Rapamycin improves satellite cells’ autophagy and muscle regeneration during hypercapnia
Joseph Balnis, Emily L. Jackson, Lisa A. Drake, Diane V. Singer, Ramon Bossardi Ramos, Harold A. Singer, Ariel Jaitovich
Joseph Balnis, Emily L. Jackson, Lisa A. Drake, Diane V. Singer, Ramon Bossardi Ramos, Harold A. Singer, Ariel Jaitovich
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Research Article Pulmonology

Rapamycin improves satellite cells’ autophagy and muscle regeneration during hypercapnia

Abstract

Both CO2 retention, or hypercapnia, and skeletal muscle dysfunction predict higher mortality in critically ill patients. Mechanistically, muscle injury and reduced myogenesis contribute to critical illness myopathy, and while hypercapnia causes muscle wasting, no research has been conducted on hypercapnia-driven dysfunctional myogenesis in vivo. Autophagy flux regulates myogenesis by supporting skeletal muscle stem cell — satellite cell — activation, and previous data suggest that hypercapnia inhibits autophagy. We tested whether hypercapnia worsens satellite cell autophagy flux and myogenic potential and if autophagy induction reverses these deficits. Satellite cell transplantation and lineage-tracing experiments showed that hypercapnia undermined satellite cells’ activation, replication, and myogenic capacity. Bulk and single-cell sequencing analyses indicated that hypercapnia disrupts autophagy, senescence, and other satellite cell programs. Autophagy activation was reduced in hypercapnic cultured myoblasts, and autophagy genetic knockdown phenocopied these changes in vitro. Rapamycin stimulation led to AMPK activation and downregulation of the mTOR pathway, which are both associated with accelerated autophagy flux and cell replication. Moreover, hypercapnic mice receiving rapamycin showed improved satellite cell autophagy flux, activation, replication rate, and posttransplantation myogenic capacity. In conclusion, we have shown that hypercapnia interferes with satellite cell activation, autophagy flux, and myogenesis, and systemic rapamycin administration improves these outcomes.

Authors

Joseph Balnis, Emily L. Jackson, Lisa A. Drake, Diane V. Singer, Ramon Bossardi Ramos, Harold A. Singer, Ariel Jaitovich

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Figure 1

Chronic hypercapnia exposure causes skeletal muscle dysfunction.

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Chronic hypercapnia exposure causes skeletal muscle dysfunction. (A) Ven...
(A) Venous bicarbonate, a surrogate of chronic hypercapnia exposure, is elevated in the hypercapnic (HC) mice compared with their normocapnic (NC) counterparts (n = 3). (B) Food intake is significantly reduced in HC mice (n = 6). (C) Daily motion is not different between NC and HC mice (n = 6). (D) Gross body mass is reduced in HC mice in comparison with NC counterparts (n = 10 NC, 11 HC). (E) Freshly isolated tibialis anterior (TA) muscles from HC mice weigh less than NC mice–procured muscles (n = 11). (F and G) Sectioning and immunofluorescence stain of the extensor digitorum longus (EDL) muscle, automatically quantified, show reduced average myofiber cross-sectional area in HC mice (n = 4). (H) Mice in HC conditions have reduced limb grip strength (n = 4). (I) Isolated muscle contractility of EDL from HC mice shows lower absolute force when electrically stimulated in comparison with NC counterparts (n = 5 NC, 4 HC). (J) When corrected for muscle mass, HC muscles show no myofiber-specific force reduction when compared with NC littermates (n = 5 NC, 4 HC). All statistical comparisons were performed using Student’s t test; *P < 0.05, **P < 0.01, and ***P < 0.001.