Search

Your search keyword '"Chen, Kaiwen W"' showing total 28 results
Start Over Author "Chen, Kaiwen W" Search Limiters Available in Library Collection
28 results on '"Chen, Kaiwen W"'

2. The small molecule raptinal can simultaneously induce apoptosis and inhibit PANX1 activity

Author

Santavanond, Jascinta P., Chiu, Yu-Hsin, Tixeira, Rochelle, Liu, Zonghan, Yap, Jeremy K. Y., Chen, Kaiwen W., Li, Chen-Lu, Lu, Yi-Ru, Roncero-Carol, Joan, Hoijman, Esteban, Rutter, Stephanie F., Shi, Bo, Ryan, Gemma F., Hodge, Amy L., Caruso, Sarah, Baxter, Amy A., Ozkocak, Dilara C., Johnson, Chad, Day, Zoe I., Mayfosh, Alyce J., Hulett, Mark D., Phan, Thanh K., Atkin-Smith, Georgia K., and Poon, Ivan K. H.

Published
2024
Full Text
View/download PDF

9. Genetic targeting of Card19 is linked to disrupted NINJ1 expression, impaired cell lysis, and increased susceptibility to Yersinia infection

Author

Bjanes, Elisabet, primary, Sillas, Reyna Garcia, additional, Matsuda, Rina, additional, Demarco, Benjamin, additional, Fettrelet, Timothée, additional, DeLaney, Alexandra A., additional, Kornfeld, Opher S., additional, Lee, Bettina L., additional, Rodríguez López, Eric M., additional, Grubaugh, Daniel, additional, Wynosky-Dolfi, Meghan A., additional, Philip, Naomi H., additional, Krespan, Elise, additional, Tovar, Dorothy, additional, Joannas, Leonel, additional, Beiting, Daniel P., additional, Henao-Mejia, Jorge, additional, Schaefer, Brian C., additional, Chen, Kaiwen W., additional, Broz, Petr, additional, and Brodsky, Igor E., additional

Published
2021
Full Text
View/download PDF

11. Caspase-1 cleaves Bid to release mitochondrial SMAC and drive secondary necrosis in the absence of GSDMD

Author

Heilig, Rosalie, Dilucca, Marisa, Boucher, Dave, Chen, Kaiwen W, Hancz, Dora, Demarco, Benjamin, Shkarina, Kateryna, and Broz, Petr

Subjects
Inflammasomes, Animals, Apoptosis/genetics, Apoptosis Regulatory Proteins/metabolism, BH3 Interacting Domain Death Agonist Protein/deficiency, BH3 Interacting Domain Death Agonist Protein/genetics, Caspase 1/deficiency, Caspase 1/genetics, Cells, Cultured, Gene Editing, Gene Knockout Techniques, Inflammasomes/metabolism, Intracellular Signaling Peptides and Proteins/deficiency, Intracellular Signaling Peptides and Proteins/genetics, Macrophages/metabolism, Macrophages/pathology, Mice, Mice, Inbred C57BL, Mice, Knockout, Mitochondria/metabolism, Mitochondrial Membranes/metabolism, Mitochondrial Proteins/metabolism, Necrosis/genetics, Necrosis/metabolism, Phosphate-Binding Proteins/deficiency, Phosphate-Binding Proteins/genetics, Pyroptosis/genetics, Signal Transduction/genetics, Transfection, Apoptosis, Mitochondrial Proteins, Necrosis, Pyroptosis, Research Articles, Macrophages, Caspase 1, Intracellular Signaling Peptides and Proteins, Phosphate-Binding Proteins, Mitochondria, Mitochondrial Membranes, biological phenomena, cell phenomena, and immunity, Apoptosis Regulatory Proteins, BH3 Interacting Domain Death Agonist Protein, Signal Transduction, Research Article
Abstract

Caspase-1 activation in GSDMD-deficient cells induces a rapid form of caspase-3–dependent secondary necrosis that is licenced by caspase-1–induced Bid cleavage and the release of mitochondrial SMAC., Caspase-1 drives a lytic inflammatory cell death named pyroptosis by cleaving the pore-forming cell death executor gasdermin-D (GSDMD). Gsdmd deficiency, however, only delays cell lysis, indicating that caspase-1 controls alternative cell death pathways. Here, we show that in the absence of GSDMD, caspase-1 activates apoptotic initiator and executioner caspases and triggers a rapid progression into secondary necrosis. GSDMD-independent cell death required direct caspase-1–driven truncation of Bid and generation of caspase-3 p19/p12 by either caspase-8 or caspase-9. tBid-induced mitochondrial outer membrane permeabilization was also required to drive SMAC release and relieve inhibitor of apoptosis protein inhibition of caspase-3, thereby allowing caspase-3 auto-processing to the fully active p17/p12 form. Our data reveal that cell lysis in inflammasome-activated Gsdmd-deficient cells is caused by a synergistic effect of rapid caspase-1–driven activation of initiator caspases-8/-9 and Bid cleavage, resulting in an unusually fast activation of caspase-3 and immediate transition into secondary necrosis. This pathway might be advantageous for the host in counteracting pathogen-induced inhibition of GSDMD but also has implications for the use of GSDMD inhibitors in immune therapies for caspase-1–dependent inflammatory disease.

Published
2020

12. Caspase-8–dependent gasdermin D cleavage promotes antimicrobial defense but confers susceptibility to TNF-induced lethality

Author

Demarco, Benjamin, primary, Grayczyk, James P., additional, Bjanes, Elisabet, additional, Le Roy, Didier, additional, Tonnus, Wulf, additional, Assenmacher, Charles-Antoine, additional, Radaelli, Enrico, additional, Fettrelet, Timothée, additional, Mack, Vanessa, additional, Linkermann, Andreas, additional, Roger, Thierry, additional, Brodsky, Igor E., additional, Chen, Kaiwen W., additional, and Broz, Petr, additional

Published
2020
Full Text
View/download PDF

16. Human GBP1 binds LPS to initiate assembly of a caspase-4 activating platform on cytosolic bacteria

Author

Carlos Santos, José, Boucher, Dave, Schneider, Larisa Kapinos, Demarco, Benjamin, Dilucca, Marisa, Shkarina, Kateryna, Heilig, Rosalie, Chen, Kaiwen W., Lim, Roderick Y. H., and Broz, Petr

Abstract

The human non-canonical inflammasome controls caspase-4 activation and gasdermin-Ddependent pyroptosis in response to cytosolic bacterial lipopolysaccharide (LPS). Since LPS binds and oligomerizes caspase-4, the pathway is thought to proceed without dedicated LPS sensors or an activation platform. Here we report that interferon-induced guanylate-binding proteins (GBPs) are required for non-canonical inflammasome activation by cytosolic Salmonella or upon cytosolic delivery of LPS. GBP1 associates with the surface of cytosolic Salmonella seconds after bacterial escape from their vacuole, initiating the recruitment of GBP2-4 to assemble a GBP coat. The GBP coat then promotes the recruitment of caspase-4 to the bacterial surface and caspase activation, in absence of bacteriolysis. Mechanistically, GBP1 binds LPS with high affinity through electrostatic interactions. Our findings indicate that in human epithelial cells GBP1 acts as a cytosolic LPS sensor and assembles a platform for caspase-4 recruitment and activation at LPS-containing membranes as the first step of noncanonical inflammasome signaling. [ABSTRACT FROM AUTHOR]

Published
2020
Full Text
View/download PDF

17. Interleukin-1β Maturation Triggers Its Relocation to the Plasma Membrane for Gasdermin-D-Dependent and -Independent Secretion

Author

Monteleone, Mercedes, primary, Stanley, Amanda C., additional, Chen, Kaiwen W., additional, Brown, Darren L., additional, Bezbradica, Jelena S., additional, von Pein, Jessica B., additional, Holley, Caroline L., additional, Boucher, Dave, additional, Shakespear, Melanie R., additional, Kapetanovic, Ronan, additional, Rolfes, Verena, additional, Sweet, Matthew J., additional, Stow, Jennifer L., additional, and Schroder, Kate, additional

Published
2018
Full Text
View/download PDF

18. Caspase-1 self-cleavage is an intrinsic mechanism to terminate inflammasome activity

Author

Boucher, Dave, primary, Monteleone, Mercedes, additional, Coll, Rebecca C., additional, Chen, Kaiwen W., additional, Ross, Connie M., additional, Teo, Jessica L., additional, Gomez, Guillermo A., additional, Holley, Caroline L., additional, Bierschenk, Damien, additional, Stacey, Katryn J., additional, Yap, Alpha S., additional, Bezbradica, Jelena S., additional, and Schroder, Kate, additional

Published
2018
Full Text
View/download PDF

19. XIAP Loss Triggers RIPK3- and Caspase-8-Driven IL-1β Activation and Cell Death as a Consequence of TLR-MyD88-Induced cIAP1-TRAF2 Degradation

Author

Lawlor, Kate E., primary, Feltham, Rebecca, additional, Yabal, Monica, additional, Conos, Stephanie A., additional, Chen, Kaiwen W., additional, Ziehe, Stephanie, additional, Graß, Carina, additional, Zhan, Yifan, additional, Nguyen, Tan A., additional, Hall, Cathrine, additional, Vince, Angelina J., additional, Chatfield, Simon M., additional, D’Silva, Damian B., additional, Pang, Kenneth C., additional, Schroder, Kate, additional, Silke, John, additional, Vaux, David L., additional, Jost, Philipp J., additional, and Vince, James E., additional

Published
2017
Full Text
View/download PDF

21. Rab8a interacts directly with PI3Kγ to modulate TLR4-driven PI3K and mTOR signalling

Author

Luo, Lin, primary, Wall, Adam A., additional, Yeo, Jeremy C., additional, Condon, Nicholas D., additional, Norwood, Suzanne J., additional, Schoenwaelder, Simone, additional, Chen, Kaiwen W., additional, Jackson, Shaun, additional, Jenkins, Brendan J., additional, Hartland, Elizabeth L., additional, Schroder, Kate, additional, Collins, Brett M., additional, Sweet, Matthew J., additional, and Stow, Jennifer L., additional

Published
2014
Full Text
View/download PDF

23. Beyond inflammasomes: emerging function of gasdermins during apoptosis and NETosis.

Author

Chen, Kaiwen W, Demarco, Benjamin, and Broz, Petr

Subjects
*APOPTOSIS, *INFLAMMASOMES, *PROTEINS, *CELLULAR signal transduction, *NECROSIS
Abstract

Programmed cell death is a key mechanism involved in several biological processes ranging from development and homeostasis to immunity, where it promotes the removal of stressed, damaged, malignant or infected cells. Abnormalities in the pathways leading to initiation of cell death or removal of dead cells are consequently associated with a range of human diseases including infections, autoinflammatory disease, neurodegenerative disease and cancer. Apoptosis, pyroptosis and NETosis are three well‐studied modes of cell death that were traditionally believed to be independent of one another, but emerging evidence indicates that there is extensive cross‐talk between them, and that all three pathways can converge onto the activation of the same cell death effector—the pore‐forming protein Gasdermin D (GSDMD). In this review, we highlight recent advances in gasdermin research, with a particular focus on the role of gasdermins in pyroptosis, NETosis and apoptosis, as well as cell type‐specific consequences of gasdermin activation. In addition, we discuss controversies surrounding a related gasdermin family protein, Gasdermin E (GSDME), in mediating pyroptosis and secondary necrosis following apoptosis, chemotherapy and inflammasome activation. [ABSTRACT FROM AUTHOR]

Published
2020
Full Text
View/download PDF

24. Extrinsic and intrinsic apoptosis activate pannexin‐1 to drive NLRP3 inflammasome assembly.

Author

Chen, Kaiwen W, Demarco, Benjamin, Heilig, Rosalie, Shkarina, Kateryna, Boettcher, Andreas, Farady, Christopher J, Pelczar, Pawel, and Broz, Petr

Subjects
*APOPTOSIS, *CELL death, *CANCER chemotherapy, *LYSIS, *CASPASES
Abstract

Pyroptosis is a form of lytic inflammatory cell death driven by inflammatory caspase‐1, caspase‐4, caspase‐5 and caspase‐11. These caspases cleave and activate the pore‐forming protein gasdermin D (GSDMD) to induce membrane damage. By contrast, apoptosis is driven by apoptotic caspase‐8 or caspase‐9 and has traditionally been classified as an immunologically silent form of cell death. Emerging evidence suggests that therapeutics designed for cancer chemotherapy or inflammatory disorders such as SMAC mimetics, TAK1 inhibitors and BH3 mimetics promote caspase‐8 or caspase‐9‐dependent inflammatory cell death and NLRP3 inflammasome activation. However, the mechanism by which caspase‐8 or caspase‐9 triggers cell lysis and NLRP3 activation is still undefined. Here, we demonstrate that during extrinsic apoptosis, caspase‐1 and caspase‐8 cleave GSDMD to promote lytic cell death. By engineering a novel Gsdmd D88A knock‐in mouse, we further demonstrate that this proinflammatory function of caspase‐8 is counteracted by caspase‐3‐dependent cleavage and inactivation of GSDMD at aspartate 88, and is essential to suppress GSDMD‐dependent cell lysis during caspase‐8‐dependent apoptosis. Lastly, we provide evidence that channel‐forming glycoprotein pannexin‐1, but not GSDMD or GSDME promotes NLRP3 inflammasome activation during caspase‐8 or caspase‐9‐dependent apoptosis. Synopsis: The apoptotic signalling cascade promotes NLRP3 inflammasome assembly by activating the channel‐forming glycoprotein, pannexin‐1. Extrinsic apoptosis promotes caspase‐1 and ‐8‐dependent GSDMD activation in parallel with caspase‐3/7‐dependent secondary necrosis.Caspase‐3 suppresses GSDMD‐dependent cell lysis during extrinsic apoptosis.GSDME is activated during extrinsic and intrinsic apoptosis, but it does not contribute to cell lysis in macrophages.NLRP3 assembly during extrinsic and intrinsic apoptosis is dependent on pannexin‐1 but not gasdermin D or E pores. [ABSTRACT FROM AUTHOR]

Published
2019
Full Text
View/download PDF

25. XIAP Loss Triggers RIPK3- and Caspase-8-Driven IL-1β Activation and Cell Death as a Consequence of TLR-MyD88-Induced cIAP1-TRAF2 Degradation

Author

Philipp J. Jost, Angelina J. Vince, Stephanie A. Conos, Yifan Zhan, Kate Schroder, David L. Vaux, Simon M Chatfield, Monica Yabal, Carina Graß, Stephanie Ziehe, John Silke, Kaiwen W. Chen, Kate E. Lawlor, Ken C Pang, Tan A. Nguyen, James E Vince, Damian B D'Silva, Rebecca Feltham, Cathrine Hall, Lawlor, Kate E, Feltham, Rebecca, Yabal, Monica, Conos, Stephanie A, Chen, Kaiwen W, Ziehe, Stephanie, Graß, Carina, Zhan, Yifan, Nguyen, Tan A, Hall, Cathrine, Vince, Angelina J, Chatfield, Simon M, D'Silva, Damian B, Pang, Kenneth C, Schroder, Kate, Silke, John, Vaux, David L, Jost, Philipp J, and Vince, James E

Subjects
0301 basic medicine, Programmed cell death, TRAF2, proteasomal degradation, Necroptosis, Interleukin-1beta, necroptosis, Inhibitor of apoptosis, Caspase 8, RIPK3, General Biochemistry, Genetics and Molecular Biology, caspase-8, Inhibitor of Apoptosis Proteins, 03 medical and health sciences, Mice, XIAP, NLRP3, autoinflammatory disease, autoinflammatory conditions, Toll-like receptor, medicine, XIAP deficiency, Animals, XIAP Deficiency, lcsh:QH301-705.5, Mice, Knockout, Cell Death, Chemistry, Toll-Like Receptors, apoptosis, Inflammasome, interferon, TNF Receptor-Associated Factor 2, 3. Good health, cIAP1, TNFR2, 030104 developmental biology, cell death, interleukin (IL)-18, lcsh:Biology (General), Receptor-Interacting Protein Serine-Threonine Kinases, Myeloid Differentiation Factor 88, Proteolysis, Cancer research, medicine.drug
Abstract

X-linked Inhibitor of Apoptosis (XIAP) deficiency predisposes people to pathogen-associated hyperinflammation. Upon XIAP loss, Toll-like receptor (TLR) ligation triggers RIPK3-caspase-8-mediated IL-1β activation and death in myeloid cells. How XIAP suppresses these events remains unclear. Here, we show that TLR-MyD88 causes the proteasomal degradation of the related IAP, cIAP1, and its adaptor, TRAF2, by inducing TNF and TNF Receptor 2 (TNFR2) signaling. Genetically, we define that myeloid-specific cIAP1 loss promotes TLR-induced RIPK3-caspase-8 and IL-1β activity in the absence of XIAP. Importantly, deletion of TNFR2 in XIAP-deficient cells limited TLR-MyD88-induced cIAP1-TRAF2 degradation, cell death, and IL-1β activation. In contrast to TLR-MyD88, TLR-TRIF-induced interferon (IFN)β inhibited cIAP1 loss and consequent cell death. These data reveal how, upon XIAP deficiency, a TLR-TNF-TNFR2 axis drives cIAP1-TRAF2 degradation to allow TLR or TNFR1 activation of RIPK3-caspase-8 and IL-1β. This mechanism may explain why XIAP-deficient patients can exhibit symptoms reminiscent of patients with activating inflammasome mutations. Refereed/Peer-reviewed

Published
2017

26. Caspase-1 self-cleavage is an intrinsic mechanism to terminate inflammasome activity

Author

Dave Boucher, Rebecca C. Coll, Alpha S. Yap, Damien Bierschenk, Jelena S. Bezbradica, Kaiwen W. Chen, Guillermo A. Gomez, Mercedes Monteleone, Kate Schroder, Katryn J. Stacey, Connie M. Ross, Jessica L. Teo, Caroline L. Holley, Boucher, Dave, Monteleone, Mercedes, Coll, Rebecca C, Chen, Kaiwen W, Ross, Connie M, Teo, Jessica L, Gomez, Guillermo A, Holley, Caroline L, Bierschenk, Damien, Stacey, Katryn J, Yap, Alpha S, Bezbradica, Jelena S, and Schroder, Kate

Subjects
0301 basic medicine, Cell type, Inflammasomes, medicine.medical_treatment, animal diseases, viruses, Immunology, Kinetics, Cell, Interleukin-1beta, Caspase 1, caspase-1, inflammasome-dependent inflammatory responses, Article, law.invention, 03 medical and health sciences, Tetramer, law, medicine, otorhinolaryngologic diseases, Immunology and Allergy, inflammasomes, Research Articles, Protease, Chemistry, Macrophages, Inflammasome, Cell biology, 030104 developmental biology, medicine.anatomical_structure, nervous system, Recombinant DNA, sense organs, medicine.drug
Abstract

The inflammasome generates caspase-1 p20/p10, presumed to be the active protease. Boucher et al. demonstrate that the inflammasome contains an active caspase-1 species, p33/p10, and functions as a holoenzyme. Further caspase-1 self-processing generates and releases p20/p10 to terminate protease activity., Host-protective caspase-1 activity must be tightly regulated to prevent pathology, but mechanisms controlling the duration of cellular caspase-1 activity are unknown. Caspase-1 is activated on inflammasomes, signaling platforms that facilitate caspase-1 dimerization and autoprocessing. Previous studies with recombinant protein identified a caspase-1 tetramer composed of two p20 and two p10 subunits (p20/p10) as an active species. In this study, we report that in the cell, the dominant species of active caspase-1 dimers elicited by inflammasomes are in fact full-length p46 and a transient species, p33/p10. Further p33/p10 autoprocessing occurs with kinetics specified by inflammasome size and cell type, and this releases p20/p10 from the inflammasome, whereupon the tetramer becomes unstable in cells and protease activity is terminated. The inflammasome–caspase-1 complex thus functions as a holoenzyme that directs the location of caspase-1 activity but also incorporates an intrinsic self-limiting mechanism that ensures timely caspase-1 deactivation. This intrinsic mechanism of inflammasome signal shutdown offers a molecular basis for the transient nature, and coordinated timing, of inflammasome-dependent inflammatory responses., Graphical Abstract

Published
2018

27. Active MLKL triggers the NLRP3 inflammasome in a cell-intrinsic manner

Author

James M. Murphy, Lachlan Whitehead, Lisa M Lindqvist, Seth L. Masters, Stephanie A. Conos, Dominic De Nardo, Hideki Hara, Kate Schroder, James E Vince, Gabriel Núñez, Kate E. Lawlor, David L. Vaux, Kaiwen W. Chen, Conos, Stephanie A, Chen, Kaiwen W, De Nardo, Dominic, Hara, Hideki, Whitehead, Lachlan, Nunez, Gabriel, Masters, Seth L, Murphy, James M, Schroder, Kate, Vaux, David L, Lawlor, Kate E, Lindqvist, Lisa M, and Vince, James E

Subjects
0301 basic medicine, Programmed cell death, Multidisciplinary, integumentary system, interleukin-1β, Necroptosis, Pyroptosis, Caspase 1, necroptosis, Signal transducing adaptor protein, Inflammasome, Biology, Gasdermin D, Proinflammatory cytokine, Cell biology, Multidisciplinary Sciences, 03 medical and health sciences, 030104 developmental biology, NLRP3, medicine, Secretion, MLKL, medicine.drug
Abstract

Necroptosis is a physiological cell suicide mechanism initiated by receptor-interacting protein kinase-3 (RIPK3) phosphorylation of mixed-lineage kinase domain-like protein (MLKL), which results in disruption of the plasma membrane. Necroptotic cell lysis, and resultant release of proinflammatory mediators, is thought to cause inflammation in necroptotic disease models. However, we previously showed that MLKL signaling can also promote inflammation by activating the nucleotide-binding oligomerization domain (NOD)- like receptor protein 3 (NLRP3) inflammasome to recruit the adaptor protein apoptosis-Associated speck-like protein containing a caspase activation and recruitment domain (ASC) and trigger caspase-1 processing of the proinflammatory cytokine IL-1β. diseases. Here, we provide evidence that MLKL-induced activation of NLRP3 requires (i) the death effector four-helical bundle of MLKL, (ii) oligomerization and association of MLKL with cellular membranes, and (iii) a reduction in intracellular potassium concentration. Although genetic or pharmacological targeting of NLRP3 or caspase-1 prevented MLKLinduced IL-1β secretion, they did not prevent necroptotic cell death. Gasdermin D (GSDMD), the pore-forming caspase-1 substrate required for efficient NLRP3-Triggered pyroptosis and IL-1β release, was not essential for MLKL-dependent death or IL-1β secretion. Imaging of MLKL-dependent ASC speck formation demonstrated that necroptotic stimuli activate NLRP3 cell-intrinsically, indicating that MLKL-induced NLRP3 inflammasome formation and IL-1β cleavage occur before cell lysis. Furthermore, we show that necroptotic activation of NLRP3, but not necroptotic cell death alone, is necessary for the activation of NF-κB in healthy bystander cells. Collectively, these results demonstrate the potential importance of NLRP3 inflammasome activity as a driving force for inflammation in MLKLdependent Refereed/Peer-reviewed

Published
2017

28. Caspase-1 cleaves Bid to release mitochondrial SMAC and drive secondary necrosis in the absence of GSDMD.

Author

Heilig R, Dilucca M, Boucher D, Chen KW, Hancz D, Demarco B, Shkarina K, and Broz P

Subjects
Animals, Apoptosis genetics, BH3 Interacting Domain Death Agonist Protein genetics, Caspase 1 genetics, Cells, Cultured, Gene Editing, Gene Knockout Techniques, Inflammasomes metabolism, Intracellular Signaling Peptides and Proteins genetics, Macrophages metabolism, Macrophages pathology, Mice, Mice, Inbred C57BL, Mice, Knockout, Mitochondrial Membranes metabolism, Necrosis genetics, Necrosis metabolism, Phosphate-Binding Proteins genetics, Pyroptosis genetics, Transfection, Apoptosis Regulatory Proteins metabolism, BH3 Interacting Domain Death Agonist Protein deficiency, Caspase 1 deficiency, Intracellular Signaling Peptides and Proteins deficiency, Mitochondria metabolism, Mitochondrial Proteins metabolism, Phosphate-Binding Proteins deficiency, Signal Transduction genetics
Abstract

Caspase-1 drives a lytic inflammatory cell death named pyroptosis by cleaving the pore-forming cell death executor gasdermin-D (GSDMD). Gsdmd deficiency, however, only delays cell lysis, indicating that caspase-1 controls alternative cell death pathways. Here, we show that in the absence of GSDMD, caspase-1 activates apoptotic initiator and executioner caspases and triggers a rapid progression into secondary necrosis. GSDMD-independent cell death required direct caspase-1-driven truncation of Bid and generation of caspase-3 p19/p12 by either caspase-8 or caspase-9. tBid-induced mitochondrial outer membrane permeabilization was also required to drive SMAC release and relieve inhibitor of apoptosis protein inhibition of caspase-3, thereby allowing caspase-3 auto-processing to the fully active p17/p12 form. Our data reveal that cell lysis in inflammasome-activated Gsdmd -deficient cells is caused by a synergistic effect of rapid caspase-1-driven activation of initiator caspases-8/-9 and Bid cleavage, resulting in an unusually fast activation of caspase-3 and immediate transition into secondary necrosis. This pathway might be advantageous for the host in counteracting pathogen-induced inhibition of GSDMD but also has implications for the use of GSDMD inhibitors in immune therapies for caspase-1-dependent inflammatory disease., (© 2020 Heilig et al.)

Published
2020
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results