Abstract
Ezrin, a member of the ERM (Ezrin/Radixin/Moesin) protein family, is an Actin-plasma membrane linker protein mediating cellular integrity and function. In-vivo study of such interactions is a complex task due to the presence of a large number of endogenous binding partners for both Ezrin and Actin. Further, C-terminal actin binding capacity of the full length Ezrin is naturally shielded by its N-terminal, and only rendered active in the presence of Phosphatidylinositol bisphosphate (PIP2) or phosphorylation at the C-terminal threonine. Here, we demonstrate a strategy for the design, expression and purification of constructs, combining the Ezrin C-terminal actin binding domain, with functional elements such as fusion tags and fluorescence tags to facilitate purification and fluorescence microscopy based studies. For the first time, internal His tag was employed for purification of Ezrin actin binding domain based on in-silico modeling. The functionality (Ezrin-actin interaction) of these constructs was successfully demonstrated by using Total Internal Reflection Fluorescence Microscopy. This design can be extended to other members of the ERM family as well.
Highlights
Cytoskeleton proteins are involved in several cellular processes such as maintaining cell shape, motility or cell division and provide structural support to the plasma membrane [1, 2]
The FERM domain binds to the plasma membrane and the C-terminal F-actin binding domain interacts with actin to form ternary complexes, which are involved in signal transduction
Bright and dark ezrinABD were cloned in both pGEX-4T-1 and pMAL-c5X to check the influence of GST and maltose binding protein (MBP) fusion tags on solubility and to improve expression
Summary
Cytoskeleton proteins are involved in several cellular processes such as maintaining cell shape, motility or cell division and provide structural support to the plasma membrane [1, 2]. Actin, one such cytoskeleton protein, is highly conserved and abundantly available in eukaryotic cells [3]. The FERM domain binds to the plasma membrane and the C-terminal F-actin binding domain interacts with actin to form ternary complexes, which are involved in signal transduction.
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