Abstract
Nemaline myopathy is the most common disease entity among non-dystrophic skeletal muscle congenital diseases. The first disease causing mutation (Met9Arg) was identified in the gene encoding α-tropomyosinslow gene (TPM3). Considering the conflicting findings of the previous studies on the transgenic (Tg) mice carrying the TPM3 Met9Arg mutation, we investigated carefully the effect of the Met9Arg mutation in 8–9 month-old Tg(TPM3)Met9Arg mice on muscle function using a multiscale methodological approach including skinned muscle fibers analysis and in vivo investigations by magnetic resonance imaging and 31-phosphorus magnetic resonance spectroscopy. While in vitro maximal force production was reduced in Tg(TPM3)Met9Arg mice as compared to controls, in vivo measurements revealed an improved mechanical performance in the transgenic mice as compared to the former. The reduced in vitro muscle force might be related to alterations occuring at the cross-bridges level with muscle-specific underlying mechanisms. In vivo muscle improvement was not associated with any changes in either muscle volume or energy metabolism. Our findings indicate that TPM3(Met9Arg) mutation leads to a mild muscle weakness in vitro related to an alteration at the cross-bridges level and a paradoxical gain of muscle function in vivo. These results clearly point out that in vitro alterations are muscle-dependent and do not necessarily translate into similar changes in vivo.
Highlights
Nemaline myopathy (NM), the most common form of congenital myopathies, is a genetic muscular disorder characterized by muscle weakness and rod-shaped structures in skeletal muscle [1]
Considering that Tm plays a key role in the regulation of skeletal muscle contraction by controlling the Ca2+ sensitivity of force and by modulating the kinetics of actin–myosin cross-bridge cycling [10], it has been suggested that the changes in dimeric species related to the Met9Arg mutation might exert a poisoning effect on skeletal muscle function [11]
When normalized to muscle volume, maximal force was 30% higher (P,0.05) in Tg(TPM3)Met9Arg group relative to WT group at neutral (1.7260.04 mN/mm3 vs. 1.3260.05 mN/mm3, respectively), short (1.9760.06 mN/mm3 vs. 1.4760.07 mN/mm3, respectively) and long (1.7960.05 mN/mm3 vs. 1.3760.09 mN/mm3, respectively) muscle length, indicating that force normalization using either muscle volume or maximal CSA leads to similar differences between the two groups
Summary
Nemaline myopathy (NM), the most common form of congenital myopathies, is a genetic muscular disorder characterized by muscle weakness and rod-shaped structures in skeletal muscle [1]. Nine genes, most of them encoding proteins associated with muscle thin filaments, have been identified as causing NM in humans [3,4]. Considering that Tm plays a key role in the regulation of skeletal muscle contraction by controlling the Ca2+ sensitivity of force and by modulating the kinetics of actin–myosin cross-bridge cycling [10], it has been suggested that the changes in dimeric species related to the Met9Arg mutation might exert a poisoning effect on skeletal muscle function [11]. Recent studies reported an alteration of cross-bridge cycling kinetics in other TPM3-based NM [12,13], the effect of Met9Arg substitution on human skeletal muscle fiber function has never been investigated probably due to the paucity of muscle biopsy material
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