A nanobody-gold conjugate for the detection of GFP-tagged synaptic proteins by dual light-electron microscopy

To meet the constantly improving spatial resolution offered by advanced microscopy techniques to study sub-cellular structures in biology, there is a need for small, monovalent probes that label proteins of interest with high specificity and minimal distance to the target, and are compatible with various imaging modalities. In this direction, we designed a strategy to generate minimal-size probes composed of a controlled 1:1 conjugate between a small domain binder and a 1.4 nm-gold nanoparticle with direct access to fluorescent labelling for dual light-electron microscopy. Our approach was applied to the widely used single-domain antibody against GFP (GBP). The modified GBP-gold conjugate retained normal binding to purified GFP in vitro, specifically labelled COS-7 cells and neurons expressing GFP-tagged synaptic membrane proteins, and penetrated readily into tight cell-cell contacts including neuronal synapses. The optional fluorescence labelling with a second ALFA nanobody allowed dSTORM imaging, while the silver-enhanced nanogold particle detected in TEM was used to characterize the number and nanoscale organization of individual proteins in the synaptic cleft. We counted a small number of endogenous neurexins in the pre-synapse and a larger number of AMPA receptors in the post-synapse, often aligned in nanodomains. This GBP-gold probe thus emerges as a potent tool to label an ever-increasing repertoire of GFP-tagged proteins in numerous biological organisms and models.