Literature DB >> 33589776

A toolbox for imaging RIPK1, RIPK3, and MLKL in mouse and human cells.

André L Samson1,2, Cheree Fitzgibbon3, Komal M Patel3, Joanne M Hildebrand3,4, Lachlan W Whitehead3,4, Joel S Rimes3,4, Annette V Jacobsen3,4, Christopher R Horne3,4, Xavier J Gavin3,4, Samuel N Young3, Kelly L Rogers3,4, Edwin D Hawkins3,4, James M Murphy5,6.   

Abstract

Necroptosis is a lytic, inflammatory cell death pathway that is dysregulated in many human pathologies. The pathway is executed by a core machinery comprising the RIPK1 and RIPK3 kinases, which assemble into necrosomes in the cytoplasm, and the terminal effector pseudokinase, MLKL. RIPK3-mediated phosphorylation of MLKL induces oligomerization and translocation to the plasma membrane where MLKL accumulates as hotspots and perturbs the lipid bilayer to cause death. The precise choreography of events in the pathway, where they occur within cells, and pathway differences between species, are of immense interest. However, they have been poorly characterized due to a dearth of validated antibodies for microscopy studies. Here, we describe a toolbox of antibodies for immunofluorescent detection of the core necroptosis effectors, RIPK1, RIPK3, and MLKL, and their phosphorylated forms, in human and mouse cells. By comparing reactivity with endogenous proteins in wild-type cells and knockout controls in basal and necroptosis-inducing conditions, we characterise the specificity of frequently-used commercial and recently-developed antibodies for detection of necroptosis signaling events. Importantly, our findings demonstrate that not all frequently-used antibodies are suitable for monitoring necroptosis by immunofluorescence microscopy, and methanol- is preferable to paraformaldehyde-fixation for robust detection of specific RIPK1, RIPK3, and MLKL signals.

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Year:  2021        PMID: 33589776      PMCID: PMC8257593          DOI: 10.1038/s41418-021-00742-x

Source DB:  PubMed          Journal:  Cell Death Differ        ISSN: 1350-9047            Impact factor:   12.067


  61 in total

1.  Viral MLKL Homologs Subvert Necroptotic Cell Death by Sequestering Cellular RIPK3.

Authors:  Emma J Petrie; Jarrod J Sandow; Wil I L Lehmann; Lung-Yu Liang; Diane Coursier; Samuel N Young; Wilhelmus J A Kersten; Cheree Fitzgibbon; André L Samson; Annette V Jacobsen; Kym N Lowes; Amanda E Au; Hélène Jousset Sabroux; Najoua Lalaoui; Andrew I Webb; Guillaume Lessene; Gerard Manning; Isabelle S Lucet; James M Murphy
Journal:  Cell Rep       Date:  2019-09-24       Impact factor: 9.423

2.  Respiratory Syncytial Virus Infection Promotes Necroptosis and HMGB1 Release by Airway Epithelial Cells.

Authors:  Jennifer Simpson; Zhixuan Loh; Md Ashik Ullah; Jason P Lynch; Rhiannon B Werder; Natasha Collinson; Vivian Zhang; Yves Dondelinger; Mathieu J M Bertrand; Mark L Everard; Christopher C Blyth; Gunter Hartel; Antoon J Van Oosterhout; Peter J Gough; John Bertin; John W Upham; Kirsten M Spann; Simon Phipps
Journal:  Am J Respir Crit Care Med       Date:  2020-06-01       Impact factor: 21.405

3.  Herpes simplex virus suppresses necroptosis in human cells.

Authors:  Hongyan Guo; Shinya Omoto; Philip A Harris; Joshua N Finger; John Bertin; Peter J Gough; William J Kaiser; Edward S Mocarski
Journal:  Cell Host Microbe       Date:  2015-02-11       Impact factor: 21.023

Review 4.  Regulated necrosis in kidney ischemia-reperfusion injury.

Authors:  Aspasia Pefanis; Francesco L Ierino; James M Murphy; Peter J Cowan
Journal:  Kidney Int       Date:  2019-03-07       Impact factor: 10.612

5.  Necroptosis Promotes Staphylococcus aureus Clearance by Inhibiting Excessive Inflammatory Signaling.

Authors:  Kipyegon Kitur; Sarah Wachtel; Armand Brown; Matthew Wickersham; Franklin Paulino; Hernán F Peñaloza; Grace Soong; Susan Bueno; Dane Parker; Alice Prince
Journal:  Cell Rep       Date:  2016-08-11       Impact factor: 9.423

6.  Phosphorylation-driven assembly of the RIP1-RIP3 complex regulates programmed necrosis and virus-induced inflammation.

Authors:  Young Sik Cho; Sreerupa Challa; David Moquin; Ryan Genga; Tathagat Dutta Ray; Melissa Guildford; Francis Ka-Ming Chan
Journal:  Cell       Date:  2009-06-12       Impact factor: 41.582

7.  EspL is a bacterial cysteine protease effector that cleaves RHIM proteins to block necroptosis and inflammation.

Authors:  Jaclyn S Pearson; Cristina Giogha; Sabrina Mühlen; Ueli Nachbur; Chi L L Pham; Ying Zhang; Joanne M Hildebrand; Clare V Oates; Tania Wong Fok Lung; Danielle Ingle; Laura F Dagley; Aleksandra Bankovacki; Emma J Petrie; Gunnar N Schroeder; Valerie F Crepin; Gad Frankel; Seth L Masters; James Vince; James M Murphy; Margaret Sunde; Andrew I Webb; John Silke; Elizabeth L Hartland
Journal:  Nat Microbiol       Date:  2017-01-13       Impact factor: 30.964

8.  Necroptosis and ferroptosis are alternative cell death pathways that operate in acute kidney failure.

Authors:  Tammo Müller; Christin Dewitz; Jessica Schmitz; Anna Sophia Schröder; Jan Hinrich Bräsen; Brent R Stockwell; James M Murphy; Ulrich Kunzendorf; Stefan Krautwald
Journal:  Cell Mol Life Sci       Date:  2017-05-27       Impact factor: 9.261

9.  Necroptosis restricts influenza A virus as a stand-alone cell death mechanism.

Authors:  Maria Shubina; Bart Tummers; David F Boyd; Ting Zhang; Chaoran Yin; Avishekh Gautam; Xi-Zhi J Guo; Diego A Rodriguez; William J Kaiser; Peter Vogel; Douglas R Green; Paul G Thomas; Siddharth Balachandran
Journal:  J Exp Med       Date:  2020-11-02       Impact factor: 14.307

10.  Human cytomegalovirus protein pUL36: A dual cell death pathway inhibitor.

Authors:  Alice Fletcher-Etherington; Luis Nobre; Katie Nightingale; Robin Antrobus; Jenna Nichols; Andrew J Davison; Richard J Stanton; Michael P Weekes
Journal:  Proc Natl Acad Sci U S A       Date:  2020-07-20       Impact factor: 12.779
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  6 in total

1.  Endothelial Caspase-8 prevents fatal necroptotic hemorrhage caused by commensal bacteria.

Authors:  Stefanie M Bader; Simon P Preston; Katie Saliba; Adam Lipszyc; Zoe L Grant; Liana Mackiewicz; Andrew Baldi; Anne Hempel; Michelle P Clark; Thanushi Peiris; William Clow; Jan Bjelic; Michael D Stutz; Philip Arandjelovic; Jack Teale; Fashuo Du; Leigh Coultas; James M Murphy; Cody C Allison; Marc Pellegrini; Andre L Samson
Journal:  Cell Death Differ       Date:  2022-07-23       Impact factor: 12.067

2.  Single cell analysis of PANoptosome cell death complexes through an expansion microscopy method.

Authors:  Yaqiu Wang; Nagakannan Pandian; Joo-Hui Han; Balamurugan Sundaram; SangJoon Lee; Rajendra Karki; Clifford S Guy; Thirumala-Devi Kanneganti
Journal:  Cell Mol Life Sci       Date:  2022-09-28       Impact factor: 9.207

3.  A family harboring an MLKL loss of function variant implicates impaired necroptosis in diabetes.

Authors:  Joanne M Hildebrand; Bernice Lo; Sara Tomei; Valentina Mattei; Samuel N Young; Cheree Fitzgibbon; James M Murphy; Abeer Fadda
Journal:  Cell Death Dis       Date:  2021-04-01       Impact factor: 8.469

4.  Human RIPK3 maintains MLKL in an inactive conformation prior to cell death by necroptosis.

Authors:  Yanxiang Meng; Katherine A Davies; Cheree Fitzgibbon; Samuel N Young; Sarah E Garnish; Christopher R Horne; Cindy Luo; Jean-Marc Garnier; Lung-Yu Liang; Angus D Cowan; Andre L Samson; Guillaume Lessene; Jarrod J Sandow; Peter E Czabotar; James M Murphy
Journal:  Nat Commun       Date:  2021-11-22       Impact factor: 14.919

5.  Blockage of MLKL prevents myelin damage in experimental diabetic neuropathy.

Authors:  Jia Guo; Zehui Guo; Yanju Huang; Suchen Ma; Bo Yan; Chenjie Pan; Zhaodi Jiang; Fengchao Wang; Zhiyuan Zhang; Yuwei Da; Xiaodong Wang; Zhengxin Ying
Journal:  Proc Natl Acad Sci U S A       Date:  2022-03-28       Impact factor: 12.779

6.  Human RIPK3 C-lobe phosphorylation is essential for necroptotic signaling.

Authors:  Yanxiang Meng; Christopher R Horne; Andre L Samson; Laura F Dagley; Samuel N Young; Jarrod J Sandow; Peter E Czabotar; James M Murphy
Journal:  Cell Death Dis       Date:  2022-06-23       Impact factor: 9.685
  6 in total

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