Sarcospan protects against LGMD R5 via remodeling of the sarcoglycan complex composition in dystrophic mice
Ekaterina I. Mokhonova, Daniel Helzer, Ravinder Malik, Hafsa Mamsa, Jackson Walker, Mark Maslanka, Tess S. Fleser, Mohammad H. Afsharinia, Shiheng Liu, Johan Holmberg, Z. Hong Zhou, Eric J. Deeds, Kirk C. Hansen, Elizabeth M. McNally, Rachelle H. Crosbie
Ekaterina I. Mokhonova, Daniel Helzer, Ravinder Malik, Hafsa Mamsa, Jackson Walker, Mark Maslanka, Tess S. Fleser, Mohammad H. Afsharinia, Shiheng Liu, Johan Holmberg, Z. Hong Zhou, Eric J. Deeds, Kirk C. Hansen, Elizabeth M. McNally, Rachelle H. Crosbie
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Research Article Cell biology Muscle biology

Sarcospan protects against LGMD R5 via remodeling of the sarcoglycan complex composition in dystrophic mice

Abstract

The dystrophin-glycoprotein complex (DGC) is composed of peripheral and integral membrane proteins at the muscle cell membrane that link the extracellular matrix with the intracellular cytoskeleton. While it is well established that genetic mutations that disrupt the structural integrity of the DGC result in numerous muscular dystrophies, the 3D structure of the complex has remained elusive. Two recent elegant cryoEM structures of the DGC illuminate its molecular architecture and reveal the unique structural placement of sarcospan (SSPN) within the complex. SSPN, a 25 kDa tetraspanin-like protein, anchors β-dystroglycan to the β-, γ- and δ-sarcoglycan trimer, supporting the conclusions of biochemical studies that SSPN is a core element for DGC assembly and stabilization. Here, we advance these studies by revealing that SSPN provides scaffolding in δ-sarcoglycanopathies, enabling substitution of δ-sarcoglycan by its homolog, ζ-sarcoglycan, leading to the structural integrity of the DGC and prevention of limb-girdle muscular dystrophy R5. Three-dimensional modeling reveals that ζ-sarcoglycan preserves protein-protein interactions with the sarcospan, sarcoglycans, dystroglycan, and dystrophin. The structural integrity of the complex maintains myofiber attachment to the extracellular matrix and protects the cell membrane from contraction-induced damage. These findings demonstrate that sarcospan prevents limb-girdle muscular dystrophy R5 by remodeling of the sarcoglycan complex composition.

Authors

Ekaterina I. Mokhonova, Daniel Helzer, Ravinder Malik, Hafsa Mamsa, Jackson Walker, Mark Maslanka, Tess S. Fleser, Mohammad H. Afsharinia, Shiheng Liu, Johan Holmberg, Z. Hong Zhou, Eric J. Deeds, Kirk C. Hansen, Elizabeth M. McNally, Rachelle H. Crosbie

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Figure 12

Coevolutionary analysis of protein pairs in the SG-SSPN complex and control proteins.

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Coevolutionary analysis of protein pairs in the SG-SSPN complex and cont...
Coevolution of residues from SSPN, α-SG, β-SG, δ-SG, γ-SG, ε-SG, ζ-SG, dystroglycan, and 2 control proteins GAPDH and ATP1A1 was analyzed. (A) Workflow schematic of the mutual information-based coevolutionary analysis. (B) Dot plot integrating mutual information scores and coevolution significance for each protein pair. Dot size represents the proportion of significantly coevolving residue pairs (q-value < 0.05) and color (yellow to red) indicates the fraction of residue pairs with nonzero mutual information scores. The more intense yellow color between SSPN and γ-SG indicates a higher fraction of nonzero mutual information scores for this protein pair. This analysis revealed a strong coevolutionary relationship between SSPN and γ-SG.