The inflammasome is a critical molecular complex that activates interleukin-1 driven inflammation in response to pathogen-and danger-associated signals. Germline mutations in the inflammasome sensor NLRP1 cause Mendelian systemic autoimmunity and skin cancer susceptibility, but its endogenous regulation remains less understood. Here we use a proteomics screen to uncover dipeptidyl dipeptidase DPP9 as a novel interacting partner with human NLRP1 and a related inflammasome regulator, CARD8. DPP9 functions as an endogenous inhibitor of NLRP1 inflammasome in diverse primary cell types from human and mice. DPP8/9 inhibition via small molecule drugs and CRISPR/Cas9-mediated genetic deletion specifically activate the human NLRP1 inflammasome, leading to ASC speck formation, pyroptotic cell death, and secretion of cleaved interleukin-1. Mechanistically, DPP9 interacts with a unique autoproteolytic domain (Function to Find Domain (FIIND)) found in NLRP1 and CARD8. This scaffolding function of DPP9 and its
Immune sensor proteins are critical to the function of the human innate immune system. The full repertoire of cognate triggers for human immune sensors is not fully understood. Here, we report that human NLRP1 is activated by 3C proteases (3Cpros) of enteroviruses, such as human rhinovirus (HRV). 3Cpros directly cleave human NLRP1 at a single site between Glu130 and Gly131. This cleavage triggers N-glycine–mediated degradation of the autoinhibitory NLRP1 N-terminal fragment via the cullinZER1/ZYG11B complex, which liberates the activating C-terminal fragment. Infection of primary human airway epithelial cells by live human HRV triggers NLRP1-dependent inflammasome activation and IL-18 secretion. Our findings establish 3Cpros as a pathogen-derived trigger for the human NLRP1 inflammasome and suggest that NLRP1 may contribute to inflammatory diseases of the airway.
Signals arising from bacterial infections are detected by pathogen recognition receptors (PRRs) and are transduced by specialized adapter proteins in mammalian cells. The Receptor-interacting-serine/threonine-protein kinase 2 (RIPK2 or RIP2) is such an adapter protein that is critical for signal propagation of the Nucleotide-binding-oligomerization-domain-containing proteins 1/2 (NOD1 and NOD2). Dysregulation of this signaling pathway leads to defects in bacterial detection and in some cases autoimmune diseases. Here, we show that the Caspase-activation-and-recruitment-domain (CARD) of RIP2 (RIP2-CARD) forms oligomeric structures upon stimulation by either NOD1-CARD or NOD2-2CARD. We reconstitute this complex, termed the RIPosome in vitro and solve the cryo-EM filament structure of the active RIP2-CARD complex at 4.1 Å resolution. The structure suggests potential mechanisms by which CARD domains from NOD1 and NOD2 initiate the oligomerization process of RIP2-CARD. Together with structure guided mutagenesis experiments at the CARD-CARD interfaces, we demonstrate molecular mechanisms how RIP2 is activated and self-propagating such signal.
Nod-like receptor (NLR) proteins activate pyroptotic cell death and IL-1 driven inflammation by assembling and activating the inflammasome complex. Closely related sensor proteins NLRP1 and CARD8 undergo unique auto-proteolysis-dependent activation and are implicated in auto-inflammatory diseases; however, their mechanisms of activation are not understood. Here we report the structural basis of how the activating domains (FIINDUPA-CARD) of NLRP1 and CARD8 self-oligomerize to assemble distinct inflammasome complexes. Recombinant FIINDUPA-CARD of NLRP1 forms a two-layered filament, with an inner core of oligomerized CARD surrounded by an outer ring of FIINDUPA. Biochemically, self-assembled NLRP1-CARD filaments are sufficient to drive ASC speck formation in cultured human cells—a process that is greatly enhanced by NLRP1-FIINDUPA which forms oligomers in vitro. The cryo-EM structures of NLRP1-CARD and CARD8-CARD filaments, solved here at 3.7 Å, uncover unique structural features that enable NLRP1 and CARD8 to discriminate between ASC and pro-caspase-1. In summary, our findings provide structural insight into the mechanisms of activation for human NLRP1 and CARD8 and reveal how highly specific signaling can be achieved by heterotypic CARD interactions within the inflammasome complexes.
Nod-like receptor (NLR) proteins activate pyroptotic cell death and IL-1 driven inflammation by assembling and activating the inflammasome complex. Closely related NLR proteins, NLRP1 and CARD8 undergo unique auto-proteolysis-dependent activation and are implicated in auto-inflammatory diseases; however, the molecular mechanisms of activation are not understood. Here we report the structural basis of how the activating domains (FIIND UPA -CARD) of NLRP1 and CARD8 self-oligomerize to trigger the assembly of distinct inflammasome complexes. Recombinant FIIND UPA -CARD of NLRP1 forms a two-layered filament, with an inner core composed of oligomerized CARD domains and the outer layer consisting of FIIND UPA rings.Biochemically, oligomerized NLRP1-CARD is sufficient to drive ASC speck formation in cultured human cells via filament formation-a process that is greatly enhanced by NLRP1-FIIND UPA , which forms ring-like oligomers in vitro. In addition, we report the cryo-EM structures of NLRP1-CARD and CARD8-CARD filaments at 3.7 Å, which uncovers unique structural features that enable NLRP1 and CARD8 to discriminate between ASC and pro-caspase-1. In summary, our findings provide unique structural insight into the mechanisms of activation for human NLRP1 and CARD8, uncovering an unexpected level of specificity in inflammasome signaling mediated by heterotypic CARD domain interactions.
Viruses pose a constant threat to human health. As a result our innate immune system has evolved multiple strategies to detect the presence of intracellular viral pathogen-associated molecular patterns (PAMPs). The full repertoire of human immune sensors and their PAMP ligands are not completely understood. Here we report that human NLRP1 senses and is activated by 3C proteases (3Cpros) of enteroviruses. Mechanistically, 3Cpros cleave human NLRP1 at a single site immediately after its primate-specific PYRIN domain, leading to oligomerization of its C-terminal fragment. Expression of 3Cpros in primary human cells cause NLRP1-dependent ASC oligomerization, pyroptotic cell death and IL-1 secretion. Consistent with our observation that NLRP1 is the predominant endogenous inflammasome sensor in human airway epithelium, we find that its genetic deletion, or that of ASC, abrogates IL-18 secretion from rhinovirus (HRV)-infected primary human bronchial epithelial cells. Our findings identify the first cognate PAMP ligand for human NLRP1 and assign a new function for the NLRP1 inflammasome in human antiviral immunity and airway inflammation. These results challenge the widely held notion that viral proteases largely serve to disable host immune sensing, and suggest that the human NLRP1 inflammasome may be a therapeutic target to treat inflammatory airway diseases including asthma.
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