IL-6–HaloTag® enables live-cell plasma membrane staining, flow cytometry, functional expression, and deorphaning of recombinant odorant receptors
The assignment of cognate odorant/agonist pairs is a prerequisite for an understanding of odorant coding at the receptor level. However, the identification of new ligands for odorant receptors in cell-based assays has been challenging, due to their individual and rather sub-optimal plasma membrane expression, as compared with other G protein-coupled receptors. Accessory proteins, such as the chaperone RTP1S, or Ric8b, have improved the surface expression of at least a portion of odorant receptors. Typically, recombinant odorant receptors carry N-terminal tags, which proved helpful for their functional membrane expression. The most common tag is the ‘Rho-tag’, representing an N-terminal part of rhodopsin, but also ‘Lucy-‘ or ‘Flag-tag’ extensions have been described. Here, we used a bi-functional N-terminal tag, called ‘IL-6-HaloTag®’, with IL-6 facilitating functional cell surface expression of recombinant odorant receptors, and the HaloTag® protein, serving as a highly specific acceptor for cell-impermeant or cell-permeant, fluorophore-coupled ligands, which enable the quantification of odorant receptor expression by live-cell flow cytometry. Our experiments revealed on average an about four-fold increased surface expression, a four-fold higher signaling amplitude, and a significant higher potency of odorant-induced cAMP signaling of six different human IL-6-HaloTag®-odorant receptors across five different receptor families in NxG 108CC15 cells, as compared to their Rho-tag–HaloTag® constructs. We observed similar results in HEK-293 cells. Moreover, screening an IL-6–HaloTag®-odorant receptor library with allyl phenyl acetate, revealed both known receptors as best responders for this compound. In summary, the IL-6–HaloTag® represents a promising tool for the de-orphaning of odorant receptors.
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