Minimal size MIDGE vectors improve transgene expression in vivo.

Viral and plasmid vectors may cause immunological side-effects resulting from the expression of therapeutically unwanted genes and from CpG motifs contained in their sequence. A new vector type for minimalistic, immunological-defined gene expression (MIDGE) may overcome these problems. MIDGE is a minimal size gene transfer unit consisting of the expression cassette, including promotor, gene and RNA-stabilizing sequences, flanked by two short hairpin oligonucleotide sequences. DNA not encoding the desired gene is reduced to a minimum. To compare transfection efficiencies in vivo hydrodynamics-based, systemic transfection was performed in BALB/c mice with MIDGE vectors and corresponding plasmids. The transfection efficiencies of the MIDGE vectors as measured by luciferase expression were significantly higher in liver (2.5-fold), lung (3.5-fold), kidneys (3.9-fold) and heart (17-fold) as compared to plasmids. The mean numbers of MIDGE vector molecules per cell as measured by quantitative PCR were also significantly higher. These advantages suggest the preferential use of this new vector type for clinical gene therapy studies.

Novel non-viral method for transfection of primary leukemia cells and cell lines.

BACKGROUND: Tumor cells such as leukemia and lymphoma cells are possible targets for gene therapy. However, previously leukemia and lymphoma cells have been demonstrated to be resistant to most of non-viral gene transfer methods. METHODS: The aim of this study was to analyze various methods for transfection of primary leukemia cells and leukemia cell lines and to improve the efficiency of gene delivery. Here, we evaluated a novel electroporation based technique called nucleofection. This novel technique uses a combination of special electrical parameters and specific solutions to deliver the DNA directly to the cell nucleus under mild conditions. RESULTS: Using this technique for gene transfer up to 75% of primary cells derived from three acute myeloid leukemia (AML) patients and K562 cells were transfected with the green flourescent protein (GFP) reporter gene with low cytotoxicity. In addition, 49(+/- 9.7%) of HL60 leukemia cells showed expression of GFP. CONCLUSION: The non-viral transfection method described here may have an impact on the use of primary leukemia cells and leukemia cell lines in cancer gene therapy.

Generation of activated and antigen-specific T cells with cytotoxic activity after co-culture with dendritic cells.

Co-culturing of immunological effector cells with antigen-pulsed DC leads to an increase of cytotoxic activity against antigen-expressing tumour cells. Using this approach, we could detect up to 2.8% antigen-specific CTLs after co-culture with antigen-pulsed DC. However, the required high effector cell numbers remain a major obstacle in immunotherapy. In this study, we show an approach for generating activated and antigen-specific effector cells that enables us to decrease effector to target cell ratios. We used an interferon-gamma secretion assay to enrich activated effector cells after co-culture with antigen-pulsed dendritic cells (DC). Purified immunological effector cells lysed 58.3% of antigen-expressing tumour cells at an effector to target ratio of 1:1. Furthermore, using MHC-IgG complexes, we enriched effector cells expressing antigen-specific T-cell receptor after co-culture with DC. Performing ELISpot, flow cytometry and TCR analysis, we could show a significant increase of activated and specific TCR-expressing effector cells after co-culture with DC.