IL-10 is a potent anti-inflammatory cytokine interfering with antigen presentation by inducing the intracellular sequestration of MHC class II (MHC-II) molecules. Here we studied the contribution of membrane-associated RING-CH (MARCH) ubiquitin ligase family members to the IL-10-induced down-regulation of MHC-II molecules. We found that MARCH1 and MARCH8 proteins are the most potent family members for the downregulation of MHC-II surface expression in transfected cells, but only MARCH1 mRNA expression is strongly induced by IL-10 in human primary monocytes. We detected monoand poly-ubiquitinated forms of MHC-II molecules both in IL-10-treated monocytes and in cells transfected with MARCH1. We also show direct interaction between MHC-II and MARCH1 molecules in co-immunoprecipitation assays. Finally, we found that siRNAmediated knockdown of MARCH1 reverses IL-10-induced MHC-II down-regulation in primary monocytes. Thus, the immunosuppressive effect of IL-10 on antigen presentation is mediated through induced expression of MARCH1.
The signals that regulate the fate of circulating monocytes remain unknown. In the present study, we demonstrate that triggering of the NOD2 receptor by muramyl dipeptide (MDP) converts inflammatory Ly6C monocytes into patrolling Ly6C monocytes. Administration of MDP to Nr4a1 mice, which lack Ly6C monocytes, or to Ly6C-depleted mice led to the emergence of blood-patrolling monocytes with a profile similar to that of Ly6C monocytes, including high expression of CX3CR1 and LFA1. Using intravital microscopy in animal models of inflammatory diseases, we also found that converted Ly6C monocytes patrol the endothelium of blood vessels and that their presence contributes to a reduction in the inflammatory response following MDP injection. Our results demonstrate that NOD2 contributes to the regulation of blood monocytes and suggest that it could be therapeutically targeted to treat inflammatory diseases.
HLA-DO is an intracellular non-classical class II major histocompatibility complex molecule expressed in the endocytic pathway of B lymphocytes, which regulates the loading of antigenic peptides onto classical class II molecules such as HLA-DR. The activity of HLA-DO is mediated through its interaction with the peptide editor HLA-DM. Here, our results demonstrate that although HLA-DO is absolutely dependent on its association with DM to egress the endoplasmic reticulum, the cytoplasmic portion of its  chain encodes a functional lysosomal sorting signal. By confocal microscopy and flow cytometry analysis, we show that reporter transmembrane molecules fused to the cytoplasmic tail of HLA-DO accumulated in Lamp-1 ؉ vesicles of transfected HeLa cells. Mutagenesis of a leucine-leucine motif abrogated lysosomal accumulation and resulted in cell surface redistribution of reporter molecules. Finally, we show that mutation of the di-leucine sequence in DO did not alter its lysosomal sorting when associated with DM molecules. Taken together, these results demonstrate that lysosomal expression of the DO-DM complex is mediated primarily by the tyrosine-based motif of HLA-DM and suggest that the DO-encoded motif is involved in the fine-tuning of the intracellular sorting. Major histocompatibility complex (MHC)1 class II molecules are heterodimeric cell surface glycoproteins that present antigens to CD4 ϩ T cells (1). The antigenic peptide-class II complexes are expressed on specialized antigen-presenting cells such as macrophages and B lymphocytes. Following their synthesis, the ␣ and  subunits of the class II molecule associate in the endoplasmic reticulum (ER) together with the invariant chain (Ii) (2). The latter folds in part through the groove of the class II molecule, stabilizing the ␣ heterodimer and preventing the undesirable binding of ER polypeptides (3-6). Studies using mice with inactivated Ii genes suggested that Ii is necessary for efficient exit of newly synthesized class II molecules from the ER (7, 8). However, it was later demonstrated that high levels of class II molecules reach the surface of Ii Ϫ dendritic cells (9). Moreover, transfected cells express a substantial amount of class II molecules at their plasma membrane even in the absence of Ii (10). Such a phenotype probably results from the binding of endogenous peptides or polypeptides present in the ER (6, 11) and supports the notion that occupancy of the peptide-binding groove is sufficient to allow ER egress (12).Another function of Ii is to direct efficiently MHC class II molecules to the endocytic antigen-loading compartments (13-15). Two short leucine-based sequences located in the cytoplasmic tail of Ii are responsible for trafficking through the endocytic pathway (16,17). Similar motifs in many proteins are specifically recognized at the cell surface and trans-Golgi by elements of the sorting machinery (reviewed in Ref. 18).Once the class II-Ii complex reaches the endosomal compartments, the invariant chain is progressively degraded by v...
These authors contributed equally to this work.
The human-specific p35 isoform of the invariant chain (Ii) includes an R-X-R endoplasmic reticulum (ER) retention motif that is inactivated upon HLA-DR binding. Although the masking is assumed to involve the cytoplasmic tails of class II molecules, the mechanism underlying this function remains to be investigated. Moreover, in light of the polymorphic nature of the class II cytosolic tails, little is known about the capacity of various isotypes or alleles to overcome the retention signal of Iip35. To gain further insights into these issues, we first addressed the proposed role of the HLA-DR cytoplasmic tails. As shown by flow cytometry, the presence of Iip35 in transfected HeLa cells prevented surface expression of HLA-DR molecules lacking their cytoplasmic tails (DRalphaTM/betaTM). These truncated class II molecules and Iip35 accumulated in the ER, and co-localized with calnexin, as determined by confocal microscopy. Sensitivity of DRalphaTM/betaTM to endoglycosidase H treatment confirmed that these molecules do not reach the trans-Golgi network when associated with Iip35. Further characterization revealed that the beta chain cytosolic tail is critical for efficient ER egress of class II/Iip35 complexes. Interestingly, our results clearly demonstrate for the first time that DP and DQ isotypes can also overcome the retention motif of Iip35 through a mechanism involving their very distinctive polymorphic beta chain cytoplasmic tails. Altogether, these results further dissect the masking of di-basic retention signals, and emphasize the interplay between class II molecules and Ii for the transport of the complex to the endocytic pathway.
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