Elimination Of Transgene Expression Research Articles

Recombinant adenovirus expressing ICP47 gene suppresses the ability of dendritic cells by restricting specific T cell responses

Adenoviral vectors have been demonstrated to be one of the most effective vehicles to deliver foreign DNA into dendritic cells (DCs). However, the response of host immune systems against foreign gene products is a major obstacle to successful gene therapy. Infected cell protein 47 (ICP47) inhibits MHC Ⅰ antigen presentation pathway by binding to host transporter associated with antigen presentation (TAP), and thereby attenuates of specific cytotoxic T lymphocytes (CTLs) responses and evades the host immune clearance. This subject was designed to construct a recombinant adenovirus expressing His-tag-ICP47 fusion protein to investigate further the role of ICP47 in the elimination of transgene expression. Consequently, a recombinant adenovirus expressing the His-tag-ICP47 fusion protein was successfully constructed and it had the abilities of attenuating the stimulatory capacity of DCs by reducing the proliferation of lymphocytes and cytokine production of perforin compared with those of the r-track group and the control group. Our observations provide the first evidence of the regulation mechanism of ICP47 on DC-based immunotherapy for long-term persistence.

Immune-mediated loss of transgene expression from virally transduced brain cells is irreversible, mediated by IFNγ, perforin, and TNFα, and due to the elimination of transduced cells.

The adaptive immune response to viral vectors reduces vector-mediated transgene expression from the brain. It is unknown, however, whether this loss is caused by functional downregulation of transgene expression or death of transduced cells. Herein, we demonstrate that during the elimination of transgene expression, the brain becomes infiltrated with CD4(+) and CD8(+) T cells and that these T cells are necessary for transgene elimination. Further, the loss of transgene-expressing brain cells fails to occur in the absence of IFNγ, perforin, and TNFα receptor. Two methods to induce severe immune suppression in immunized animals also fail to restitute transgene expression, demonstrating the irreversibility of this process. The need for cytotoxic molecules and the irreversibility of the reduction in transgene expression suggested to us that elimination of transduced cells is responsible for the loss of transgene expression. A new experimental paradigm that discriminates between downregulation of transgene expression and the elimination of transduced cells demonstrates that transduced cells are lost from the brain upon the induction of a specific antiviral immune response. We conclude that the anti-adenoviral immune response reduces transgene expression in the brain through loss of transduced cells.

Immune Responses to AAV in Canine Muscle Monitored by Cellular Assays and Noninvasive Imaging

We previously demonstrated that direct intramuscular injection of rAAV2 or rAAV6 in wild-type dogs resulted in robust T-cell responses to viral capsid proteins, and others have shown that cellular immunity to adeno-associated virus (AAV) capsid proteins coincided with liver toxicity and elimination of transgene expression in a human trial of hemophilia B. Here, we show that the heparin-binding ability of a given AAV serotype does not determine the induction of T-cell responses following intramuscular injection in dogs, and identify multiple epitopes in the AAV capsid protein that are recognized by T cells elicited by AAV injection. We also demonstrate that noninvasive magnetic resonance imaging (MRI) can accurately detect local inflammatory responses following intramuscular rAAV injection in dogs. These studies suggest that pseudotyping rAAV vectors to remove heparin-binding activity will not be sufficient to abrogate immunogenicity, and validate the utility of enzyme-linked immunosorbent spot (ELISpot) assay and MRI for monitoring immune and inflammatory responses following intramuscular injection of rAAV vectors in preclinical studies in dogs. These assays should be incorporated into future human clinical trials of AAV gene therapy to monitor immune responses.

Immune Responses to Adenovirus and Adeno-Associated Vectors Used for Gene Therapy of Brain Diseases: The Role of Immunological Synapses in Understanding the Cell Biology of Neuroimmune Interactions

Researchers have conducted numerous pre-clinical and clinical gene transfer studies using recombinant viral vectors derived from a wide range of pathogenic viruses such as adenovirus, adeno-associated virus, and lentivirus. As viral vectors are derived from pathogenic viruses, they have an inherent ability to induce a vector specific immune response when used in vivo. The role of the immune response against the viral vector has been implicated in the inconsistent and unpredictable translation of pre-clinical success into therapeutic efficacy in human clinical trials using gene therapy to treat neurological disorders. Herein we thoroughly examine the effects of the innate and adaptive immune responses on therapeutic gene expression mediated by adenoviral, AAV, and lentiviral vectors systems in both pre-clinical and clinical experiments. Furthermore, the immune responses against gene therapy vectors and the resulting loss of therapeutic gene expression are examined in the context of the architecture and neuroanatomy of the brain immune system. The chapter closes with a discussion of the relationship between the elimination of transgene expression and the in vivo immunological synapses between immune cells and target virally infected brain cells. Importantly, although systemic immune responses against viral vectors injected systemically has thought to be deleterious in a number of trials, results from brain gene therapy clinical trials do not support this general conclusion suggesting brain gene therapy may be safer from an immunological standpoint.

Immunological thresholds in neurological gene therapy: highly efficient elimination of transduced cells might be related to the specific formation of immunological synapses between T cells and virus-infected brain cells.

First-generation adenovirus can be engineered with powerful promoters to drive expression of therapeutic transgenes. Numerous clinical trials for glioblastoma multiforme using first generation adenoviral vectors have either been performed or are ongoing, including an ongoing, Phase III, multicenter trial in Europe and Israel (Ark Therapeutics, Inc.). Although in the absence of anti-adenovirus immune responses expression in the brain lasts 6-18 months, systemic infection with adenovirus induces immune responses that inhibit dramatically therapeutic transgene expression from first generation adenoviral vectors, thus, potentially compromising therapeutic efficacy. Here, we show evidence of an immunization threshold for the dose that generates an immune response strong enough to eliminate transgene expression from the CNS. For the systemic immunization to eliminate transgene expression from the brain, > or = 1 x 10(7) infectious units (iu) of adenovirus need to be used as immunogen. Furthermore, this immune response eliminates >90% of transgene expression from 1 x 10(7)-1 x 10(3) iu of vector injected into the striatum 60 days earlier. Importantly, elimination of transgene expression is independent of the nature of the promoter that drives transgene expression and is accompanied by brain infiltration of CD8(+) T cells and macrophages. In conclusion, once the threshold for systemic immunization (i.e. 1 x 10(7) iu) is crossed, the immune response eliminates transgene expression by >90% even from brains that receive as little as 1000 iu of adenoviral vectors, independently of the type of promoter that drives expression.

745. CD4-T Cell Responses Mediated by IFNγ and Perforin Eliminate Adenoviral-Mediated Transgene Expression from the CNS of Mice by Cytolytic and Non-Cytolytic Mechanisms

Gene therapy approaches using first generation adenoviral vectors (RAds) can achieve long-term transgene expression in the brain, and therapeutic effects in animal models of brain tumors and neurodegeneration. However, long term expression and vectors' efficiency can be limited by immune responses, characterized by inflammation in the brain and the eventual elimination of transgene expression. Injection of first generation RAds into the striatum followed by peripheral immunization has allowed us to determine the cellular and molecular mechanisms by which the adaptive immune response regulates transgene expression in the CNS. Our experiments provided the following results: (1) systemic immunization against RAd reduced transgene expression by 30 days post-immunization; (2) the time course of entry of lymphocytes into the brain is as follows: first, CD4+, followed by CD45+ and F4/80+, and lastly, CD8+ T cells; (3) lymphocytes and macrophages contacted and phagocytosed transduced cells; (4) transgene expression persisted in the CNS of Rag1(|[minus]|/|[minus]|), CD4(|[minus]|/|[minus]|), IFN|[gamma]|(|[minus]|/|[minus]|) and perforin(|[minus]|/|[minus]|) animals; and (5) even in the absence of transgene expression, we could detect the presence of RAd genomes by quantitative TaqMan PCR. In summary, our data suggest the existence of a CD4-T cell response mediated by IFN|[gamma]| and potentially perforin that eliminates transgene expressing cells from the CNS. The continued presence of viral vector genomes, suggests the presence of non-cytolytic mechanisms as well. The balance of cytotoxic, and non-cytotoxic mechanisms is currently being investigated further.

Adenoviral vector-mediated gene therapy in the mouse lung: no role of Fas-Fas ligand interactions for elimination of transgene expression in bronchioepithelial cells.

The early successes of adenoviral vector-mediated gene therapies in the lung have been hampered by the immune response directed against viral proteins and transgene product. Intratracheal administration of adenovirus vector in immune-competent mice transduces bronchioepithelial cells of lung extremely efficiently; however, transgene expression is eliminated within 2 weeks. Extinction of transgene expression has been attributed to infiltrating cytotoxic T lymphocytes (CTLs). Fas-Fas ligand (Fas-FasL) interactions play a critical role in the effector function of the CTL killing. We have previously demonstrated that this interacting pair of molecules plays a critical role in elimination of transgene expression in mouse liver. In this study we investigated the role of Fas-FasL interactions in CTL effector functions in vivo in mouse lung. Analyses of these molecules in lung showed constitutive expression of Fas in bronchiooepithelial cells. On the other hand, FasL was inducible in the bronchioepithelial cells after adenovirus vector treatment. The in vivo role of the Fas-FasL interactions was determined by adoptive transfer of splenocytes from normal immune-competent mice to Fas-deficient mice (B6-lpr); likewise, the function of FasL on CTLs was analyzed by the ability of splenocytes from FasL-deficient mice (B6-gld) to eliminate transgene expression in Rag1-deficient mice. These studies demonstrate that despite expression of Fas and FasL in bronchioepithelial cells and CTLs, these interacting molecules do not play a critical role in elimination of transgene expression in the lung.

Respiratory muscles as a target for adenovirus-mediated gene therapy.

The protein dystrophin is absent in the muscles of patients with Duchenne muscular dystrophy (DMD) as well as dystrophin-deficient mice with muscular dystrophy (mdx mice). The mdx mouse diaphragm closely resembles the human DMD phenotype and thus provides a useful model for studies of dystrophin gene replacement. Recombinant adenovirus vectors (AdVs) hold promise as a means for delivering a functional dystrophin gene to muscle. As an initial step toward this goal, we have determined the efficiency and functional consequences of AdV-mediated reporter gene transfer to the diaphragm in both normal and mdx adult mice. At 1 week after AdV administration, there was a high level of transgene expression in the diaphragm. One month later, however, elimination of transgene expression was observed along with a significant decrease in force production by both normal and mdx diaphragms. Immunosuppression with cyclosporine did not augment the level of transgene expression, but a beneficial effect on diaphragm force-generating capacity was observed in both groups of animals. In order to further elucidate the cellular mechanisms underlying these findings, the effects of AdV gene inactivation (by ultraviolet (UV) irradiation) and interference with host T-lymphocyte subsets were examined. Both UV-inactivation of AdV and CD8+ T-cell deficiency were found to significantly alleviate AdV-induced reductions in diaphragm force-generating capacity. Brief (2 day) administration of a neutralizing antibody against host CD4+ T-cells also produced a trend towards mitigation of AdV-induced contractile dysfunction. In addition, transgene expression one month after AdV delivery was significantly enhanced with inhibition of either CD4+ or CD8+ T-cell function. The data suggest two major sources of reduced force generation after recombinant adenovirus vector-mediated gene transfer to muscle: 1) a cytotoxic component associated with recombinant adenovirus vector transcriptional activity; and 2) an immune-based component of more delayed onset that is primarily dependent upon CD8+ T-cell activity. These results have important implications for the design of future generation vectors and the potential need for immunosuppressive therapy after recombinant adenovirus vector mediated dystrophin gene transfer to Duchenne muscular dystrophy patients.