Transcriptional reprogramming and ultrastructure during atrophy and recovery of mouse soleus muscle

doi:10.1152/physiolgenomics.00100.2004

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Physiol. Genomics 20: 97-107, 2004. First published October 12, 2004; doi:10.1152/physiolgenomics.00100.2004
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Received 23 April 2004; accepted in final form 11 October 2004.
Physiological Genomics 20:97-107 (2004)
1094-8341/04 $5.00 © 2004 American Physiological Society

Transcriptional reprogramming and ultrastructure during atrophy and recovery of mouse soleus muscle

Christoph Däpp, Silvia Schmutz, Hans Hoppeler and Martin Flück

Institute of Anatomy, University of Bern, Bern, Switzerland

This study investigated the use of the hindlimb suspension (HS)and reloading model of mice for the mapping of ultrastructuraland gene expressional alterations underlying load-dependentmuscular adaptations. Mice were hindlimb suspended for 7 daysor kept as controls (n = 12). Soleus muscles were harvestedafter HS (HS7, n = 23) or after resuming ambulatory cage activity(reloading) for either 1 day (R1, n = 13) or 7 days (R7, n =9). Using electron microscopy, a reduction in mean fiber area(–37%) and in capillary-to-fiber ratio (from 1.83 to 1.42)was found for HS7. Subsequent reloading caused an increase ininterstitial cells (+96%) and in total capillary length (+57%),whereas mean fiber area and capillary-to-fiber ratio did notsignificantly change compared with HS. Total RNA in the soleusmuscle was altered with both HS (–63%) and reloading (+108%in R7 compared with control). This is seen as an important adaptivemechanism. Gene expression alterations were assessed by a muscle-specificlow-density cDNA microarray. The transcriptional adjustmentsindicate an early increase of myogenic factors during reloadingtogether with an overshoot of contractile (MyHC I and IIa) andmetabolic (glycolytic and oxidative) mRNA amounts and suggestmechano-sensitivity of factors keeping the sarcomeres in register(desmin, titin, integrin-ß1). Important differencesto published data from former rat studies were found with themouse HS model for contractile and glycolytic enzyme expression.These species-specific differences need to be considered whentransgenic mice are used for the elucidation of monogeneticfactors in mechano-dependent muscle plasticity.

unloading; mechanical loading; simulated microgravity; gene expression; rat

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