Cysteine post‐translational modifications regulate protein interactions of caveolin‐3

Caveolae are small flask‐shaped invaginations of the surface membrane which are proposed to recruit and co‐localize signaling molecules. The distinctive caveolar shape is achieved by the oligomeric structural protein caveolin, of which three isoforms exist. Aside from the finding that caveolin‐3 is...

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Bibliographic Details
Published in:The FASEB journal 2024-03, Vol.38 (5), p.e23535-n/a
Main Authors: Ashford, Fiona, Kuo, Chien‐Wen, Dunning, Emma, Brown, Elaine, Calagan, Sarah, Jayasinghe, Izzy, Henderson, Colin, Fuller, William, Wypijewski, Krzysztof
Format: Article
Language:English
Subjects:
acylation
caveolae
glutathiolation
microdomains
palmitoylation
redox
S‐acylation
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Summary:Caveolae are small flask‐shaped invaginations of the surface membrane which are proposed to recruit and co‐localize signaling molecules. The distinctive caveolar shape is achieved by the oligomeric structural protein caveolin, of which three isoforms exist. Aside from the finding that caveolin‐3 is specifically expressed in muscle, functional differences between the caveolin isoforms have not been rigorously investigated. Caveolin‐3 is relatively cysteine‐rich compared to caveolins 1 and 2, so we investigated its cysteine post‐translational modifications. We find that caveolin‐3 is palmitoylated at 6 cysteines and becomes glutathiolated following redox stress. We map the caveolin‐3 palmitoylation sites to a cluster of cysteines in its C terminal membrane domain, and the glutathiolation site to an N terminal cysteine close to the region of caveolin‐3 proposed to engage in protein interactions. Glutathiolation abolishes caveolin‐3 interaction with heterotrimeric G protein alpha subunits. Our results indicate that a caveolin‐3 oligomer contains up to 66 palmitates, compared to up to 33 for caveolin‐1. The additional palmitoylation sites in caveolin‐3 therefore provide a mechanistic basis by which caveolae in smooth and striated muscle can possess unique phospholipid and protein cargoes. These unique adaptations of the muscle‐specific caveolin isoform have important implications for caveolar assembly and signaling. Caveolins are the structural proteins of caveolae. Caveolin‐1 is ubiquitously expressed, and caveolin‐3 is muscle‐specific. We report that a caveolin‐3 protomer is palmitoylated on 6 cysteines per monomer: twice as many sites as for caveolin‐1. Redox stress‐induced glutathiolation near the caveolin‐3 amino terminus abolishes its interaction with heterotrimeric G proteins. We provide a mechanistic basis by which caveolae in muscle can possess unique phospholipid and protein cargoes, driven by the differential post‐translational modifications of caveolin‐3 cysteines.
ISSN:0892-6638
1530-6860
DOI:10.1096/fj.202201497RR