Literature DB >> 23760083

Transient systemic mtDNA damage leads to muscle wasting by reducing the satellite cell pool.

Xiao Wang1, Alicia M Pickrell, Susana G Rossi, Milena Pinto, Lloye M Dillon, Aline Hida, Richard L Rotundo, Carlos T Moraes.   

Abstract

With age, muscle mass and integrity are progressively lost leaving the elderly frail, weak and unable to independently care for themselves. Defined as sarcopenia, this age-related muscle atrophy appears to be multifactorial but its definite cause is still unknown. Mitochondrial dysfunction has been implicated in this process. Using a novel transgenic mouse model of mitochondrial DNA (mtDNA) double-strand breaks (DSBs) that presents a premature aging-like phenotype, we studied the role of mtDNA damage in muscle wasting. We caused DSBs in mtDNA of adult mice using a ubiquitously expressed mitochondrial-targeted endonuclease, mito-PstI. We found that a short, transient systemic mtDNA damage led to muscle wasting and a decline in locomotor activity later in life. We found a significant decline in muscle satellite cells, which decreases the muscle's capacity to regenerate and repair during aging. This phenotype was associated with impairment in acetylcholinesterase (AChE) activity and assembly at the neuromuscular junction (NMJ), also associated with muscle aging. Our data suggests that systemic mitochondrial dysfunction plays important roles in age-related muscle wasting by preferentially affecting the myosatellite cell pool.

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Year:  2013        PMID: 23760083      PMCID: PMC3766186          DOI: 10.1093/hmg/ddt251

Source DB:  PubMed          Journal:  Hum Mol Genet        ISSN: 0964-6906            Impact factor:   6.150


  58 in total

1.  Changes in aging mouse neuromuscular junctions are explained by degeneration and regeneration of muscle fiber segments at the synapse.

Authors:  Yue Li; Young il Lee; Wesley J Thompson
Journal:  J Neurosci       Date:  2011-10-19       Impact factor: 6.167

2.  Attenuation of age-related changes in mouse neuromuscular synapses by caloric restriction and exercise.

Authors:  Gregorio Valdez; Juan C Tapia; Hyuno Kang; Gregory D Clemenson; F H Gage; Jeff W Lichtman; Joshua R Sanes
Journal:  Proc Natl Acad Sci U S A       Date:  2010-08-02       Impact factor: 11.205

3.  The striatum is highly susceptible to mitochondrial oxidative phosphorylation dysfunctions.

Authors:  Alicia M Pickrell; Hirokazu Fukui; Xiao Wang; Milena Pinto; Carlos T Moraes
Journal:  J Neurosci       Date:  2011-07-06       Impact factor: 6.167

4.  Neuromuscular junction morphology, fiber-type proportions, and satellite-cell proliferation rates are altered in MyoD(-/-) mice.

Authors:  Raymond Macharia; Anthony Otto; Petr Valasek; Ketan Patel
Journal:  Muscle Nerve       Date:  2010-07       Impact factor: 3.217

5.  Endurance exercise rescues progeroid aging and induces systemic mitochondrial rejuvenation in mtDNA mutator mice.

Authors:  Adeel Safdar; Jacqueline M Bourgeois; Daniel I Ogborn; Jonathan P Little; Bart P Hettinga; Mahmood Akhtar; James E Thompson; Simon Melov; Nicholas J Mocellin; Gregory C Kujoth; Tomas A Prolla; Mark A Tarnopolsky
Journal:  Proc Natl Acad Sci U S A       Date:  2011-02-22       Impact factor: 11.205

6.  Mitochondrial DNA damage level determines neural stem cell differentiation fate.

Authors:  Wei Wang; Ying Esbensen; David Kunke; Rajikala Suganthan; Lyudmila Rachek; Magnar Bjørås; Lars Eide
Journal:  J Neurosci       Date:  2011-06-29       Impact factor: 6.167

7.  Systemic mitochondrial dysfunction and the etiology of Alzheimer's disease and down syndrome dementia.

Authors:  Pinar E Coskun; Joanne Wyrembak; Olga Derbereva; Goar Melkonian; Eric Doran; Ira T Lott; Elizabeth Head; Carl W Cotman; Douglas C Wallace
Journal:  J Alzheimers Dis       Date:  2010       Impact factor: 4.472

8.  Somatic progenitor cell vulnerability to mitochondrial DNA mutagenesis underlies progeroid phenotypes in Polg mutator mice.

Authors:  Kati J Ahlqvist; Riikka H Hämäläinen; Shuichi Yatsuga; Marko Uutela; Mügen Terzioglu; Alexandra Götz; Saara Forsström; Petri Salven; Alexandre Angers-Loustau; Outi H Kopra; Henna Tyynismaa; Nils-Göran Larsson; Kirmo Wartiovaara; Tomas Prolla; Aleksandra Trifunovic; Anu Suomalainen
Journal:  Cell Metab       Date:  2012-01-04       Impact factor: 27.287

9.  Aberrant mitochondrial homeostasis in the skeletal muscle of sedentary older adults.

Authors:  Adeel Safdar; Mazen J Hamadeh; Jan J Kaczor; Sandeep Raha; Justin Debeer; Mark A Tarnopolsky
Journal:  PLoS One       Date:  2010-05-24       Impact factor: 3.240

10.  Striking denervation of neuromuscular junctions without lumbar motoneuron loss in geriatric mouse muscle.

Authors:  Ruth Jinfen Chai; Jana Vukovic; Sarah Dunlop; Miranda D Grounds; Thea Shavlakadze
Journal:  PLoS One       Date:  2011-12-02       Impact factor: 3.240
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  24 in total

Review 1.  The emergence of the mitochondrial genome as a partial regulator of nuclear function is providing new insights into the genetic mechanisms underlying age-related complex disease.

Authors:  Martin P Horan; David N Cooper
Journal:  Hum Genet       Date:  2013-12-04       Impact factor: 4.132

Review 2.  Mechanisms linking mtDNA damage and aging.

Authors:  Milena Pinto; Carlos T Moraes
Journal:  Free Radic Biol Med       Date:  2015-05-13       Impact factor: 7.376

Review 3.  Mitochondria Initiate and Regulate Sarcopenia.

Authors:  Stephen E Alway; Junaith S Mohamed; Matthew J Myers
Journal:  Exerc Sport Sci Rev       Date:  2017-04       Impact factor: 6.230

Review 4.  Manipulating and elucidating mitochondrial gene expression with engineered proteins.

Authors:  Christopher P Wallis; Louis H Scott; Aleksandra Filipovska; Oliver Rackham
Journal:  Philos Trans R Soc Lond B Biol Sci       Date:  2019-12-02       Impact factor: 6.237

5.  Mitochondrial-specific autophagy linked to mitochondrial dysfunction following traumatic freeze injury in mice.

Authors:  Anna S Nichenko; W Michael Southern; Kayvan Forouhesh Tehrani; Anita E Qualls; Alexandra B Flemington; Grant H Mercer; Amelia Yin; Luke J Mortensen; Hang Yin; Jarrod A Call
Journal:  Am J Physiol Cell Physiol       Date:  2019-11-13       Impact factor: 4.249

6.  The use of mitochondria-targeted endonucleases to manipulate mtDNA.

Authors:  Sandra R Bacman; Sion L Williams; Milena Pinto; Carlos T Moraes
Journal:  Methods Enzymol       Date:  2014       Impact factor: 1.600

7.  Transient mitochondrial DNA double strand breaks in mice cause accelerated aging phenotypes in a ROS-dependent but p53/p21-independent manner.

Authors:  Milena Pinto; Alicia M Pickrell; Xiao Wang; Sandra R Bacman; Aixin Yu; Aline Hida; Lloye M Dillon; Paul D Morton; Thomas R Malek; Siôn L Williams; Carlos T Moraes
Journal:  Cell Death Differ       Date:  2016-12-02       Impact factor: 15.828

Review 8.  Mitochondrial Diseases Part II: Mouse models of OXPHOS deficiencies caused by defects in regulatory factors and other components required for mitochondrial function.

Authors:  Luisa Iommarini; Susana Peralta; Alessandra Torraco; Francisca Diaz
Journal:  Mitochondrion       Date:  2015-01-29       Impact factor: 4.160

Review 9.  Mitochondrial dysfunction and sarcopenia of aging: from signaling pathways to clinical trials.

Authors:  Emanuele Marzetti; Riccardo Calvani; Matteo Cesari; Thomas W Buford; Maria Lorenzi; Bradley J Behnke; Christiaan Leeuwenburgh
Journal:  Int J Biochem Cell Biol       Date:  2013-07-08       Impact factor: 5.085

10.  Fis1 deficiencies differentially affect mitochondrial quality in skeletal muscle.

Authors:  Zhe Zhang; Danielle A Sliter; Christopher K E Bleck; Shuzhe Ding
Journal:  Mitochondrion       Date:  2019-09-14       Impact factor: 4.160
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