Growing old too early, automated assessment of skeletal muscle single fiber biomechanics in ageing R349P desmin knock-in mice using the MyoRobot technology

Abstract

AbstractMuscle biomechanics is determined by active motor-protein assembly and passive strain transmission through cytoskeletal structures. The extrasarcomeric desmin filament network aligns myofibrils at the z-discs, provides nuclear-sarcolemmal anchorage and may also serve as memory for muscle repositioning following large strains. Our previous analyses of R349P desmin knock-in mice, an animal model for the human R350P desminopathy, already depicted pre-clinical changes in myofibrillar arrangement and increased fiber bundle stiffness compatible with a pre-aged phenotype in the disease. Since the specific effect of R349P desmin on axial biomechanics in fully differentiated muscle fibers is unknown, we used our automated MyoRobot biomechatronics platform to compare passive and active biomechanics in single fibers derived from fast- and slow-twitch muscles from adult to senile mice hetero- or homozygous for this desmin mutation with wild-type littermates. Experimental protocols involved caffeine-induced Ca2+-mediated force transients, pCa-force curves, resting length-tension curves, visco-elasticity and ‘slack-tests’. We demonstrate that the presence of R349P desmin predominantly increased single fiber axial stiffness in both muscle types with a pre-aged phenotype over wild-type fibers. Axial viscosity was unaffected. Likewise, no systematic changes in Ca2+-mediated force properties were found. Notably, mutant single fibers showed faster unloaded shortening over wild-type fibers. Effects of ageing seen in the wild-type always appeared earlier in the mutant desmin fibers. Impaired R349P desmin muscle biomechanics is clearly an effect of a compromised intermediate filament network rather than secondary to fibrosis.