Project description:A breach in tolerance to self-antigens induces expansion of autoreactive T cells, ultimately leading to autoimmune inflammation. While autoreactive T cells are principal drivers of autoimmunity, tissue pathology is alternatively driven by innate cytokines, indicating that autoreactive T cells can induce innate inflammation. This study has led to the discovery that effector memory T (Tem) cells trigger double stranded breaks via mitochondrial ROS production in interacting DCs. Consequently, initiation of the DNA damage response leads to activation of a cGAS-independent, STING-TRAF6-NFkB signaling axis. STING deficient DCs display significant defects in transcriptional induction and functional production of IL-1b and IL-6 following their interaction with Tem cells, both in vitro and in vivo. The discovery of Tem induced innate inflammation through DNA damage and a non-canonical STING-mediated NFkB activation presents this pathway as a potential target to alleviate T cell driven autoimmune inflammation.

Project description:A breach in tolerance to self-antigens induces expansion of autoreactive T cells, ultimately leading to autoimmune inflammation. While autoreactive T cells are principal drivers of autoimmunity, tissue pathology is alternatively driven by innate cytokines, indicating that autoreactive T cells can induce innate inflammation. This study has led to the discovery that effector memory T (Tem) cells trigger double stranded breaks via mitochondrial ROS production in interacting DCs. Consequently, initiation of the DNA damage response leads to activation of a cGAS-independent, STING-TRAF6-NFkB signaling axis. STING deficient DCs display significant defects in transcriptional induction and functional production of IL-1b and IL-6 following their interaction with Tem cells, both in vitro and in vivo. The discovery of Tem induced innate inflammation through DNA damage and a non-canonical STING-mediated NFkB activation presents this pathway as a potential target to alleviate T cell driven autoimmune inflammation.

Project description:Effector Memory T cells induce DC-intrinsic DNA damage and a non-canonical STING pathway during innate inflammation

Project description:Effector Memory T cells induce DC-intrinsic DNA damage and a non-canonical STING pathway during innate inflammation [ATAC]

Project description:Dendritic cells (DCs) are the most abundant immune cells in the kidney and form an intricate network in the tubulointerstitium, suggesting that they may play an important role in interstitial infections such as pyelonephritis. Here, we optimized a murine pyelonephritis model by instilling uropathogenic Escherichia coli two times at a 3-hour interval, which produced an infection rate of 84%. By 3 hours after the second instillation, resident kidney DCs began secreting the chemokine CXCL2, which recruits neutrophilic granulocytes. During the time studied, DCs remained responsible for most of the CXCL2 production. Neutrophils began infiltrating the kidney 3 hours after the second instillation and phagocytozed bacteria. Macrophages followed 3 hours later and contributed much less to both CXCL2 production and bacterial phagocytosis. To investigate whether DCs recruit neutrophils into the kidney for antibacterial defense, we used CD11c.DTR mice allowing conditional depletion of CD11c(+) dendritic cells. The absence of CD11c(+) DCs markedly delayed neutrophil recruitment and bacterial clearance. In conclusion, these findings suggest that the tubulointerstitial dendritic cell network serves an innate immune sentinel function against bacterial pyelonephritis.

Project description:Plasmacytoid dendritic cells (pDCs) are potent producers of type I and type III IFNs and play a major role in antiviral immunity and autoimmune disorders. The innate sensing of nucleic acids remains the major initiating factor for IFN production by pDCs. TLR-mediated sensing of nucleic acids via endosomal pathways has been studied and documented in detail, whereas the sensing of DNA in cytosolic compartment in human pDCs remains relatively unexplored. We now demonstrate the existence and functionality of the components of cytosolic DNA-sensing pathway comprising cyclic GMP-AMP (cGAMP) synthase (cGAS) and stimulator of IFN gene (STING) in human pDCs. cGAS was initially located in the cytosolic compartment of pDCs and time-dependently colocalized with non-CpG double-stranded immunostimulatory DNA (ISD). Following the colocalization of ISD with cGAS, the downstream pathway was triggered as STING disassociated from its location at the endoplasmic reticulum. Upon direct stimulation of pDCs by STING agonist 2'3' cGAMP or dsDNA, pDC-s produced type I, and type III IFN. Moreover, we documented that cGAS-STING-mediated IFN production is mediated by nuclear translocation of IRF3 whereas TLR9-mediated activation occurs through IRF7. Our data also indicate that pDC prestimulation of cGAS-STING dampened the TLR9-mediated IFN production. Furthermore, triggering of cGAS-STING induced expression of SOCS1 and SOCS3 in pDCs, indicating a possible autoinhibitory loop that impedes IFN production by pDCs. Thus, our study indicates that the cGAS-STING pathway exists in parallel to the TLR9-mediated DNA recognition in human pDCs with cross-talk between these two pathways.

Project description:Cytokine storm and sterile inflammation are common features of T cell-mediated autoimmune diseases and T cell-targeted cancer immunotherapies. Although blocking individual cytokines can mitigate some pathology, the upstream mechanisms governing overabundant innate inflammatory cytokine production remain unknown. Here, we have identified a critical signaling node that is engaged by effector memory T cells (TEM) to mobilize a broad proinflammatory program in the innate immune system. Cognate interactions between TEM and myeloid cells led to induction of an inflammatory transcriptional profile that was reminiscent, yet entirely independent, of classical pattern recognition receptor (PRR) activation. This PRR-independent "de novo" inflammation was driven by preexisting TEM engagement of both CD40 and tumor necrosis factor receptor (TNFR) on myeloid cells. Cytokine toxicity and autoimmune pathology could be completely rescued by ablating these pathways genetically or pharmacologically in multiple models of T cell-driven inflammation, indicating that TEM instruction of the innate immune system is a primary driver of associated immunopathology. Thus, we have identified a previously unknown trigger of cytokine storm and autoimmune pathology that is amenable to therapeutic interventions.

Project description:Inflammation induced by recognition of pathogen-associated molecular patterns markedly affects subsequent adaptive responses. We asked whether the adaptive immune system can also affect the character and magnitude of innate inflammatory responses. We found that the response of memory, but not naive, CD4(+) T cells enhances production of multiple innate inflammatory cytokines and chemokines (IICs) in the lung and that, during influenza infection, this leads to early control of virus. Memory CD4(+) T cell-induced IICs and viral control require cognate antigen recognition and are optimal when memory cells are either T helper type 1 (T(H)1) or T(H)17 polarized but are independent of interferon-gamma (IFN-gamma) and tumor necrosis factor-alpha (TNF-alpha) production and do not require activation of conserved pathogen recognition pathways. This represents a previously undescribed mechanism by which memory CD4(+) T cells induce an early innate response that enhances immune protection against pathogens.

Project description:There is an urgent need for alternative therapies targeting human dendritic cells (DCs) that could reverse inflammatory syndromes in many autoimmune and inflammatory diseases and organ transplantations. Here, we describe a bispecific antibody (bsAb) strategy tethering two pathogen-recognition receptors at the surface of human DCs. This cross-linking switches DCs into a tolerant profile able to induce regulatory T-cell differentiation. The bsAbs, not parental Abs, induced interleukin 10 and transforming growth factor β1 secretion in monocyte-derived DCs and human peripheral blood mononuclear cells. In addition, they induced interleukin 10 secretion by synovial fluid cells in rheumatoid arthritis and gout patients. This concept of bsAb-induced tethering of surface pathogen-recognition receptors switching cell properties opens a new therapeutic avenue for controlling inflammation and restoring immune tolerance.

Project description:In a T-cell-inflamed phenotype, tumor eradication works best and is potentiated by immunotherapy such as checkpoint blockade. However, a majority of patients die despite receiving immunotherapy. One reason is insufficient T cell priming and infiltration in the tumor. Nature provides us with innate immune mechanisms in T-cell-inflamed tumors that we can adopt for more personalized immunotherapy strategies. Tumor sensing through innate signaling pathways and efficient antigen-presenting possess a significant role in bridging innate and adaptive immunity and generating a T-cell-inflamed tumor. One approach to strengthen these innate immune mechanisms is to deliver innate immune factors such as STING or activated DCs into the tumor microenvironment, in particular in patients resistant to checkpoint blockade. The low number of DCs in the tumor bed could potentially be increased with the growth factor FMS-like tyrosine kinase 3 ligand (Flt3L). CD103+ DCs are integral for three phases of anti-tumor immunity: priming, recruiting, and re-invigoration of effector T cells. Re-activation of dysfunctional T cells is achieved via co-stimulatory molecules such as the 4-1BB ligand. The presence of myeloid-cell-derived CXCL9 and CXCL10 in the tumor microenvironment can predict response to immunotherapy. We outline recent preclinical and clinical approaches to deliver these crucial components bridging innate and adaptive immunity into the tumor microenvironment.