Early adenoviral gene expression mediates immunosuppression by transduced dendritic cell (DC): implications for immunotherapy using genetically modified DC.

Long-lasting, high-level gene expression in the absence of a toxic or inflammatory response to viral Ags is necessary for the successful application of genetically modified dendritic cell (DC). We previously demonstrated that efficient transduction of mature DC using DeltaE1DeltaE3 adenoviruses suppressed their stimulatory capacity for T cells. The current study was designed to investigate in more detail the suppressive effect of Ad-DC. We demonstrate that immunosuppression is not mediated by alterations in the T cell phenotype or cytokine profiles released by stimulated T cells. Also DC phenotypes are not affected. However, we demonstrate a cell cycle arrest of the T cell population stimulated by adenovirally transduced DC. Surprisingly, only freshly transduced DC are perturbed in their stimulatory capacity. Experiments using cycloheximide to block early intracellular viral gene expression showed that viral genes expressed in DC are responsible for this transient immunosuppression. In agreement with these findings, high-capacity (gutless) Ad-vectors that differ in viral gene expression from conventional DeltaE1DeltaE3 adenovirus are suitable for an efficient transduction of human DC. DC transduced with gutless Ad-vectors showed a high allostimulatory capacity for CD4(+) and CD8(+) T cells. Thus, the immunosuppressive effect of DeltaE1DeltaE3 Ad-transduced mature DC seems to be the result of early viral gene expression in DC that can be prevented using gutless Ad-vectors for transduction. These results have important implications for the use of genetically modified DC for therapeutic application.

Hepatocarcinoma cells constitutively expressing adenoviral E1-genes provide a tumor model for intratumoral replication of E1-deficient adenoviruses.

The elimination of malignant tumors by intratumoral virus replication is a challenging therapeutic approach but is critically dependent on the speed and efficacy of intratumoral virus spread. The expression of oncolytic transgenes in the context of a replicating virus may help to enhance the therapeutic potency of this strategy. We have established a human hepatocarcinoma-derived cell line (Huh7-E1) which stably expresses adenoviral E1-genes. Tumors derived from these cells support replication of E1-deficient adenoviruses in SCID mice. This model can be used to evaluate E1-negative viruses encoding reporter genes or oncolytic transgenes in a replicating context. Most oncolytic viruses for human use could then be re-engineered as E1-postive viruses. Moreover, Huh7-E1 tumors release human alpha-1-antitrypsin (hAAT), which allows the monitoring of occult growing tumors (i.e. liver, peritoneum) by measuring serum hAAT levels.

A midkine promoter-based conditionally replicative adenovirus for treatment of pediatric solid tumors and bone marrow tumor purging.

The treatment of advanced neuroblastoma (NB) or Ewing's sarcoma (ES) is one of the major challenges in pediatric oncology. Both malignancies are refractory to conventional therapies and have an extremely poor prognosis. High-dose myeloablative radiochemotherapy with autologous bone marrow or peripheral blood stem cell rescue is one of the most aggressive treatments attempted for these diseases but is often undermined by residual tumor cells contaminating the graft. Thus, in this approach, purging of tumor cells from the graft is key to the prevention of relapse after transplantation. We investigated a novel approach to eliminate tumor cells from the bone marrow or peripheral blood stem cell graft without causing stem cell damage through the use of a conditionally replicative adenovirus (Ad). ES and NB are sensitive to Ad infection, and advanced NBs express a high level of the growth/differentiation factor midkine (MK). We confirmed in this study that ES cell lines (SK-ES-1 and RD-ES) are also sensitive to Ad infection and express high levels of MK. In contrast, CD34+ stem cells are refractory to Ad infection and express very little MK. A conditionally replicative Ad in which the expression of E1 is controlled by the MK promoter achieved good levels of viral replication in NB or ES and induced remarkable tumor cell killing. On the other hand, this virus caused no damage to CD34+ cells even after 3 h of infection at a dose of 1000 multiplicity of infection. We concluded that application of this replication-competent Ad to hematopoietic grafts could be a simple but effective procedure to achieve complete tumor cell purging.

In vitro and in vivo biology of recombinant adenovirus vectors with E1, E1/E2A, or E1/E4 deleted.

Isogenic, E3-deleted adenovirus vectors defective in E1, E1 and E2A, or E1 and E4 were generated in complementation cell lines expressing E1, E1 and E2A, or E1 and E4 and characterized in vitro and in vivo. In the absence of complementation, deletion of both E1 and E2A completely abolished expression of early and late viral genes, while deletion of E1 and E4 impaired expression of viral genes, although at a lower level than the E1/E2A deletion. The in vivo persistence of these three types of vectors was monitored in selected strains of mice with viral genomes devoid of transgenes to exclude any interference by immunogenic transgene-encoded products. Our studies showed no significant differences among the vectors in the short-term maintenance and long-term (4-month) persistence of viral DNA in liver and lung cells of immunocompetent and immunodeficient mice. Furthermore, all vectors induced similar antibody responses and comparable levels of adenovirus-specific cytotoxic T lymphocytes. These results suggest that in the absence of transgenes, the progressive deletion of the adenovirus genome does not extend the in vivo persistence of the transduced cells and does not reduce the antivirus immune response. In addition, our data confirm that, in the absence of transgene expression, mouse cellular immunity to viral antigens plays a minor role in the progressive elimination of the virus genome.

Advances in adenoviral vectors: from genetic engineering to their biology.

Ad2 and Ad5 belong to a group of human cytolytic viruses that target the respiratory airways for reproduction, whereas latent infections establish within other tissues. Signals therefore exist that control this dichotomic process in different cell types, perhaps including cis and/or trans elements of viral origin. Since 1993, Ad2- and Ad5-based adenoviruses lacking all or part of the E1 regulatory region have been undergoing evaluation in phase I trials that target cancer and cystic fibrosis. These viruses are extremely attenuated and actually do not reproduce in most human cells. However, they retain most of the virus genetic program and often promote a significant cytotoxicity after infection, emphasizing the need to further cripple the virus biology to extend the duration of transgene expression, if required. We will review the strategies currently followed to engineer a professional lytic virus for epithelial cells into an innocuous gene delivery vehicle. Potential effects on the transducing properties of the vector that may result from the inactivation of viral activities that normally allow/regulate extrachromosomal gene expression during wild-type infection are discussed.

A gene transfer vector-cell line system for complete functional complementation of adenovirus early regions E1 and E4.

The improvements to adenovirus necessary for an optimal gene transfer vector include the removal of virus gene expression in transduced cells, increased transgene capacity, complete replication incompetence, and elimination of replication-competent virus that can be produced during the growth of first-generation adenovirus vectors. To achieve these aims, we have developed a vector-cell line system for complete functional complementation of both adenovirus early region 1 (E1) and E4. A library of cell lines that efficiently complement both E1 and E4 was constructed by transforming 293 cells with an inducible E4-ORF6 expression cassette. These 293-ORF6 cell lines were used to construct and propagate viruses with E1 and E4 deleted. While the construction and propagation of AdRSV beta gal.11 (an E1-/E4- vector engineered to contain a deletion of the entire E4 coding region) were possible in 293-ORF6 cells, the yield of purified virus was depressed approximately 30-fold compared with that of E1- vectors. The debilitation in AdRSV beta gal.11 vector growth was found to correlate with reduced fiber protein and mRNA accumulation. AdCFTR.11A, a modified E1-/E4- vector with a spacer sequence placed between late region 5 and the right inverted terminal repeat, efficiently expressed fiber and grew with the same kinetic profile and virus yield as did E1- vectors. Moreover, purified AdCFTR.11A yields were equivalent to E1- vector levels. Since no overlapping sequences exist in the E4 regions of E1-/E4- vectors and 293-ORF6 cell lines, replication-competent virus cannot be generated by homologous recombination. In addition, these second-generation E1-/E4- vectors have increased transgene capacity and have been rendered virus replication incompetent outside of the new complementing cell lines.