Microbes or danger signals trigger inflammasome sensors, which induce polymerization of the adapter ASC and assembly of an ASC speck. ASC specks recruit and activate caspase-1, which induces IL-1β cytokine maturation and pyroptotic cell death. Here we show that after pyroptosis ASC specks accumulate in the extracellular space, where they promote further IL-1β maturation. In addition, phagocytosis of ASC specks induces lysosomal damage, nucleation of soluble ASC as well as caspase-1 and IL-1β activation in the recipient cell. ASC specks appear in bodily fluids from inflamed tissues and autoantibodies against ASC specks develop in patients and animals with autoimmune pathologies. Together, these findings reveal extracellular functions of ASC specks and a novel form of cell-to-cell communication.
Autoreactive B cells are activated by DNA, chromatin, or chromatin-containing immune complexes (ICs) through a mechanism dependent on dual engagement of the BCR and TLR9. We examined the contribution of endogenous DNA sequence elements to this process. DNA sequence can determine both recognition by the BCR and by TLR9. DNA fragments containing CpG islands, a natural source of unmethylated CpG dinucleotides, promote the activation of DNA-reactive B cells derived from BCR transgenic mice as well as DNA-reactive B cells present in the normal repertoire. ICs containing these CpG island fragments are potent ligands for AM14 IgG2a-reactive B cells. In contrast, ICs containing total mammalian DNA, or DNA fragments lacking immunostimulatory motifs, fail to induce B cell proliferation, indicating that BCR crosslinking alone is insufficient to activate low-affinity autoreactive B cells. Importantly, priming B cells with IFN-α lowers the BCR activation threshold and relaxes the selectivity for CpG-containing DNA. Taken together, our findings underscore the importance of endogenous CpG-containing DNAs in the TLR9-dependent activation of autoreactive B cells and further identify an important mechanism through which IFN-α can contribute to the pathogenesis of systemic lupus erythematosus.
Innate immune PRRs sense nucleic acids from microbes and orchestrate cytokine
production to resolve infection. Inappropriate recognition of host nucleic acids also
results in autoimmune disease. Here we utilize a model of inflammation resulting from
accrual of self DNA (DNase II−/−
Ifnar−/−) to understand the role of PRR sensing
pathways in arthritis and autoantibody production. Using mice deficient in DNase II/Ifnar
together with deficiency in either STING or AIM2 (TKO), we reveal central roles for the
STING and AIM2 pathway in arthritis. AIM2 TKO mice show limited inflammasome activation
and, like STING TKO mice, have reduced inflammation in joints. Surprisingly, autoantibody
production is maintained in AIM2 and STING TKO mice, while DNase
II−/− Ifnar−/− mice
also deficient in Unc93b, a chaperone required for TLR7/9 endosomal localization, fail to
produce autoantibodies to nucleic acids. Collectively, these data support distinct roles
for cytosolic and endosomal nucleic acid sensing pathways in disease manifestations.
In mice that fail to express the phagolysosomal endonuclease, DNase II, and the type I IFN receptor, excessive accrual of undegraded DNA results in a STING-dependent, TLR-independent inflammatory arthritis. These double knockout (DKO) mice develop additional indications of systemic autoimmunity, including anti-nuclear autoantibodies and splenomegaly, not found in Unc93b1−/− DKO mice and therefore TLR-dependent. The DKO autoantibodies predominantly detect RNA-associated autoantigens, commonly targeted in TLR7-dominated SLE-prone mice. To determine whether an inability of TLR9 to detect endogenous DNA could explain the absence of dsDNA-reactive autoantibodies in DKO mice, we used a novel class of bifunctional autoantibodies, IgM/DNA DVD-Ig™ molecules, to activate B cells through a BCR/TLR9-dependent mechanism. DKO B cells could not respond to the IgM/DNA DVD-Ig™ molecule, despite a normal response to both anti-IgM and CpG ODN 1826. Thus DKO B cells only respond to RNA-associated ligands because DNase II-mediated degradation of self-DNA is required for TLR9 activation.
Endosomal Toll-like receptors (TLRs) play an important role in systemic autoimmune diseases such as SLE, where DNA- and RNA-associated autoantigens activate autoreactive B cells through TLR9- and TLR7-dependent pathways. Nevertheless, TLR9-deficient autoimmune prone mice develop more severe clinical disease, while TLR7-deficient and TLR7/9-double deficient autoimmune-prone mice develop less severe disease. To determine whether the regulatory activity of TLR9 is B cell intrinsic, we have now directly compared the functional properties of autoantigen activated WT, TLR9-deficient and TLR7-deficient B cells, in an experimental system where proliferation depends on BCR/TLR co-engagement. In vitro, TLR9-deficient cells are less dependent on survival factors for a sustained proliferative response than either WT or TLR7-deficient cells. The TLR9-deficient cells also preferentially differentiate toward the plasma cell lineage, as indicated by expression of CD138, sustained expression of IRF4, and other molecular markers of plasma cells. In vivo, autoantigen-activated TLR9-deficient cells give rise to greater numbers of autoantibody producing cells. Our results identify distinct roles for TLR7 and TLR9 in the differentiation of autoreactive B cells that explain the capacity of TLR9 to limit, and TLR7 to promote, the clinical features of SLE.
Glaucoma is a multifactorial disease resulting in the death of retinal ganglion cells (RGCs) and irreversible blindness. Glaucoma-associated RGC cell death depends on the pro-apoptotic and proinflammatory activity of membrane-bound FasL (mFasL). In contrast to mFasL, the natural soluble FasL cleavage product (sFasL) inhibits mFasL-mediated apoptosis and inflammation and is therefore a mFasL antagonist. DBA/2J (D2) mice spontaneously develop glaucoma and predictably RGC destruction is exacerbated by expression of a mutated membrane-only FasL (mFasL) gene that lacks the extracellular cleavage site. Remarkably, one time intraocular adeno-associated virus-mediated gene delivery of sFasL (AAV2.sFasL) provides complete and sustained neuroprotection in both the chronic D2 and acute microbead-induced models of glaucoma, even in the presence of elevated intraocular pressure (IOP). This protection correlated with inhibition of glial activation, reduced production of TNFα, and decreased apoptosis of RGCs and loss of axons. These data indicate that cleavage of FasL under homeostatic conditions, and the ensuing release of sFasL, normally limits the neurodestructive activity of FasL. The data further support the notion that sFasL, and not mFasL, contributes to the immune privileged status of the eye.
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