A genetically encoded red fluorescence dopamine biosensor enables dual imaging of dopamine and norepinephrine

Dopamine (DA) and norepinephrine (NE) are pivotal neuromodulators that regulate a broad range of brain functions, often in concert. Despite their physiological importance, untangling the relationship between DA and NE in finely controlling output functions is currently challenging, primarily due to a lack of techniques to visualize spatiotemporal dynamics with sufficiently high selectivity. Although genetically encoded fluorescent biosensors have been developed to detect DA, their poor selectivity prevents distinguishing DA from NE. Here, we report the development of a red fluorescent genetically encoded GPCR (G protein-coupled receptor)-activation reporter for DA termed R-GenGAR-DA. More specifically, a circular permutated red fluorescent protein (cpmApple) was inserted into the third intracellular loop of human DA receptor D1 (DRD1) followed by the screening of mutants within the linkers between DRD1 and cpmApple. We developed two variants: R-GenGAR-DA1.1, which brightened following DA stimulation, and R-GenGAR-DA1.2, which dimmed. R-GenGAR-DA1.2 demonstrated reasonable dynamic range ({Delta}F/F0 = -50%) and DA affinity (EC50 = 0.7 {micro}M) as well as the highest selectivity for DA over NE (143-fold) amongst available DA biosensors. Due to its high selectivity, R-GenGAR-DA1.2 allowed dual-color fluorescence live imaging for monitoring DA and NE, combined with the existing green-NE biosensor GRABNE1m, which has high selectivity for NE over DA (>350-fold) in HeLa cells and hippocampal neurons grown from primary culture. By enabling precise measurement of DA, as well as simultaneous visualization of DA and NE, the red-DA biosensor R-GenGAR-DA1.2 is promising in advancing our understanding of the interplay between DA and NE in organizing key brain functions. Significance StatementThe neuromodulators dopamine and norepinephrine modulate a broad range of brain functions, often in concert. One current challenge is to measure dopamine and norepinephrine dynamics simultaneously with high spatial and temporal resolution. We therefore developed a red-dopamine biosensor that has 143-fold higher selectivity for dopamine over norepinephrine. Taking advantage of its high selectivity for dopamine over norepinephrine, this red-dopamine biosensor allowed dual-color fluorescence live imaging for monitoring dopamine and norepinephrine in both HeLa cells and hippocampal neurons in vitro combined with the existing green-norepinephrine biosensor that has 350-fold selectivity for norepinephrine over dopamine. Thus, this approach can provide new opportunities to advance our understanding of high spatial and temporal dynamics of dopamine and norepinephrine in normal and abnormal brain functions.