GABAA/Benzodiazepine receptors in acutely isolated hippocampal astrocytes

The properties of GABA receptor-mediated responses were examined in noncultured astrocytes, acutely isolated from the mature rat hippocampus. Whole-cell patch clamping revealed a GABA-activated Cl- conductance that was mimicked by the GABAA receptor agonist muscimol and depressed by the GABAA antagonists bicuculline and picrotoxin. The GABAA-activated currents were potentiated by the barbiturate pentobarbital and the benzodiazepine diazepam. The benzodiazepine inverse agonist DMCM either enhanced or depressed the astrocytic GABAA-mediated responses, suggesting receptor heterogeneity with respect to pharmacologic profiles. In addition, GABA evoked an increase in [Ca2+]n measured by indo-1 fluorometry, which was depressed in the presence of verapamil or picrotoxin. A GABAA-induced depolarization, therefore, causes Ca2+ influx through voltage-gated Ca2+ channels. The expression and subcellular localization of GABAA receptors and its subunits were examined using immunohistochemical and fluorescent benzodiazepine binding techniques. Polyclonal antisera raised against the GABAA/benzodiazepine receptor, which recognizes multiple subunit isoforms, labeled receptors on the astrocytic cell body and most large processes. In contrast, antisera generated against either alpha 1 or beta 1 subunit peptides revealed immunoreactivity predominantly on a subset of processes. To determine the subcellular distribution of membrane-bound receptors, a fluorescent benzodiazepine derivative was superfused over live astrocytes and visualized with laser-scanning confocal microscopy. Specific fluorescence was distributed in discrete clusters on the cell soma and a subset of distal processes. Collectively, these data support the view that astrocytes, like neurons, express GABAA receptors and target subunit isoforms to distinct cellular localizations. Astrocytic GABAA receptors may be involved in both [Cl-]o and [pH]o homeostasis, and a GABA-evoked increase in [Ca2+]i could serve as a signal between GABAergic neurons and astrocytes

A critical role for astrocytes in hypercapnic vasodilation in brain

Cerebral blood flow (CBF) is controlled by arterial blood pressure, arterial CO2, arterial O2, and brain activity and is largely constant in the awake state. Although small changes in arterial CO2 are particularly potent to change CBF (1 mmHg variation in arterial CO2 changes CBF by 3-4%), the coupling mechanism is incompletely understood. We tested the hypothesis that astrocytic prostaglandin E2 (PgE2) plays a key role for cerebrovascular CO2 reactivity and that preserved synthesis of glutathione is essential for the full development of this response. We combined two-photon imaging microscopy in brain slices with in vivo work in rats and C57Bl/6J mice to examine the hemodynamic responses to CO2 and somatosensory stimulation before and after inhibition of astrocytic glutathione and PgE2 synthesis. We demonstrate that hypercapnia (increased CO2) evokes an increase in astrocyte [Ca2+]i and stimulates COX-1 activity. The enzyme downstream of COX-1 that synthesizes PgE2 (microsomal prostaglandin E synthase-1) depends critically for its vasodilator activity on the level of glutathione in the brain. We show that when glutathione levels are reduced, astrocyte calcium-evoked release of PgE2 is decreased and vasodilation triggered by astrocyte [Ca2+]i in vitro and by hypercapnia in vivo is inhibited. Astrocyte synthetic pathways, dependent on glutathione, are involved in cerebrovascular reactivity to CO2. Reductions in glutathione levels in ageing, stroke or schizophrenia could lead to dysfunctional regulation of CBF and subsequent neuronal damage

In vivo imaging reveals that pregabalin inhibits cortical spreading depression and propagation to subcortical brain structures

Functional Genomics of Muscle, Nerve and Brain Disorder

Nitric oxide sensitive depolarization-induced hyperpolarization: a possible role for gap junctions during development

Electrical coupling is a widespread feature of developing neuronal circuits and it contributes to the generation of patterned activity, In the developing rat hippocampus, release of GABA by coactive hilar interneurones generates widespread synchronized activity, Here it is shown that hilar interneurones strongly rectify in the outward direction when depolarized, This depolarization-induced hyperpolarization, abolished by gap junction uncouplers, is modulated by nitric oxide, This phenomenon might represent a current-shunting mechanism of the excess current by providing functional inhibition at a developmental stage when GABA is excitatory, Spatial buffering of the current might represent an osmotic mechanism for growth and differentiation