Mouse fukutin deletion impairs dystroglycan processing and recapitulates muscular dystrophy
Aaron M. Beedle, Amy J. Turner, Yoshiaki Saito, John D. Lueck, Steven J. Foltz, Marisa J. Fortunato, Patricia M. Nienaber, Kevin P. Campbell
Aaron M. Beedle, Amy J. Turner, Yoshiaki Saito, John D. Lueck, Steven J. Foltz, Marisa J. Fortunato, Patricia M. Nienaber, Kevin P. Campbell
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Research Article

Mouse fukutin deletion impairs dystroglycan processing and recapitulates muscular dystrophy

Abstract

Dystroglycan is a transmembrane glycoprotein that links the extracellular basement membrane to cytoplasmic dystrophin. Disruption of the extensive carbohydrate structure normally present on α-dystroglycan causes an array of congenital and limb girdle muscular dystrophies known as dystroglycanopathies. The essential role of dystroglycan in development has hampered elucidation of the mechanisms underlying dystroglycanopathies. Here, we developed a dystroglycanopathy mouse model using inducible or muscle-specific promoters to conditionally disrupt fukutin (Fktn), a gene required for dystroglycan processing. In conditional Fktn-KO mice, we observed a near absence of functionally glycosylated dystroglycan within 18 days of gene deletion. Twenty-week-old KO mice showed clear dystrophic histopathology and a defect in glycosylation near the dystroglycan O-mannose phosphate, whether onset of Fktn excision driven by muscle-specific promoters occurred at E8 or E17. However, the earlier gene deletion resulted in more severe phenotypes, with a faster onset of damage and weakness, reduced weight and viability, and regenerating fibers of smaller size. The dependence of phenotype severity on the developmental timing of muscle Fktn deletion supports a role for dystroglycan in muscle development or differentiation. Moreover, given that this conditional Fktn-KO mouse allows the generation of tissue- and timing-specific defects in dystroglycan glycosylation, avoids embryonic lethality, and produces a phenotype resembling patient pathology, it is a promising new model for the study of secondary dystroglycanopathy.

Authors

Aaron M. Beedle, Amy J. Turner, Yoshiaki Saito, John D. Lueck, Steven J. Foltz, Marisa J. Fortunato, Patricia M. Nienaber, Kevin P. Campbell

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Figure 2

Biochemical analyses of dystroglycan in skeletal muscle from Fktn-KO mice and littermates.

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Biochemical analyses of dystroglycan in skeletal muscle from Fktn-KO mic...
(A) Western blot analyses of WGA-purified skeletal muscle from myf5-Cre/Fktn (E8) KO mice and littermates (LC, Het). All KOs have reduced αDG mass, as measured by detection of core protein (αDG core). This corresponds to a complete loss of αDG binding activity in laminin overlay (Lam O/L) and loss or reduction of αDG glyco-epitopes (αDG glyco). βDG protein is detected in all cases. (B) Western blot analyses of MCK-Cre/Fktn (E17) KO and littermates, as in A. (C) Detection of αDG free phosphate. WGA-enriched skeletal muscle was applied to PHOS-beads to capture proteins with exposed phosphates. αDG from control mice has no free phosphate, but E8 and E17 muscle KOs (myf5-Cre/Fktn KO, MCK-Cre/Fktn KO) contain a substantial proportion with exposed phosphate. βDG is normally phosphorylated and serves as an experimental control.