Integrated expression analysis of muscle hypertrophy identifies Asb2 as a negative regulator of muscle mass
Jonathan R. Davey, … , David E. James, Paul Gregorevic
Jonathan R. Davey, … , David E. James, Paul Gregorevic
Published April 21, 2016
Citation Information: JCI Insight. 2016;1(5):e85477. https://doi.org/10.1172/jci.insight.85477.
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Research Article Aging Muscle biology

Integrated expression analysis of muscle hypertrophy identifies Asb2 as a negative regulator of muscle mass

Abstract

The transforming growth factor-β (TGF-β) signaling network is a critical regulator of skeletal muscle mass and function and, thus, is an attractive therapeutic target for combating muscle disease, but the underlying mechanisms of action remain undetermined. We report that follistatin-based interventions (which modulate TGF-β network activity) can promote muscle hypertrophy that ameliorates aging-associated muscle wasting. However, the muscles of old sarcopenic mice demonstrate reduced response to follistatin compared with healthy young-adult musculature. Quantitative proteomic and transcriptomic analyses of young-adult muscles identified a transcription/translation signature elicited by follistatin exposure, which included repression of ankyrin repeat and SOCS box protein 2 (Asb2). Increasing expression of ASB2 reduced muscle mass, thereby demonstrating that Asb2 is a TGF-β network–responsive negative regulator of muscle mass. In contrast to young-adult muscles, sarcopenic muscles do not exhibit reduced ASB2 abundance with follistatin exposure. Moreover, preventing repression of ASB2 in young-adult muscles diminished follistatin-induced muscle hypertrophy. These findings provide insight into the program of transcription and translation events governing follistatin-mediated adaptation of skeletal muscle attributes and identify Asb2 as a regulator of muscle mass implicated in the potential mechanistic dysfunction between follistatin-mediated muscle growth in young and old muscles.

Authors

Jonathan R. Davey, Kevin I. Watt, Benjamin L. Parker, Rima Chaudhuri, James G. Ryall, Louise Cunningham, Hongwei Qian, Vittorio Sartorelli, Marco Sandri, Jeffrey Chamberlain, David E. James, Paul Gregorevic

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Figure 2

Quantitative proteomic analysis reveals changes in protein signature associated with acute and chronic follistatin expression in skeletal muscle.

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Quantitative proteomic analysis reveals changes in protein signature ass...
(A) Schematic displaying the experimental workflow for iTRAQ sample labeling and tandem mass spectrometry (MS/MS) analysis. (B) Distribution of the quantified proteins relative to no-DOX samples with a ± 1.5–fold expression change cut-off (moderated t test, adjusted P < 0.05, n = 3). (C) Pearson correlation between replicates from 2- and 28-day follistatin treatments. (D) Gene set enrichment analysis predicted pathways regulated across the indicated time points in the proteomics data set. The upregulated pathways are shown in red, downregulated are shown in blue, and pathways showing a mixed response are highlighted in green (P < 0.05). (E) Z-score scatterplot of the proteins concordantly changed at 2 and 28 days from the 2-dimensional directional pathway analysis. Significantly upregulated proteins are highlighted in red in quadrant I, and downregulated proteins are cultured in blue in quadrant III (integrated P < 0.05); proteins that remained unaltered under the tested hypotheses are shown in gray. Isobaric labeling for relative and absolute quantitation, iTRAQ; hydrophilic interaction chromatography, HILIC; nano-ultra high performance liquid chromatography, nanoUHPLC; differentially expressed, DE; recombinant adeno-associated virus, rAAV; tibialis anterior muscle,TA; doxycycline, DOX; tetracycline responsive follistatin, indFST.