Project description:STING activation by cyclic dinucleotides in mammals induces Type I Interferon- and NFkB-related gene expression, and the lipidation of LC3B at Golgi membranes. While the mechanisms of the Interferon-related responses are well understood, the mechanism of NFkB activation mediated by STING activation, and how the multi-functional responses downstream of STING signaling are related remain unknown. We report that STING activation induces K63 and linear ubiquitin chain formation, and ubiquitin co-localizes with STING and LC3B at Golgi-derived vesicles. Loss of the LUBAC E3 ubiquitin ligase subunit, HOIP, prevents formation of the linear, but not K63-linked, ubiquitin chains. The ubiquitin and LC3B binding proteins, Optineurin and TNIP1, are co-localized with STING activation-induced, perinuclear LC3B foci via their UBAN domains, however loss of HOIP does not influence this localization, indicating they may bind the K63-linked ubiquitin chains. HOIP-mediated linear ubiquitin chains are well established to mediate NFkB downstream of TNFa and IL1beta receptor stimulation. Loss of HOIP in monocytic THP-1 cells inhibits STING-induced NFkB activation and NFkB-related gene transcription, as well as Interferon-related transcription. Further, the recently reported proton channel activity of STING that blocks LC3B lipidation at Golgi membranes is also important for both K63 and Linear ubiquitin chain formation, and NFkB signaling. Thus, STING induces HOIP and linear ubiquitin chain formation to activate NFkB.

Project description:Activation of Stimulator of interferon genes (STING) is well known to upregulate inflammation through canonical TBK1 signaling. STING is recently found to activate noncanonical functions through its transmembrane proton channel. Whether STING stimulates any transcription programs through its channel is unknown. In this study, we identified the transcription factor EB (TFEB) as a downstream effector of the STING channel. TFEB is a transcriptional regulator of lysosomal biogenesis and autophagy. Using RNA sequencing approaches, we confirmed that STING activated transcriptional upregulation of lysosomal biogenesis and autophagy independently of TBK1.

Project description:The cGAS-STING pathway forms a major component of the innate immune system. cGAS-STING signalling is induced by detection of either foreign (i.e. pathogenic) or mislocalised host double stranded (ds)DNA present within the cytosol. STING acts as the major signalling hub, where it controls activation of transcription factors IRF3 and NF-B for expression of type I interferons and inflammatory cytokines, respectively. Under resting conditions STING resides on the ER membrane. However, following activation STING traffics to the Golgi to initiate downstream signalling, and subsequently to endolysosomal regions for degradation and termination of signalling. However, while STING is known to be degraded by lysosomes, the mechanisms controlling its delivery remain poorly defined. Here we utilised a mass spectrometry approach to assess phosphorylation changes in primary macrophages following STING activation. This identified a large number of phosphorylation events in proteins involved in intracellular transport, including vesicular trafficking. We utilised high-temporal microscopy to track STING vesicular transport in live macrophages. We observed that while macrophages exhibit rapid degradation of STING (i.e., 4-6 h), basal STING protein levels return slowly (i.e., >24 h). Despite STING protein recovery, ultimately macrophages remain unresponsive to re-challenge with STING ligands. Using a combination of imaging and biochemical approaches we subsequently identify that the endosomal complexes required for transport (ESCRT) pathway detects ubiquitinated STING on endosomes, which facilitates the degradation of STING. Disrupting ESCRT recognition of STING via knockdown of the ESCRT-0 component HRS or inhibiting ESCRT function via overexpression of a dominant negative form of VPS4a enhances STING signalling and cytokine production. Therefore, we have characterised the mechanisms that controls effective termination of STING signalling. Dysregulation of STING localisation or its degradation has been implicated in several diseases including autoimmune, autoinflammatory and neuroinflammatory diseases, hence a clearer understanding of STING degradation is imperative for a better understanding of STING-dependent disease pathologies.

Project description:The Golgi apparatus plays a central role in the protein glycosylation where it is required for secretory trafficking. Abnormal morphology of the Golgi apparatus has been widely observed in neurodegenerative disease. Golgi pH regulator (GPHR) is an anion channel essential for acidification of the Golgi lumen and its essential for normal morphology and function of the Golgi apparatus. To address the Golgi dysfunction in neuronal cells, we established brain-specific GPHR knockout mice (GPHRf/f;Nes).

Project description:Androgen receptor (AR) plays an essential role in normal prostate development and prostate cancer (PCa) progression. To understand the role of AR at the single-cell level, we performed single-cell transcriptome analysis on PCa cells stimulated with androgen and antiandrogen to reconstruct the dynamic and direct AR transcriptional network. Our work reveals that androgen stimulates the ER and Golgi stress response , promoting secreting protein trafficking, and inhibiting cell apoptosis. Moreover, we identify an ER-to-Golgi protein vesicle-mediated transport gene signature essential for maximal androgen-mediated ER-Golgi trafficking, cell proliferation, and association with PCa prognosis and progression. Notably, we show that AR collaborates with CREB3L2, XXX, to coordinately promote ER-Golgi trafficking of Golgi enzyme Mannosidase II and PCa cell survival. Finally, we show the inhibition of the ER-Golgi transport process with Brefeldin A leads to tumor regression. Our study collectively reveals the heterogeneity of PCa cell transcriptional response to androgen stimulation, demonstrates a functional role for increased ER-Golgi trafficking process, and provides a mechanism for how the process is augmented in PCa as well as the potential of targeting may provide novel treatment strategies.

Project description:STING-mediated activation of TAK1 at the ER, which in turn induces STING phosphorylation and initiates STEEP-mediated STING trafficking. These findings shed light on an early signaling event in the regulation of STING exit from ER.

Project description:Hepatocellular carcinoma (HCC) emerges from chronic inflammation to which activation of hepatic stellate cells (HSCs) contributes by shaping a pro-tumorigenic microenvironment. Key to this process is p62, whose inactivation leads to enhanced hepatocarcinogenesis. Here, we show that while p62 positively regulates STING ubiquitination by TRIM32 by displacing NBR1, which results in the activation of the interferon (IFN) cascade, NBR1 prevents TRIM32 interaction with and the activation of STING, leading to impaired IFN synthesis. NBR1 also antagonizes STING function by promoting its trafficking from the Golgi to the endosome-lysosomal degradative cascade independent of autophagy. Importantly, NBR1 deletion completely reverts the tumor-promoting function of p62-deficient HSCs. The upregulation of the STING-IFN pathway by NBR1 deficiency enhances the anti-tumor response mediated by CD8+ T cells. These results identify NBR1 as a synthetic vulnerability of p62-deficiency in HSCs. NBR1 loss, by promoting the STING/IFN pathway, boosts anti-tumor CD8+ T cell responses to restrain HCC.

Project description:Hepatocellular carcinoma (HCC) emerges from chronic inflammation to which activation of hepatic stellate cells (HSCs) contributes by shaping a pro-tumorigenic microenvironment. Key to this process is p62, whose inactivation leads to enhanced hepatocarcinogenesis. Here, we show that while p62 positively regulates STING ubiquitination by TRIM32 by displacing NBR1, which results in the activation of the interferon (IFN) cascade, NBR1 prevents TRIM32 interaction with and the activation of STING, leading to impaired IFN synthesis. NBR1 also antagonizes STING function by promoting its trafficking from the Golgi to the endosome-lysosomal degradative cascade independent of autophagy. Importantly, NBR1 deletion completely reverts the tumor-promoting function of p62-deficient HSCs. The upregulation of the STING-IFN pathway by NBR1 deficiency enhances the anti-tumor response mediated by CD8+ T cells. These results identify NBR1 as a synthetic vulnerability of p62-deficiency in HSCs. NBR1 loss, by promoting the STING/IFN pathway, boosts anti-tumor CD8+ T cell responses to restrain HCC.

Project description:The volume-regulated anion channel (VRAC) is a hexameric complex formed by LRRC8 proteins. VRACs are responsible for the regulatory volume decrease (RVD) after hypotonic cell swelling by mediating the efflux of chloride. Besides chloride, LRRC8 proteins transport other molecules including immunomodulatory cyclic dinucleotides (CDNs) such as 2’3’cGAMP. Here we identify LRRC8C as a critical component of VRACs in T cells, where its deletion abolishes VRAC currents and RVD. We find that LRRC8C mediates the transport of 2’3’cGAMP in T cells. T cells of Lrrc8c-/- mice have increased cell cycle progression, proliferation, survival, Ca2+ influx and cytokine production in vitro and enhanced T cell mediated immunity in vivo. We used RNA sequencing of CD4+ T cells from wild-type (WT) and Lrrc8c-/- mice to determine the effects of impaired cGAMP signaling in T cells. T cells of Lrrc8c-/- mice had impaired p53 signaling which was associated with decreased p53 expression. We found that uptake of 2’3’cGAMP and other CDNs via LRRC8C results in STING activation and p53 accumulation. Inhibition of STING in WT T cells recapitulates the phenotype of LRRC8C-deficient T cells whereas overexpression of p53 inhibits enhanced T cell function in the absence of LRRC8C. These findings establish cGAMP uptake through LRRC8C and subsequent STING-p53 signaling as a novel inhibitory signaling pathway in T cells and adaptive immunity.

Project description:Stimulator of interferon genes (STING), the central hub protein of the cGAS-STING signaling, is essential for type I IFN production of innate immunity. However, prolonged or excessive activation of STING is highly related to autoimmune diseases, most of which exhibit the hallmark of elevated expression of type I interferons and IFN-stimulated genes (ISGs). Thus, the activity of STING must be stringently controlled to maintain immune homeostasis. Here, we reported that CK1α, a protein serine/threonine kinase, was essential to prevent the over-activation of STING-mediated type I IFN signaling through autophagic degradation of STING. Mechanistically, CK1α interacted with STING upon the cGAS-STING pathway activation and promoted STING autophagic degradation by enhancing the phosphorylation of p62 at serine 349, which was critical for p62 mediated STING autophagic degradation. Consistently, SSTC3, a selective CK1α agonist, significantly attenuated the response of the cGAS-STING signaling by promoting STING autophagic degradation. Importantly, pharmaceutical activation of CK1α using SSTC3 markedly repressed the systemic autoinflammatory responses in the Trex1-/- mouse autoimmune disease model and effectively suppressed the production of IFNs and ISGs in the PBMCs of SLE patients. Taken together, our study reveals a novel regulatory role of CK1α in the autophagic degradation of STING to maintain immune homeostasis. Manipulating CK1α through SSTC3 might be a potential therapeutic strategy for alleviating STING-mediated aberrant type I IFNs in autoimmune diseases.