Orientation of the Dysferlin C2A Domain is Responsive to the Composition of Lipid Membranes

Dysferlin is a 230 kD protein that plays a critical function in the active resealing of micron-sized injuries to the muscle sarcolemma by recruiting vesicles to patch the injured site via vesicle fusion. Muscular dystrophy is observed in humans when mutations disrupt this repair process or dysferlin...

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Published in:The journal of physical chemistry. B 2023-01, Vol.127 (2), p.577-589
Main Authors: Carpenter, Andrew P., Khuu, Patricia, Weidner, Tobias, Johnson, Colin P., Roeters, Steven J., Baio, Joe E.
Format: Article
Language:English
Subjects:
B: Soft Matter, Fluid Interfaces, Colloids, Polymers, and Glassy Materials
Cell Membrane - chemistry
Dysferlin - chemistry
Dysferlin - metabolism
Humans
Lipids - chemistry
Membrane Proteins - chemistry
Membrane Proteins - metabolism
Muscle Proteins - chemistry
Muscle Proteins - metabolism
Protein Binding
Sarcolemma - chemistry
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Summary:Dysferlin is a 230 kD protein that plays a critical function in the active resealing of micron-sized injuries to the muscle sarcolemma by recruiting vesicles to patch the injured site via vesicle fusion. Muscular dystrophy is observed in humans when mutations disrupt this repair process or dysferlin is absent. While lipid binding by dysferlin’s C2A domain (dysC2A) is considered fundamental to the membrane resealing process, the molecular mechanism of this interaction is not fully understood. By applying nonlinear surface-specific vibrational spectroscopy, we have successfully demonstrated that dysferlin’s N-terminal C2A domain (dysC2A) alters its binding orientation in response to a membrane’s lipid composition. These experiments reveal that dysC2A utilizes a generic electrostatic binding interaction to bind to most anionic lipid surfaces, inserting its calcium binding loops into the lipid surface while orienting its β-sheets 30–40° from surface normal. However, at lipid surfaces, where PI­(4,5)­P2 is present, dysC2A tilts its β-sheets more than 60° from surface normal to expose a polybasic face, while it binds to the PI­(4,5)­P2 surface. Both lipid binding mechanisms are shown to occur alongside dysC2A-induced lipid clustering. These different binding mechanisms suggest that dysC2A could provide a molecular cue to the larger dysferlin protein as to signal whether it is bound to the sarcolemma or another lipid surface.
ISSN:1520-6106
1520-5207
DOI:10.1021/acs.jpcb.2c06716