Circulating protein synthesis rates reveal skeletal muscle proteome dynamics
Mahalakshmi Shankaran, … , Benjamin F. Miller, Marc K. Hellerstein
Mahalakshmi Shankaran, … , Benjamin F. Miller, Marc K. Hellerstein
Published January 4, 2016; First published December 14, 2015
Citation Information: J Clin Invest. 2016;126(1):288-302. https://doi.org/10.1172/JCI79639.
View: Text | PDF
Categories: Technical Advance Muscle biology

Circulating protein synthesis rates reveal skeletal muscle proteome dynamics

Abstract

Here, we have described and validated a strategy for monitoring skeletal muscle protein synthesis rates in rodents and humans over days or weeks from blood samples. We based this approach on label incorporation into proteins that are synthesized specifically in skeletal muscle and escape into the circulation. Heavy water labeling combined with sensitive tandem mass spectrometric analysis allowed integrated synthesis rates of proteins in muscle tissue across the proteome to be measured over several weeks. Fractional synthesis rate (FSR) of plasma creatine kinase M-type (CK-M) and carbonic anhydrase 3 (CA-3) in the blood, more than 90% of which is derived from skeletal muscle, correlated closely with FSR of CK-M, CA-3, and other proteins of various ontologies in skeletal muscle tissue in both rodents and humans. Protein synthesis rates across the muscle proteome generally changed in a coordinate manner in response to a sprint interval exercise training regimen in humans and to denervation or clenbuterol treatment in rodents. FSR of plasma CK-M and CA-3 revealed changes and interindividual differences in muscle tissue proteome dynamics. In human subjects, sprint interval training primarily stimulated synthesis of structural and glycolytic proteins. Together, our results indicate that this approach provides a virtual biopsy, sensitively revealing individualized changes in proteome-wide synthesis rates in skeletal muscle without a muscle biopsy. Accordingly, this approach has potential applications for the diagnosis, management, and treatment of muscle disorders.

Authors

Mahalakshmi Shankaran, Chelsea L. King, Thomas E. Angel, William E. Holmes, Kelvin W. Li, Marc Colangelo, John C. Price, Scott M. Turner, Christopher Bell, Karyn L. Hamilton, Benjamin F. Miller, Marc K. Hellerstein

×

Figure 4

Human skeletal muscle proteome dynamics in sedentary and SIT subjects.

Options: View larger image (or click on image) Download as PowerPoint
Human skeletal muscle proteome dynamics in sedentary and SIT subjects. (...
(A) Heatmap of FSRs (% week–1) of 139 proteins measured in muscle of 5 sedentary subjects and 6 subjects who underwent SIT. Each horizontal line represents an individual protein. (B) Mean FSR of proteins in DAVID gene ontology term, biological processes level 5, that were significantly different as a group (P < 0.05 in paired t tests for proteins with Benjamini-Hochberg multiple test corrections) in sedentary (n = 3–5) or sprint (n = 4–6) subjects. Black lines reflect proteins whose FSRs were significantly different (uncorrected P < 0.05, unpaired t tests between subjects in the 2 groups) within the ontologies. For glucose metabolic process: phosphoglycerate mutase 2; fructose-1,6-bisphosphatase isozyme 2; pyruvate kinase isozymes M1/M2; malate dehydrogenase cytoplasmic; triosephosphate isomerase; fructose-bisphosphate aldolase A; and phosphoglycerate kinase 1. For striated muscle contraction: Phosphoglycerate mutase 2, Fructose-bisphosphate aldolase A, and myosin light chain 1/3 skeletal muscle isoform. For regulation of apoptosis: heat shock 70 kDa protein 1A/1B. (C) FSRs of 20 proteins that were significantly different between sedentary (n = 5) and sprint (n = 6) subjects (unpaired t tests between the 2 groups with Benjamini-Hochberg multiple test corrections). For each protein, the bar represents mean, minimum, and maximum FSR; symbols within bars represent individual FSR values.