Bacterial lipopolysaccharide triggers human caspase-4 (murine caspase-11) to cleave gasdermin-D and induce pyroptotic cell death. How lipopolysaccharide sequestered in membranes of cytosol-invading bacteria activates caspases remains unknown. Here we show that in interferon-γ stimulated cells guanylate binding proteins (GBPs) assemble on the surface of Gram-negative bacteria into polyvalent signaling platforms required for activation of caspase-4. Caspase-4 activation is hierarchically controlled by GBPs; GBP1 initiates platform assembly, GBP2 and GBP4 control caspase-4 recruitment, whereas GBP3 governs caspase-4 activation. In response to cytosol-invading bacteria, activation of caspase-4 through the GBP platform is essential to induce gasdermin-D dependent pyroptosis and processing of interleukin-18, thereby destroying the replicative niche for intracellular bacteria and alerting neighboring cells, respectively. Caspase-11 and GBPs epistatically protect mice against lethal bacterial challenge. Multiple antagonists of the pathway encoded by
Shigella flexneri
, a cytosol-adapted bacterium, provide compelling evolutionary evidence for the importance of the GBP-Caspase-4 pathway in anti-bacterial defense.
Guanylate-binding proteins (GBPs) have recently emerged as central orchestrators of immunity to infection, inflammation, and neoplastic diseases. Within numerous host cell types, these IFN-induced GTPases assemble into large nanomachines that execute distinct host defense activities against a wide variety of microbial pathogens. In addition, GBPs customize inflammasome responses to bacterial infection and sepsis, where they act as critical rheostats to amplify innate immunity and regulate tissue damage. Similar functions are becoming evident for metabolic inflammatory syndromes and cancer, further underscoring the importance of GBPs within infectious as well as altered homeostatic settings. A better understanding of the basic biology of these IFN-induced GTPases could thus benefit clinical approaches to a wide spectrum of important human diseases.
Traditional views of the inflammasome highlight pre-existing core components being assembled under basal conditions shortly after infection or tissue damage. Recent work, however, suggests the inflammasome machinery is also subject to tunable or inducible signals that may accelerate its autocatalytic properties and dictate where inflammasome assembly takes place in the cell. Many of these immune signals operate downstream of interferon (IFN) receptors to elicit inflammasome regulators, including a new family of IFN-induced GTPases termed guanylate binding proteins (GBPs). Here, we examine the critical roles for IFN-induced GBPs in directing inflammasome subtype-specific responses and their consequences for cell-autonomous immunity against a wide variety of microbial pathogens. We discuss emerging mechanisms of action and the potential impact of these GBPs on predisposition to sepsis and other infectious or inflammatory diseases.
Background: TNF receptor-associated factor 2 (TRAF2) is a key adaptor molecule in the TNF receptor (TNFR) signaling pathway.
Results: TRAF-interacting protein (TRIP) inhibits Lys63 -linked TRAF2 ubiquitination by blocking the binding of the cofactor sphingosine 1-phosphate (S1P) to the TRAF2 RING domain. Conclusion: TRIP negatively regulates the TRAF2 ubiquitin-dependent pathway by modulating the TRAF2-S1P interaction. Significance: TRIP is an important cellular regulator of the TNFR-mediated inflammatory response.
Background: Genetic defects in the OSTM1 (osteopetrosis-associated transmembrane protein 1) gene cause autosomal recessive osteopetrosis.
Results:The loss of the transmembrane domain in the OSTM1 gene produces a secreted form of truncated OSTM1 that inhibits osteoclast differentiation and survival. Conclusion: Extracellular secretion of a truncated OSTM1 is negatively involved in osteoclastogenesis. Significance: We identified a novel function for the secreted form of truncated OSTM1 in osteoclastogenesis.
Apoptosis has an important role in maintaining tissue homeostasis in cellular stress responses such as inflammation, endoplasmic reticulum stress, and oxidative stress. T-cell death-associated gene 51 (TDAG51) is a member of the pleckstrin homology-like domain family and was first identified as a pro-apoptotic gene in T-cell receptor-mediated cell death. However, its pro-apoptotic function remains controversial. In this study, we investigated the role of TDAG51 in oxidative stress-induced apoptotic cell death in mouse embryonic fibroblasts (MEFs). TDAG51 expression was highly increased by oxidative stress responses. In response to oxidative stress, the production of intracellular reactive oxygen species was significantly enhanced in TDAG51-deficient MEFs, resulting in the activation of caspase-3. Thus, TDAG51 deficiency promotes apoptotic cell death in MEFs, and these results indicate that TDAG51 has a protective role in oxidative stress-induced cell death in MEFs.
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