Guidelines for the use and interpretation of assays for monitoring autophagy (4th edition)1 DJ Klionsky, AK Abdel-Aziz, S Abdelfatah, M Abdellatif, A Abdoli, S Abel, ... autophagy 17 (1), 1-382, 2021 | 13216* | 2021 |
Galectin 8 targets damaged vesicles for autophagy to defend cells against bacterial invasion TLM Thurston, MP Wandel, N von Muhlinen, A Foeglein, F Randow Nature 482 (7385), 414-418, 2012 | 1065 | 2012 |
The TBK1 adaptor and autophagy receptor NDP52 restricts the proliferation of ubiquitin-coated bacteria TLM Thurston, G Ryzhakov, S Bloor, N Von Muhlinen, F Randow Nature immunology 10 (11), 1215-1221, 2009 | 957 | 2009 |
Specific recognition of linear ubiquitin chains by NEMO is important for NF-κB activation S Rahighi, F Ikeda, M Kawasaki, M Akutsu, N Suzuki, R Kato, T Kensche, ... Cell 136 (6), 1098-1109, 2009 | 864 | 2009 |
Neuropilin-1 expression on regulatory T cells enhances their interactions with dendritic cells during antigen recognition M Sarris, KG Andersen, F Randow, L Mayr, AG Betz Immunity 28 (3), 402-413, 2008 | 510 | 2008 |
Endoplasmic reticulum chaperone gp96 is required for innate immunity but not cell viability F Randow, B Seed Nature cell biology 3 (10), 891-896, 2001 | 411 | 2001 |
Spatiotemporal control of ULK1 activation by NDP52 and TBK1 during selective autophagy JNS Vargas, C Wang, E Bunker, L Hao, D Maric, G Schiavo, F Randow, ... Molecular cell 74 (2), 347-362. e6, 2019 | 365 | 2019 |
LC3C, bound selectively by a noncanonical LIR motif in NDP52, is required for antibacterial autophagy N von Muhlinen, M Akutsu, BJ Ravenhill, Á Foeglein, S Bloor, ... Molecular cell 48 (3), 329-342, 2012 | 354 | 2012 |
Self and nonself: how autophagy targets mitochondria and bacteria F Randow, RJ Youle Cell host & microbe 15 (4), 403-411, 2014 | 294 | 2014 |
Cellular self-defense: how cell-autonomous immunity protects against pathogens F Randow, JD MacMicking, LC James Science 340 (6133), 701-706, 2013 | 288 | 2013 |
A LC3-interacting motif in the influenza A virus M2 protein is required to subvert autophagy and maintain virion stability R Beale, H Wise, A Stuart, BJ Ravenhill, P Digard, F Randow Cell host & microbe 15 (2), 239-247, 2014 | 262 | 2014 |
Viral avoidance and exploitation of the ubiquitin system F Randow, PJ Lehner Nature cell biology 11 (5), 527-534, 2009 | 248 | 2009 |
The cargo receptor NDP52 initiates selective autophagy by recruiting the ULK complex to cytosol-invading bacteria BJ Ravenhill, KB Boyle, N von Muhlinen, CJ Ellison, GR Masson, ... Molecular cell 74 (2), 320-329. e6, 2019 | 247 | 2019 |
SINTBAD, a novel component of innate antiviral immunity, shares a TBK1‐binding domain with NAP1 and TANK G Ryzhakov, F Randow The EMBO journal 26 (13), 3180-3190, 2007 | 233 | 2007 |
Ubiquitylation of lipopolysaccharide by RNF213 during bacterial infection EG Otten, E Werner, A Crespillo-Casado, KB Boyle, V Dharamdasani, ... Nature 594 (7861), 111-116, 2021 | 216 | 2021 |
The role of ‘eat-me’signals and autophagy cargo receptors in innate immunity KB Boyle, F Randow Current opinion in microbiology 16 (3), 339-348, 2013 | 215 | 2013 |
Guanylate-binding proteins convert cytosolic bacteria into caspase-4 signaling platforms MP Wandel, BH Kim, ES Park, KB Boyle, K Nayak, B Lagrange, A Herod, ... Nature immunology 21 (8), 880-891, 2020 | 211 | 2020 |
LUBAC-synthesized linear ubiquitin chains restrict cytosol-invading bacteria by activating autophagy and NF-κB J Noad, A Von Der Malsburg, C Pathe, MA Michel, D Komander, ... Nature microbiology 2 (7), 1-10, 2017 | 208 | 2017 |
Vaccinia virus protein C6 is a virulence factor that binds TBK-1 adaptor proteins and inhibits activation of IRF3 and IRF7 L Unterholzner, RP Sumner, M Baran, H Ren, DS Mansur, NM Bourke, ... PLoS pathogens 7 (9), e1002247, 2011 | 185 | 2011 |
Inhibition of IκB kinase by vaccinia virus virulence factor B14 RAJ Chen, G Ryzhakov, S Cooray, F Randow, GL Smith PLoS pathogens 4 (2), e22, 2008 | 176 | 2008 |