Abstract
ABSTRACTMyosin is vital for body movement and heart contractility. Mutations in MYH7, encoding slow/β-cardiac myosin heavy chain, are an important cause of hypertrophic and dilated cardiomyopathy, as well as skeletal muscle disease. A dominant missense mutation (R1845W) in MYH7 has been reported in several unrelated cases of myosin storage myopathy. We have developed a Drosophila model for a myosin storage myopathy in order to investigate the dose-dependent mechanisms underlying the pathological roles of the R1845W mutation. This study shows that a higher expression level of the mutated allele is concomitant with severe impairment of muscle function and progressively disrupted muscle morphology. The impaired muscle morphology associated with the mutant allele was suppressed by expression of Thin (herein referred to as Abba), an E3 ubiquitin ligase. This Drosophila model recapitulates pathological features seen in myopathy patients with the R1845W mutation and severe ultrastructural abnormalities, including extensive loss of thick filaments with selective A-band loss, and preservation of I-band and Z-disks were observed in indirect flight muscles of flies with exclusive expression of mutant myosin. Furthermore, the impaired muscle morphology associated with the mutant allele was suppressed by expression of Abba. These findings suggest that modification of the ubiquitin proteasome system may be beneficial in myosin storage myopathy by reducing the impact of MYH7 mutation in patients.
Highlights
Myosin heavy chain (MyHC) is the molecular motor of muscle and forms the backbone of the sarcomeric thick filaments
While mutations mainly located within the globular head of slow/ß-cardiac MyHC are an important cause of hypertrophic and dilated cardiomyopathy (Walsh et al, 2010), mutations located at the α-helical coiled-coil C-terminal rod domain (LMM) cause two skeletal myosin myopathies, Laing distal myopathy and myosin storage myopathy (MSM), with or without cardiac involvement (Tajsharghi and Oldfors, 2013)
Mutations associated with Laing distal myopathy that are situated at distance from the assembly competence domain might cause other effects on the thick filament structure and function leading to different pathology (Tajsharghi and Oldfors, 2013)
Summary
Myosin heavy chain (MyHC) is the molecular motor of muscle and forms the backbone of the sarcomeric thick filaments. MSM is a protein aggregate myopathy associated with myosin accumulation (Tajsharghi et al, 2003) It is caused by primarily dominant mutations located within or close to the 29-residue assembly competence domain in the distal end of the LMM of slow/ß-cardiac MyHC (Tajsharghi and Oldfors, 2013), which is known to be critical for the proper assembly of sarcomeric myosin rod filaments (Sohn et al, 1997). Mutations in this region may cause defective integration of dimers into the thick filament leading to accumulation of unassembled MyHC. MSM and Laing distal myopathy show distinct morphological and clinical phenotypes, depending on the mutated residue at the tail region (Tajsharghi and Oldfors, 2013)
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