Literature DB >> 31339428

SQSTM1/p62 promotes mitochondrial ubiquitination independently of PINK1 and PRKN/parkin in mitophagy.

Tatsuya Yamada1, Ted M Dawson2,3,4, Toru Yanagawa5, Miho Iijima1, Hiromi Sesaki1.   

Abstract

The ubiquitination of mitochondrial proteins labels damaged mitochondria for degradation through mitophagy. We recently developed an in vivo system in which mitophagy is slowed by inhibiting mitochondrial division through knockout of Dnm1l/Drp1, a dynamin related GTPase that mediates mitochondrial division. Using this system, we revealed that the ubiquitination of mitochondrial proteins required SQSTM1/p62, but not the ubiquitin E3 ligase PRKN/parkin, during mitophagy. Here, we tested the role of PINK1, a mitochondrial protein kinase that activates mitophagy by phosphorylating ubiquitin, in mitochondrial ubiquitination by knocking out Pink1 in dnm1l-knockout liver. We found mitochondrial ubiquitination did not decrease in the absence of PINK1; instead, PINK1 was required for the degradation of MFN1 (mitofusin 1) and MFN2, two homologous outer membrane proteins that mediate mitochondrial fusion in dnm1l-knockout hepatocytes. These data suggest that mitochondrial ubiquitination is promoted by SQSTM1 independently of PINK1 and PRKN during mitophagy. PINK1 and PRKN appear to control the balance between mitochondrial division and fusion in vivo. Abbreviations: DNM1L/DRP1: dynamin 1-like; KEAP1: kelch-like ECH-associated protein 1; KO: knockout; MAP1LC3/LC3: microtubule-associated protein 1 light chain 3; MFN1/2: mitofusin 1/2; OPA1: OPA1, mitochondrial dynamin like GTPase; PDH: pyruvate dehydrogenase E1; PINK1: PTEN induced putative kinase 1; PRKN/parkin: parkin RBR E3 ubiquitin protein ligase.

Entities:  

Keywords:  Dnm1l/Drp1; PINK1; PRKN/parkin; mitochondria; mitochondrial division; mitophagy

Year:  2019        PMID: 31339428      PMCID: PMC6844492          DOI: 10.1080/15548627.2019.1643185

Source DB:  PubMed          Journal:  Autophagy        ISSN: 1554-8627            Impact factor:   16.016


  32 in total

1.  Homeostatic levels of p62 control cytoplasmic inclusion body formation in autophagy-deficient mice.

Authors:  Masaaki Komatsu; Satoshi Waguri; Masato Koike; Yu-Shin Sou; Takashi Ueno; Taichi Hara; Noboru Mizushima; Jun-Ichi Iwata; Junji Ezaki; Shigeo Murata; Jun Hamazaki; Yasumasa Nishito; Shun-Ichiro Iemura; Tohru Natsume; Toru Yanagawa; Junya Uwayama; Eiji Warabi; Hiroshi Yoshida; Tetsuro Ishii; Akira Kobayashi; Masayuki Yamamoto; Zhenyu Yue; Yasuo Uchiyama; Eiki Kominami; Keiji Tanaka
Journal:  Cell       Date:  2007-12-14       Impact factor: 41.582

2.  Dual roles for glucokinase in glucose homeostasis as determined by liver and pancreatic beta cell-specific gene knock-outs using Cre recombinase.

Authors:  C Postic; M Shiota; K D Niswender; T L Jetton; Y Chen; J M Moates; K D Shelton; J Lindner; A D Cherrington; M A Magnuson
Journal:  J Biol Chem       Date:  1999-01-01       Impact factor: 5.157

3.  p62/sequestosome-1 knockout delays neurodegeneration induced by Drp1 loss.

Authors:  Tatsuya Yamada; Yoshihiro Adachi; Toru Yanagawa; Miho Iijima; Hiromi Sesaki
Journal:  Neurochem Int       Date:  2017-05-18       Impact factor: 3.921

Review 4.  A new pathway for mitochondrial quality control: mitochondrial-derived vesicles.

Authors:  Ayumu Sugiura; Gian-Luca McLelland; Edward A Fon; Heidi M McBride
Journal:  EMBO J       Date:  2014-08-08       Impact factor: 11.598

Review 5.  Mitonuclear communication in homeostasis and stress.

Authors:  Pedro M Quirós; Adrienne Mottis; Johan Auwerx
Journal:  Nat Rev Mol Cell Biol       Date:  2016-03-09       Impact factor: 94.444

Review 6.  p62/SQSTM1 functions as a signaling hub and an autophagy adaptor.

Authors:  Yoshinori Katsuragi; Yoshinobu Ichimura; Masaaki Komatsu
Journal:  FEBS J       Date:  2015-10-16       Impact factor: 5.542

7.  Ubiquitin is phosphorylated by PINK1 to activate parkin.

Authors:  Fumika Koyano; Kei Okatsu; Hidetaka Kosako; Yasushi Tamura; Etsu Go; Mayumi Kimura; Yoko Kimura; Hikaru Tsuchiya; Hidehito Yoshihara; Takatsugu Hirokawa; Toshiya Endo; Edward A Fon; Jean-François Trempe; Yasushi Saeki; Keiji Tanaka; Noriyuki Matsuda
Journal:  Nature       Date:  2014-06-04       Impact factor: 49.962

Review 8.  The ubiquitin signal and autophagy: an orchestrated dance leading to mitochondrial degradation.

Authors:  Koji Yamano; Noriyuki Matsuda; Keiji Tanaka
Journal:  EMBO Rep       Date:  2016-02-08       Impact factor: 8.807

9.  Elimination of paternal mitochondria in mouse embryos occurs through autophagic degradation dependent on PARKIN and MUL1.

Authors:  Rebecca Rojansky; Moon-Yong Cha; David C Chan
Journal:  Elife       Date:  2016-11-17       Impact factor: 8.140

10.  Basal Mitophagy Occurs Independently of PINK1 in Mouse Tissues of High Metabolic Demand.

Authors:  Thomas G McWilliams; Alan R Prescott; Lambert Montava-Garriga; Graeme Ball; François Singh; Erica Barini; Miratul M K Muqit; Simon P Brooks; Ian G Ganley
Journal:  Cell Metab       Date:  2018-01-11       Impact factor: 27.287
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  28 in total

Review 1.  Aging-Dependent Mitophagy Dysfunction in Alzheimer's Disease.

Authors:  Mingxue Song; Xiulan Zhao; Fuyong Song
Journal:  Mol Neurobiol       Date:  2021-01-08       Impact factor: 5.590

Review 2.  Mitochondrial division, fusion and degradation.

Authors:  Daisuke Murata; Kenta Arai; Miho Iijima; Hiromi Sesaki
Journal:  J Biochem       Date:  2020-03-01       Impact factor: 3.387

Review 3.  Insight into Crosstalk Between Mitophagy and Apoptosis/Necroptosis: Mechanisms and Clinical Applications in Ischemic Stroke.

Authors:  Yan-di Yang; Zi-Xin Li; Xi-Min Hu; Hao Wan; Qi Zhang; Rui Xiao; Kun Xiong
Journal:  Curr Med Sci       Date:  2022-04-07

4.  Expanding Views of Mitochondria in Parkinson's Disease: Focusing on PINK1 and GBA1 Mutations.

Authors:  Yu Yuan; Xizhen Ma; Ning Song; Junxia Xie
Journal:  Neurosci Bull       Date:  2022-05-11       Impact factor: 5.271

5.  Modeling of mitochondrial bioenergetics and autophagy impairment in MELAS-mutant iPSC-derived retinal pigment epithelial cells.

Authors:  Sujoy Bhattacharya; Jinggang Yin; Weihong Huo; Edward Chaum
Journal:  Stem Cell Res Ther       Date:  2022-06-17       Impact factor: 8.079

6.  Newcastle disease virus degrades SIRT3 via PINK1-PRKN-dependent mitophagy to reprogram energy metabolism in infected cells.

Authors:  Yabin Gong; Ning Tang; Panrao Liu; Yingjie Sun; Shanxin Lu; Weiwei Liu; Lei Tan; Cuiping Song; Xusheng Qiu; Ying Liao; Shengqing Yu; Xiufan Liu; Shu-Hai Lin; Chan Ding
Journal:  Autophagy       Date:  2021-10-31       Impact factor: 13.391

Review 7.  Genes Implicated in Familial Parkinson's Disease Provide a Dual Picture of Nigral Dopaminergic Neurodegeneration with Mitochondria Taking Center Stage.

Authors:  Rafael Franco; Rafael Rivas-Santisteban; Gemma Navarro; Annalisa Pinna; Irene Reyes-Resina
Journal:  Int J Mol Sci       Date:  2021-04-28       Impact factor: 5.923

Review 8.  Common Principles and Specific Mechanisms of Mitophagy from Yeast to Humans.

Authors:  Rajesh Kumar; Andreas S Reichert
Journal:  Int J Mol Sci       Date:  2021-04-22       Impact factor: 5.923

9.  Mitochondrial fission, integrity and completion of mitophagy require separable functions of Vps13D in Drosophila neurons.

Authors:  Ryan Insolera; Péter Lőrincz; Alec J Wishnie; Gábor Juhász; Catherine A Collins
Journal:  PLoS Genet       Date:  2021-08-12       Impact factor: 5.917

10.  Mitochondrial Safeguard: a stress response that offsets extreme fusion and protects respiratory function via flickering-induced Oma1 activation.

Authors:  Daisuke Murata; Tatsuya Yamada; Takeshi Tokuyama; Kenta Arai; Pedro M Quirós; Carlos López-Otín; Miho Iijima; Hiromi Sesaki
Journal:  EMBO J       Date:  2020-11-17       Impact factor: 14.012
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