Literature DB >> 26785495

Parkin-mediated mitophagy directs perinatal cardiac metabolic maturation in mice.

Guohua Gong1, Moshi Song1, Gyorgy Csordas2, Daniel P Kelly3, Scot J Matkovich1, Gerald W Dorn4.   

Abstract

In developing hearts, changes in the cardiac metabolic milieu during the perinatal period redirect mitochondrial substrate preference from carbohydrates to fatty acids. Mechanisms responsible for this mitochondrial plasticity are unknown. Here, we found that PINK1-Mfn2-Parkin-mediated mitophagy directs this metabolic transformation in mouse hearts. A mitofusin (Mfn) 2 mutant lacking PINK1 phosphorylation sites necessary for Parkin binding (Mfn2 AA) inhibited mitochondrial Parkin translocation, suppressing mitophagy without impairing mitochondrial fusion. Cardiac Parkin deletion or expression of Mfn2 AA from birth, but not after weaning, prevented postnatal mitochondrial maturation essential to survival. Five-week-old Mfn2 AA hearts retained a fetal mitochondrial transcriptional signature without normal increases in fatty acid metabolism and mitochondrial biogenesis genes. Myocardial fatty acylcarnitine levels and cardiomyocyte respiration induced by palmitoylcarnitine were concordantly depressed. Thus, instead of transcriptional reprogramming, fetal cardiomyocyte mitochondria undergo perinatal Parkin-mediated mitophagy and replacement by mature adult mitochondria. Mitophagic mitochondrial removal underlies developmental cardiomyocyte mitochondrial plasticity and metabolic transitioning of perinatal hearts.
Copyright © 2015, American Association for the Advancement of Science.

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Year:  2015        PMID: 26785495      PMCID: PMC4747105          DOI: 10.1126/science.aad2459

Source DB:  PubMed          Journal:  Science        ISSN: 0036-8075            Impact factor:   47.728


  50 in total

1.  PARIS (ZNF746) repression of PGC-1α contributes to neurodegeneration in Parkinson's disease.

Authors:  Joo-Ho Shin; Han Seok Ko; Hochul Kang; Yunjong Lee; Yun-Il Lee; Olga Pletinkova; Juan C Troconso; Valina L Dawson; Ted M Dawson
Journal:  Cell       Date:  2011-03-04       Impact factor: 41.582

2.  PINK1-phosphorylated mitofusin 2 is a Parkin receptor for culling damaged mitochondria.

Authors:  Yun Chen; Gerald W Dorn
Journal:  Science       Date:  2013-04-26       Impact factor: 47.728

3.  Parkin is a lipid-responsive regulator of fat uptake in mice and mutant human cells.

Authors:  Kye-Young Kim; Mark V Stevens; M Hasina Akter; Sarah E Rusk; Robert J Huang; Alexandra Cohen; Audrey Noguchi; Danielle Springer; Alexander V Bocharov; Tomas L Eggerman; Der-Fen Suen; Richard J Youle; Marcelo Amar; Alan T Remaley; Michael N Sack
Journal:  J Clin Invest       Date:  2011-08-25       Impact factor: 14.808

4.  Bioenergetics, mitochondria, and cardiac myocyte differentiation.

Authors:  George A Porter; Jennifer Hom; David Hoffman; Rodrigo Quintanilla; Karen de Mesy Bentley; Shey-Shing Sheu
Journal:  Prog Pediatr Cardiol       Date:  2011-05

5.  Mitochondrial contagion induced by Parkin deficiency in Drosophila hearts and its containment by suppressing mitofusin.

Authors:  Poonam Bhandari; Moshi Song; Yun Chen; Yan Burelle; Gerald W Dorn
Journal:  Circ Res       Date:  2013-11-05       Impact factor: 17.367

6.  Mitofusin 2 is necessary for striatal axonal projections of midbrain dopamine neurons.

Authors:  Seungmin Lee; Fredrik H Sterky; Arnaud Mourier; Mügen Terzioglu; Staffan Cullheim; Lars Olson; Nils-Göran Larsson
Journal:  Hum Mol Genet       Date:  2012-08-21       Impact factor: 6.150

7.  A mitochondrial protein compendium elucidates complex I disease biology.

Authors:  David J Pagliarini; Sarah E Calvo; Betty Chang; Sunil A Sheth; Scott B Vafai; Shao-En Ong; Geoffrey A Walford; Canny Sugiana; Avihu Boneh; William K Chen; David E Hill; Marc Vidal; James G Evans; David R Thorburn; Steven A Carr; Vamsi K Mootha
Journal:  Cell       Date:  2008-07-11       Impact factor: 41.582

8.  Impaired dopamine release and synaptic plasticity in the striatum of PINK1-deficient mice.

Authors:  Tohru Kitada; Antonio Pisani; Douglas R Porter; Hiroo Yamaguchi; Anne Tscherter; Giuseppina Martella; Paola Bonsi; Chen Zhang; Emmanuel N Pothos; Jie Shen
Journal:  Proc Natl Acad Sci U S A       Date:  2007-06-11       Impact factor: 11.205

9.  Differential expression analysis for sequence count data.

Authors:  Simon Anders; Wolfgang Huber
Journal:  Genome Biol       Date:  2010-10-27       Impact factor: 13.583

10.  Two rare human mitofusin 2 mutations alter mitochondrial dynamics and induce retinal and cardiac pathology in Drosophila.

Authors:  William H Eschenbacher; Moshi Song; Yun Chen; Poonam Bhandari; Peter Zhao; Casey C Jowdy; John T Engelhard; Gerald W Dorn
Journal:  PLoS One       Date:  2012-09-05       Impact factor: 3.240
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  148 in total

Review 1.  Beyond Mitophagy: The Diversity and Complexity of Parkin Function.

Authors:  Sarah E Shires; Richard N Kitsis; Åsa B Gustafsson
Journal:  Circ Res       Date:  2017-04-14       Impact factor: 17.367

2.  Preventing permeability transition pore opening increases mitochondrial maturation, myocyte differentiation and cardiac function in the neonatal mouse heart.

Authors:  Jayson V Lingan; Ryan E Alanzalon; George A Porter
Journal:  Pediatr Res       Date:  2017-01-31       Impact factor: 3.756

3.  Autophagy regulates functional differentiation of mammary epithelial cells.

Authors:  Jessica Elswood; Scott J Pearson; H Ross Payne; Rola Barhoumi; Monique Rijnkels; Weston W Porter
Journal:  Autophagy       Date:  2020-02-05       Impact factor: 16.016

4.  What You Eat Affects Your Shape.

Authors:  Elizabeth Murphy; Brian Glancy; Charles Steenbergen
Journal:  Circ Res       Date:  2018-01-05       Impact factor: 17.367

5.  The tethering function of mitofusin2 controls osteoclast differentiation by modulating the Ca2+-NFATc1 axis.

Authors:  Anna Ballard; Rong Zeng; Allahdad Zarei; Christine Shao; Linda Cox; Hui Yan; Antonietta Franco; Gerald W Dorn; Roberta Faccio; Deborah J Veis
Journal:  J Biol Chem       Date:  2020-03-12       Impact factor: 5.157

6.  Mitochondrial function in engineered cardiac tissues is regulated by extracellular matrix elasticity and tissue alignment.

Authors:  Davi M Lyra-Leite; Allen M Andres; Andrew P Petersen; Nethika R Ariyasinghe; Nathan Cho; Jezell A Lee; Roberta A Gottlieb; Megan L McCain
Journal:  Am J Physiol Heart Circ Physiol       Date:  2017-07-21       Impact factor: 4.733

7.  BNIP3L/NIX and FUNDC1-mediated mitophagy is required for mitochondrial network remodeling during cardiac progenitor cell differentiation.

Authors:  Mark A Lampert; Amabel M Orogo; Rita H Najor; Babette C Hammerling; Leonardo J Leon; Bingyan J Wang; Taeyong Kim; Mark A Sussman; Åsa B Gustafsson
Journal:  Autophagy       Date:  2019-02-22       Impact factor: 16.016

8.  A fluorescence-based imaging method to measure in vitro and in vivo mitophagy using mt-Keima.

Authors:  Nuo Sun; Daniela Malide; Jie Liu; Ilsa I Rovira; Christian A Combs; Toren Finkel
Journal:  Nat Protoc       Date:  2017-07-13       Impact factor: 13.491

Review 9.  Mitophagy in cardiovascular homeostasis.

Authors:  Ruohan Zhang; Judith Krigman; Hongke Luo; Serra Ozgen; Mingchong Yang; Nuo Sun
Journal:  Mech Ageing Dev       Date:  2020-04-11       Impact factor: 5.432

Review 10.  Parkin-dependent mitophagy in the heart.

Authors:  Gerald W Dorn
Journal:  J Mol Cell Cardiol       Date:  2015-11-22       Impact factor: 5.000
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