A limb-girdle muscular dystrophy 2I model of muscular dystrophy identifies corrective drug compounds for dystroglycanopathies
Peter R. Serafini, Michael J. Feyder, Rylie M. Hightower, Daniela Garcia-Perez, Natássia M. Vieira, Angela Lek, Devin E. Gibbs, Omar Moukha-Chafiq, Corinne E. Augelli-Szafran, Genri Kawahara, Jeffrey J. Widrick, Louis M. Kunkel, Matthew S. Alexander
Peter R. Serafini, Michael J. Feyder, Rylie M. Hightower, Daniela Garcia-Perez, Natássia M. Vieira, Angela Lek, Devin E. Gibbs, Omar Moukha-Chafiq, Corinne E. Augelli-Szafran, Genri Kawahara, Jeffrey J. Widrick, Louis M. Kunkel, Matthew S. Alexander
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Research Article Muscle biology

A limb-girdle muscular dystrophy 2I model of muscular dystrophy identifies corrective drug compounds for dystroglycanopathies

Abstract

Zebrafish are a powerful tool for studying muscle function owing to their high numbers of offspring, low maintenance costs, evolutionarily conserved muscle functions, and the ability to rapidly take up small molecular compounds during early larval stages. Fukutin-related protein (FKRP) is a putative protein glycosyltransferase that functions in the Golgi apparatus to modify sugar chain molecules of newly translated proteins. Patients with mutations in the FKRP gene can have a wide spectrum of clinical symptoms with varying muscle, eye, and brain pathologies depending on the location of the mutation in the FKRP protein. Patients with a common L276I FKRP mutation have mild adult-onset muscle degeneration known as limb-girdle muscular dystrophy 2I (LGMD2I), whereas patients with more C-terminal pathogenic mutations develop the severe Walker-Warburg syndrome (WWS)/muscle-eye-brain (MEB) disease. We generated fkrp-mutant zebrafish that phenocopy WWS/MEB pathologies including severe muscle breakdowns, head malformations, and early lethality. We have also generated a milder LGMD2I-model zebrafish via overexpression of a heat shock–inducible human FKRP (L276I) transgene that shows milder muscle pathology. Screening of an FDA-approved drug compound library in the LGMD2I zebrafish revealed a strong propensity towards steroids, antibacterials, and calcium regulators in ameliorating FKRP-dependent pathologies. Together, these studies demonstrate the utility of the zebrafish to both study human-specific FKRP mutations and perform compound library screenings for corrective drug compounds to treat muscular dystrophies.

Authors

Peter R. Serafini, Michael J. Feyder, Rylie M. Hightower, Daniela Garcia-Perez, Natássia M. Vieira, Angela Lek, Devin E. Gibbs, Omar Moukha-Chafiq, Corinne E. Augelli-Szafran, Genri Kawahara, Jeffrey J. Widrick, Louis M. Kunkel, Matthew S. Alexander

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Figure 1

Generation of FKRP-mutant zebrafish using TALENs.

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Generation of FKRP-mutant zebrafish using TALENs. (A) Schematic showing ...
(A) Schematic showing TALEN-mediated genomic targeting of the zebrafish fkrp locus. (B) Diagram of coding and noncoding exons of the zebrafish fkrp transcribed mRNA. Exon 3 is the only coding exon of the zebrafish fkrp gene. (C) Various FKRP-mutant zebrafish lines generated using TALEN-mediated genomic engineering. (D) PCR genotyping of zebrafish tail biopsies showing the 13-bp deletion at exon 3 of the zebrafish fkrp gene locus showing fkrp WT, heterozygous, and homozygous mutant zebrafish. (E) Western blot images of protein lysates of fkrp WT, heterozygous, and homozygous mutant zebrafish at 5 dpf. Immunoblots using antibodies against zebrafish FKRP, glycosylated α-dystroglycan (α-dag1), β-dystroglycan (β-dag1), laminin, and β-actin. (F) Brightfield and birefringence images of sibling (unaffected) and fkrp–/– (Δ13bp; affected) zebrafish at 5 dpf at low (×2) and high magnification (×10). The arrowhead indicates pericardiac edema in the fkrp–/– (Δ13bp) zebrafish. (G) Two additional fkrp-mutant lines, a 3-bp deletion (Δ3bp) deletion and a 5-bp insertion (+5bp), were also generated and showed a similar phenotype to the fkrp–/– Δ13bp homozygous mutants. Scale bars: 300 μm.