RNA interference-mediated gene silencing in murine T cells: in vitro and in vivo validation of proinflammatory target genes.

BACKGROUND: T cells play a central role in many inflammatory diseases, hence the identification and validation of T cell-specific target genes will increase the understanding of T cell function in pathologic inflammatory situations. RNA interference (RNAi), with its ability to induce specific gene silencing in mammalian cells, represents a powerful technology to investigate and validate the function of pharmaceutical target genes in vitro and in vivo. The aim of the present study was to systematically explore RNAi-mediated gene-silencing of known T cell-specific model signaling molecules in primary murine T cells in vitro and in vivo. RESULTS: We demonstrate that siRNA delivery and subsequent silencing of T cell specific genes is substantially increased, if murine T cells were activated prior siRNA transfection. Silencing of ZAP70, p56Lck as well as PLC-gamma1 protein expression resulted in impaired function of T cells in vitro. Furthermore, delayed type hypersensitivity (DTH) was ameliorated in vivo after adoptive transfer of ZAP70-silenced T cells. CONCLUSION: The combination of RNAi-mediated gene silencing and adoptive transfer of gene-silenced T cells, thus, may allow the identification and analysis of T cell-specific targets for therapeutic intervention. Additionally, this model system may represent an alternative to conventional time consuming and cost intensive gene targeting approaches.

Fate of Chlamydophila pneumoniae in human monocyte-derived dendritic cells: long lasting infection.

Earlier studies from this group demonstrated that Chlamydophila pneumoniae co-localized with dendritic cells (DC) in temporal artery biopsies from patients with giant cell arteritis (GCA). To investigate the interaction of DC with C. pneumoniae we employed an in vitro cell culture system of human monocyte derived DC. These DC were infected with C. pneumoniae and observed at regular time intervals up to 25 days post infection. Chlamydiae were visualized inside DC by both confocal and electron microscopy. Statistical analysis showed an increase in the number of chlamydial antigen during that period (p < 0.00005, chi2-test). Titration of DC lysates on HEp-2 cells showed that infectious progeny was recovered at various intervals but showed no exponential growth. Additionally, RT-PCR analyses of infected DC identified transcripts from dnaA, ftsK and tal throughout a period of 14 days, indicating viable chlamydiae. Thus, human monocyte-derived DC are susceptible to C. pneumoniae infection. These results indicate that C. pneumoniae-infected DC can play an important role in the transmission of these bacteria in GCA and other chlamydial diseases.

RNA transfer and its use in dendritic cell-based immunotherapy.

RNA is a key macromolecule for the mobilisation and interpretation of genetic information. Research has sought to exploit the inherent properties of RNA, such as the direct production of proteins in the cytoplasm without the need for nuclear translocation. This property makes the delivery of genes into postmitotic cells especially attractive. Recently, RNA transfer into postmitotic dendritic cells (DCs) has emerged as a potential new therapeutic agent in the area of immunotherapy. DCs are the most important regulators of the immune system. Thus, transfecting DCs with RNA allows the specific manipulation of immune responses and, thereby, the treatment of a variety of diseases, such as cancer. Preclinical studies have demonstrated that RNA-transduced DCs efficiently stimulate antigen-specific T cell responses in vitro and in animal tumour models. In addition, the clinical data from Phase I and II trials of tumour patients indicate that RNA-transduced DCs represent a promising approach for the development of future vaccination strategies. The use of RNA molecules as therapeutic agents is a relatively new approach in the treatment of diseases, such as cancer, but has received increasing attention during the past decade. Especially in the field of immunotherapy, the inherent properties of RNA molecules in combination with immunostimulating dendritic cells (DCs) are being investigated at present for their beneficial therapeutic effect. Immunotherapy is based on the stimulation of the patient's immune system to recognise and eliminate infected cells or tumour cells in an antigen-specific manner. Current approaches focus on the stimulation of CD8(+) cytotoxic T lymphocyte responses, as well as on the induction of CD4(+) T helper cell responses, in order to obtain optimal and sustained immune responses capable of eliminating altered cells. This review mainly focuses on the potential use of RNA-transduced DCs as a therapeutic strategy in the treatment of cancer, as current studies on the treatment of infectious diseases are just beginning.

Progressive and controlled development of mouse dendritic cells from Flt3+CD11b+ progenitors in vitro.

Dendritic cells (DC) represent key regulators of the immune system, yet their development from hemopoietic precursors is poorly defined. In this study, we describe an in vitro system for amplification of a Flt3(+)CD11b(+) progenitor from mouse bone marrow with specific cytokines. Such progenitor cells develop into both CD11b(+) and CD11b(-) DC, and CD8alpha(+) and CD8alpha(-) DC in vivo. Furthermore, with GM-CSF, these progenitors synchronously differentiated into fully functional DC in vitro. This two-step culture system yields homogeneous populations of Flt3(+)CD11b(+) progenitor cells in high numbers and allows monitoring the consecutive steps of DC development in vitro under well-defined conditions. We used phenotypic and functional markers and transcriptional profiling by DNA microarrays to study the Flt3(+)CD11b(+) progenitor and differentiated DC. We report here on an extensive analysis of the surface Ag expression of Flt3(+)CD11b(+) progenitor cells and relate that to surface Ag expression of hemopoietic stem cells. Flt3(+)CD11b(+) progenitors studied exhibit a broad overlap of surface Ags with stem cells and express several stem cell Ags such as Flt3, IL-6R, c-kit/SCF receptor, and CD93/AA4.1, CD133/AC133, and CD49f/integrin alpha(6). Thus, Flt3(+)CD11b(+) progenitors express several stem cell surface Ags and develop into both CD11b(+) and CD11b(-) DC, and CD8alpha(+) and CD8alpha(-) DC in vivo, and thus into both of the main conventional DC subtypes.

RNA-containing adenovirus/polyethylenimine transfer complexes effectively transduce dendritic cells and induce antigen-specific T cell responses.

BACKGROUND: Dendritic cells (DCs) are the most potent antigen-presenting cells in initiating primary immune responses. Given the unique properties of DCs, gene-modified DCs represent a particularly attractive approach for immunotherapy of diseases such as cancer. METHODS: Gene-modified DCs were obtained by a receptor-mediated gene delivery system using adenovirus (Ad) particles as ligand and RNA or DNA condensed by polyethylenimine (PEI). In vitro transcribed polyadenylated or non-polyadenylated RNA was used. RNA-transduced DCs were generated expressing chicken ovalbumin (OVA) or chimeric constructs thereof, and compared with DNA-transduced DCs. RESULTS: Ad/PEI transfection complexes efficiently delivered RNA into DCs. Such RNA-transduced DCs induced OVA-specific T cell responses more effectively than DNA-transduced DCs. Furthermore, DCs transduced with polyadenylated RNA were more potent in stimulating CD4(+) and CD8(+) T cell responses than DCs transduced with non-polyadenylated RNA and this was particularly important for CD4(+) T cell responses. CONCLUSIONS: Ad/PEI/RNA transfection is an efficient means for generating RNA-transduced DCs and for stimulating antigen-specific T cell responses. Polyadenylation of RNA enhances CD8(+) T cell responses and is essential for CD4(+) T cell responses.

Transcriptional profiling identifies Id2 function in dendritic cell development.

Dendritic cells (DCs) are potent antigen-presenting cells with a pivotal role in antigen-specific immune responses. Here, we found that the helix-loop-helix transcription factor Id2 is up-regulated during DC development in vitro and crucial for the development of distinct DC subsets in vivo. Id2-/- mice lack Langerhans cells (LCs), the cutaneous contingent of DCs, and the splenic CD8alpha+ DC subset is markedly reduced. Mice deficient for transforming growth factor (TGF)-beta also lack LCs, and we demonstrate here that, in DCs, TGF-beta induces Id2 expression. We also show that Id2 represses B cell genes in DCs. These findings reveal a TGF-beta-Id2 signaling pathway in DCs and suggest a mechanism by which Id2 affects the lineage choice of B cell and DC progenitors.

The impact of c-met/scatter factor receptor on dendritic cell migration.

Dendritic cells (DC) are professional antigen-presenting cells that possess both migratory properties and potent T cell stimulatory activity, and that allow the uptake of antigenic material inperipheral tissues and its subsequent presentation in the T cell areas of lymphoid organs. Thus motility represents a central property that is required for DC function. Here we report on the expression of the receptor tyrosine kinase c-met in DC. c-Met is the high affinity receptor for scatter factor (SF)/hepatocyte growth factor, and ligand-activated c-met exhibits mitogenic, morphogenic andmotogenic activity in vivo and in vitro. c-Met is signaling competent in DC since it is effectively tyrosine phosphorylated in response to SF ligand. It is demonstrated here that ligand-activated c-met regulates DC adhesion to the extracellular matrix component laminin but leaves antigen presenting function unaffected. Importantly, in ear sheet explant experiments activationof c-met by ligand induces emigration of cutaneous DC (Langerhans cell, LC) from skin, but SF is not a chemoattractant factor for DC. Our results suggest an important role of the c-met/SF system in DC/LC migration.

Receptor-mediated gene delivery.

Receptor-mediated gene delivery capitalises on the presence of specific cell surface molecules for DNA uptake into cells and represents a particularly appealing approach for targeting vector DNA to specific cell types in vivo and in vitro. Various ligand/DNA and antibody/DNA transfer complexes were generated that, following binding to cells, are internalised and reach the endosomal compartment. Vector complexes contain endosomolytic components that ensure vector release from the endosome and translocation of vector DNA into the nucleus where transcription occurs. Thus, receptor-mediated gene delivery encompasses several critical steps that must be considered when designing and applying such vector systems.