Abstract
Many membrane proteins function as dimers or larger oligomers, including transporters, channels, certain signaling receptors, and adhesion molecules. In some cases, the interactions between individual proteins may be weak and/or dependent on specific lipids, such that detergent solubilization used for biochemical and structural studies disrupts functional oligomerization. Solubilized membrane protein oligomers can be captured in lipid nanodiscs, but this is an inefficient process that can produce stoichiometrically and topologically heterogeneous preparations. Here, we describe a technique to obtain purified homogeneous membrane protein dimers in nanodiscs using a split GFP (sGFP) tether. Complementary sGFP tags associate to tether the coexpressed dimers and control both stoichiometry and orientation within the nanodiscs, as assessed by quantitative Western blotting and negative-stain EM. The sGFP tether confers several advantages over other methods: it is highly stable in solution and in SDS-PAGE, which facilitates screening of dimer expression and purification by fluorescence, and also provides a dimer-specific purification handle for use with GFP nanobody–conjugated resin. We used this method to purify a Frizzled-4 homodimer and a Frizzled-4/low-density lipoprotein receptor–related protein 6 heterodimer in nanodiscs. These examples demonstrate the utility and flexibility of this method, which enables subsequent mechanistic molecular and structural studies of membrane protein pairs.
Highlights
Integral membrane proteins play critical roles in cell signaling, molecular transport, and adhesion
We developed a flexible method utilizing the self-assembly of split GFP fragments to generate defined membrane protein dimers
The intact receptor-GFP complex can be detected by flow cytometry, fluorescence size exclusion chromatography (FSEC), and SDS-PAGE in-gel fluorescence for facile construct screening
Summary
Integral membrane proteins play critical roles in cell signaling, molecular transport, and adhesion. These factors limit the use of liposomes for structural and some functional analyses These considerations show that a method to obtain pure membrane protein homo- and hetero-oligomers in a lipid environment is crucial for understanding molecular mechanisms governing receptors, transporters, adhesion proteins, and other membrane proteins that function in complexes. To this end, membrane proteins have been reconstituted into high-density lipoprotein particles (nanodiscs) (9), which offers several advantages compared to liposome reconstitution. Prior studies have suggested that ligand-induced homo- and heterodimerization of these receptors initiates signaling, so we prepared Fzd homodimers as well as Fzd4/LRP6 heterodimers in order to understand the contribution of receptor dimerization to the initial steps of Wnt/β-catenin signal transduction (13)
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