Vesicle formation by self-assembly of membrane-bound matrix proteins into a fluidlike budding domain

Anna V. Shnyrova; Juan Ayllon; Ilya I. Mikhalyov; Enrique Villar; Joshua Zimmerberg; Vadim A. Frolov

doi:10.1083/jcb.200705062

Vesicle formation by self-assembly of membrane-bound matrix proteins into a fluidlike budding domain

Anna V. Shnyrova, Juan Ayllon, Ilya I. Mikhalyov, Enrique Villar, Joshua Zimmerberg, Vadim A. Frolov

Research output: Contribution to journal › Article › peer-review

49 Scopus citations

Abstract

The shape of enveloped viruses depends critically on an internal protein matrix, yet it remains unclear how the matrix proteins control the geometry of the envelope membrane. We found that matrix proteins purified from Newcastle disease virus adsorb on a phospholipid bilayer and condense into fluidlike domains that cause membrane deformation and budding of spherical vesicles, as seen by fluorescent and electron microscopy. Measurements of the electrical admittance of the membrane resolved the gradual growth and rapid closure of a bud followed by its separation to form a free vesicle. The vesicle size distribution, confined by intrinsic curvature of budding domains, but broadened by their merger, matched the virus size distribution. Thus, matrix proteins implement domain-driven mechanism of budding, which suffices to control the shape of these proteolipid vesicles.

Original language	English
Pages (from-to)	627-633
Number of pages	7
Journal	Journal of Cell Biology
Volume	179
Issue number	4
DOIs	https://doi.org/10.1083/jcb.200705062
State	Published - 19 Nov 2007
Externally published	Yes

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title = "Vesicle formation by self-assembly of membrane-bound matrix proteins into a fluidlike budding domain",

abstract = "The shape of enveloped viruses depends critically on an internal protein matrix, yet it remains unclear how the matrix proteins control the geometry of the envelope membrane. We found that matrix proteins purified from Newcastle disease virus adsorb on a phospholipid bilayer and condense into fluidlike domains that cause membrane deformation and budding of spherical vesicles, as seen by fluorescent and electron microscopy. Measurements of the electrical admittance of the membrane resolved the gradual growth and rapid closure of a bud followed by its separation to form a free vesicle. The vesicle size distribution, confined by intrinsic curvature of budding domains, but broadened by their merger, matched the virus size distribution. Thus, matrix proteins implement domain-driven mechanism of budding, which suffices to control the shape of these proteolipid vesicles.",

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AU - Shnyrova, Anna V.

AU - Ayllon, Juan

AU - Mikhalyov, Ilya I.

AU - Villar, Enrique

AU - Zimmerberg, Joshua

AU - Frolov, Vadim A.

PY - 2007/11/19

Y1 - 2007/11/19

N2 - The shape of enveloped viruses depends critically on an internal protein matrix, yet it remains unclear how the matrix proteins control the geometry of the envelope membrane. We found that matrix proteins purified from Newcastle disease virus adsorb on a phospholipid bilayer and condense into fluidlike domains that cause membrane deformation and budding of spherical vesicles, as seen by fluorescent and electron microscopy. Measurements of the electrical admittance of the membrane resolved the gradual growth and rapid closure of a bud followed by its separation to form a free vesicle. The vesicle size distribution, confined by intrinsic curvature of budding domains, but broadened by their merger, matched the virus size distribution. Thus, matrix proteins implement domain-driven mechanism of budding, which suffices to control the shape of these proteolipid vesicles.

AB - The shape of enveloped viruses depends critically on an internal protein matrix, yet it remains unclear how the matrix proteins control the geometry of the envelope membrane. We found that matrix proteins purified from Newcastle disease virus adsorb on a phospholipid bilayer and condense into fluidlike domains that cause membrane deformation and budding of spherical vesicles, as seen by fluorescent and electron microscopy. Measurements of the electrical admittance of the membrane resolved the gradual growth and rapid closure of a bud followed by its separation to form a free vesicle. The vesicle size distribution, confined by intrinsic curvature of budding domains, but broadened by their merger, matched the virus size distribution. Thus, matrix proteins implement domain-driven mechanism of budding, which suffices to control the shape of these proteolipid vesicles.

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Vesicle formation by self-assembly of membrane-bound matrix proteins into a fluidlike budding domain

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