Down-regulation of retroviral transgene expression during differentiation of progenitor-derived dendritic cells

piggyBac transposon plus insulators overcome epigenetic silencing to provide for stable signaling pathway reporter cell lines

Genetically modified hematopoietic progenitors represent an important testing platform for a variety of cell-based therapies, pharmaceuticals, diagnostics and other applications. Stable expression of a transfected gene of interest in the cells is often obstructed by its silencing. DNA transposons offer an attractive non-viral alternative of transgene integration into the host genome, but their broad applicability to leukocytes and other "transgene unfriendly" cells has not been fully demonstrated. Here we assess stability of piggyBac transposon-based reporter expression in murine prostate adenocarcinoma TRAMP-C2, human monocyte THP-1 and erythroleukemia K562 cell lines, along with macrophages and dendritic cells (DCs) that have differentiated from the THP-1 transfects. The most efficient and stable reporter activity was observed for combinations of the transposon inverted terminal repeats and one 5'- or two cHS4 core insulators flanking a green fluorescent protein reporter construct, with no detectable silencing over 10 months of continuous cell culture in absence of any selective pressure. In monocytic THP-1 cells, the functional activity of luciferase reporters for NF-κB, Nrf2, or HIF-1α has not decreased over time and was retained following differentiation into macrophages and DCs, as well. These results imply pB as a versatile tool for gene integration in monocytic cells in general, and as a convenient access route to DC-based signaling pathway reporters suitable for high-throughput assays, in particular.

Lentiviral-mediated transcriptional targeting of dendritic cells for induction of T cell tolerance in vivo

Dendritic cells (DCs) are important APCs able to induce both tolerance and immunity. Therefore, DCs are attractive targets for immune intervention. However, the ex vivo generation and manipulation of DCs at sufficient numbers and without changing their original phenotypic and functional characteristics are major obstacles. To manipulate DCs in vivo, we developed a novel DC-specific self-inactivating lentiviral vector system using the 5' untranslated region from the DC-STAMP gene as a putative promoter region. We show that a gene therapy approach with these DC-STAMP-lentiviral vectors yields long-term and cell-selective transgene expression in vivo. Furthermore, transcriptionally targeted DCs induced functional, Ag-specific CD4 and CD8 T cell tolerance in vivo, which could not be broken by viral immunization. Tolerized CTL were unable to induce autoimmune diabetes in a murine autoimmune model system. Therefore, delivering transgenes specifically to DCs by using viral vectors might be a promising tool in gene therapy.

An immunotherapy approach with dendritic cells genetically modified to express the tumor-associated antigen, HER2

Dendritic cells (DC), genetically modified to express ovalbumin by the retroviral vector GCDNsap, can elicit stronger anti-tumor immunity than those loaded with the peptides. To assess the clinical feasibility of the strategy, such DC were prepared by differentiation of hematopoietic progenitor cells transduced with the human epidermal growth factor receptor 2 (HER2). When inoculated in mice, the DC primed both HER2-specific cytotoxic T lymphocytes and type 1 T helper lymphocytes, resulting in production of HER2-specific antibody. Of importance is that the antibody mediated antibody-dependent cellular cytotoxicity and opsonization. The potent anti-tumor effects were also confirmed by results of experiments using HER2-transgenic mice. Inoculation of HER2-transduced DC resulted in longer disease-free survival of treated mice that showed significant reduction of primary and metastatic tumors. Interestingly, footpad inoculation resulted in stronger anti-tumor effects compared to subcutaneous administration and induced higher levels of the HER2-specific antibody, suggesting that an important role of humoral immunity in anti-tumor effects for malignancies with membrane-type tumor-associated antigens (TAA). Taken together, vaccination of the TAA-transduced DC may represent a promising form of therapy for breast cancers expressing HER2.

Hematopoietic stem cell-targeted neonatal gene therapy reverses lethally progressive osteopetrosis in oc/oc mice

Infantile malignant osteopetrosis (IMO) is a fatal disease caused by lack of functional osteoclasts, and the only available treatment is hematopoietic stem cell (HSC) transplantation. In the majority of patients, the TCIRG1 gene, coding for a subunit of a proton pump essential for bone resorption, is mutated. Oc/oc mice have a deletion in the homologue gene (tcirg1) and die at 3 to 4 weeks, but can be rescued by neonatal transplantation of HSCs. Here, HSC-targeted gene therapy of osteopetrosis in the oc/oc mouse model was developed. Oc/oc fetal liver cells depleted of Ter119-expressing erythroid cells were transduced with a retroviral vector expressing tcirg1 and GFP, and subsequently transplanted intraperitoneally to irradiated neonatal oc/oc mice. Eight of 15 mice survived past the normal life span of oc/oc mice. In vitro osteoclastogenesis revealed formation of GFP-positive osteoclasts and bone resorption, albeit at a lower level than from wild-type cells. The skeletal phenotype was analyzed by X-ray and histopathology and showed partial correction at 8 weeks and almost normalization after 18 weeks. In summary, osteopetrosis in oc/oc mice can be reversed by neonatal transplantation of gene-modified HSCs leading to long-term survival. This represents a significant step toward the development of gene therapy for osteopetrosis.

Potent Vaccine Therapy with Dendritic Cells Genetically Modified by the Gene-Silencing-Resistant Retroviral Vector GCDNsap

Dendritic cells (DCs) genetically modified to express tumor-associated antigens (TAAs) would be promising tools in cancer immunotherapy. However, the use of retroviral vectors for such modifications is still a challenge because of low transduction efficiency and gene silencing in DCs. We have established an efficient method to prepare such DCs by in vitro differentiation of hematopoietic progenitor cells transduced with chicken ovalbumin (OVA) cDNA via the gene-silencing-resistant retroviral vector GCDNsap packaged in vesicular stomatitis virus G protein. When c-KIT(+)/lineage(-) cells were transduced with OVA followed by expansion and differentiation, more than 90% of mature DCs expressed the transgene. Mice inoculated with those cells completely rejected the OVA-expressing tumor E.G7-OVA, and the anti-tumor effects were stronger than those observed in mice inoculated with the same number of OVA peptide-pulsed DCs. The mice harbored more cytotoxic T lymphocytes (CTLs) against E.G7-OVA and produced antibody against OVA, suggesting the generation of multiple CTLs recognizing different OVA epitopes and OVA-specific CD4(+) T cells. Successive inoculations of the transduced DCs in a therapeutic setting eradicated preexisting E.G7-OVA and prevented the progression of retransplanted tumors. Thus, this vaccine therapy may represent a potent immunotherapeutic approach for various malignant tumors that express suitable TAAs.

Loss of gene expression in lentivirus- and retrovirus-transduced neural progenitor cells is correlated to migration and differentiation in the adult spinal cord

Gene transfer into multipotent neural progenitor cells (NPC) and stem cells may provide for a cell replacement therapy and allow the delivery of therapeutic proteins into the degenerating or injured nervous system. Previously, murine leukemia virus-based retroviral vectors expressing GFP from an internal EF-1alpha promoter and lentiviral vectors expressing GFP from a hybrid CMV/beta-actin promoter have been described to be resistant to stem cell specific gene silencing. Therefore, we investigated whether these viral vectors allow stable in vivo gene expression in genetically modified NPC isolated from the adult rat spinal cord. In vitro, NPC genetically modified to express GFP using the described retroviral vector showed strong GFP expression in undifferentiated NPC. However, in vitro differentiation resulted in the loss of GFP expression in 50% of cells. Grafting of BrdU-prelabeled NPC to the spinal cord resulted in a loss of GFP expression in 70% and 95% of surviving NPC at 7 and 28 days post-grafting, respectively. The loss in gene expression was paralleled by the differentiation of NPC into a glial phenotype. Transgene downregulation although less profound was also observed in cells modified with lentiviral vectors, whereas in vivo lentiviral gene transfer resulted in stable transgene expression for up to 16 months. Thus, in vivo gene expression in genetically engineered neural progenitor cells is temporally limited and mostly restricted to undifferentiated NPC using the viral vectors tested.

Lentiviral transduction of human hematopoietic cells by HIV-1- and SIV-based vectors containing a bicistronic cassette driven by various internal promoters

BACKGROUND

Lentiviral gene transfer into hematopoietic cells has been mostly optimized with vectors carrying a single reporter gene. For many clinical applications, lentiviral vectors should contain more than one gene because transduced cells should be enriched by a selectable marker or killed for safety reasons after use. Thus, we compared various vectors containing a bicistronic cassette driven by different ubiquitous promoters for their ability to transduce human T-lymphocytes, CD34+-cells, and dendritic cells (DCs) derived from CD34+-cells or monocytes.

METHODS

We designed HIV or SIV constructs containing a bicistronic cassette composed of two reporter genes (thy1/GFP) linked by an internal ribosome entry site sequence and driven by the cytomegalovirus (CMV) or elongation factor 1alpha (EF1alpha) promoters. The woodchuck hepatitis virus post-transcriptional regulatory element (WPRE) was or not inserted within the constructs, the Vpx accessory protein was or not used for SIV vectors. Target cells were infected at the same multiplicity of infection, transduction efficiency was analyzed both by flow cytometry and vector integration.

RESULTS

For T-cells, HIV-based vectors/WPRE+ in which the thy1/GFP cassette was driven by the EF1alpha promoter were more efficient than SIV-based vectors. For CD34+-cells and CD34+-derived DCs, better thy1/GFP expression was achieved when the CMV promoter drove the cassette inserted into HIV-based vectors/WPRE+. Conversely, for monocyte-derived DCs, the cassette yielded better thy1/GFP expression when inserted into SIV-based vectors/WPRE+ and driven by the CMV or EF1alpha promoters, the use of Vpx significantly improving the expression levels.

CONCLUSIONS

Our results provide guidelines for improving the transduction of T-cells, CD34+-cells or DCs with lentiviral bicistronic vectors designed for clinical applications.

Efficient transduction and long-term retroviral expression of the melanoma-associated tumor antigen tyrosinase in CD34(+) cord blood-derived dendritic cells

Differentiation of genetically modified CD34(+) hematopoietic stem cells into dendritic cells (DCs) will contribute to the development of immunotherapeutic anticancer protocols. Retroviral vectors that have been used for the transduction of CD34(+) cells face the problem of gene silencing when integrated into the genome of repopulating stem cells. We reasoned that a high copy number of retroviral DNA sequences might overcome silencing of transgene expression during expansion and differentiation of progenitor cells into functional DCs. To prove this, we utilized a retroviral vector with bicistronic expression of the melanoma-associated antigen tyrosinase and the enhanced green fluorescent protein (EGFP). Human cord blood CD34(+) cells were transduced with vesicular stomatitis virus G-protein (VSV-G) pseudotyped Moloney murine leukemia virus (MoMuLV) particles using 100-150 multiplicity of infection. During expansion of transduced cells with immature phenotype, transgene expression was strongly silenced, but upon differentiation into mature DCs, residual transgene expression was retained. Intracellular processing of the provirally expressed tyrosinase was tested in a chromium release assay utilizing a cytotoxic T cell clone specific for a HLA-A*0201-restricted tyrosinase peptide. We suggest that retroviral transduction of tumor-associated antigens in hematopoietic progenitor cells and subsequent differentiation into DCs is a suitable basis for the development of potent anti-tumor vaccines.

Cellular vaccine therapy for cancer

Observations that cells of the immune system are able to kill tumor cells both in vitro and in animal models have provided a compelling rationale for pursuit of a strategy whereby immune cells are administered as a therapeutic vaccine to patients with cancer. The successful outcome of this approach depends upon the ability to deliver this therapy in a manner in which a potent immune response is elicited. By harnessing the capacity of dendritic cells that are pivotal in priming the immune response and using gene therapy approaches to optimise the immune response, this may ultimately prove efficacious in the management of human cancer. Promising reports from recent clinical trials suggest that this may well be a realistic goal.