Antioxidant enzyme gene delivery to protect from HIV-1 gp120-induced neuronal apoptosis

Human immunodeficiency virus-1 (HIV-1) infection in the central nervous system (CNS) may lead to neuronal loss and progressively deteriorating CNS function: HIV-1 gene products, especially gp120, induce free radical-mediated apoptosis. Reactive oxygen species (ROS), are among the potential mediators of these effects. Neurons readily form ROS after gp120 exposure, and so might be protected from ROS-mediated injury by antioxidant enzymes such as Cu/Zn-superoxide dismutase (SOD1) and/or glutathione peroxidase (GPx1). Both enzymes detoxify oxygen free radicals. As they are highly efficient gene delivery vehicles for neurons, recombinant SV40-derived vectors were used for these studies. Cultured mature neurons derived from NT2 cells and primary fetal neurons were transduced with rSV40 vectors carrying human SOD1 and/or GPx1 cDNAs, then exposed to gp120. Apoptosis was measured by terminal deoxynucleotidyl transferase-mediated nick end labeling (TUNEL) assay. Transduction efficiency of both neuron populations was >95%, as assayed by immunostaining. Transgene expression was also ascertained by Western blotting and direct assays of enzyme activity. Gp120 induced apoptosis in a high percentage of unprotected NT2-N. Transduction with SV(SOD1) and SV(GPx1) before gp120 challenge reduced neuronal apoptosis by >90%. Even greater protection was seen in cells treated with both vectors in sequence. Given singly or in combination, they protect neuronal cells from HIV-1-gp120 induced apoptosis. We tested whether rSV40 s can deliver antioxidant enzymes to the CNS in vivo: intracerebral injection of SV(SOD1) or SV(GPx1) into the caudate putamen of rat brain yielded excellent transgene expression in neurons. In vivo transduction using SV(SOD1) also protected neurons from subsequent gp120-induced apoptosis after injection of both into the caudate putamen of rat brain. Thus, SOD1 and GPx1 can be delivered by SV40 vectors in vitro or in vivo. This approach may merit consideration for therapies in HIV-1-induced encephalopathy.     

Intracisternal rSV40 administration provides effective pan-CNS transgene expression

Potential genetic treatments for many generalized central nervous system (CNS) diseases require transgene expression throughout the CNS. Using oxidant stress and apoptosis caused by HIV-1 envelope gp120 as a model, we studied pan-CNS neuroprotective gene delivery into the cisterna magna (CM). Recombinant SV40 vectors carrying Cu/Zn superoxide dismutase or glutathione peroxidase were injected into rat CMs following intraperitoneal administration of mannitol. Sustained transgene expression was seen in neurons throughout the CNS. On challenge, 8 weeks later with gp120 injected into the caudate putamen, significant neuroprotection was documented. Thus, intracisternal administration of antioxidant-carrying rSV40 vectors may be useful in treating widespread CNS diseases such as HIV-1-associated neurocognitive disorders characterized by oxidative stress.     

Strategies for CNS-directed gene delivery: in vivo gene transfer to the brain using SV40-derived vectors

Gene transfer to the central nervous system (CNS) has been approached using various vectors. Recombinant SV40-derived vectors (rSV40s) transduce neurons and microglia effectively in vitro, so we tested rSV40s gene transfer to the CNS in vivo, and characterized the distribution, duration and cell types transduced. We used rSV40s carrying Human Immunodeficiency Virus Type 1 Net protein (HIV-1 Nef) with a C-terminal FLAG epitope tag as a marker, and another with Cu/Zn superoxide dismutase (SOD1). Rats were given vectors stereotaxically, either intraparenchymally into the caudate-putamen (CP) or into the lateral ventricle (LV). FLAG expression was studied for 3 months by immunostaining serial brain sections. After intraparenchymal administration, numerous transgene-expressing cells were seen, many as far as 4 mm from the injection site. Transgene expression remained strong throughout the 3-month study period. Coimmunostaining for lineage markers showed that neurons and, more rarely, microglial cells were tranduced, except astrocytes and oligodendroglia. After injection into the LV, high levels of transgene expression were detected throughout the frontal cortex by Western analysis. Systemic mannitol-induced hyperosmolarity further augmented LV transgene delivery. SV40-derived vectors may, thus, be useful for long-term gene expression in the brain, whether locally by intraparenchymal administration or diffusely by intraventricular injection, with or without mannitol.     

Inhibiting AIDS in the central nervous system: gene delivery to protect neurons from HIV

Gene therapy to treat primary and secondary CNS diseases, including neuro-AIDS, has not yet been effective. New approaches to delivering therapeutic genes to the central nervous system are therefore required. Recombinant SV40 vectors (rSV40) transduce both dividing and quiescent cells efficiently, and so we tested them for their ability to deliver anti-HIV-1 transgenes to terminally differentiated human NT2-derived neurons (NT2-N). These vectors transduced>95% of immature as well as mature human neurons efficiently, without detectable toxicity and without requiring selection. rSV40 gene delivery was stable to retinoic acid-induced neuronal differentiation. The rSV40 vectors used in these studies, SV(RevM10) and SV(AT), respectively carried the cDNAs for RevM10, a trans-dominant mutant of HIV-1 Rev, and human α1-antitrypsin. As measured by HIV-1 p24 antigen assays and by immunostaining for gp120, NT2-N treated with these vectors strongly resisted challenge with different strains of HIV-1. Protection from HIV replication and HIV-induced cytotoxicity was conferred by SV(AT) and SV(RevM10) and remained constant throughout retinoic acid-induced neuronal differentiation and for the duration of these studies (≥11 weeks). rSV40 transduction of human neurons might therefore be a practicable approach to gene delivery for the treatment of CNS diseases, including neuro-AIDS.     

Gene transfer to the rhesus monkey brain using SV40-derived vectors is durable and safe

Gene transfer to central nervous system (CNS) has been approached using various vectors. Recombinant SV40-derived vectors (rSV40s) transduce human neurons and microglia effectively in vitro and in rodent brains in vivo, so we tested rSV40s gene transfer to rhesus monkey CNS in vivo, to characterize the distribution, duration and safety of such gene delivery. We used rSV40s carrying HIV-1 RevM10 with a carboxyl-terminal AU1 epitope tag as a marker, and others with the antioxidant enzymes, Cu/Zn superoxide dismutase and glutathione peroxidase. Vectors were injected stereotaxically into the caudate nucleus. Transgene expression was studied at 1 and 6 months by immunostaining serial brain sections. After intraparenchymal administration, numerous transgene-expressing cells were seen, with a longitudinal extent of 20?mm. In neurons and, more rarely, microglial cells, transgene expression remained strong throughout the 6-month study period. Astrocytes and oligodendroglia were not transduced. No evidence of inflammation or tissue damage was observed. SV40-derived vectors may thus be useful for long-term gene expression in the monkey brain and, potentially, in the human brain.     

HIV-1 proprotein processing as a target for gene therapy

The central role of endoconvertases and HIV-1 protease (HIV-1 PR) in the processing of HIV proproteins makes the design of specific inhibitors important in anti-HIV gene therapy. Accordingly, we tested native alpha(1) antitrypsin (alpha(1)AT) delivered by a recombinant simian virus-40-based vector, SV(AT), as an inhibitor of HIV-1 proprotein maturation. Cell lines and primary human lymphocytes were transduced with SV(AT) without selection and detectable toxicity. Expression of alpha(1)AT was confirmed by Northern blotting, immunoprecipitation and immunostaining. SV(AT)-transduced cells showed no evidence of HIV-1-related cytopathic effects when challenged with high doses of HIV-1(NL4-3). As measured by HIV-1 p24 assay, SV(AT)-transduced cells were protected from HIV-1(NL4-3) at challenge dose of 40 000 TCID(50) (MOI = 0.04). In addition, peripheral blood lymphocytes treated with SV(AT) were protected from HIV doses challenge up to 40 000 TCID(50) (MOI = 0.04). By Western blot analyses, the delivered alpha(1)AT inhibited cellular processing of gp160 to gp120 and decreased HIV-1 virion gp120. SV(AT) inhibited processing of p55(Gag) as well. Furthermore, high levels of uncleaved p55(Gag) protein were detected in HIV virus particles recovered from SV(AT)-transduced cells lines and primary lymphocytes. Thus, delivering alpha(1)AT using SV(AT) to human lymphocytes strongly inhibits replication of HIV-1, most likely by inhibiting the activities both of the cellular serine proteases involved in processing gp160 and of the aspartyl protease, HIV-1 PR, which cleaves p55(Gag). alpha(1)AT delivered by SV(AT) may represent a novel and effective strategy for gene therapy to interfere with HIV replication, by blocking a stage in the virus replicative cycle that has until now been inaccessible to gene therapeutic intervention.     

Inhibition of HIV-1 by an anti-integrase single-chain variable fragment (SFv): delivery by SV40 provides durable protection against HIV-1 and does not require selection.

Human immunodeficiency virus type 1 (HIV-1) encodes several proteins that are packaged into virus particles. Integrase (IN) is an essential retroviral enzyme, which has been a target for developing agents to inhibit virus replication. In previous studies, we showed that intracellular expression of single-chain variable antibody fragments (SFvs) that bind IN, delivered via retroviral expression vectors, provided resistance to productive HIV-1 infection in T-lymphocytic cells. In the current studies, we evaluated simian-virus 40 (SV40) as a delivery vehicle for anti-IN therapy of HIV-1 infection. Prior work suggested that delivery using SV40 might provide a high enough level of transduction that selection of transduced cells might be unnecessary. In these studies, an SV40 expression vector was developed to deliver SFv-IN (SV(Aw)). Expression of the SFv-IN was confirmed by Western blotting and immunofluorescence staining, which showed that > 90% of SupT1 T-lymphocytic cells treated with SV(Aw) expressed the SFv-IN protein without selection. When challenged, HIV-1 replication, as measured by HIV-1 p24 antigen expression and syncytium formation, was potently inhibited in cells expressing SV40-delivered SFv-IN. Levels of inhibition of HIV-1 infection achieved using this approach were comparable to those achieved using murine leukemia virus (MLV) as a transduction vector, the major difference being that transduction using SV40 did not require selection in culture whereas transduction with MLV did require selection. Therefore, the SV40 vector as gene delivery system represents a novel therapeutic strategy for gene therapy to target HIV-1 proteins and interfere with HIV-1 replication.     

Trans-activated interferon-alpha2 delivered to T cells by SV40 inhibits early stages in the HIV-1 replicative cycle

Several lines of evidence suggest a potential major role for interferon (IFN) in controlling HIV-1 replication. However, this inhibition is moderate and is reversible upon IFN removal. To achieve prolonged high concentrations of IFN at the site of infection, we devised an SV40-based vector, SV[HIVLTR]IFN, to direct the synthesis of human IFN-alpha2, by employing a virus-trans-activated human IFN-alpha2 gene to be transcribed in response to HIV-1 infection. Expression of IFN-alpha2 was confirmed by Northern and Western blotting, in SV[HIVLTR]IFN-transduced, HIV-1-challenged human lymphocyte lines and primary human lymphocytes. SV[HIVLTR]IFN-transduced cells showed no evidence of HIV-1-related cytophatic effects when challenged with high doses of HIV-1(NL4-3). As measured by supernatant HIV-1 p24 antigen concentration, IFN-alpha2-expressing cell lines and peripheral blood lymphocytes (PBL) were protected from high-dose challenges of HIV-1. rSV40-delivered IFN-alpha2 inhibited gp120 protein synthesis and expression of HIV-1 mRNAs. Finally, Southern analysis revealed that levels of proviral DNA were markedly reduced in SV[HIVLTR]IFN-transduced cells compared to control cultures. IFN-alpha2 expression driven by HIVLTR delivered by an rSV40 vector thus strongly inhibits HIV-1 replication, probably by blocking a preintegration step in HIV-1 infection. Targeted expression of IFN-alpha2 delivered by SV40 can thus repress HIV-1 replication, and may be a useful approach to HIV-1 treatment.     

Improved antibiotic-free plasmid vector design by incorporation of transient expression enhancers

Methods to improve plasmid-mediated transgene expression are needed for gene medicine and gene vaccination applications. To maintain a low risk of insertional mutagenesis-mediated gene activation, expression-augmenting sequences would ideally function to improve transgene expression from transiently transfected intact plasmid, but not from spurious genomically integrated vectors. We report herein the development of potent minimal, antibiotic-free, high-manufacturing-yield mammalian expression vectors incorporating rationally designed additive combinations of expression enhancers. The SV40 72?bp enhancer incorporated upstream of the cytomegalovirus (CMV) enhancer selectively improved extrachromosomal transgene expression. The human T-lymphotropic virus type I (HTLV-I) R region, incorporated downstream of the CMV promoter, dramatically increased mRNA translation efficiency, but not overall mRNA levels, after transient transfection. A similar mRNA translation efficiency increase was observed with plasmid vectors incorporating and expressing the protein kinase R-inhibiting adenoviral viral associated (VA)1 RNA. Strikingly, HTLV-I R and VA1 did not increase transgene expression or mRNA translation efficiency from plasmid DNA after genomic integration. The vector platform, when combined with electroporation delivery, further increased transgene expression and improved HIV-1 gp120 DNA vaccine-induced neutralizing antibody titers in rabbits. These antibiotic-free vectors incorporating transient expression enhancers are safer, more potent alternatives to improve transgene expression for DNA therapy or vaccination.     

Systemic mannitol-induced hyperosmolality amplifies rAAV2-mediated striatal transduction to a greater extent than local co-infusion.

Recombinant viral vectors derived from adeno-associated virus serotype 2 (rAAV2) have been investigated as highly effective vehicles for gene transfer to the central nervous system (CNS). Transduction with rAAV2 vectors results in long-term transgene expression in CNS neurons. Optimal injection parameters leading to efficient targeting and spread of the transgene to large neuroanatomical regions are important in molecular gene therapy studies of the CNS. In the present study, we reexamined the effects of both local and systemic administration of mannitol-induced hyperosmolality on facilitation of transgene expression and vector distribution in the CNS. Systemic intraperitoneal administration of mannitol prior to vector administration improved gene transfer to striatal neurons, increasing the total number of transduced cells by 400% and vector distribution by 200%. On the other hand, local coadministration of mannitol in the striatum increased the number of transduced striatal neurons by 25% and had little effect on transduction volume. In conclusion, we have demonstrated that systemic coadministration of mannitol significantly enhances transgene spread of rAAV2 viral delivery in the brain to a much greater degree than local coadministration.     

Scatter factor mitigates HIV-1 gp120-induced human mesangial cell injury

HIV-1 gp120 protein has been shown to promote mesangial cell (MC) injury. Scatter factor (SF) is a growth factor that plays a reparative role in various experimental models of renal lesions. We hypothesize that SF protects MC against HIV-1 gp120-induced MC injury. gp120 at a low dose, stimulated HMC proliferation (p < 0.0001). SF (50 ng/ml) further enhanced low-dose gp120-induced HMC proliferation. However, gp120 at higher doses (10-100 ng/ml) promoted HMC apoptosis. Nevertheless, SF attenuated the high-dose gp120-induced HMC apoptosis. Interestingly, gp120 at a low dose not only induced NF-kappaB activation but also increased p21(cip1/waf1) andp27(kip1) protein levels.     

A genetically engineered spleen necrosis virus-derived retroviral vector that displays the HIV type 1 glycoprotein 120 envelope peptide

We reported that SNV-derived retroviral vectors, which display single-chain antibodies on the viral surface, enable cell type-specific gene delivery into various human cells. In particular, the SNV cell type-specific gene delivery vector system appears to be well suited to transduce genes into cells of the human hematopoietic system (Jiang et al., J. Virol. 72:10148-10156, 1998). Here, we report the construction of SNV vector particles that display the complete gp120 surface unit of the envelope protein of human immunodeficiency virus type 1 (HIV-1) on the viral surface. The complete gp120-coding region of a T cell-tropic HIV-1 strain (LAI/BRU) was fused to a short peptide spacer coding region [(Gly4Ser)3] linking it to the SNV TM-coding region. The corresponding protein was expressed as a single 145-kDa peptide as expected. This peptide was nontoxic and could be stably expressed in dog D17 SNV-derived packaging cells. Particles harvested from stable packaging lines infected CD4+ human hematopoietic cells with titers exceeding 10(5) CFU/ml supernatant tissue culture medium. Titers in other, CD4- cell lines expressing various coreceptors of HIV-1 were 100-fold lower than titers obtained in CD4+ cells. Specificity of infection was demonstrated by antibody inhibition assays or by preincubating cells with SDF-1alpha, the ligand, which binds to the CXCR4 coreceptor, to which this gp120 binds. Our data indicate that binding of the HIV-1 gp120 to either CD4 or CXCR4 is sufficient to enable infection of human cells with SNV vector particles. We constructed retroviral vector particles that display chimeric HIV-1-SU-SNV-TM proteins plus wild-type SNV envelope on the viral surface. Such particles allowed efficient infection of CD4-positive human T lymphocytes, and, at a lower efficiency, also cells expressing CXCR4 without CD4. These data coincide with our earlier hypothesis that the chimeric envelope is required only to bind the vector particle to a cell surface receptor of the target cell, while membrane fusion is mediated by wild-type Env, which alone is not sufficient to enable infection of human cells.     

SV40-based gene therapy vectors: turning an adversary into a friend

For gene delivery to be of use, a situation suitable for delivery of genetic material, a specific genetic construct to be delivered and the appropriate means to deliver it are required. Simian virus-40 (SV40) gene therapy vectors for gene transfer may be an important advance in the latter category. While other vectors are variably limited for example by immunogenicity, difficulties in production, restricted specificity, low titers, poor transduction efficiency, etc., recombinant viral vectors based on SV40 (rSV40) should not be similarly constrained. They are easily manipulated and produced at very high titer, stable, apparently lacking in immunogenicity, and capable of providing sustained high levels of transgene expression in almost any cell type, whether resting or dividing. The major limitation of SV40-derived vectors is packaging capacity, which restricts insert sizes. The rationale for developing SV40 as a gene therapy vector is reviewed, based on what is known of wild-type SV40. Studies with rSV40 gene transfer have focused mostly on hematopoietic progenitor cells (CD34+) and their derivatives, and on gene delivery to the liver. In both settings, in vitro and in vivo, SV40 has been very effective. It is therefore a highly promising gene delivery vehicle that may complement other vectors that are currently in use or that are being developed.     

What can SV40-derived vectors do for gene therapy?

The limited success of gene therapy as an approach to treating human disease largely reflects the limitations of the gene delivery vectors that have been used. Poor titers, low transduction efficiency, waning transgene expression and immunogenicity have remained obstacles in the field. As a consequence, much research in normal, immunocompetent animals has not demonstrated therapeutic levels of gene delivery, and results from most human clinical trials have been predictably discouraging. Recombinant gene transfer vectors derived from SV40 virus (rSV40) are potentially of great interest for those working in gene therapy, since these vectors are not subject to many of the problems that have limited gene delivery using other vector systems. rSV40 is made at a very high titer and infects - and so transduces - almost all nucleated cell types very efficiently, regardless of lineage or whether they are resting or dividing; they integrate and are not susceptible to transgene silencing; and they elicit no detectable immune response on the part of normal animals and so can be used to deliver multiple transgenes over time and in sequence. The recent development of 'gutless' rSV40 vectors has expanded the range of potential therapeutic transgenes that can be delivered with this system and added flexibility to the expression configurations that can be accommodated. All of these functional characteristics of SV40-derived vectors have their bases in the biology of SV40 and similar viruses, and have important implications for the potential utility of rSV40 vectors in gene therapeutics. Like all viral gene delivery systems, these vectors have their idiosyncrasies and limitations. They also allow gene delivery that bypasses many of the difficulties that have plagued the field from its inception.     

Conditional expression of alpha1-antitrypsin delivered by recombinant SV40 vectors protects lymphocytes against HIV

Constitutive expression of alpha(1)-antitrypsin (alpha(1)AT), a serine protease inhibitor, by a recombinant simian virus-40-based vector blocks both HIV gp160 and p55 processing, and so is a powerful inhibitor of HIV replication. To apply these findings more effectively in devising HIV therapies, we tested HIV LTR conditional promoter, to drive the expression of alpha(1)AT. SV[LTR](AT) was designed so that synthesis of human alpha(1)AT would be trans-activated by HIV infection. Cell lines and primary human lymphocytes were transduced with SV[LTR](AT) without selection and detectable toxicity. Responsiveness of alpha(1)AT expression to HIV Tat or HIV challenge was confirmed by Northern blotting, RT-PCR, cytofluorimetry and immunostaining. SV[LTR](AT)-transduced cells were protected from HIV-1(NL4-3) at a challenge dose of 0.04 MOI (T-cell lines) or 0.2 MOI (peripheral blood lymphocytes). Conditional expression of alpha(1)AT consistently protected T cells from HIV challenge as effectively as did constitutive expression. Combining the efficiency of rSV40 vectors with HIV-responsive expression of a highly effective anti-HIV therapeutic may be an effective approach to gene therapy of HIV replication.     

Liver-targeted gene therapy by SV40-based vectors using the hydrodynamic injection method

Efficient reconstitution of defective genes in hepatocytes could be used to treat various liver and systemic diseases through gene therapy. To explore the potential of SV40-based vectors in liver gene therapy, we constructed SV/luc, an SV40 T-antigen replacement transduction vector, that was propagated on COS and COT cells, which supply the SV40 T-antigen in trans. For liver targeting, BALB/C mice were injected via the tail vein with SV/luc stocks containing 3 x 10(6) to 10(8) transducing units in a volume of 1-2 ml. Luciferase activity was monitored with a light-detection cooled charged-coupled device (CCCD) camera, which enables continuous in vivo measurement of luc expression. The SV40 vector proved to be efficient in gene delivery to the liver, leading to long-term (> or =107 days) transgene expression in hepatocytes. Optimal results were obtained with 3 x 10(6) to 3 x 10(7) transducing units. The hydrodynamic vector delivery method caused transient liver inflammatory changes, with full recovery within days. Low levels of SV40-neutralizing antibodies were detected in the sera of treated mice; however, there was no indication of vector or transgene-specific cellular immune responses. Vectors packaged in vitro, using recombinant capsid proteins and plasmid DNA, were also effective in liver transduction. These results suggest that SV40 vectors may be useful for liver gene therapy.