Abstract
Muscular dystrophies are disorders characterized by progressive muscle loss and weakness that are both genotypically and phenotypically heterogenous. Progression of muscle disease arises from impaired regeneration, plasma membrane instability, defective membrane repair, and calcium mishandling. The ferlin protein family, including dysferlin and myoferlin, are calcium-binding, membrane-associated proteins that regulate membrane fusion, trafficking, and tubule formation. Mice lacking dysferlin (Dysf), myoferlin (Myof), and both dysferlin and myoferlin (Fer) on an isogenic inbred 129 background were previously demonstrated that loss of both dysferlin and myoferlin resulted in more severe muscle disease than loss of either gene alone. Furthermore, Fer mice had disordered triad organization with visibly malformed transverse tubules and sarcoplasmic reticulum, suggesting distinct roles of dysferlin and myoferlin. To assess the physiological role of disorganized triads, we now assessed excitation contraction (EC) coupling in these models. We identified differential abnormalities in EC coupling and ryanodine receptor disruption in flexor digitorum brevis myofibers isolated from ferlin mutant mice. We found that loss of dysferlin alone preserved sensitivity for EC coupling and was associated with larger ryanodine receptor clusters compared to wildtype myofibers. Loss of myoferlin alone or together with a loss of dysferlin reduced sensitivity for EC coupling, and produced disorganized and smaller ryanodine receptor cluster size compared to wildtype myofibers. These data reveal impaired EC coupling in Myof and Fer myofibers and slightly potentiated EC coupling in Dysf myofibers. Despite high homology, dysferlin and myoferlin have differential roles in regulating sarcotubular formation and maintenance resulting in unique impairments in calcium handling properties.
Highlights
Muscular dystrophies are disorders characterized by progressive muscle loss and weakness that are both genotypically and phenotypically heterogenous
We found that loss of dysferlin alone caused a small reduction in calcium transient amplitude but did not reduce sensitivity of excitation contraction (EC) coupling or alter cell shortening, whereas loss of myoferlin alone or in combination with dysferlin caused aberrant EC coupling with smaller calcium transients and slower calcium release kinetics
We were interested in assessing the response of the myofibers to twitch, summating and tetanic stimuli, so we stimulated the cells at twitch, 40 Hz, and 80 Hz and measured unloaded sarcomere length shortening and calcium transients
Summary
Muscular dystrophies are disorders characterized by progressive muscle loss and weakness that are both genotypically and phenotypically heterogenous. Loss of myoferlin alone or together with a loss of dysferlin reduced sensitivity for EC coupling, and produced disorganized and smaller ryanodine receptor cluster size compared to wildtype myofibers. These data reveal impaired EC coupling in Myof and Fer myofibers and slightly potentiated EC coupling in Dysf myofibers. Abbreviations WT Wild-type Myof Myoferlin-null mouse Dysf Dysferlin-null mouse Fer Ferlin-null mouse EC Excitation–contraction SR Sarcoplasmic reticulum DHPR Dihydropyridine receptor RyR Ryanodine receptor FDB Flexor digitorum brevis SL Sarcomere length. Muscular dystrophies are disorders characterized by progressive muscle loss and weakness that often result from loss of function mutations in cytoskeletal and membrane-associated proteins[1,2,3]. Unlike dysferlin, no clinical forms of muscular dystrophy due to mutations in myoferlin have been reported
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