Abstract
Ferlins are an ancient family of C2 domain-containing proteins, with emerging roles in vesicular trafficking and human disease. Dysferlin mutations cause inherited muscular dystrophy, and dysferlin also shows abnormal plasma membrane expression in other forms of muscular dystrophy. We establish dysferlin as a short-lived (protein half-life approximately 4-6 h) and transitory transmembrane protein (plasma membrane half-life approximately 3 h), with a propensity for rapid endocytosis when mutated, and an association with a syntaxin-4 endocytic route. Dysferlin plasma membrane expression and endocytic rate is regulated by the C2B-FerI-C2C motif, with a critical role identified for C2C. Disruption of C2C dramatically reduces plasma membrane dysferlin (by 2.5-fold), due largely to accelerated endocytosis (by 2.5-fold). These properties of reduced efficiency of plasma membrane expression due to accelerated endocytosis are also a feature of patient missense mutant L344P (within FerI, adjacent to C2C). Importantly, dysferlin mutants that demonstrate accelerated endocytosis also display increased protein lability via endosomal proteolysis, implicating endosomal-mediated proteolytic degradation as a novel basis for dysferlin-deficiency in patients with single missense mutations. Vesicular labeling studies establish that dysferlin mutants rapidly transit from EEA1-positive early endosomes through to dextran-positive lysosomes, co-labeled by syntaxin-4 at multiple stages of endosomal transit. In summary, our studies define a transient biology for dysferlin, relevant to emerging patient therapeutics targeting dysferlin replacement. We introduce accelerated endosomal-directed degradation as a basis for lability of dysferlin missense mutants in dysferlinopathy, and show that dysferlin and syntaxin-4 similarly transit a common endosomal pathway in skeletal muscle cells.
Highlights
Dysferlin belongs to the ferlin family of proteins, an ancient family with emerging roles in cellular trafficking and vesicle fusion
Given the recent study associating otoferlin with syntaxin-1 [25], we explored the relationship between dysferlin and syntaxin-4, which localizes to the plasma membrane and is highly expressed in skeletal muscle [26]
Dysferlin is a tail-anchored protein, with multiple tandem C2 domains that are likely to underlie its role in calcium-dependent and vesicle-mediated membrane resealing
Summary
Patients and Ethics—We identified the L344P mutation in two sisters referred to our Neuromuscular Clinic and laboratory. ⌬C2C*B (Dysferlin ⌬Met303-Ala497) was derived through ligation of the dysferlin 5Ј-fragment EcoRI/BspEI (Klenow fill-in to blunt), into the plasmid backbone pcDNA4-EGFPdysferlinMycHis restricted with EcoRI/Sbf I (T4 blunt), resulting in deletion of the cDNA sequence between BspEI and Sbf I. C2F-TM contains the C-terminal dysferlin fragment from Iso1738 and was derived through ligation of a BamHI (Klenow blunted)/NotI fragment of pcDNA4-EGFPdysferlinMycHis religated into EcoRI (Klenow blunted)/NotI-digested vector backbone. Cells were incubated in medium containing cholera toxinAlexa488 (1:100) and anti-MycAlexa555 (1:100) for 2 h at 37 °C, acid washed, fixed, and mounted as above. For LDL uptake, transfected differentiated C2C12 myotubes were serum starved overnight, incubated in LDLdil (33 g/ml) for 30 min at 37 °C, acid washed, fixed, and mounted as above.
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