SUMMARY Inflammasomes elicit host defense inside cells by activating caspase-1 for cytokine maturation and cell death. AIM2 and NLRP3 are representative sensor proteins in two major families of inflammasomes. The adaptor protein ASC bridges the sensor proteins and caspase-1 to form ternary inflammasome complexes, achieved through pyrindomain (PYD) interactions between sensors and ASC, and caspase activation and recruitment domain (CARD) interactions between ASC and caspase-1. We found that PYD and CARD both form filaments. Activated AIM2 and NLRP3 nucleate PYD filaments of ASC, which in turn cluster the CARD of ASC. ASC thus nucleates CARD filaments of caspase-1 leading to proximity-induced activation. Endogenous NLRP3 inflammasome is also filamentous. The cryo-EM structure of ASCPYD filament at near-atomic resolution provides a template for homo- and hetero-PYD/PYD associations, as confirmed by structure-guided mutagenesis. We propose that ASC-dependent inflammasomes in both families share a unified assembly mechanism that involves two successive steps of nucleation-induced polymerization.
The NLR family apoptosis inhibitory proteins (NAIPs) bind conserved bacterial ligands, such as the bacterial rod protein PrgJ, and recruit NLR family CARD-containing protein 4 (NLRC4) as the inflammasome adapter to activate innate immunity. We found that the PrgJ-NAIP2-NLRC4 inflammasome is assembled into multisubunit disk-like structures through a unidirectional adenosine triphosphatase polymerization, primed with a single PrgJ-activated NAIP2 per disk. Cryo–electron microscopy (cryo-EM) reconstruction at subnanometer resolution revealed a ~90° hinge rotation accompanying NLRC4 activation. Unlike in the related heptameric Apaf-1 apoptosome, in which each subunit needs to be conformationally activated by its ligand before assembly, a single PrgJ-activated NAIP2 initiates NLRC4 polymerization in a domino-like reaction to promote the disk assembly. These insights reveal the mechanism of signal amplification in NAIP-NLRC4 inflammasomes.
Inflammasomes are cytosolic caspase-1 activation complexes that sense intrinsic and extrinsic danger signals to trigger inflammatory responses and pyroptotic cell death. Homotypic interactions by Pyrin domains (PYD) and caspase recruitment domains (CARD) in inflammasome component proteins mediate oligomerization into filamentous assemblies. Several cytosolic proteins consisting of only the interaction domains exert inhibitory effects on inflammasome assembly. In this study, we determined the structure of human caspase-1CARD filament by cryo-electron microscopy and investigated the biophysical properties of two caspase-1-like CARD-only proteins, human inhibitor of CARD (INCA or CARD17) and ICEBERG (or CARD18). Our results reveal the surprising finding that INCA caps caspase-1 filament, thereby exerting potent inhibition with low nanomolar Ki on caspase-1CARD polymerization in vitro and inflammasome activation in cells. While caspase-1CARD uses six complementary surfaces of three types for filament assembly, INCA is defective in two of the six interfaces to terminate caspase-1 filament.
Summary Caspase-8 activation can be triggered by death receptor-mediated formation of the death-inducing signaling complex (DISC) and by the inflammasome adaptor ASC. Caspase-8 assembles with FADD at the DISC and with ASC at the inflammasome through its tandem death effector domain (tDED), which is regulated by the tDED-containing cellular inhibitor cFLIP and the viral inhibitor MC159. Here we present the caspase-8 tDED filament structure determined by cryo-electron microscopy. Extensive assembly interfaces not predicted by the previously proposed linear DED chain model were uncovered, and further confirmed by structure-based mutagenesis in filament formation in vitro, and Fas-induced apoptosis and ASC-mediated caspase-8 recruitment in cells. Structurally, the two DEDs in caspase-8 use quasi-equivalent contacts to enable assembly. Using the tDED filament structure as a template, structural analyses reveal the interaction surfaces between FADD and caspase-8, and the distinct mechanisms of regulation by cFLIP and MC159 through comingling and capping, respectively.
Canonical inflammasomes are cytosolic supramolecular complexes that activate caspase-1 upon sensing extrinsic microbial invasions and intrinsic sterile stress signals. During inflammasome assembly, adaptor proteins ASC and NLRC4 recruit caspase-1 through homotypic caspase recruitment domain (CARD) interactions, leading to caspase-1 dimerization and activation. Activated caspase-1 processes proinflammatory cytokines and Gasdermin D to induce cytokine maturation and pyroptotic cell death. Here, we present cryo-electron microscopy (cryo-EM) structures of NLRC4 CARD and ASC CARD filaments mediated by conserved three types of asymmetric interactions (types I, II, and III). We find that the CARDs of these two adaptor proteins share a similar assembly pattern, which matches that of the caspase-1 CARD filament whose structure we defined previously. These data indicate a unified mechanism for downstream caspase-1 recruitment through CARD-CARD interactions by both adaptors. Using structure modeling, we further show that full-length NLRC4 assembles via two separate symmetries at its CARD and its nucleotide-binding domain (NBD), respectively. ASC | NLRC4 | inflammasome | caspase-1 | CARD
Ploegh et al. raised an alpaca single-domain antibody (VHH) against the inflammasome adaptor ASC. VHHASC blocks inflammasome activation in vitro and in living cells, and demonstrates a role of the ASC CARD domain in cross-linking ASC Pyrin domain filaments.
Inflammasomes are supramolecular signaling complexes that activate a subset of caspases known as the inflammatory caspases, an example of which is caspase 1. Upon stimulation by microbial and damage‐associated signals, inflammasomes assemble to elicit the first line of host defense via the proteolytic maturation of cytokines interleukin‐1β and interleukin‐18, and by induction of pyroptotic cell death. Inflammasome assembly requires activation of an upstream sensor, a downstream effector and, in most cases, an adaptor molecule such as apoptosis‐associate speck‐like protein containing a caspase recruitment domain (ASC). Depending on whether ASC is required, inflammasomes can be categorized into ASC‐dependent and ASC‐independent inflammasomes. Here, we review current understandings of the structures of inflammasomes, as probed using traditional structural methods, as well as biochemical, biophysical and single‐molecule methods. The key structural scaffold for inflammasome assembly is composed of filaments of Pyrin domains and caspase recruitment domains (CARD) in the sensor, adaptor and effector components. Nucleated polymerization appears to govern the ordered assembly process from activation of a Pyrin domain‐containing sensor such as AIM2 by dsDNA or NLRP3 by extracellular particulates, to recruitment of the Pyrin domain and CARD‐containing adaptor ASC, and finally to activation of CARD‐containing caspase 1. The underlying filamentous architecture of inflammasomes and the cooperativity in the assembly may explain the ‘all‐or‐none’ response in inflammasome activation. Inflammasomes are tightly regulated by a number of cytosolic inhibitors, which may change the morphology and assembly kinetics of inflammasomes. Biochemical and cellular studies suggest that Pyrin domain and CARD filaments possess prion‐like properties in propagating inflammasome activation within and between cells.
SUMMARY Mouse p202 containing two HIN domains antagonizes AIM2 inflammasome signaling and potentially modifies lupus susceptibility. We found only HIN1 of p202 binds dsDNA, while HIN2 forms a homo-tetramer. Crystal structures of HIN1 revealed that dsDNA is bound on the opposite face to the site used in AIM2 and IFI16. The structure of HIN2 revealed a dimer of dimers, with the face analogous to the HIN1 dsDNA binding site being a dimerization interface. Electron microscopy imaging showed that HIN1 is flexibly linked to HIN2 in p202, and tetramerization provided enhanced avidity for dsDNA. Surprisingly, HIN2 of p202 interacts with AIM HIN domain. We propose this results in spatial separation of AIM2 pyrin domains, and indeed p202 prevented dsDNA-dependent clustering of ASC and AIM2 inflammasome activation. We hypothesize that while p202 was evolutionarily selected to limit AIM2-mediated inflammation in some mouse strains, the same mechanism contributes to increased interferon production and lupus susceptibility.
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