Desmin knockout muscles generate lower stress and are less vulnerable to injury compared with wild-type muscles

The functional roleof the skeletal muscle intermediate filament system was investigated bymeasuring the magnitude of muscle force loss after cyclic eccentriccontraction (EC) in normal and desmin null mouse extensor digitorumlongus muscles. Isometric stress generated was significantly greater inwild-type (313 ± 8 kPa) compared with knockout muscles (276 ± 13 kPa) before EC (P < 0.05), but 1 h after 10 ECs, both muscle types generated identical levels of stress (~250kPa), suggesting less injury to the knockout. Differences in injurysusceptibility were not explained by the different absolute stresslevels imposed on wild-type versus knockout muscles (determined bytesting older muscles) or by differences in fiber length or mechanicalenergy absorbed. Morphometric analysis of longitudinal electronmicrographs indicated that Z disks from knockout muscles were morestaggered (0.36 ± 0.03 µm) compared with wild-type muscles(0.22 ± 0.03 µm), which may indicate that the knockoutcytoskeleton is more compliant. These data demonstrate that lack of theintermediate filament system decreases isometric stress production andthat the desmin knockout muscle is less vulnerable to mechanical injury.