on exogenous delivery, and so its application has been limited. To overcome this limitation, we have now developed a chitosan-based nanocarrier (chitosan-g-stearic acid, CSO–SA) for intracellular delivery of DrzBS, then compared the inhibition effect of our CSO–SA/DrzBS complex to a common transfection reagent, Lipofectamine™ 2000/DrzBS, on hepatitis B surface antigen expression. The synthesized CSO–SA assembles into micelles in an aqueous solution and exhibits excellent cytoplasmic targeting, and could protect DrzBS from degradation by ribonuclease. CSO–SA/DrzBS showed a higher inhibition rate (IR) than Lipofectamine™ 2000/DrzBS. Moreover, at the same DrzBS concentration (1.2 μmol L⁻¹), the maximum IR of CSO–SA/DrzBS micelles was 2.4-fold that of the Lipofectamine™ 2000/DrzBS complex, and held on for 96 hours. Compared with Lipofectamine™ 2000/DrzBS, CSO–SA/DrzBS achieved a higher HBV inhibition effect. This study demonstrates that CSO–SA micelles can serve as a potential vector for DrzBS and that CSO–SA/DrzBS micelles are a promising application for anti-HBV gene therapy.

DrzBS, which targets HBV S gene expression, has important research significance and potential application value. CSO-SA is a safe and efficient non-viral gene carrier and CSO-SA/DrzBS micelles are a promising application for anti-HBV gene therapy.     

Hybrid Nonviral/Viral Vector Systems for Improved piggyBac DNA Transposon In Vivo Delivery

The DNA transposon piggyBac is a potential therapeutic agent for multiple genetic diseases such as cystic fibrosis (CF). Recombinant piggyBac transposon and transposase are typically codelivered by plasmid transfection; however, plasmid delivery is inefficient in somatic cells in vivo and is a barrier to the therapeutic application of transposon-based vector systems. Here, we investigate the potential for hybrid piggyBac/viral vectors to transduce cells and support transposase-mediated genomic integration of the transposon. We tested both adenovirus (Ad) and adeno-associated virus (AAV) as transposon delivery vehicles. An Ad vector expressing hyperactive insect piggyBac transposase (iPB7) was codelivered. We show transposase-dependent transposition activity and mapped integrations in mammalian cells in vitro and in vivo from each viral vector platform. We also demonstrate efficient and persistent transgene expression following nasal delivery of piggyBac/viral vectors to mice. Furthermore, using piggyBac/Ad expressing Cystic Fibrosis transmembrane Conductance Regulator (CFTR), we show persistent correction of chloride current in well-differentiated primary cultures of human airway epithelial cells derived from CF patients. Combining the emerging technologies of DNA transposon-based vectors with well-studied adenoviral and AAV delivery provides new tools for in vivo gene transfer and presents an exciting opportunity to increase the delivery efficiency for therapeutic genes such as CFTR.     

Systemic and specific delivery of small interfering RNAs to the liver mediated by apolipoprotein A-I.

Tissue-targeted delivery of small interfering RNA (siRNA) must be achieved before RNA interference (RNAi) technology can be used in practical therapeutic approaches. In this study, the potential of apolipoprotein A-I (apo A-I) for the systemic delivery of nucleic acids to the liver is demonstrated using real-time in vivo imaging. As a proof of concept, synthetic siRNAs against hepatitis B virus (HBV) were formulated into complexes of apo A-I and 1,2-dioleoyl-3-trimethylammonium-propane (DOTAP)/cholesterol (DTC-Apo) and injected intravenously (i.v.) into a mouse model carrying replicating HBV. We show that administration of these nanoparticles can significantly reduce viral protein expression by receptor-mediated endocytosis. The advantages of the apo A-I-mediated siRNA delivery method are its liver specificity, its effectiveness at low doses (< or = 2 mg/kg) in only a single treatment, and its persistent antiviral effect up to 8 days. The liver-targeted gene silencing was also shown by in vivo images, in which bioluminescent signals emitted from the liver were efficiently reduced after i.v. administration of luciferase-specific siRNA and DTC-Apo lipoplex. Thus, our unique approach to siRNA delivery creates a foundation for the development of a new class of promising therapeutics against hepatitis viruses or hepatocyte genes related to tumor growth.     

The short hairpin RNA driven by polymerase II suppresses both wild-type and lamivudine-resistant hepatitis B virus strains

BACKGROUND: Chronic infection with hepatitis B virus (HBV) is widespread because of the limited availability of therapeutic treatments. Although previous reports have suggested that RNA interference has promise as a treatment for HBV infection, further studies of long-term and off-target drug effects on HBV, especially on drug-resistant strains of HBV, are needed. Therefore, seven vectors that express short hairpin RNAs (shRNAs), driven by the polymerase II promoter, pSilencer4.1/HBV, were constructed to target open reading frames (ORFs) of the HBV C and S genes from wild-type and drug-resistant strains. Treatment efficiency was also assessed. METHODS: The pSilencer4.1/HBV vectors were investigated in HepG2.2.15 cells and transgenic mice that consistently produce wild-type HBV. Additionally, vectors that produce a lamivudine-resistant strain of HBV were developed and cotransfected, along with pSilencer/HBV, into both HepG2 cells and mice. The effects of polymerase-II-driven pSilencer4.1/HBV were compared with those of polymerase-III-driven pSilencer3.1/HBV at both the gene and protein level. RESULTS: pSilencer4.1/HBV inhibited the expression of viral protein, DNA and HBV subtype ayw mRNA in both HepG2.2.15 cells and transgenic mice. Toxicity, as well as off-target effects, did not occur after a short- to medium-term examination. Moreover, an HBV strain resistant to lamivudine, subtype adr, was suppressed by shRNA in both HepG2 cells and mice. In contrast to polymerase III, vectors that used polymerase II could drive efficient silencing without off-target effects. CONCLUSIONS: Silencing by shRNA dramatically inhibited HBV expression and replication regardless of strain type. ShRNA could therefore be a promising treatment for HBV infection.     

Genetically Engineered Microvesicles Carrying Suicide mRNA/Protein Inhibit Schwannoma Tumor Growth

Microvesicles (MVs) play an important role in intercellular communication by carrying mRNAs, microRNAs (miRNAs), non-coding RNAs, proteins, and DNA from cell to cell. To our knowledge, this is the first report of delivery of a therapeutic mRNA/protein via MVs for treatment of cancer. We first generated genetically engineered MVs by expressing high levels of the suicide gene mRNA and protein–cytosine deaminase (CD) fused to uracil phosphoribosyltransferase (UPRT) in MV donor cells. MVs were isolated from these cells and used to treat pre-established nerve sheath tumors (schwannomas) in an orthotopic mouse model. We demonstrated that MV-mediated delivery of CD-UPRT mRNA/protein by direct injection into schwannomas led to regression of these tumors upon systemic treatment with the prodrug (5-fluorocytosine (5-FC)), which is converted within tumor cells to 5-fluorouracil (5-FU)–an anticancer agent. Taken together, these studies suggest that MVs can serve as novel cell-derived “liposomes” to effectively deliver therapeutic mRNA/proteins to treatment of diseases.     

GLP-1 gene delivery for the treatment of type 2 diabetes

Glucagon-like peptide-1 (GLP-1) is a potent insulinotrophic hormone, which makes GLP-1 an attractive candidate for the treatment of type 2 diabetes. However, the short plasma half-life of the active forms of GLP-1 poses an obstacle to the sustained delivery of this peptide. In this study, we evaluated the effect of GLP-1 gene delivery both in vitro and in vivo using a new plasmid constructed with a modified GLP-1 (7-37) cDNA. This cDNA contains a furin cleavage site between the start codon and the GLP-1 coding region. The expression of the GLP-1 gene was driven by a chicken β-actin promoter (pβGLP1). The level of the GLP-1 mRNA was evaluated by RT-PCR 24 h after transfection. The in vitro results showed a dose-dependent expression of GLP-1. Coculture assay of the GLP-1 plasmid-transfected cells with isolated rat islet cells demonstrated that GLP-1 increased insulin secretion by twofold, compared to controls during a hyperglycemic challenge. A single injection of polyethyleneimine/pβGLP1 complex into ZDF rats resulted in increasing insulin secretion and decreasing blood glucose level that was maintained for 2 weeks. This GLP-1 gene delivery system may provide an effective and safe treatment modality for type 2 diabetes.     

Enhanced Antitumor Efficacy of Vasculostatin (Vstat120) Expressing Oncolytic HSV-1

Oncolytic viral (OV) therapy is a promising therapeutic modality for brain tumors. Vasculostatin (Vstat120) is the cleaved and secreted extracellular fragment of brain-specific angiogenesis inhibitor 1 (BAI1), a brain-specific receptor. To date, the therapeutic efficacy of Vstat120 delivery into established tumors has not been investigated. Here we tested the therapeutic efficacy of combining Vstat120 gene delivery in conjunction with OV therapy. We constructed RAMBO (Rapid Antiangiogenesis Mediated By Oncolytic virus), which expresses Vstat120 under the control of the herpes simplex virus (HSV) IE4/5 promoter. Secreted Vstat120 was detected as soon as 4 hours postinfection in vitro and was retained for up to 13 days after OV therapy in subcutaneous tumors. RAMBO-produced Vstat120 efficiently inhibited endothelial cell migration and tube formation in vitro (P = 0.0005 and P = 0.0184, respectively) and inhibited angiogenesis (P = 0.007) in vivo. There was a significant suppression of intracranial and subcutaneous glioma growth in mice treated with RAMBO compared to the control virus, HSVQ (P = 0.0021 and P < 0.05, respectively). Statistically significant reduction in tumor vascular volume fraction (VVF) and microvessel density (MVD) was observed in tumors treated with RAMBO. This is the first study to report the antitumor effects of Vstat120 delivery into established tumors and supports the further development of RAMBO as a possible cancer therapy.