Fatiguing Contractions Induce Acute Redox Signaling in Mouse Muscle

Abstract

Protein S-glutathionylation (P-SSG) is a reversible redox modification known to alter the activity of transcription factors, kinases, and contractile proteins as well as protect critical cysteine residues from irreversible oxidation. Exercise elicits an acute oxidative stress that is reported to result in beneficial adaptive responses, a process known as redox signaling. We hypothesized that redox signaling will occur through P-SSG of regulatory cysteines following fatiguing muscle contractions. To test this hypothesis, we performed acute fatiguing contractions using an in vivo stimulation protocol on anesthetized CB6F1 (BALB/cBy x C57BL/6) mice. Muscle force production was monitored by a force transducer throughout the 15 minutes of fatiguing stimulations. The right (stimulated) and left (unstimulated) gastrocnemius were collected 60 minutes after the last stimulation and processed for redox proteomics using resin-assisted thiol enrichment and selective reduction. Redox proteomics revealed over 1,500 P-SSG modifications that were significantly increased by fatiguing contractions. Mitochondrial proteins were among the most sensitive to glutathionylation. Ingenuity Pathway Analysis revealed mitochondrial dysfunction, calcium signaling, cytoskeleton signaling, and oxidative stress response in the top ten affected pathways. Critical cysteines on beta-actin, troponin I, ryanodine receptor 1, SERCA1, ATP synthase subunit alpha and NADH dehydrogenase flavoprotein 1 were among those significantly glutathionylated that have previously been reported to alter protein and muscle function. These modifications of redox sensitive proteins implicate rapid regulation of metabolism, excitation/contraction coupling, kinase activity, and contractile protein function, and protection from irreversible oxidation. Together, these data suggest a direct role of ROS in acute exercise signaling and map the redox sensitive proteome in mouse muscle. This study lays the groundwork for future investigation into the redox signaling of altered exercise adaptation associated with chronic conditions, such as sarcopenia, the age-related loss of muscle mass and function.