Ligands for FKBP12 Increase Ca2+ Influx and Protein Synthesis to Improve Skeletal Muscle Function

Chang Seok Lee; Dimitra K. Georgiou; Adán Dagnino-Acosta; Jianjun Xu; Iskander I. Ismailov; Mark Knoblauch; Tanner O. Monroe; Ruirui Ji; Amy D. Hanna; Aditya Joshi; Cheng Long; Joshua M. Oakes; Ted Tran; Benjamin T. Corona; Sabina Lorca; Christopher P. Ingalls; Vihang A. Narkar; Johanna T. Lanner; J. Henri Bayle; William J. Durham; Susan L. Hamilton

doi:10.1074/jbc.m114.586289

Ligands for FKBP12 Increase Ca2+ Influx and Protein Synthesis to Improve Skeletal Muscle Function

Chang Seok Lee(Baylor College of Medicine), Dimitra K. Georgiou(Baylor College of Medicine), Adán Dagnino-Acosta(Baylor College of Medicine), Jianjun Xu(Baylor College of Medicine), Iskander I. Ismailov(Baylor College of Medicine), Mark Knoblauch(Baylor College of Medicine), Tanner O. Monroe(Baylor College of Medicine), Ruirui Ji(Baylor College of Medicine), Amy D. Hanna(Baylor College of Medicine), Aditya Joshi(Baylor College of Medicine), Cheng Long(Baylor College of Medicine), Joshua M. Oakes(Baylor College of Medicine), Ted Tran(Baylor College of Medicine), Benjamin T. Corona(Georgia State University), Sabina Lorca(The University of Texas Health Science Center at Houston), Christopher P. Ingalls(Georgia State University), Vihang A. Narkar(The University of Texas Health Science Center at Houston), Johanna T. Lanner(Baylor College of Medicine), J. Henri Bayle(Baylor College of Medicine), William J. Durham(The University of Texas Medical Branch at Galveston), Susan L. Hamilton(Baylor College of Medicine)

Journal of Biological Chemistry

July 23, 2014

10.1074/jbc.m114.586289

Cited by 27Open Access

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Abstract

Rapamycin at high doses (2-10 mg/kg body weight) inhibits mammalian target of rapamycin complex 1 (mTORC1) and protein synthesis in mice. In contrast, low doses of rapamycin (10 μg/kg) increase mTORC1 activity and protein synthesis in skeletal muscle. Similar changes are found with SLF (synthetic ligand for FKBP12, which does not inhibit mTORC1) and in mice with a skeletal muscle-specific FKBP12 deficiency. These interventions also increase Ca(2+) influx to enhance refilling of sarcoplasmic reticulum Ca(2+) stores, slow muscle fatigue, and increase running endurance without negatively impacting cardiac function. FKBP12 deficiency or longer treatments with low dose rapamycin or SLF increase the percentage of type I fibers, further adding to fatigue resistance. We demonstrate that FKBP12 and its ligands impact multiple aspects of muscle function.

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