IFN-␥ orchestrates a potent antimicrobial host response. However, the underlying molecular basis for this immunological defense system is largely unknown. In a systematic approach to identify IFN-␥-regulated host effector molecules, a notable number of transcripts with consensus GTP-binding motives were obtained. Further extensive transcriptome and genome analyses identified five novel family members of murine guanylate-binding proteins (mGBPs) now designated mGBP6, 7, 8, 9, and 10. Moreover, in this study, all 10 mGBP members (mGBP1-10) were extensively characterized. mGBPs are selectively up-regulated in vitro by a set of proinflammatory cytokines and TLR agonists as well as in vivo after Listeria monocytogenes and Toxoplasma gondii infection. After IFN-␥ stimulation, mGBP1, 2, 3, 6, 7, and 9 are associated with intracellular Toxoplasma parasites and, interestingly, virulent Toxoplasma interfere with mGBP recruitment. Taken together, mGBPs comprise an important set of host defense molecules.
The dendritic cell (DC) immunoreceptors (DCIR) and DC-immunoactivating receptors (DCAR) represent a subfamily of cell surface C-type lectin receptors (CLR), whose multifunctional capacities range from classical Ag uptake and immunoregulatory mechanisms to the involvement in DC ontogeny. On the basis of the generation of specific mAbs, we functionally characterized mouse DCAR1 (mDCAR1) as a member of the DCIR/DCAR family. Expression of mDCAR1 was strongly tissue dependent. mDCAR1 expression on DCs was restricted to the CD8+ DC subset in spleen and thymus and on subpopulations of CD11b+ myeloid cells in bone marrow and spleen, whereas the molecule was not detectable on both cell types in lymph nodes and peripheral blood. With respect to the function of CLRs as pattern recognition receptors, Ag delivered via mDCAR1 was internalized, was trafficked to early and late endosomes/lysosomes and, as a consequence, induced cellular and humoral responses in vivo even in the absence of CD40 stimulation. Intriguingly, upon triggering mDCAR1, CD8+ DCs increased the secretion of bioactive IL-12, whereas IL-10 release is markedly reduced, thereby indicating that Ag recognized by mDCAR1 induces enhanced proinflammatory responses. These data indicate that mDCAR1 is a functional receptor on cells of the immune system and provides further insights into the regulation of immune responses by CLRs.
Plasmacytoid dendritic cells (pDCs) play an important role in innate and adaptive immunity and were shown to be identical to previously described natural interferon (IFN)-α-producing cells. Here, we describe two functionally distinct pDC subpopulations that are characterized by the differential expression of stem cell antigen-1 (Sca-1; Ly-6A/E). Sca-1(-) pDCs are mainly found in the BM, appear first during development, show a higher proliferative activity, and represent the more precursor phenotype. Sca-1(+) pDCs are mostly located in secondary lymphoid organs and represent a later developmental stage. Sca-1(-) pDCs give rise to an Sca-1(+) subset upon activation or in response to endogenous type I IFN. Interestingly, in contrast to Sca-1(-) pDCs, Sca-1(+) pDCs are defective in IFN-α production upon endosomal TLR9 stimulation, whereas lysosomal signaling via TLR9 is functional in both subsets. Gene expression analysis revealed that osteopontin is strongly upregulated in Sca-1(-) pDCs. These data provide evidence for the molecular basis of the observed functional heterogeneity, as the intracellular isoform of osteopontin couples TLR9 signaling to IFN-α expression. Taken together, our results indicate that Sca-1(-) pDCs are an early developmental stage of pDCs with distinct innate functions representing the true murine natural IFN-α-producing cells.
Despite their role in the induction of adaptive immune responses, plasmacytoid dendritic cells (pDC) play also a crucial role in innate immune defense by recognizing pathogen derived molecular patterns. Unmethylated CpG motifs of bacterial DNA bind specifically endosomal and lysosomal TLR9 in pDCs, thereby inducing secretion of type I IFN or proinflammatory cytokines and classical DC maturation, respectively. However, TLR9 also recognizes CpG motifs in vertebrate DNA of damaged cells as danger-associated molecular patterns (DAMPs) that activate pDCs. For in-vitro research pDCs may be isolated by indirect magnetic cell separation using either Miltenyi Biotec’s column-based or a column-free system from other suppliers. Here we describe the influence of the isolation method on the functionality of the purified pDCs. In addition to the significantly better separation performance, our column-based method enriched 10- and 30-fold less DNA-containing dead cells and debris, respectively. Although both methods yielded pDCs with a comparable phenotype instantly after isolation, after 24h of culture without stimulation pDCs isolated with the column-free system appeared pre-activated as demonstrated by elevated expression of CD80, −83, −86 and HLA-DR and by significantly higher basal IFN-α secretion. Moreover, upon stimulation with CpG-B pDCs isolated with the column-free method induced extraordinary high amounts of IFN-α, whereas pDCs isolated with our system exhibited normal responses to CpG-A and CpG-B. These results clearly demonstrate that unspecific enrichment of dead cells and debris may significantly influence the activation status of the isolated pDCs and therefore affect the results of downstream applications.
Stem cell antigen-1 (Sca-1), a phosphatidylinositol-linked membrane protein is one of the most prominent stem cell markers. Functionally, Sca-1 is involved in cross-talk between lymphocyte precursors and stromal cells and plays an important role in the thymic development of T-cells and TcR-dependent activation. Here we show that expression of Sca-1 on PDC defines functionally different developmental stages of PDC in mice. The proportion of the Sca-1+ PDC showed an organ specific variation ranging from 10-20% in BM to >80% in LN. Sca-1- PDC appeared earlier in the development and give rise to Sca-1+ PDC without the need for activation. In addition to the naturally occurring up-regulation, Sca-1 expression could be further induced by TLR7 and TLR9 mediated activation. Interestingly, when exposed to CpG-oligonucleotides (TLR9), Sca-1- PDC produced significantly higher amounts of IFN-alpha. This was further confirmed by two observations: (1) after stimulation with TLR9-ligands purified PDC from BM (mainly Sca-1-) produced up to 100-fold higher amounts of IFN-alpha when compared to PDC from LN (predominantly Sca-1+), (2) Sca-1- PDC expressed significantly higher amount of genes involved in TLR mediated IFN-alpha induction, including MyD88, IRF3, IRF5, IFNAR1 and IFNAR2. Taking together, our results identify Sca-1 as a developmental marker of PDC, which defines two functionally heterogeneous subsets of PDC.
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