Mechanical unloading of 3D-engineered muscle leads to muscle atrophy by suppressing protein synthesis.

Three-dimensional (3D)-engineered muscle is an useful approach to a more comprehensive understanding of molecular mechanisms underlying unloading-induced muscle atrophy. We investigated the effects of mechanical unloading on molecular muscle protein synthesis (MPS)- and muscle protein breakdown (MPB)-related signaling pathways involved in muscle atrophy in 3D-engineered muscle, and to better understand in vitro model of muscle disuse. The 3D-engineered muscle consisting of C2C12 myoblasts and type-1 collagen gel was allowed to differentiate for 2 wk and divided into three groups: 0 days of stretched-on control (CON), 2 and/or 7 days of stretched-on (ON), in which both ends of the muscle were fixed with artificial tendons, and the stretched-off group (OFF), in which one side of the artificial tendon was detached. Muscle weight (-38.1% to -48.4%), length (-67.0% to -73.5%), twitch contractile force (-70.5% to -75.0%), and myosin heavy chain expression (-32.5% to -50.5%) in the OFF group were significantly decreased on and compared with the ON group ( < 0.05, respectively), despite that ON group was stable over time. Although determinative molecular signaling could not be identified, the MPS rate reflected by puromysin-labeled protein was significantly decreased following mechanical unloading ( < 0.05, -38.5% to -51.1%). Meanwhile, MPB, particularly the ubiquitin-proteasome pathway, was not impacted. Hence, mechanical unloading of 3D-engineered muscle in vitro leads to muscle atrophy by suppressing MPS, cell differentiation, and cell growth rather than the promotion of MPB. Three-dimensional (3D)-engineered muscles have recently been shown to closely replicate the in vivo architecture. We found that mechanical unloading of 3D-engineered muscle led to muscle disuse atrophy accompanied by reduced functional properties and contractile protein expression via suppression of muscle protein synthesis. This novel model may improve the in vitro testing of modalities with the potential to reduce mechanical unloading-induced atrophy.