Abstract
Bimolecular fluorescence complementation (BiFC) has been widely used to visualize protein-protein interactions (PPIs) in cells. Until now, however, the resolution of BiFC has been limited by the diffraction of light to ∼250 nm, much larger than the nanometer scale at which PPIs occur or are regulated. Cellular imaging at the nanometer scale has recently been realized with single molecule superresolution imaging techniques such as photoactivated localization microscopy (PALM). Here we have combined BiFC with PALM to visualize PPIs inside cells with nanometer spatial resolution and single molecule sensitivity. We demonstrated that PAmCherry1, a photoactivatable fluorescent protein commonly used for PALM, can be used as a BiFC probe when split between residues 159 and 160 into two fragments. PAmCherry1 BiFC exhibits high specificity and high efficiency even at 37°C in detecting PPIs with virtually no background from spontaneous reconstitution. Moreover, the reconstituted protein maintains the fast photoconversion, high contrast ratio, and single molecule brightness of the parent PAmCherry1, which enables selective PALM localization of PPIs with ∼18 nm spatial precision. With BiFC-PALM, we studied the interactions between the small GTPase Ras and its downstream effector Raf, and clearly observed nanoscale clustering and diffusion of individual KRas G12D/CRaf RBD (Ras-binding domain) complexes on the cell membrane. These observations provided novel insights into the regulation of Ras/Raf interaction at the molecular scale, which would be difficult with other techniques such as conventional BiFC, fluorescence co-localization or FRET.
Highlights
Protein-protein interactions (PPIs) play a central role in biology[1], yet fundamental information such as their subcellular location is lacking for many of them
In the crystal structure of PAmCherry1[20], this site is located in the loop between betasheets 7 and 8 (Fig.1A), a position successfully used for bimolecular fluorescence complementation (BiFC) of many fluorescent proteins (FPs)[4]
Several techniques, including BiFC[2,3,4], fluorescence resonance energy transfer (FRET)[30], and fluorescence co-localization have been commonly used for visualizing molecular interactions, including PPIs, in whole cells
Summary
Protein-protein interactions (PPIs) play a central role in biology[1], yet fundamental information such as their subcellular location is lacking for many of them. When the two candidate proteins interact, the fragments are brought into proximity to reconstitute a complete fluorescent protein. This allows detection of PPIs with high sensitivity and subcellular resolution. A fundamental limitation of conventional BiFC and light microscopy, is that the best spatial resolution is ,250 nm due to the diffraction of light. This resolution is insufficient considering the scale at which PPIs occur, i.e., a few nanometers. A clear understanding of PPIs and their roles in cellular processes requires that PPIs be visualized with nanometer resolution
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