Distinct genetic regions modify specific muscle groups in muscular dystrophy

Phenotypic expression in the muscular dystrophies is variable, even with the identical mutation, providing strong evidence that genetic modifiers influence outcome. To identify genetic modifier loci, we used quantitative trait locus mapping in two differentially affected mouse strains with muscular dystrophy. Using the Sgcg model of limb girdle muscular dystrophy that lacks the dystrophin-associated protein γ-sarcoglycan, we evaluated chromosomal regions that segregated with two distinct quantifiable characteristics of muscular dystrophy, membrane permeability and fibrosis. We previously identified a single major locus on murine chromosome 7 that influences both traits of membrane permeability and fibrosis in the quadriceps muscle. Using a larger cohort, we now found that this same interval strongly associated with both traits in all limb skeletal muscle groups studied, including the gastrocnemius/soleus, gluteus/hamstring, and triceps muscles. In contrast, the muscles of the trunk were modified by distinct genetic loci, possibly reflecting the embryological origins and physiological stressors unique to these muscle groups. A locus on chromosome 18 was identified that modified membrane permeability of the abdominal muscles, and a locus on chromosome 3 was found that regulated diaphragm and abdominal muscle fibrosis. Fibrosis in the heart associated with a region on chromosome 9 and likely reflects differential function between cardiac and skeletal muscle. These data underscore the complexity of inheritance and penetrance of single-gene disorders

The superhealing MRL background improves muscular dystrophy

<p>Abstract</p> <p>Background</p> <p>Mice from the MRL or “superhealing” strain have enhanced repair after acute injury to the skin, cornea, and heart. We now tested an admixture of the MRL genome and found that it altered the course of muscle pathology and cardiac function in a chronic disease model of skeletal and cardiac muscle. Mice lacking γ-sarcoglycan (<it>Sgcg</it>), a dystrophin-associated protein, develop muscular dystrophy and cardiomyopathy similar to their human counterparts with limb girdle muscular dystrophy. With disruption of the dystrophin complex, the muscle plasma membrane becomes leaky and muscles develop increased fibrosis.</p> <p>Methods</p> <p>MRL/MpJ mice were bred with <it>Sgcg</it> mice, and cardiac function was measured. Muscles were assessed for fibrosis and membrane leak using measurements of hydroxyproline and Evans blue dye. Quantitative trait locus mapping was conducted using single nucleotide polymorphisms distinct between the two parental strains.</p> <p>Results</p> <p>Introduction of the MRL genome reduced fibrosis but did not alter membrane leak in skeletal muscle of the <it>Sgcg</it> model. The MRL genome was also associated with improved cardiac function with reversal of depressed fractional shortening and the left ventricular ejection fraction. We conducted a genome-wide analysis of genetic modifiers and found that a region on chromosome 2 was associated with cardiac, diaphragm muscle and abdominal muscle fibrosis.</p> <p>Conclusions</p> <p>These data are consistent with a model where the MRL genome acts in a dominant manner to suppress fibrosis in this chronic disease setting of heart and muscle disease.</p

Annexin A6 modifies muscular dystrophy by mediating sarcolemmal repair.

Many monogenic disorders, including the muscular dystrophies, display phenotypic variability despite the same disease-causing mutation. To identify genetic modifiers of muscular dystrophy and its associated cardiomyopathy, we used quantitative trait locus mapping and whole genome sequencing in a mouse model. This approach uncovered a modifier locus on chromosome 11 associated with sarcolemmal membrane damage and heart mass. Whole genome and RNA sequencing identified Anxa6, encoding annexin A6, as a modifier gene. A synonymous variant in exon 11 creates a cryptic splice donor, resulting in a truncated annexin A6 protein called ANXA6N32. Live cell imaging showed that annexin A6 orchestrates a repair zone and cap at the site of membrane disruption. In contrast, ANXA6N32 dramatically disrupted the annexin A6-rich cap and the associated repair zone, permitting membrane leak. Anxa6 is a modifier of muscular dystrophy and membrane repair after injury

Myoferlin is required for insulin-like growth factor response and muscle growth

Insulin-like growth factor (IGF) is a potent stimulus of muscle growth. Myoferlin is a membrane-associated protein important for muscle development and regeneration. Myoferlin-null mice have smaller muscles and defective myoblast fusion. To understand the mechanism by which myoferlin loss retards muscle growth, we found that myoferlin-null muscle does not respond to IGF1. In vivo after IGF1 infusion, control muscle increased myofiber diameter by 25%, but myoferlin-null muscle was unresponsive. Myoblasts cultured from myoferlin-null muscle and treated with IGF1 also failed to show the expected increase in fusion to multinucleate myotubes. The IGF1 receptor colocalized with myoferlin at sites of myoblast fusion. The lack of IGF1 responsiveness in myoferlin-null myoblasts was linked directly to IGF1 receptor mistrafficking as well as decreased IGF1 signaling. In myoferlin-null myoblasts, the IGF1 receptor accumulated into large vesicular structures. These vesicles colocalized with a marker of late endosomes/lysosomes, LAMP2, specifying redirection from a recycling to a degradative pathway. Furthermore, ultrastructural analysis showed a marked increase in vacuoles in myoferlin-null muscle. These data demonstrate that IGF1 receptor recycling is required for normal myogenesis and that myoferlin is a critical mediator of postnatal muscle growth mediated by IGF1.—Demonbreun, A. R., Posey, A. D., Heretis, K., Swaggart, K. A., Earley, J. U., Pytel, P., McNally, E. M. Myoferlin is required for insulin-like growth factor response and muscle growth

Annexin A6 modifies muscular dystrophy by mediating sarcolemmal repair.

Many monogenic disorders, including the muscular dystrophies, display phenotypic variability despite the same disease-causing mutation. To identify genetic modifiers of muscular dystrophy and its associated cardiomyopathy, we used quantitative trait locus mapping and whole genome sequencing in a mouse model. This approach uncovered a modifier locus on chromosome 11 associated with sarcolemmal membrane damage and heart mass. Whole genome and RNA sequencing identified Anxa6, encoding annexin A6, as a modifier gene. A synonymous variant in exon 11 creates a cryptic splice donor, resulting in a truncated annexin A6 protein called ANXA6N32. Live cell imaging showed that annexin A6 orchestrates a repair zone and cap at the site of membrane disruption. In contrast, ANXA6N32 dramatically disrupted the annexin A6-rich cap and the associated repair zone, permitting membrane leak. Anxa6 is a modifier of muscular dystrophy and membrane repair after injury