Membrane insertion mechanism of the caveola coat protein Cavin1

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Significance

Caveolae are cholesterol-enriched membrane invaginations linked to severe muscle and lipid disorders. Their formation is dependent on assembly of the protein Cavin1 at the lipid membrane interface driving membrane curvature. In this work, we dissect the mechanism for how Cavin1 binds and inserts into membranes using a combination of biochemical and biophysical characterization as well as computational modeling. The proposed model for membrane assembly potentiates dynamic switching between shielded and exposed hydrophobic helices used for membrane insertion and clarifies how Cavin1 can drive membrane curvature and the formation of caveolae.

Abstract

Caveolae are small plasma membrane invaginations, important for control of membrane tension, signaling cascades, and lipid sorting. The caveola coat protein Cavin1 is essential for shaping such high curvature membrane structures. Yet, a mechanistic understanding of how Cavin1 assembles at the membrane interface is lacking. Here, we used model membranes combined with biophysical dissection and computational modeling to show that Cavin1 inserts into membranes. We establish that initial phosphatidylinositol ( 4, 5) bisphosphate [PI(4,5)P ₂]–dependent membrane adsorption of the trimeric helical region 1 (HR1) of Cavin1 mediates the subsequent partial separation and membrane insertion of the individual helices. Insertion kinetics of HR1 is further enhanced by the presence of flanking negatively charged disordered regions, which was found important for the coassembly of Cavin1 with Caveolin1 in living cells. We propose that this intricate mechanism potentiates membrane curvature generation and facilitates dynamic rounds of assembly and disassembly of Cavin1 at the membrane.

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Most cited references 38

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Caveolin, a protein component of caveolae membrane coats.

K. Rothberg, J Heuser, W C Donzell … (1992)

Caveolae have been implicated in the transcytosis of macromolecules across endothelial cells and in the receptor-mediated uptake of 5-methyltetrahydrofolate. Structural studies indicate that caveolae are decorated on their cytoplasmic surface by a unique array of filaments or strands that form striated coatings. To understand how these nonclathrin-coated pits function, we performed structural analysis of the striated coat and searched for the molecular component(s) of the coat material. The coat cannot be removed by washing with high salt; however, exposure of membranes to cholesterol-binding drugs caused invaginated caveolae to flatten and the striated coat to disassemble. Antibodies directed against a 22 kd substrate for v-src tyrosine kinase in virus-transformed chick embryo fibroblasts decorated the filaments, suggesting that this molecule is a component of the coat. We have named the molecule caveolin. Caveolae represent a third type of coated membrane specialization that is involved in molecular transport.

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Author and article information

Journal

Journal ID (nlm-ta): Proc Natl Acad Sci U S A

Journal ID (iso-abbrev): Proc Natl Acad Sci U S A

Journal ID (hwp): pnas

Journal ID (publisher-id): pnas

Title: Proceedings of the National Academy of Sciences of the United States of America

Publisher: National Academy of Sciences

ISSN (Print): 0027-8424

ISSN (Electronic): 1091-6490

Publication date (Electronic): 13 June 2022

Publication date (Print): 21 June 2022

Publication date PMC-release: 13 June 2022

Volume: 119

Issue: 25

Electronic Location Identifier: e2202295119

Affiliations

[1] ^aIntegrative Medical Biology, Umeå University , 901 87 Umeå, Sweden;

[2] ^bDepartment of Clinical Microbiology, Umeå University , 901 85 Umeå, Sweden;

[3] ^cWallenberg Centre for Molecular Medicine, Umeå University , 901 85 Umeå, Sweden;

[4] ^dDepartment of Pharmacy, Uppsala Biomedical Center, Uppsala University , 751 23 Uppsala, Sweden;

[5] ^eInstitute of Physical Chemistry, Martin Luther University Halle-Wittenberg , 06120 Halle (Saale), Germany

Author notes

²To whom correspondence may be addressed. Email: madlen.hubert@ 123456farmaci.uu.se or richard.lundmark@ 123456umu.se .

Edited by James Hurley, University of California, Berkeley, CA; received February 8, 2022; accepted May 10, 2022

Author contributions: K.-C.L., H.P., E.L., S.H., A.K., M.H., and R.L. designed research; K.-C.L., H.P., E.L., S.H., A.K., A.S., V.J., J.M., C.S., and M.H. performed research; H.P., S.H., and A.K. contributed new reagents/analytic tools; K.-C.L., H.P., E.L., S.H., A.K., A.S., C.A.S.B., M.B., C.S., M.H., and R.L. analyzed data; and K.-C.L., M.H., and R.L. wrote the paper.

¹Present address: Membrane Biochemistry and Transport, Institute Pasteur, 75015 Paris, France.