Jueqi Chen scite author profile

SUMMARY Pathogens and cellular danger signals activate sensors such as RIG-I and NLRP3 to produce robust immune and inflammatory responses through respective adaptor proteins MAVS and ASC, which harbor essential N-terminal CARD and PYRIN domains, respectively. Here, we show that CARD and PYRIN function as bona fide prions in yeast and their prion forms are inducible by their respective upstream activators. Likewise, a yeast prion domain can functionally replace CARD and PYRIN in mammalian cell signaling. Mutations in MAVS and ASC that disrupt their prion activities in yeast also abrogate their ability to signal in mammalian cells. Furthermore, fibers of recombinant PYRIN can convert ASC into functional polymers capable of activating caspase-1. Remarkably, a conserved fungal NOD-like receptor and prion pair can functionally reconstitute signaling of NLRP3 and ASC PYRINs in mammalian cells. These results indicate that prion-like polymerization is a conserved signal transduction mechanism in innate immunity and inflammation.

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PtdIns4P on dispersed trans-Golgi network mediates NLRP3 inflammasome activation

Chen¹,

Chen²

2018

Nature

523

452

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The NLRP3 inflammasome, which has been linked to human inflammatory diseases, is activated by a plethora of stimuli. How NLRP3 is activated by such diverse stimuli is a central question that is unresolved. Here we show that different NLRP3 stimuli lead to a hitherto unknown disassembly of trans-Golgi network (TGN). NLRP3 is recruited to the dispersed TGN (dTGN) through ionic bonding between a conserved polybasic region in NLRP3 and the negatively-charged phosphatidylinositol 4-phosphate (PI4P) on dTGN. dTGN then serves as a scaffold for NLRP3 aggregation into multiple puncta, which polymerize the adaptor ASC to activate the downstream signaling cascade. Disruption of interaction between NLRP3 and PI4P on dTGN blocked NLRP3 aggregation and signaling. These results indicate that recruitment of NLRP3 to dTGN is an early and common cellular event that leads to NLRP3 aggregation and activation in response to diverse stimuli.

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Detection of Microbial Infections Through Innate Immune Sensing of Nucleic Acids

Tan

Sun

Chen

et al. 2018

Annu. Rev. Microbiol.

361

332

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Microbial infections are recognized by the innate immune system through germline-encoded pattern recognition receptors (PRRs). As most microbial pathogens contain DNA and/or RNA during their life cycle, nucleic acid sensing has evolved as an essential strategy for host innate immune defense. Pathogen-derived nucleic acids with distinct features are recognized by specific host PRRs localized in endolysosomes and the cytosol. Activation of these PRRs triggers signaling cascades that culminate in the production of type I interferons and proinflammatory cytokines, leading to induction of an antimicrobial state, activation of adaptive immunity, and eventual clearance of the infection. Here, we review recent progress in innate immune recognition of nucleic acids upon microbial infection, including pathways involving endosomal Toll-like receptors, cytosolic RNA sensors, and cytosolic DNA sensors. We also discuss the mechanisms by which infectious microbes counteract host nucleic acid sensing to evade immune surveillance.

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MAVS recruits multiple ubiquitin E3 ligases to activate antiviral signaling cascades

et al. 2013

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RNA virus infections are detected by the RIG-I family of receptors, which induce type-I interferons through the mitochondrial protein MAVS. MAVS forms large prion-like polymers that activate the cytosolic kinases IKK and TBK1, which in turn activate NF-κB and IRF3, respectively, to induce interferons. Here we show that MAVS polymers recruit several TRAF proteins, including TRAF2, TRAF5, and TRAF6, through distinct TRAF-binding motifs. Mutations of these motifs that disrupted MAVS binding to TRAFs abrogated its ability to activate IRF3. IRF3 activation was also abolished in cells lacking TRAF2, 5, and 6. These TRAF proteins promoted ubiquitination reactions that recruited NEMO to the MAVS signaling complex, leading to the activation of IKK and TBK1. These results delineate the mechanism of MAVS signaling and reveal that TRAF2, 5, and 6, which are normally associated with NF-κB activation, also play a crucial role in IRF3 activation in antiviral immune responses.DOI: http://dx.doi.org/10.7554/eLife.00785.001

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Direct, Noncatalytic Mechanism of IKK Inhibition by A20

et al. 2011

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SUMMARY A20 is a potent anti-inflammatory protein that inhibits NF-κB, and A20 dysfunction is associated with autoimmunity and B-cell lymphoma. A20 harbors a deubiquitination enzyme domain and can employ multiple mechanisms to antagonize ubiquitination upstream of NEMO, a regulatory subunit of the IκB kinase complex (IKK). However, direct evidence of IKK inhibition by A20 is lacking, and the inhibitory mechanism remains poorly understood. Here we show that A20 can directly impair IKK activation without deubiquitination or impairment of ubiquitination enzymes. We find that polyubiquitin binding by A20, which is largely dependent on A20’s seventh zinc finger motif (ZnF7), induces specific binding to NEMO. Remarkably, this ubiquitin-induced recruitment of A20 to NEMO is sufficient to block IKK phosphorylation by its upstream kinase TAK1. Our results suggest a non-catalytic mechanism of IKK inhibition by A20 and a means by which polyubiquitin chains can specify a signaling outcome.

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Jueqi Chen

Prion-like Polymerization Underlies Signal Transduction in Antiviral Immune Defense and Inflammasome Activation

PtdIns4P on dispersed trans-Golgi network mediates NLRP3 inflammasome activation

Detection of Microbial Infections Through Innate Immune Sensing of Nucleic Acids

MAVS recruits multiple ubiquitin E3 ligases to activate antiviral signaling cascades

Direct, Noncatalytic Mechanism of IKK Inhibition by A20

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