ATP confers tumorigenic properties to dendritic cells by inducing amphiregulin secretion.

ATP, which has an important proinflammatory action as danger signal, induces the semimaturation of dendritic cells (DCs) that can be associated with immune tolerance. We identified epidermal growth factor receptor ligands as target genes of ATPγS, a slowly hydrolyzed ATP derivative, by a gene profiling approach in DCs. Amphiregulin was the most highly up-regulated gene in response to ATPγS. Human monocyte-derived DCs and mouse bone marrow-derived DCs released amphiregulin (AREG) after purinergic receptor activation, with a contribution of P2Y(11) and A(2B) receptor, respectively. Supernatants of LPS+ATPγS-stimulated DCs induced smooth muscle cell and Lewis Lung Carcinoma (LLC) cell growth in vitro. The coinjection of LPS+ATPγS-stimulated DCs or their supernatants with LLC cells increased tumor weight in mice compared with LPS-treated DCs. The preincubation of LPS+ATPγS-treated DC supernatants with an anti-AREG blocking antibody inhibited their positive effect on smooth muscle cell density and tumor growth. The present study demonstrates for the first time that DCs can be a source of AREG. ATP released from tumor cells might exert a tumorigenic action by stimulating the secretion of AREG from DCs. Antagonists of purinergic receptors expressed on DCs and anti-AREG blocking antibodies could have a therapeutic potential as antitumor agents.

Gene expression profiling defines ATP as a key regulator of human dendritic cell functions.

Extracellular ATP and PGE2 are two cAMP-elevating agents inducing semimaturation of human monocyte-derived dendritic cells (MoDCs). We have extensively compared the gene expression profiles induced by adenosine 5'-O-(3-thiotriphosphate) (ATPgammaS) and PGE2 in human MoDCs using microarray technology. At 6 h of stimulation, ATPgammaS initiated an impressive expression profile compared with that of PGE2 (1125 genes compared with 133 genes, respectively) but after 24 h the number of genes regulated by ATPgammaS or PGE2 was more comparable. Many target genes involved in inflammation have been identified and validated by quantitative RT-PCR experiments. We have then focused on novel ATPgammaS and PGE2 target genes in MoDCs including CSF-1, MCP-4/CCL13 chemokine, vascular endothelial growth factor-A, and neuropilin-1. ATPgammaS strongly down-regulated CSF-1 receptor mRNA and CSF-1 secretion, which are involved in monocyte and dendritic cell (DC) differentiation. Additionally, ATPgammaS down-regulated several chemokines involved in monocyte and DC migration including CCL2/MCP-1, CCL3/MIP-1alpha, CCL4/MIP-1beta, CCL8/MCP-2, and CCL13/MCP-4. Interestingly, vascular endothelial growth factor A, a major angiogenic factor displaying immunosuppressive properties, was secreted by MoDCs in response to ATPgammaS, ATP, or PGE2, alone or in synergy with LPS. Finally, flow cytometry experiments have demonstrated that ATPgammaS, ATP, and PGE2 down-regulate neuropilin-1, a receptor playing inter alia an important role in the activation of T lymphocytes by DCs. Our data give an extensive overview of the genes regulated by ATPgammaS and PGE2 in MoDCs and an important insight into the therapeutic potential of ATP- and PGE2-treated human DCs.

Combined effect of pH and concentration on the activities of gentamicin and oxacillin against Staphylococcus aureus in pharmacodynamic models of extracellular and intracellular infections.

BACKGROUND: Staphylococcus aureus survives in acid media, including phagolysosomes. Conflicting in vitro/in vivo data exist on its susceptibility to antibiotics in such environments. METHODS: Oxacillin and gentamicin activities against methicillin-susceptible S. aureus ATCC 25923 were compared extracellularly (broth; different pH) and assessed intracellularly (THP-1 macrophages), using a pharmacological approach (antibiotic concentrations: 0.01-1000 x MIC). Antibiotic cellular contents were determined by microbiological assay. RESULTS: MICs and MBCs increased 72-fold for gentamicin, and decreased 8-fold for oxacillin between pH 7.4 and 5.0. Plots of log(10) colony-forming unit changes at 24 h versus log(10) of antibiotic concentration followed sigmoidal shapes, allowing calculation of EC(50) (relative potency) and apparent E(max) (relative efficacy) in all conditions. In broth, the EC(50) of gentamicin rose 316-fold and that of oxacillin decreased 15-fold with unchanged apparent E(max) [-5 log (limit of detection)] between pH 7.4 and 5. Intracellularly, EC(50)s were similar to those observed extracellularly at pH 7.4, but E(max) values were much lower (-1 log) for both antibiotics. Calculations based on the assumed pH in phagolysosomes (5.4) and on local accumulation of antibiotics (gentamicin, 23-fold; oxacillin, 0.05-fold) suggest that the contrasting effects of acid pH on relative potencies of gentamicin and oxacillin could be almost exactly compensated for by differences in accumulation. CONCLUSIONS: The weak activity of gentamicin and oxacillin towards intraphagocytic S. aureus compared with extracellular forms is not related to an overall decrease of their relative potencies but to impaired efficacy, suggesting the need for new approaches to improve the eradication of intracellular S. aureus.