Rapid lipopolysaccharide-induced differentiation of CD14(+) monocytes into CD83(+) dendritic cells is modulated under serum-free conditions by exogenously added IFN-gamma and endogenously produced IL-10.

We showed previously that about half of purified CD14(+) peripheral blood monocytes cultured under serum-free conditions and treated with GM-CSF and bacterial LPS rapidly (2 - 4 day) differentiate into CD83(+) dendritic cells (DC). The remaining cells retain the CD14(+)/CD83(-) monocyte/macrophage phenotype. In order to identify factors that influence whether monocytes differentiate into DC or remain on the monocyte/macrophage developmental pathway, we evaluated the effects of exogenously added IFN-gamma and endogenously produced IL-10 on the proportion and function of CD14(+) monocytes that adopt DC characteristics in response to LPS. IFN-gamma priming dramatically increased the proportion of monocytes that adopted stable DC characteristics in response to LPS, improved their T cell allosensitizing capacity, and enhanced levels of secreted IL-12 heterodimer. IFN-gamma priming also suppressed the production of IL-10, a cytokine known to have inhibitory effects on DC differentiation. When monocytes were treated with LPS plus IL-10-neutralizing antibodies, dramatically enhanced DC differentiation, IL-12 secretion, and T cell allosensitizing capacity were observed, mimicking in many respects the effects of IFN-gamma priming. IFN-gamma primed cells still displayed appreciable sensitivity to exogenously added IL-10, suggesting that attenuated IL-10 secretion is partially responsible for the enhancing effects of IFN-gamma. These studies therefore identify IFN-gamma as a DC differentiation co-factor for CD14(+) monocytes, and IL-10 as an autocrine/paracrine inhibitor of DC differentiation, linking these agents for the first time as mutually opposed regulators that govern whether CD14(+) cells differentiate into DC upon contact with LPS or remain on the monocyte/macrophage developmental pathway.

CD14+ monocytes as dendritic cell precursors: diverse maturation-inducing pathways lead to common activation of NF-kappab/RelB.

Dendritic cells are extremely potent antigen-presenting cells that are primarily responsible for the sensitization of naïve T cells to protein antigen in vivo. For this reason, dendritic cells are the focus of intense study. Despite this interest, relatively little information is available on the signal transduction pathways that regulate the development and activity of these cells. The last several years, however, have seen a steady accumulation of data regarding methods to cultivate large numbers of DC, the characterization of attendant signals that drive DC development from various precursor cells, and the induction of nuclear transcription factors that presumably direct alterations in gene expression that regulate aspects of DC development. In this review, we briefly summarize some of these findings, with emphasis on monocyte-derived dendritic cells and a discussion of two distinct types of signaling pathways that appear to regulate the final maturation of DC: one pathway calcium-dependent and cyclosporine A-sensitive, the other pathway CsA-insensitive. Although evidence suggests these signaling pathways are quite divergent in their upstream components, they both appear to activate NF-kappaB nuclear factors, particularly RelB.

Bacterial lipopolysaccharide, TNF-alpha, and calcium ionophore under serum-free conditions promote rapid dendritic cell-like differentiation in CD14+ monocytes through distinct pathways that activate NK-kappa B.

To facilitate the study of signaling pathways involved in myeloid dendritic cell (DC) differentiation, we have developed a serum-free culture system in which human CD14+ peripheral blood monocytes differentiate rapidly in response to bacterial LPS, TNF-alpha, or calcium ionophore (CI). Within 48-96 h, depending on the inducing agent, the cells acquire many immunophenotypical, morphological, functional, and molecular properties of DC. However, there are significant differences in the signaling pathways used by these agents, because 1) LPS-induced, but not CI-induced, DC differentiation required TNF-alpha production; and 2) cyclosporin A inhibited differentiation induced by CI, but not that induced by LPS. Nevertheless, all three inducing agents activated members of the NF-kappaB family of transcription factors, including RelB, suggesting that despite differences in upstream elements, the signaling pathways all involve NF-kappaB. In this report we also demonstrate and offer an explanation for two observed forms of the RelB protein and show that RelB can be induced in myeloid cells, either directly or indirectly, through a calcium-dependent and cyclosporin A-sensitive pathway.