BAK/BAX macropores facilitate mitochondrial herniation and mtDNA efflux during apoptosis

McArthur, Kate; Whitehead, Lachlan; Heddleston, John M.; Li, Lucy; Padman, Benjamin Scott; Oorschot, Viola; Geoghegan, Niall; Davidson, Sophia; Chin, Hui San; Lane, Rachael M.; Dramićanin, Marija; Saunders, Tahnee L.; Sugiana, Canny; Lessene, Romina; Osellame, Laura D.; Chew, Teng Leong; Dewson, Grant; Lazarou, Michael; Ramm, Georg; Lessène, Guillaume; Ryan, Michael; Rogers, Kelly L.; Delft, Mark F. van; Kile, Benjamin T.

doi:10.1126/science.aao6047

Cited by 721 publications

(560 citation statements)

References 81 publications

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“…Indeed, they found that treatment of cells with BCL‐2 targeting drugs, called BH3 mimetics, was able to stimulate the release of the pro‐inflammatory cytokines IL‐6, IL‐8, CXCL1 and FGF‐2 in the absence of cell death. Consistent with recent findings, this pro‐inflammatory phenotype was dependent on BAX/BAK and STING (McArthur et al , ; Riley et al , ). Accordingly, they found that depleting cells of mtDNA, using a mitochondrial‐targeted viral DNase, was able to reduce IL‐6 secretion following BH3‐mimetic treatment.…”

Section: Limited Mitochondrial Permeabilisation Drives Inflammation Isupporting

confidence: 91%

“…Mitochondrial permeabilisation elicits inflammation in multiple ways. For instance, recent work shows that mtDNA is ejected from permeabilised mitochondria during cell death, activating cGAS‐STING‐dependent type I interferon production (McArthur et al , ; Riley et al , ). While dispensable for cell death, apoptotic caspases serve to dampen inflammation by targeting multiple cellular processes (McIlwain et al , ; Ning et al , ).…”

Section: Limited Mitochondrial Permeabilisation Drives Inflammation Imentioning

confidence: 99%

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Mitochondria and pathogen immunity: from killer to firestarter

Riley

Tait

2019

The EMBO Journal

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Serving as an innate defence mechanism, invading pathogens elicit a broad inflammatory response in cells. In this issue, Brokatzky et al (2019) report that pathogens can cause activation of BAX/BAK which permeabilises a limited number of mitochondria. Induction of DNA damage, or release of mtDNA, triggers STING‐dependent pro‐inflammatory cytokine expression and secretion, revealing an unexpected role for the mitochondrial apoptotic machinery in immune defence.

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Section: Limited Mitochondrial Permeabilisation Drives Inflammation Isupporting

confidence: 91%

Section: Limited Mitochondrial Permeabilisation Drives Inflammation Imentioning

confidence: 99%

Mitochondria and pathogen immunity: from killer to firestarter

Riley

Tait

2019

The EMBO Journal

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“…Little IL‐6 secretion was seen in melanoma cells where apoptosis signaling was inhibited by Bcl‐X L (Fig F and G). Mitochondrial DNA (mtDNA) may, when released into the cytosol (McArthur et al , ), trigger a cytokine response through the cyclic GMP‐AMP synthase (cGAS) and the stimulator of interferon genes (STING) (Rongvaux et al , ; White et al , ). We therefore generated a HeLa cell line where mtDNA was degraded upon tamoxifen‐regulated expression of a viral DNase (HSV‐1 UL 12.5) targeted to mitochondria (Corcoran et al , ) (Fig H).…”

Section: Resultsmentioning

confidence: 99%

A non‐death function of the mitochondrial apoptosis apparatus in immunity

et al. 2019

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Apoptosis is a frequent form of programmed cell death, but the apoptotic signaling pathway can also be engaged at a low level, in the absence of cell death. We here report that such sub‐lethal engagement of mitochondrial apoptosis signaling causes the secretion of cytokines from human epithelial cells in a process controlled by the Bcl‐2 family of proteins. We further show that sub‐lethal signaling of the mitochondrial apoptosis pathway is initiated by infections with all tested viral, bacterial, and protozoan pathogens and causes damage to the genomic DNA. Epithelial cells infected with these pathogens secreted cytokines, and this cytokine secretion upon microbial infection was substantially reduced if mitochondrial sub‐lethal apoptosis signaling was blocked. In the absence of mitochondrial pro‐apoptotic signaling, the ability of epithelial cells to restrict intracellular bacterial growth was impaired. Triggering of the mitochondrial apoptosis apparatus thus not only causes apoptosis but also has an independent role in immune defense.

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“…CCs do not activate platelets directly or induce clotting of full blood (C. Shi, T. Kim, S. Steiger, S. R. Mulay, B. M. Klinkhammer, T. Bäuerle, M. E. Melica, P. Romagnani, L. Yang, D. Möckel, M. Baues, E. Mammadova‐Bach, B. Sanne, J. W. M. Heemskerk, A. Braun, T. Lammers, P. Boor, H. J. Anders, unpublished observation) but trigger mechanical injury to endothelial cells and activate complements, which leads to the release of tissue factor and nuclear DNA both initiating the clotting process (C. Shi, T. Kim, S. Steiger, S. R. Mulay, B. M. Klinkhammer, T. Bäuerle, M. E. Melica, P. Romagnani, L. Yang, D. Möckel, M. Baues, E. Mammadova‐Bach, B. Sanne, J. W. M. Heemskerk, A. Braun, T. Lammers, P. Boor, H. J. Anders, unpublished observation). The indirect activation of platelets increases the amount of prothrombotic extracellular DNA as activated platelets release mitochondrial DNA (C. Shi, T. Kim, S. Steiger, S. R. Mulay, B. M. Klinkhammer, T. Bäuerle, M. E. Melica, P. Romagnani, L. Yang, D. Möckel, M. Baues, E. Mammadova‐Bach, B. Sanne, J. W. M. Heemskerk, A. Braun, T. Lammers, P. Boor, H. J. Anders, unpublished observation) . Also, NETs partially contribute to this process (C. Shi, T. Kim, S. Steiger, S. R. Mulay, B. M. Klinkhammer, T. Bäuerle, M. E. Melica, P. Romagnani, L. Yang, D. Möckel, M. Baues, E. Mammadova‐Bach, B. Sanne, J. W. M. Heemskerk, A. Braun, T. Lammers, P. Boor, H. J. Anders, unpublished observation).…”

Section: How Do Crystals Trigger Thrombosis?mentioning

confidence: 99%

A guide to crystal‐related and nano‐ or microparticle‐related tissue responses

et al. 2020

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Crystals and nano‐ and microparticles form inside the human body from intrinsic proteins, minerals, or metabolites or enter the body as particulate matter from occupational and environmental sources. Associated tissue injuries and diseases mostly develop from cellular responses to such crystal deposits and include inflammation, cell necrosis, granuloma formation, tissue fibrosis, and stone‐related obstruction of excretory organs. But how do crystals and nano‐ and microparticles trigger these biological processes? Which pathomechanisms are identical across different particle types, sizes, and shapes? In addition, which mechanisms are specific to the atomic or molecular structure of crystals or to specific sizes or shapes? Do specific cellular or molecular mechanisms qualify as target for therapeutic interventions? Here, we provide a guide to approach this diverse and multidisciplinary research domain. We give an overview about the clinical spectrum of crystallopathies, about shared and specific pathomechanisms as a conceptual overview before digging deeper into the specialty field of interest.

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BAK/BAX macropores facilitate mitochondrial herniation and mtDNA efflux during apoptosis

Cited by 721 publications

References 81 publications

Mitochondria and pathogen immunity: from killer to firestarter

Mitochondria and pathogen immunity: from killer to firestarter

A non‐death function of the mitochondrial apoptosis apparatus in immunity

A guide to crystal‐related and nano‐ or microparticle‐related tissue responses

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