epsilon-sarcoglycan replaces alpha-sarcoglycan in smooth muscle to form a unique dystrophin-glycoprotein complex.

The sarcoglycan complex has been well characterized in striated muscle, and defects in its components are associated with muscular dystrophy and cardiomyopathy. Here, we have characterized the smooth muscle sarcoglycan complex. By examination of embryonic muscle lineages and biochemical fractionation studies, we demonstrated that epsilon-sarcoglycan is an integral component of the smooth muscle sarcoglycan complex along with beta- and delta-sarcoglycan. Analysis of genetically defined animal models for muscular dystrophy supported this conclusion. The delta-sarcoglycan-deficient cardiomyopathic hamster and mice deficient in both dystrophin and utrophin showed loss of the smooth muscle sarcoglycan complex, whereas the complex was unaffected in alpha-sarcoglycan null mice in agreement with the finding that alpha-sarcoglycan is not expressed in smooth muscle cells. In the cardiomyopathic hamster, the smooth muscle sarcoglycan complex, containing epsilon-sarcoglycan, was fully restored following intramuscular injection of recombinant delta-sarcoglycan adenovirus. Together, these results demonstrate a tissue-dependent variation in the sarcoglycan complex and show that epsilon-sarcoglycan replaces alpha-sarcoglycan as an integral component of the smooth muscle dystrophin-glycoprotein complex. Our results also suggest a molecular basis for possible differential smooth muscle dysfunction in sarcoglycan-deficient patients.

Molecular pathogenesis of muscle degeneration in the delta-sarcoglycan-deficient hamster.

The BIO14.6 hamster is an extensively used animal model of autosomal recessive cardiomyopathy and muscular dystrophy. Recently, a large deletion in the 5' end of the delta-sarcoglycan gene was found to be the primary genetic defect in the hamster. In the present investigation, we studied the effects of the delta-sarcoglycan deletion on transcription, expression, and function of the dystrophin-glycoprotein complex in skeletal and cardiac muscle. We demonstrated that in striated muscle the genetic defect leads to the complete deficiency of delta-sarcoglycan and a concomitant loss of alpha-, beta-, and gamma-sarcoglycan. In addition, absence of the sarcoglycan complex reduced the expression of alpha-dystroglycan in striated muscle fibers. These findings indicated that the primary defect in the BIO14.6 hamster leads to the dissociation of the dystroglycan complex from the sarcoglycan complex and disrupted anchorage of alpha-dystroglycan to the cell surface. Using intravenous injection of Evans blue dye as an in vivo tracer assay, we demonstrated that perturbation of the dystrophin-glycoprotein complex caused extensive fiber damage in skeletal and cardiac muscle of the BIO14.6 hamster. Based on our results, we propose that loss of delta-sarcoglycan results in the impairment of sarcolemmal integrity, finally leading to muscular dystrophy and cardiomyopathy.

Beta-sarcoglycan: genomic analysis and identification of a novel missense mutation in the LGMD2E Amish isolate.

The sarcoglycan complex is involved in the etiology of four autosomal recessive limb-girdle muscular dystrophies (LGMD2C-F). A missense mutation (T151R) in the beta-sarcoglycan gene on chromosome 4q12 has been shown to cause a mild form of LGMD2E in 11 families from a Southern Indiana Amish community sharing a common haplotype. We now report that two sibs from another Amish family with mild LGMD2E are compound heterozygotes for chromosome 4q12 markers. In order to characterize the genetic defect in this new family, we determined the genomic organization of the beta-sarcoglycan gene. A second missense mutation (R91C) has now been identified in this LGMD2E Amish family. This mutation is also present in the homozygous state in another family of probable Amish ancestry. Finally, analysis of all the components of the dystrophin-glycoprotein complex was performed for the first time on a biopsy from a patient homozygous for the beta-sarcoglycan mutation (T151R). Interestingly, in addition to the loss of the entire sarcoglycan complex, we detected a reduction of alpha-dystroglycan which suggests a role for the sarcoglycan complex in stabilizing alpha-dystroglycan at the sarcolemma.

A novel form of familial congenital muscular dystrophy in two adolescents.

We report on two brothers (the product of first-degree consanguineous marriage; aged 15 and 12 years) who presented with severe hypotonia at birth, proximal muscle weakness associated with delayed motor milestones but normal cognitive function. Investigations (at 4 years of age) revealed mildly elevated serum creatine kinase (CK) levels (300 and 824 IU/l; N < or = 210). Muscle biopsies showed minimal change myopathy, no neurogenic atrophy but remarkable type-1 fibre predominance (up to 85.5%) without fibre-type disproportion. Clinical examination at 12 and 9 years, respectively, showed mild facial weakness and high-arched palate in both patients. The younger sibling also had ptosis but otherwise normal external ocular muscles. They showed symmetric proximal muscle weakness and wasting associated with calf-muscle hypertrophy. They could walk independently. A repeat muscle biopsy showed advanced dystrophic changes in the younger patient at the age of 10 years. Virtually all the remaining fibres were type 1. Immunohistochemistry revealed normal expression of the dystrophin-glycoprotein complex (DGC), including dystrophin, beta-dystroglycan, alpha-(adhalin), beta-, gamma-, and delta-sarcoglycan, laminin-alpha2 chain (merosin) and syntrophin. Mild dystrophic features and type-1 fibre predominance (92.5%) were seen in the biopsy of the older patient, whereas immunohistochemistry showed normal expression of the DGC. Both cases also showed clear expression of integrin alpha7 at the muscle fibre surface and in the blood vessels. Three years later, they could still walk, but with difficulty, and the older brother showed enlargement of the tongue and echocardiographic features of left ventricular dilated cardiomyopathy.