Nanocones to study initial steps of Endocytosis

Sangmoo Jeong; Milos Galic

doi:10.1007/978-1-4939-0944-5_19

Nanocones to study initial steps of Endocytosis

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

Abstract

Vesicle endocytosis at the plasma membrane is associated with a precise temporal choreography in the recruitment of cytosolic proteins that sense, generate, or stabilize locally curved membrane regions. To dissect the role of membrane curvature sensing from other co-occurring events during the initial steps of endocytosis, we developed a method to artifi cially induce nanoscale deformations of the PM in living cells that is based on cone-shaped nanostructures (i.e., Nanocones). When cultured on Nanocones, cells create stable inward plasma membrane deformations to which curvature-sensing proteins are recruited. Here, we provide a detailed protocol how to use Nanocones to study recruitment during the initial steps of endocytosis in cells by fluorescence and electron microscopy.

Original language	English (US)
Pages (from-to)	275-284
Number of pages	10
Journal	Methods in Molecular Biology
Volume	1174
DOIs	https://doi.org/10.1007/978-1-4939-0944-5_19
State	Published - 2014
Externally published	Yes

Keywords

Endocytic vesicles
Endocytosis
Membrane curvature
Nanocones
Plasma membrane

ASJC Scopus subject areas

Molecular Biology
Genetics

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10.1007/978-1-4939-0944-5_19

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abstract = "Vesicle endocytosis at the plasma membrane is associated with a precise temporal choreography in the recruitment of cytosolic proteins that sense, generate, or stabilize locally curved membrane regions. To dissect the role of membrane curvature sensing from other co-occurring events during the initial steps of endocytosis, we developed a method to artifi cially induce nanoscale deformations of the PM in living cells that is based on cone-shaped nanostructures (i.e., Nanocones). When cultured on Nanocones, cells create stable inward plasma membrane deformations to which curvature-sensing proteins are recruited. Here, we provide a detailed protocol how to use Nanocones to study recruitment during the initial steps of endocytosis in cells by fluorescence and electron microscopy.",

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AU - Galic, Milos

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N2 - Vesicle endocytosis at the plasma membrane is associated with a precise temporal choreography in the recruitment of cytosolic proteins that sense, generate, or stabilize locally curved membrane regions. To dissect the role of membrane curvature sensing from other co-occurring events during the initial steps of endocytosis, we developed a method to artifi cially induce nanoscale deformations of the PM in living cells that is based on cone-shaped nanostructures (i.e., Nanocones). When cultured on Nanocones, cells create stable inward plasma membrane deformations to which curvature-sensing proteins are recruited. Here, we provide a detailed protocol how to use Nanocones to study recruitment during the initial steps of endocytosis in cells by fluorescence and electron microscopy.

AB - Vesicle endocytosis at the plasma membrane is associated with a precise temporal choreography in the recruitment of cytosolic proteins that sense, generate, or stabilize locally curved membrane regions. To dissect the role of membrane curvature sensing from other co-occurring events during the initial steps of endocytosis, we developed a method to artifi cially induce nanoscale deformations of the PM in living cells that is based on cone-shaped nanostructures (i.e., Nanocones). When cultured on Nanocones, cells create stable inward plasma membrane deformations to which curvature-sensing proteins are recruited. Here, we provide a detailed protocol how to use Nanocones to study recruitment during the initial steps of endocytosis in cells by fluorescence and electron microscopy.

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Nanocones to study initial steps of Endocytosis

Abstract

Keywords

ASJC Scopus subject areas

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