Guo-Feng Tian scite author profile

Local increase in blood flow during neural activity forms the basis for functional brain imaging, but its mechanism remains poorly defined. Here we show that cortical astrocytes in vivo possess a powerful mechanism for rapid vasodilation. We imaged the activity of astrocytes labeled with the calcium (Ca(2+))-sensitive indicator rhod-2 in somatosensory cortex of adult mice. Photolysis of caged Ca(2+) in astrocytic endfeet ensheathing the vessel wall was associated with an 18% increase in arterial cross-section area that corresponded to a 37% increase in blood flow. Vasodilation occurred with a latency of only 1-2 s, and both indomethacin and the cyclooxygenase-1 inhibitor SC-560 blocked the photolysis-induced hyperemia. These observations implicate astrocytes in the control of local microcirculation and suggest that one of their physiological roles is to mediate vasodilation in response to increased neural activity.

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An astrocytic basis of epilepsy

Tian

Azmi²,

Takano

et al. 2005

Nat Med

741

639

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Hypersynchronous neuronal firing is a hallmark of epilepsy, but the mechanisms underlying simultaneous activation of multiple neurons remains unknown. Epileptic discharges are in part initiated by a local depolarization shift that drives groups of neurons into synchronous bursting. In an attempt to define the cellular basis for hypersynchronous bursting activity, we studied the occurrence of paroxysmal depolarization shifts after suppressing synaptic activity by TTX and voltage-gated Ca 2+ channel blockers. Here we report that paroxysmal depolarization shifts can be initiated by release of glutamate from extrasynaptic sources or by photolysis of caged Ca 2+ in astrocytes. Two-photon imaging of live exposed cortex revealed that several anti-epileptics, including valproate, gabapentin and phenytoin, reduced the ability of astrocytes to transmit Ca 2+ signaling. Our results reveal an unanticipated key role for astrocytes in seizure activity. As such, these findings identify astrocytes as a proximal target for the treatment of epileptic disorders.Epilepsy is a neurological disorder in which normal brain function is disrupted as a consequence of intensive burst activity from groups of neurons1. Epilepsies result from long-lasting plastic changes in the brain affecting the expression of receptors and channels, and involve sprouting and reorganization of synapses, as well as reactive gliosis2 ,3 . Several lines of evidence suggest a key role of glutamate in the pathogenesis of epilepsy. Local or systemic administration of glutamate agonists triggers excessive neuronal firing, whereas glutamate receptor (GluR) antagonists have anticonvulsant properties 4 . The observation that astrocytes release glutamate via a regulated Ca 2+ dependent mechanism 5-8 prompted us to hypothesize that glutamate released by astrocytes plays a causal role in synchronous firing of large populations of neurons.Paroxysmal depolarization shifts (PDSs) are abnormal prolonged depolarizations with repetitive spiking and are reflected as interictal discharges in the electroencephalogram 2, 3. We report here that glutamate released by astrocytes can trigger PDSs in several models of experimental seizure. A unifying feature of seizure activity was its consistent association Corresponding author: Guo-Feng Tian (Guo-Feng_Tian@URMC.Rochester.edu). * These authors contributed equally to this work. NIH Public Access RESULTS PDSs can be triggered by an action potential-independent mechanismTo examine the cellular mechanism underlying PDSs, we patched CA1 pyramidal neurons in rat hippocampal slices exposed to 4-aminopyridine (4-AP). 4-AP is a K + channel blocker that induces intense electrical discharges in slices9 and seizure activity in experimental animals 10 . All slices exposed to 4-AP (61 slices from 23 rats) exhibited epileptiform bursting activity expressed as transient episodes of neuronal depolarizations eliciting trains of action potentials (Fig. 1a). Bath application of TTX promptly eliminated neuronal firing (Fig. 1b). Unexpectedly, the...

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Astrocytic Ca2+ signaling evoked by sensory stimulation in vivo

et al. 2006

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Although astrocytes are the most abundant cell type in the brain, evidence for their activation during physiological sensory activity is lacking. Here we show that whisker stimulation evokes increases in astrocytic cytosolic calcium (Ca(2+)) within the barrel cortex of adult mice. Increases in astrocytic Ca(2+) were a function of the frequency of stimulation, occurred within several seconds and were inhibited by metabotropic glutamate receptor antagonists. To distinguish between synaptic input and output, local synaptic activity in cortical layer 2 was silenced by iontophoresis of AMPA and NMDA receptor antagonists. The antagonists did not reduce astrocytic Ca(2+) responses despite a marked reduction in excitatory postsynaptic currents in response to whisker stimulation. These findings indicate that astrocytes respond to synaptic input, by means of spillover or ectopic release of glutamate, and that increases in astrocytic Ca(2+) occur independently of postsynaptic excitatory activity.

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Cortical spreading depression causes and coincides with tissue hypoxia

et al. 2007

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Cortical spreading depression (CSD) is a self-propagating wave of cellular depolarization that has been implicated in migraine and in progressive neuronal injury after stroke and head trauma. Using two-photon microscopic NADH imaging and oxygen sensor microelectrodes in live mouse cortex, we find that CSD is linked to severe hypoxia and marked neuronal swelling that can last up to several minutes. Changes in dendritic structures and loss of spines during CSD are comparable to those during anoxic depolarization. Increasing O2 availability shortens the duration of CSD and improves local redox state. Our results indicate that tissue hypoxia associated with CSD is caused by a transient increase in O2 demand exceeding vascular O2 supply.

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Systemic administration of an antagonist of the ATP-sensitive receptor P2X7 improves recovery after spinal cord injury

Peng¹,

Cotrina²,

Han³

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

390

371

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Traumatic spinal cord injury is characterized by an immediate, irreversible loss of tissue at the lesion site, as well as a secondary expansion of tissue damage over time. Although secondary injury should, in principle, be preventable, no effective treatment options currently exist for patients with acute spinal cord injury (SCI). Excessive release of ATP by the traumatized tissue, followed by activation of high-affinity P2X7 receptors, has previously been implicated in secondary injury, but no clinically relevant strategy by which to antagonize P2X7 receptors has yet, to the best of our knowledge, been reported. Here we have tested the neuroprotective effects of a systemically administered P2X7R antagonist, Brilliant blue G (BBG), in a weight-drop model of thoracic SCI in rats. Administration of BBG 15 min after injury reduced spinal cord anatomic damage and improved motor recovery without evident toxicity. Moreover, BBG treatment directly reduced local activation of astrocytes and microglia, as well as neutrophil infiltration. These observations suggest that BBG not only protected spinal cord neurons from purinergic excitotoxicity, but also reduced local inflammatory responses. Importantly, BBG is a derivative of a commonly used blue food color (FD&C blue No. 1), which crosses the blood-brain barrier. Systemic administration of BBG may thus comprise a readily feasible approach by which to treat traumatic SCI in humans.astrocytes ͉ inflammation ͉ microglia ͉ motor neurons ͉ purinergic signaling

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Guo-Feng Tian

Astrocyte-mediated control of cerebral blood flow

An astrocytic basis of epilepsy

Astrocytic Ca2+ signaling evoked by sensory stimulation in vivo

Cortical spreading depression causes and coincides with tissue hypoxia

Systemic administration of an antagonist of the ATP-sensitive receptor P2X7 improves recovery after spinal cord injury

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