Rapid astrocyte calcium signals correlate with neuronal activity and onset of the hemodynamic response in vivo
IR Winship, N Plaa, TH Murphy - Journal of Neuroscience, 2007 - Soc Neuroscience
IR Winship, N Plaa, TH Murphy
Journal of Neuroscience, 2007•Soc NeuroscienceElevation of intracellular Ca2+ in astrocytes can influence cerebral microcirculation and
modulate synaptic transmission. Recently, in vivo imaging studies identified delayed,
sensory-driven Ca2+ oscillations in cortical astrocytes; however, the long latencies of these
Ca2+ signals raises questions in regards to their suitability for a role in short-latency
modulation of cerebral microcirculation or rapid astrocyte-to-neuron communication. Here,
using in vivo two-photon Ca2+ imaging, we demonstrate that∼ 5% of sulforhodamine 101 …
modulate synaptic transmission. Recently, in vivo imaging studies identified delayed,
sensory-driven Ca2+ oscillations in cortical astrocytes; however, the long latencies of these
Ca2+ signals raises questions in regards to their suitability for a role in short-latency
modulation of cerebral microcirculation or rapid astrocyte-to-neuron communication. Here,
using in vivo two-photon Ca2+ imaging, we demonstrate that∼ 5% of sulforhodamine 101 …
Elevation of intracellular Ca2+ in astrocytes can influence cerebral microcirculation and modulate synaptic transmission. Recently, in vivo imaging studies identified delayed, sensory-driven Ca2+ oscillations in cortical astrocytes; however, the long latencies of these Ca2+ signals raises questions in regards to their suitability for a role in short-latency modulation of cerebral microcirculation or rapid astrocyte-to-neuron communication. Here, using in vivo two-photon Ca2+ imaging, we demonstrate that ∼5% of sulforhodamine 101-labeled astrocytes in the hindlimb area of the mouse primary somatosensory cortex exhibit short-latency (peak amplitude ∼0.5 s after stimulus onset), contralateral hindlimb-selective sensory-evoked Ca2+ signals that operate on a time scale similar to neuronal activity and correlate with the onset of the hemodynamic response as measured by intrinsic signal imaging. The kinetics of astrocyte Ca2+ transients were similar in rise and decay times to postsynaptic neuronal transients, but decayed more slowly than neuropil Ca2+ transients that presumably reflect presynaptic transients. These in vivo findings suggest that astrocytes can respond to sensory activity in a selective manner and process information on a subsecond time scale, enabling them to potentially form an active partnership with neurons for rapid regulation of microvascular tone and neuron–astrocyte network properties.
Soc Neuroscience
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