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Single-molecule microscopy reveals membrane microdomain organization of cells in a living vertebrate.


ABSTRACT: It has been possible for several years to study the dynamics of fluorescently labeled proteins by single-molecule microscopy, but until now this technology has been applied only to individual cells in culture. In this study, it was extended to stem cells and living vertebrate organisms. As a molecule of interest we used yellow fluorescent protein fused to the human H-Ras membrane anchor, which has been shown to serve as a model for proteins anchored in the plasma membrane. We used a wide-field fluorescence microscopy setup to visualize individual molecules in a zebrafish cell line (ZF4) and in primary embryonic stem cells. A total-internal-reflection microscopy setup was used for imaging in living organisms, in particular in epidermal cells in the skin of 2-day-old zebrafish embryos. Our results demonstrate the occurrence of membrane microdomains in which the diffusion of membrane proteins in a living organism is confined. This membrane organization differed significantly from that observed in cultured cells, illustrating the relevance of performing single-molecule microscopy in living organisms.

SUBMITTER: Schaaf MJ 

PROVIDER: S-EPMC2726327 | biostudies-literature | 2009 Aug

REPOSITORIES: biostudies-literature

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Single-molecule microscopy reveals membrane microdomain organization of cells in a living vertebrate.

Schaaf Marcel J M MJ   Koopmans Wiepke J A WJ   Meckel Tobias T   van Noort John J   Snaar-Jagalska B Ewa BE   Schmidt Thomas S TS   Spaink Herman P HP  

Biophysical journal 20090801 4


It has been possible for several years to study the dynamics of fluorescently labeled proteins by single-molecule microscopy, but until now this technology has been applied only to individual cells in culture. In this study, it was extended to stem cells and living vertebrate organisms. As a molecule of interest we used yellow fluorescent protein fused to the human H-Ras membrane anchor, which has been shown to serve as a model for proteins anchored in the plasma membrane. We used a wide-field f  ...[more]

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