Effects of weight loss and physical activity on skeletal muscle mitochondrial function in obesity

doi:10.1152/ajpendo.00322.2004

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Effects of weight loss and physical activity on skeletal muscle mitochondrial function in obesity

Elizabeth V. Menshikova,¹ Vladimir B. Ritov,¹ Frederico G. S. Toledo,¹ Robert E. Ferrell,² Bret H. Goodpaster,¹ and David E. Kelley¹

¹Division of Endocrinology and Metabolism, Department of Medicine; ²Department of Human Genetics, University of Pittsburgh, School of Medicine, Pittsburgh, Pennsylvania

Submitted 23 July 2004 ; accepted in final form 29 November 2004

The current study was undertaken to address responsiveness ofskeletal muscle mitochondrial electron transport chain (ETC)activity to weight loss (WL) and exercise in overweight or obese,sedentary volunteers. Fourteen middle-aged participants (7 male/7female) had assessments of mitochondrial ETC activity and mitochondrial(mt)DNA in vastus lateralis muscle, obtained by percutaneousbiopsy, before and after a 16-wk intervention. Mean WL was 9.7(1.5%) and the mean increase in O_{2 max} was[means (SD)] 21.7 (3.7)%. Total ETC activity increased significantly,from 0.13 (0.02) to 0.19 (0.03) U/mU creatine kinase (CK; P< 0.001). ETC activity was also assessed in mitochondriaisolated into subsarcolemmal (SSM) and intermyofibrillar (IMF-M)fractions. In response to intervention, there was a robust increaseof ETC activity in SSM (0.028 (0.007) to 0.046 (0.011) U/mUCK, P < 0.001), and in IMF-M [0.101 (0.015) to 0.148 (0.018)U/mU CK, P < 0.005]. At baseline, the percentage of ETC activitycontained in the SSM fraction was low and remained unchangedfollowing intervention [19 (3) vs. 22 (2)%], despite the increasein ETC activity. Also, muscle mtDNA content did not change significantly[1665 (213) vs. 1874 (214) mtDNA/nuclear DNA], denoting functionalimprovement rather than proliferation of mitochondria as theprincipal mechanism of enhanced ETC activity. Increases in ETCactivity were correlated with energy expenditure during exercisesessions, and ETC activity in SSM correlated with insulin sensitivityafter adjustment for O_{2 max}. In summary,skeletal muscle ETC activity is increased by WL and exercisein previously sedentary obese men and women. We conclude thatimproved skeletal muscle ETC activity following moderate WLand improved aerobic capacity contributes to associated alleviationof insulin resistance.

insulin resistance; exercise; mitochondria; mitochondrial DNA; succinate oxidase

Address for reprint requests and other correspondence: D. E. Kelley, 807-N Montefiore-Univ. Hospital, 3459 Fifth Ave., Pittsburgh, PA 15213 (E-mail: kelley{at}msx.dept-med.pitt.edu)

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				Y.-H. Yu and H. N. Ginsberg Adipocyte Signaling and Lipid Homeostasis: Sequelae of Insulin-Resistant Adipose Tissue Circ. Res., May 27, 2005; 96(10): 1042 - 1052. [Abstract] [Full Text] [PDF]