Herpes simplex virus vector-mediated delivery of glial cell line-derived neurotrophic factor rescues erectile dysfunction following cavernous nerve injury.

Erectile dysfunction (ED) is frequently associated with injury to the cavernous nerve sustained during pelvic surgery. Functional recovery from cavernous nerve injury is generally incomplete and occurs over an extended time frame. We employed a therapeutic gene transfer approach with herpes simplex virus (HSV) vector expressing glial cell line-derived neurotrophic factor (GDNF). Rat cavernous nerve was injured bilaterally using a clamp and dry ice. For HSV-treated groups, 20 microl of purified vector stock was administered directly to and around the damaged nerve. Delivery of an HSV vector expressing both green fluorescent protein (GFP) and lacZ (HSV-LacZ) was used as a control. Intracavernous pressure along with systemic arterial pressure (ICP/AP) was measured 2 and 4 weeks after the nerve injury. Fluorogold (FG) was injected into the penile crus 7 days before killing to assess nerve survival. Approximately 60% of major pelvic ganglion (MPG) cells were GFP positive after viral administration. At 4 weeks after nerve injury, rats treated with HSV-GDNF exhibited significant recovery of ICP/AP compared with control vector or untreated groups. The HSV-GDNF group also yielded more FG-positive MPG cells than the control vector group. HSV vector-mediated delivery of GDNF presents a viable approach for the treatment of ED following cavernous nerve injury.

HSV vector cytotoxicity is inversely correlated with effective TK/GCV suicide gene therapy of rat gliosarcoma.

Herpes simplex virus (HSV)-mediated delivery of the HSV thymidine kinase (tk) gene to tumor cells in combination with ganciclovir (GCV) administration may provide an effective suicide gene therapy for destruction of malignant glioblastomas. However, because HSV is a highly cytotoxic agent, gene expression from the virus is short-lived which may limit the effectiveness of HSVtk/GCV therapy. Using different replication-defective HSVtk gene vectors, we compared HSV vector backgrounds for their cytotoxic activity on infection of 9L gliosarcoma cells in culture and brain tumors in rats and evaluated the impact of vector toxicity on the effectiveness of tk/GCV-mediated suicide gene therapy. As reported previously for other cell lines, a vector deleted for both copies of the immediate-early (IE) gene ICP4 (SOZ.1) was highly toxic for 9L cells in culture while a vector deleted in addition for the ICP22 and ICP27 IE genes (T.1) reduced or arrested 9L cell proliferation with more limited cell killing. Nevertheless, both vectors supported widespread killing of uninfected cells in the presence of GCV following low multiplicity infections, indicating that vector cytotoxicity did not preempt the production of vector-encoded TK enzyme necessary for the killing of uninfected cells by the HSV-tk/GCV bystander effect. Although an SOZ.1-related vector (SHZ.2) caused tumor cell necrosis in vivo, injection of SHZ.2 at multiple coordinates thoughout the tumor followed by GCV administration failed to prolong markedly the survival of tumor-bearing rats. In contrast, a single injection of T.1 produced a life-extending response to GCV. These results indicate that vector cytotoxicity can limit the efficacy of HSV-tk/GCV treatment in vivo, which may be due to premature termination of tk gene expression with attendant abortion of the bystander effect.

Connexin 43-enhanced suicide gene therapy using herpesviral vectors.

Tumor cell transduction with the herpes simplex virus (HSV) thymidine kinase (tk) gene and treatment with ganciclovir (GCV) is a widely studied cancer gene therapy. Connexin (Cx)-dependent gap junctions between cells facilitate the intercellular spread of TK-activated GCV, thereby creating a bystander effect that improves tumor cell killing. However, tumor cells often have reduced connexin expression, thus thwarting bystander killing and the effectiveness of TK/GCV gene therapy. To improve the effectiveness of this therapy, we compared an HSV vector (TOCX) expressing Cx43 in addition to TK with an isogenic tk vector (TOZ.1) for their abilities to induce bystander killing of Cx-positive U-87 MG human glioblastoma cells and Cx-negative L929 fibrosarcoma cells in vitro and in vivo. The results showed that low-multiplicity infection of U-87 MG cells with TOCX only minimally increased GCV-mediated cell death compared with infection by TOZ.1, consistent with the endogenous level of Cx in these cells. In contrast, bystander killing of L929 cells was markedly enhanced by vector-mediated expression of Cx. In vivo experiments in which U-87 MG cells were preinfected at low multiplicity and injected into the flanks of nude mice showed complete cures of all animals in the TOCX group following GCV treatment, whereas untreated animals uniformly formed fatal tumors. TOCX injection into U-87 MG intradermal and intracranial tumors resulted in prolonged survival of the host animals in a GCV-dependent manner. Together, these results suggest that the combination of TK and Cx may be beneficial for the treatment of human glioblastoma.

Efficient gene delivery into epstein-barr virus (EBV)-transformed human B cells mediated by replication-defective herpes simplex virus-1 (HSV-1): A gene therapy model for EBV-related B cell malignancy.

Subgroups of the B cell malignancies are known to be associated with Epstein-Barr virus (EBV) infection, especially in immunocompromised patients. These are fatal and refractory to conventional antineoplastic therapy. B cells are usually post-mitotic cells and even mitogen activated or transformed B cells have shown relative resistance against viral mediated gene transfer. To address this issue, we employed a replication-defective herpes simplex virus-1 (HSV-1) to mediate gene transfer into EBV-transformed B cells. The virus expresses the herpes simplex virus thymidine kinase (HSV-TK) and the E. coli lacZ reporter genes and is designated T0Z.1. We used the lymphoblastoid cell line SWEIG as a model for human EBV-related B cell malignancy. This cell line was established by in vitro EBV infection of primary human peripheral blood mononuclear cells. When SWEIG cells were infected with T0Z.1, X-gal staining revealed lacZ expression in more than 20% cells even at multiplicity of infection (MOI) as low as 1 and the expression persisted for at least one week. Ganciclovir (GCV) administration after T0Z.1 infection effectively decreased the number of the infected tumor cells in a dose-responsive manner. Viral toxicity was analyzed by cell proliferation assay (MTS assay) and found to be little even at 10 MOI infection. Three MOI of the virus yielded maximum antineoplastic effect and more than 50% tumor cells were killed by HSV-TK/GCV. These results suggest the potential utility of replication-defective HSV-1 for the treatment of EBV-related B cell malignancies.

Modulation of mucosal and systemic immunity by enteric administration of nonreplicating herpes simplex virus expressing cytokines.

In this report the ability of enteric immunization with recombinant replication deficient (ICP4-/-) HSV expressing IFN gamma to generate protection and modulate mucosal and systemic immunity was evaluated. ICP4-/-HSV, ICP4-/-HSV expressing IL4, live replicating, and uv HSV were used as controls. Following enteric administration of live HSV, a Th1 cytokine response was induced in the spleen, while both Th1 and notable Th2 cytokine production were detected at mucosal sites. Modulation of mucosal and systemic immune response was achieved when nonreplicating recombinant HSV viruses expressing cytokines were used. Compared to the control replication defective viruses, decreased frequency of Th2 cytokine producing cells in Peyer's patches was observed following enteric administration of nonreplicating HSV expressing IFN gamma. When IFN gamma expressing virus was given enterically, modulation was observed at the systemic level, measured by ELISPOT for cytokine producing cells, ELISA from the in vitro restimulated splenic cell cultures, and by the increase of the IgG2a/IgG1 ratio in the serum. This report provides evidence that replication defective viruses expressing cytokine genes in contrast to uv HSV, are immunogenic when administered enterically and can generate significant immunomodulatory effects at the mucosal and systemic levels.

Development of herpes simplex virus replication-defective multigene vectors for combination gene therapy applications.

Some gene therapy applications will require simultaneous expression of multiple gene products to achieve a therapeutic effect. In this study we describe the generation and characterization of replication incompetent herpes simplex virus type 1 (HSV-1) vectors (HX86Z or HX86G) carrying distinct and independently regulated expression cassettes for five transgenes (hIL-2, hGM-CSF, hB7.1, HSV-tk and lacZ or hIFN gamma). The transgenes, representing 12 kb of DNA sequence, were recombined into separate loci of a single mutant virus vector deleted for 11.6 kb of vector sequences representing portions of nine viral genes, ICP4, ICP22, ICP27, ICP47, UL24, UL41, UL44, US10 and US11. Deletion of the immediate--early genes ICP4, ICP22 and ICP27 substantially reduced vector cytotoxicity, prevented early and late viral gene expression and left intact MHC class I antigen expression. Simultaneous expression of multiple transgenes was obtained for up to 7 days in primary human melanoma cells with peak expression at 2-3 days after infection. The transgenes were chosen for their potential to function synergistically in tumor destruction and vaccine gene therapy applications, but the method and vector employed could be applied to other multigene therapy strategies. This study demonstrates the potential for engineering large transgene capacity DNA viruses such as HSV-1 for expression of multiple transgenes.

Deletion of multiple immediate-early genes from herpes simplex virus reduces cytotoxicity and permits long-term gene expression in neurons.

Herpes simplex virus type 1 (HSV-1) has many attractive features that suggest its utility for gene transfer to neurons. However, viral cytotoxicity and transient transgene expression limit practical applications even in the absence of viral replication. Mutant viruses deleted for the immediate early (IE) gene, ICP4, an essential transcriptional transactivator, are toxic to many cell types in culture in which only the remaining IE genes are expressed. In order to test directly the toxicity of other IE gene products in neurons and develop a mutant background capable of longterm transgene expression, we generated mutants deleted for multiple IE genes in various combinations and tested their relative cytotoxicity in 9L rat gliosarcoma cells, Vero monkey kidney cells, and primary rat cortical and dorsal root neurons in culture. Viral mutants deleted simultaneously for the IE genes encoding ICP4, ICP22 and ICP27 showed substantially reduced cytotoxicity compared with viruses deleted for ICP4 alone or ICP4 in combination with either ICP22, ICP27 or ICP47. Infection of neurons in culture with these triple IE deletion mutants substantially enhanced cell survival and permitted transgene expression for over 21 days. Such mutants may prove useful for efficient gene transfer and extended transgene expression in neurons in vitro and in vivo.

Development of an HSV-based vector for the treatment of Parkinson's disease.

The restricted pattern of neurodegeneration seen in Parkinson's disease, and the identification of trophic factors that prevent toxin-induced degeneration of dopaminergic neurons, has spurred research into potential gene therapy for this disease. Herpes simplex virus (HSV-1) is a neurotrophic virus which naturally establishes latency in neurons. HSV-based vectors have been demonstrated to transfer and transiently express transgenes in neurons in brain in vivo. Recent experiment have shown that deletion of multiple immediate-early HSV genes reduces the potential cytotoxicity of these vectors, and in addition results in altered patterns of transgene expression that may allow for long-term expression required for human gene therapy applications.

Rapid method for construction of recombinant HSV gene transfer vectors.

Herpes simplex virus type 1 (HSV-1) is a neurotrophic human pathogen that naturally persists in neurons in a latent state and carries a large number of viral functions which can be replaced by foreign genes to create a vector for gene therapy applications. In this report we describe a two-step method for insertion/deletion mutagenesis of HSV genes and the efficient insertion of transgenes into these locations in the viral genome. The first step is the insertion of a reporter gene (lacZ) cassette flanked by Pacl restriction enzyme sites not otherwise found in the viral genome, using standard marker transfer procedures to interrupt a portion of the target HSV gene. The second step is substitution of the reporter gene with other foreign cDNAs by digestion of the vector DNA with Pacl to remove the lacZ gene and subsequent repair of the vector genome by homologous recombination with a transgene expression plasmid. Potential recombinants identified by a 'clear plaque' phenotype after X-gal staining arose at high frequency (80-100%). Of these recombinants containing the transgene in place of the lacZ gene ranged from 19-65%. Insertion of the transgene expression construct into the viral genome eliminates the Pacl sites, allowing this method to be used repeatedly for the sequential deletion of multiple HSV genes while inserting multiple transgenes. This procedure was repeated in succession to produce a vector carrying two independent expression cassettes at distinct viral loci.