Abstract
Networks of protein-protein interactions play key roles in numerous important biological processes in living subjects. An effective methodology to assess protein-protein interactions in living cells of interest is protein-fragment complement assay (PCA). Particularly the assays using fluorescent proteins are powerful techniques, but they do not directly track interactions because of its irreversibility or the time for chromophore formation. By contrast, PCAs using bioluminescent proteins can overcome these drawbacks. We herein describe an imaging method for real-time analysis of protein-protein interactions using multicolor luciferases with different spectral characteristics. The sensitivity and signal-to-background ratio were improved considerably by developing a carboxy-terminal fragment engineered from a click beetle luciferase. We demonstrate its utility in spatiotemporal characterization of Smad1–Smad4 and Smad2–Smad4 interactions in early developing stages of a single living Xenopus laevis embryo. We also describe the value of this method by application of specific protein-protein interactions in cell cultures and living mice. This technique supports quantitative analyses and imaging of versatile protein-protein interactions with a selective luminescence wavelength in opaque or strongly auto-fluorescent living subjects.
Highlights
Systematic analysis of interacting proteins is performed extensively using the yeast two-hybrid method [1], spatial and temporal information of each protein-protein interaction is crucial for understanding living cells
bimolecular fluorescence complementation (BiFC) is used for dual interaction of proteins using different spectral characteristics and it enables for quantitative analysis of dual protein interactions at a single cell level [5,6,7]
The spectral characteristics of luciferase are determined by subtle structural differences of only an amino acid residue in the hydrophobic pocket, whereas the C-terminal domain is used for accelerating the enzymatic reaction [18]
Summary
Systematic analysis of interacting proteins is performed extensively using the yeast two-hybrid method [1], spatial and temporal information of each protein-protein interaction is crucial for understanding living cells. We show potential applications of the luciferase fragments for real-time and dual imaging of kinase-induced interactions of Smad1–Smad4 and Smad2–Smad4 in different stages of a single live Xenopus laevis embryo. All these data demonstrate that McLuc1 is used for a new complementation partner of all N-terminal luciferases tested here and that each pair of luciferase fragments enables multi-color quantitative analysis of protein-protein interactions in living cells.
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