Literature DB >> 20967516

Mitochondrial biogenesis and fragmentation as regulators of muscle protein degradation.

Vanina Romanello1, Marco Sandri.   

Abstract

Mitochondria form a dynamic network that rapidly adapts to cellular energy demand. This adaptation is particularly important in skeletal muscle because of its high metabolic rate. Indeed, muscle energy level is one of the cellular checkpoints that lead either to sustained protein synthesis and growth or protein breakdown and atrophy. Mitochondrial function is affected by changes in shape, number, and localization. The dynamics that control the mitochondrial network, such as biogenesis and fusion, or fragmentation and fission, ultimately affect the signaling pathways that regulate muscle mass. Regular exercise and healthy muscles are important players in the metabolic control of human body. Indeed, a sedentary lifestyle is detrimental for muscle function and is one of the major causes of metabolic disorders such as obesity and diabetes. This article reviews the rapid progress made in the past few years regarding the role of mitochondria in the control of proteolytic systems and in the loss of muscle mass and function.

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Year:  2010        PMID: 20967516     DOI: 10.1007/s11906-010-0157-8

Source DB:  PubMed          Journal:  Curr Hypertens Rep        ISSN: 1522-6417            Impact factor:   5.369


  47 in total

1.  Activation of caspase-3 is an initial step triggering accelerated muscle proteolysis in catabolic conditions.

Authors:  Jie Du; Xiaonan Wang; Christiane Miereles; James L Bailey; Richard Debigare; Bin Zheng; S Russ Price; William E Mitch
Journal:  J Clin Invest       Date:  2004-01       Impact factor: 14.808

2.  FoxO3 controls autophagy in skeletal muscle in vivo.

Authors:  Cristina Mammucari; Giulia Milan; Vanina Romanello; Eva Masiero; Ruediger Rudolf; Paola Del Piccolo; Steven J Burden; Raffaella Di Lisi; Claudia Sandri; Jinghui Zhao; Alfred L Goldberg; Stefano Schiaffino; Marco Sandri
Journal:  Cell Metab       Date:  2007-12       Impact factor: 27.287

3.  Atrogin-1, a muscle-specific F-box protein highly expressed during muscle atrophy.

Authors:  M D Gomes; S H Lecker; R T Jagoe; A Navon; A L Goldberg
Journal:  Proc Natl Acad Sci U S A       Date:  2001-11-20       Impact factor: 11.205

4.  Identification of ubiquitin ligases required for skeletal muscle atrophy.

Authors:  S C Bodine; E Latres; S Baumhueter; V K Lai; L Nunez; B A Clarke; W T Poueymirou; F J Panaro; E Na; K Dharmarajan; Z Q Pan; D M Valenzuela; T M DeChiara; T N Stitt; G D Yancopoulos; D J Glass
Journal:  Science       Date:  2001-10-25       Impact factor: 47.728

5.  Foxo transcription factors induce the atrophy-related ubiquitin ligase atrogin-1 and cause skeletal muscle atrophy.

Authors:  Marco Sandri; Claudia Sandri; Alex Gilbert; Carsten Skurk; Elisa Calabria; Anne Picard; Kenneth Walsh; Stefano Schiaffino; Stewart H Lecker; Alfred L Goldberg
Journal:  Cell       Date:  2004-04-30       Impact factor: 41.582

6.  Suppression of autophagy in skeletal muscle uncovers the accumulation of ubiquitinated proteins and their potential role in muscle damage in Pompe disease.

Authors:  Nina Raben; Victoria Hill; Lauren Shea; Shoichi Takikita; Rebecca Baum; Noboru Mizushima; Evelyn Ralston; Paul Plotz
Journal:  Hum Mol Genet       Date:  2008-09-09       Impact factor: 6.150

Review 7.  Mitochondrial fusion and division: Regulation and role in cell viability.

Authors:  Giovanni Benard; Mariusz Karbowski
Journal:  Semin Cell Dev Biol       Date:  2009-05       Impact factor: 7.727

8.  Properties of skeletal muscle mitochondria isolated from subsarcolemmal and intermyofibrillar regions.

Authors:  A M Cogswell; R J Stevens; D A Hood
Journal:  Am J Physiol       Date:  1993-02

9.  Multiple types of skeletal muscle atrophy involve a common program of changes in gene expression.

Authors:  Stewart H Lecker; R Thomas Jagoe; Alexander Gilbert; Marcelo Gomes; Vickie Baracos; James Bailey; S Russ Price; William E Mitch; Alfred L Goldberg
Journal:  FASEB J       Date:  2004-01       Impact factor: 5.191

10.  FoxO3 coordinately activates protein degradation by the autophagic/lysosomal and proteasomal pathways in atrophying muscle cells.

Authors:  Jinghui Zhao; Jeffrey J Brault; Andreas Schild; Peirang Cao; Marco Sandri; Stefano Schiaffino; Stewart H Lecker; Alfred L Goldberg
Journal:  Cell Metab       Date:  2007-12       Impact factor: 27.287
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  51 in total

1.  Chronic expression of RCAN1-1L protein induces mitochondrial autophagy and metabolic shift from oxidative phosphorylation to glycolysis in neuronal cells.

Authors:  Gennady Ermak; Sonal Sojitra; Fei Yin; Enrique Cadenas; Ana Maria Cuervo; Kelvin J A Davies
Journal:  J Biol Chem       Date:  2012-03-02       Impact factor: 5.157

Review 2.  The emerging role of skeletal muscle oxidative metabolism as a biological target and cellular regulator of cancer-induced muscle wasting.

Authors:  James A Carson; Justin P Hardee; Brandon N VanderVeen
Journal:  Semin Cell Dev Biol       Date:  2015-12-01       Impact factor: 7.727

Review 3.  Mitochondrial health and muscle plasticity after spinal cord injury.

Authors:  Ashraf S Gorgey; Oksana Witt; Laura O'Brien; Christopher Cardozo; Qun Chen; Edward J Lesnefsky; Zachary A Graham
Journal:  Eur J Appl Physiol       Date:  2018-12-11       Impact factor: 3.078

4.  Mitochondrial biogenesis and the development of diabetic retinopathy.

Authors:  Julia M Santos; Shikha Tewari; Andrew F X Goldberg; Renu A Kowluru
Journal:  Free Radic Biol Med       Date:  2011-08-25       Impact factor: 7.376

Review 5.  Mitochondrial network remodeling: an important feature of myogenesis and skeletal muscle regeneration.

Authors:  Fasih Ahmad Rahman; Joe Quadrilatero
Journal:  Cell Mol Life Sci       Date:  2021-03-22       Impact factor: 9.261

6.  Bed rest and resistive vibration exercise unveil novel links between skeletal muscle mitochondrial function and insulin resistance.

Authors:  Helena C Kenny; Floriane Rudwill; Laura Breen; Michele Salanova; Dieter Blottner; Tim Heise; Martina Heer; Stephane Blanc; Donal J O'Gorman
Journal:  Diabetologia       Date:  2017-05-12       Impact factor: 10.122

7.  The time course of the adaptations of human muscle proteome to bed rest and the underlying mechanisms.

Authors:  Lorenza Brocca; Jessica Cannavino; Luisa Coletto; Gianni Biolo; Marco Sandri; Roberto Bottinelli; Maria Antonietta Pellegrino
Journal:  J Physiol       Date:  2012-07-30       Impact factor: 5.182

8.  Colon 26 adenocarcinoma (C26)-induced cancer cachexia impairs skeletal muscle mitochondrial function and content.

Authors:  Daria Neyroud; Rachel L Nosacka; Andrew R Judge; Russell T Hepple
Journal:  J Muscle Res Cell Motil       Date:  2019-04-03       Impact factor: 2.698

9.  Nitric oxide regulates vascular adaptive mitochondrial dynamics.

Authors:  Matthew W Miller; Leslie A Knaub; Luis F Olivera-Fragoso; Amy C Keller; Vivek Balasubramaniam; Peter A Watson; Jane E B Reusch
Journal:  Am J Physiol Heart Circ Physiol       Date:  2013-04-12       Impact factor: 4.733

10.  Muscle mTORC1 suppression by IL-6 during cancer cachexia: a role for AMPK.

Authors:  James P White; Melissa J Puppa; Song Gao; Shuichi Sato; Stephen L Welle; James A Carson
Journal:  Am J Physiol Endocrinol Metab       Date:  2013-03-26       Impact factor: 4.310
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