Synovial fluid CD1c⁺ myeloid dendritic cells – the inflammatory picture emerges

In mice and humans, plasmacytoid DCs are identifiable by their strong capacity to secrete IFN-α. Developmentally, plasmacytoid DCs depend on the transcription factor E2-2. The human PB CD141⁺ DC subset was shown to be functionally equivalent to murine CD8⁺CD103⁺CD11b^- DCs in that both had unique capacity to cross-present protein antigen to CD8⁺ T cells and depend on the transcription factor Batf3. CD141⁺ DCs have not yet been studied in the synovium but were found to have a regulatory role in the skin [5]. In contrast, the CD1c⁺ PB DC subset was shown by microarray and functional analysis to be an equivalent human population to the murine CD103^-CD11b⁺ myeloid (possibly monocyte-derived) DCs [3]. In the mouse, CD103^-CD11b⁺CD4⁺ DCs do not develop in the absence of IRF4 or RelB transcription factors [3, 6]. IRF4-dependent myeloid DCs were identified in lung and gut, where they specifically produced IL-23 and induced T helper (Th)-17 cells after fungal infection [3]. PB CD1c⁺ DCs from healthy human donors promoted Th17 and Th1 T-cell differentiation in vitro in the presence of fungal hyphae but secreted IL-10 and suppressed T-cell proliferation after Escherichia coli[3, 7]. Thus, their capacity to activate T cells is likely to be stimulus-dependent. Recently, CD1c⁺CD11c⁺HLA-DR⁺CD16^-CD14⁺ DCs were identified in human inflammatory fluids, including ascites and SF [8]. In view of their low levels of CD14 expression, their lack of CD16 expression distinguished them from non-classical inflammatory monocytes/macrophages [8]. PB CD1c⁺ DCs and inflammatory CD1c⁺ DCs expressed high levels of IRF4, FLT3, and ZBTB46 mRNA, suggesting common developmental pathways with murine CD103^-CD11b⁺ myeloid and human monocyte-derived DCs. Stimulated ascites fluid CD1c⁺ DCs secreted high levels of IL-23 and induced high levels of IL-17, IFN-γ, IL-5, and IL-13 [8].

The DCs in the article by Moret and colleagues were identified from RA SF on the basis of the expression of CD1c and lack of CD19. This enriched an activated DC population expressing high levels of HLA-DR, with only a small proportion expressing CD14. SF CD1c⁺ DCs were considerably more activated, as previously described [9], and expressed higher levels of chemokines, including IL-16, TARC, MIG, and IP-10, than their counterparts in PB from patients with RA. In autologous mixed lymphocyte cultures, SF CD1c⁺ DCs were much more efficient stimulators of CD4⁺ T-cell proliferation and Th1, Th17, and Th2 cytokine production than PB CD1c⁺ DCs. Thus, the CD1c⁺ SF DCs resemble inflammatory CD1c⁺ DCs described in SF and ascites [8] and appear to overlap considerably with the myeloid CD33⁺CD14⁺ SF DC population described to strongly stimulate autologous T cells and to express intracellular RelB, before the discovery of the CD1c⁺ myeloid DC subset marker [10, 11]. While SF DCs were previously described to express low levels of CD14, the lack of CD14 expression by the CD1c⁺ DCs isolated by Moret and colleagues very likely relates to poor discrimination of CD14^-, CD14⁺, and CD14⁺⁺ cells by the monoclonal antibody and isotype used.

In summary, CD1c⁺ SF DCs clearly are highly constitutively activated and capable of strongly chemo-attracting effector T cells producing various cytokines. MIG and IP-10 are strongly IFN-γ-dependent, suggesting a positive feedback loop with Th1 cells stimulated by synovial CD1c⁺ DCs. Similar to their monocyte-derived DC counterparts in the mouse, these DCs appear to be highly responsive to their environment, including suppression in response to various Toll-like receptor ligands, making them potentially interesting targets in RA.