Rapid and Efficient Clathrin-mediated Endocytosis Revealed in Genome-edited Mammalian Cells

Overview

Journal Nat Cell Biol

Specialty Cell Biology

Date 2011 Feb 8

PMID 21297641

Citations 141

Authors

Jeffrey B Doyon

Bryan Zeitler

Jackie Cheng

Aaron T Cheng

Jennifer M Cherone

Yolanda Santiago

Andrew H Lee

Thuy D Vo

Yannick Doyon

Jeffrey C Miller

David E Paschon

Lei Zhang

Edward J Rebar

Philip D Gregory

Fyodor D Urnov

David G Drubin

Affiliations

Soon will be listed here.

Abstract

Clathrin-mediated endocytosis (CME) is the best-studied pathway by which cells selectively internalize molecules from the plasma membrane and surrounding environment. Previous live-cell imaging studies using ectopically overexpressed fluorescent fusions of endocytic proteins indicated that mammalian CME is a highly dynamic but inefficient and heterogeneous process. In contrast, studies of endocytosis in budding yeast using fluorescent protein fusions expressed at physiological levels from native genomic loci have revealed a process that is very regular and efficient. To analyse endocytic dynamics in mammalian cells in which endogenous protein stoichiometry is preserved, we targeted zinc finger nucleases (ZFNs) to the clathrin light chain A and dynamin-2 genomic loci and generated cell lines expressing fluorescent protein fusions from each locus. The genome-edited cells exhibited enhanced endocytic function, dynamics and efficiency when compared with previously studied cells, indicating that CME is highly sensitive to the levels of its protein components. Our study establishes that ZFN-mediated genome editing is a robust tool for expressing protein fusions at endogenous levels to faithfully report subcellular localization and dynamics.

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