Genetically encoded sensors of glutamate concentration are based on FRET between cyan and yellow fluorescent proteins bracketing a bacterial glutamate-binding protein. Such sensors have yet to find quantitative applications in neurons, because of poor response amplitude in physiological buffers or when expressed on the neuronal cell surface. We have improved our glutamatesensing fluorescent reporter (GluSnFR) by systematic optimization of linker sequences and glutamate affinities. Using SuperGluSnFR, which exhibits a 6.2-fold increase in response magnitude over the original GluSnFR, we demonstrate quantitative optical measurements of the time course of synaptic glutamate release, spillover, and reuptake in cultured hippocampal neurons with centisecond temporal and spine-sized spatial resolution. During burst firing, functionally significant spillover persists for hundreds of milliseconds. These glutamate levels appear sufficient to prime NMDA receptors, potentially affecting dendritic spike initiation and computation. Stimulation frequency-dependent modulation of spillover suggests a mechanism for nonsynaptic neuronal communication.fluorescence resonance energy transfer ͉ hippocampal neurons ͉ synaptic release G lutamate is the primary excitatory neurotransmitter in the brain, and precise measurement of its spatiotemporal pattern of synaptic release and propagation would provide insight into diverse brain processes, including synaptic crosstalk, cerebral ischemia, and mechanisms of learning and memory. In hippocampal slices, synaptic glutamate spillover to the dendrite and neighboring synapses induces homeostatic regulation of glutamate release through extrasynaptic mGluR activation (1), limits synaptic independence (2), lengthens EPSC durations (3), and permits heterosynaptic LTP/LTD (4). Spillover is a primary means of chemical neurotransmission between mitral cells in the rat olfactory bulb (5) and between climbing fibers and molecular layer interneurons in cerebral cortex (6). Estimates of glutamate concentration and dynamics in synaptic, extrasynaptic, and extracellular compartments have been made by NMDAR antagonist displacement (7), glutamate uptake inhibitor application (2), whole ''sniffer'' cells (8), outside-out ''sniffer'' patch electrodes (9, 10), patch recording of astrocyte synaptically evoked transporter currents (STCs) (11), enzymatically coupled electrochemical probes (12), enzymatically coupled metabolite imaging (13), and other methods. Although each method provided a new perspective on glutamate action, all were hampered by a lack of resolution in the spatial or temporal domains because of single-site measurement, reliance on partially coupled or confounded currents, desensitizing receptors, or indirect and slow secondary cascades.Recently, the glutamate reporters glutamate-sensing fluorescent reporter (GluSnFR) ʈ (14) and fluorescent indicator protein for glutamate (FLIPE) (15) were constructed by linear genetic fusions of the glutamate periplasmic binding protein GltI (also known as ybeJ) ...
