From secretome analysis to immunology: chitosan induces major alterations in the activation of dendritic cells via a TLR4-dependent mechanism.

Dendritic cells are known to be activated by a wide range of microbial products, leading to cytokine production and increased levels of membrane markers such as major histocompatibility complex class II molecules. Such activated dendritic cells possess the capacity to activate naïve T cells. In the present study we demonstrated that immature dendritic cells secrete both the YM1 lectin and lipocalin-2. By testing the ligands of these two proteins, chitosan and siderophores, respectively, we also demonstrated that chitosan, a degradation product of various fungal and protozoal cell walls, induces an activation of dendritic cells at the membrane level, as shown by the up-regulation of membrane proteins such as class II molecules, CD80 and CD86 via a TLR4-dependent mechanism, but is not able to induce cytokine production. This led to the production of activated dendritic cells unable to stimulate T cells. However, costimulation with other microbial products overcame this partial activation and restored the capacity of these activated dendritic cells to stimulate T cells. In addition, successive stimulation with chitosan and then by lipopolysaccharide induced a dose-dependent change in the cytokinic IL-12/IL-10 balance produced by the dendritic cells.

Distinct effects of DNA-PKcs and Artemis inactivation on signal joint formation in vivo.

The assembly of functional immune receptor genes via V(D)J recombination in developing lymphocytes generates DNA double-stranded breaks intermediates that are repaired by non-homologous end joining (NHEJ). This repair pathway requires the sequential recruitment and activation onto coding and signal DNA ends of several proteins, including the DNA-dependent protein kinase and the nuclease Artemis. Artemis activity, triggered by the DNA-dependent protein kinase, is necessary to process the genes hairpin-sealed coding ends but appears dispensable for the ligation of the reciprocal phosphorylated, blunt-ended signal ends into a signal joint. The DNA-dependent protein kinase is however present on signal ends and could potentially recruit and activate Artemis during signal joint formation. To determine whether Artemis plays a role during the resolution of signal ends during V(D)J recombination, we analyzed the structure of signal joints generated in developing thymocytes during the rearrangement of T cell receptor genes in wild type mice and mice mutated for NHEJ factors. These joints exhibit junctional diversity resulting from N nucleotide polymerization by the terminal nucleotidyl transferase and nucleotide loss from one or both of the signal ends before they are ligated. Our results show that Artemis participates in the repair of signal ends in vivo. Furthermore, our results also show that while the DNA-dependent protein kinase complex protects signal ends from processing, including deletions, Artemis seems on the opposite to promote their accessibility to modifying enzymes. In addition, these data suggest that Artemis might be the nuclease responsible for nucleotide loss from signal ends during the repair process.

Biosensor for direct cell detection, quantification and analysis.

Microarrays are promising tools for cell isolation and detection. However, they have yet to be widely applied in biology. This stems from a lack of demonstration of their sensitivity and compatibility with complex biological samples, and a lack of proof that their use does not induce aberrant cellular effects. Herein, we characterized and optimized a recently developed technology associating antibody microarrays with surface plasmon resonance imaging (SPRi). Using a murine macrophage cell line we demonstrate the binding specificity of our antibody-microarrays and the correlation between SPRi signals and both the number of bound cells, and the level of expression of cell surface markers. Confocal microscopy reveals that cell binding to the chip through antibody-antigen interactions underwent morphological changes reflecting the density of the relevant cell surface marker without affecting cell viability as shown by fluorescent microscopy. The detection threshold of the microarray-SPRi system is lowered 10-fold by applying a polyethylene oxide film to the gold surface of the chip. This increased sensitivity allows the detection of cells representing as little as 0.5% of a mixed population. The potential of this method is illustrated by two applications: characterization of ligand-cell receptor interactions, allowing determination of receptor specificity, and analysis of peripheral blood mononuclear cells, demonstrating the suitability of this tool for the analysis of complex biological samples.

Analysis of the toxicity of gold nano particles on the immune system: effect on dendritic cell functions.

The effect of manufactured gold nanoparticles (NP) on the immune system was analysed through their ability to perturb the functions of dendritic cells (DC), a major actor of both innate and acquired immune responses. For this purpose, DCs were produced in culture from mouse bone marrow progenitors.The analysis of the viability of the cells after their incubation in the presence of gold NP shows that these NP are not cytotoxics even at high concentration. Furthermore, the phenotype of the DC is unchanged after the addition of NP, indicating that there is no activation of the DC. But the analysis of the cells at the intracellular level reveals important amounts of gold NP amassing in endocytic compartments. Furthermore, the secretion of cytokines is significantly modified after such internalisation indicating a potential perturbation of the immune response.