Abstract
Desmin-associated myofibrillar myopathy (MFM) has pathologic similarities to neurodegeneration-associated protein aggregate diseases. Desmin is an abundant muscle-specific intermediate filament, and disease mutations lead to its aggregation in cells, animals, and patients. We reasoned that similar to neurodegeneration-associated proteins, desmin itself may form amyloid. Desmin peptides corresponding to putative amyloidogenic regions formed seeding-competent amyloid fibrils. Amyloid formation was increased when disease-associated mutations were made within the peptide, and this conversion was inhibited by the anti-amyloid compound epigallocatechin-gallate. Moreover, a purified desmin fragment (aa 117 to 348) containing both amyloidogenic regions formed amyloid fibrils under physiologic conditions. Desmin fragment-derived amyloid coaggregated with full-length desmin and was able to template its conversion into fibrils in vitro. Desmin amyloids were cytotoxic to myotubes and disrupted their myofibril organization compared with desmin monomer or other nondesmin amyloids. Finally, desmin fragment amyloid persisted when introduced into mouse skeletal muscle. These data suggest that desmin forms seeding-competent amyloid that is toxic to myofibers. Moreover, small molecules known to interfere with amyloid formation and propagation may have therapeutic potential in MFM.
Highlights
Injury due to physical trauma is mediated by alteration in biomolecular structure and intra- and inter-molecular bonding
We further investigated the role of key interactions, salt bridges (K11-E34, K27-D52 in ubiquitin) in the folding pathway of a protein
Conversion to final protein mimics (PMs) structure was confirmed by size exclusion chromatography (SEC) and 1HNMR analysis in CDCl3
Summary
Injury due to physical trauma is mediated by alteration in biomolecular structure and intra- and inter-molecular bonding. We further investigated the role of key interactions, salt bridges (K11-E34, K27-D52 in ubiquitin) in the folding pathway of a protein. The salt-bridge null variants with hydrophobic residue mutations are thermodynamically slightly more stable and tend to fold faster, via a more stabilised intermediate, compared to the wild-type. 969-Pos Is Dodine a Protein Stabilizer or Destabilizer?
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