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- Title
Molecular mechanics underlying flat-to-round membrane budding in live secretory cells.
- Authors
Shin, Wonchul; Zucker, Ben; Kundu, Nidhi; Lee, Sung Hoon; Shi, Bo; Chan, Chung Yu; Guo, Xiaoli; Harrison, Jonathan T.; Turechek, Jaymie Moore; Hinshaw, Jenny E.; Kozlov, Michael M.; Wu, Ling-Gang
- Abstract
Membrane budding entails forces to transform flat membrane into vesicles essential for cell survival. Accumulated studies have identified coat-proteins (e.g., clathrin) as potential budding factors. However, forces mediating many non-coated membrane buddings remain unclear. By visualizing proteins in mediating endocytic budding in live neuroendocrine cells, performing in vitro protein reconstitution and physical modeling, we discovered how non-coated-membrane budding is mediated: actin filaments and dynamin generate a pulling force transforming flat membrane into Λ-shape; subsequently, dynamin helices surround and constrict Λ-profile's base, transforming Λ- to Ω-profile, and then constrict Ω-profile's pore, converting Ω-profiles to vesicles. These mechanisms control budding speed, vesicle size and number, generating diverse endocytic modes differing in these parameters. Their impact is widespread beyond secretory cells, as the unexpectedly powerful functions of dynamin and actin, previously thought to mediate fission and overcome tension, respectively, may contribute to many dynamin/actin-dependent non-coated-membrane buddings, coated-membrane buddings, and other membrane remodeling processes. Shin et al. report the molecular mechanics of membrane budding: actin and dynamin pull membrane inward to form a Λ-shape profile; dynamin helices convert Λ- to Ω-shape by constricting Λ's base, and then constrict Ω-profile's pore to form a vesicle.
- Subjects
COATED vesicles; NEUROENDOCRINE cells; BUDS; CELL survival; CLATHRIN; ACTIN
- Publication
Nature Communications, 2022, Vol 13, Issue 1, p1
- ISSN
2041-1723
- Publication type
Article
- DOI
10.1038/s41467-022-31286-4