GABA release by hippocampal astrocytes

Meur, Karim Le; Mendizabal-Zubiaga, Juan; Grandes, Pedro; Audinat, Etienne

doi:10.3389/fncom.2012.00059

Cited by 80 publications

(79 citation statements)

References 58 publications

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“…Notably, astrocytes in the olfactory bulb were able to release both GABA and glutamate to inhibit or activate synchronously groups of specific cell populations, revealing a complex astrocytic modulation of local network activity [87]. A similar dual action of astrocytes was observed in the hippocampus [89]. All in all, these results raise a number of questions on the ultimate effects of astrocytic signalling in local networks.…”

Section: Astrocytes Activated By Non-gabaergic Signals Modulate Gabaementioning

confidence: 77%

“…In astrocytes, GABA can be degraded by GABA-a-ketoglutaric acid aminotransferase (GABA-T) to glutamine, which is then released and subsequently captured by neurons. Most relevant to the focus of this review is the finding that GABA itself is released by astrocytes in many brain regions, including the olfactory bulb [87], the ventro-basal thalamus [77,88] and the hippocampus [89]. In the olfactory bulb, Kozlov and co-workers reported the first evidence that astrocytic GABA can induce slow outward currents (SOCs) in neurons.…”

Section: Astrocytes Activated By Non-gabaergic Signals Modulate Gabaementioning

confidence: 99%

“…The mechanism of astrocytic GABA release is unclear. The fact that both in ventro-basal thalamus and hippocampal slices SOCs were increased in number upon hypo-osmotic challenge suggests a release mechanism sensitive to cell volume [88,89]. A different form of GABA release has been described in astrocytes from cerebellar slices [94,95].…”

Section: Astrocytes Activated By Non-gabaergic Signals Modulate Gabaementioning

confidence: 99%

“…Do glutamatergic SICs and GABAergic SOCs derive from the same activated astrocytes or do they come from different ones? As to the GABA and glutamate release, Le Meur et al [89] suggest that different astrocytes were probably involved because simultaneous SICs and SOCs were extremely rare. It is possible, however, that the same astrocyte may release both GABA and glutamate, but from distinct releasing sites in contact with different synapses.…”

Section: Astrocytes Activated By Non-gabaergic Signals Modulate Gabaementioning

confidence: 99%

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GABAergic interneuron to astrocyte signalling: a neglected form of cell communication in the brain

Losi

Mariotti

Carmignoto

2014

Phil. Trans. R. Soc. B

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GABAergic interneurons represent a minority of all cortical neurons and yet they efficiently control neural network activities in all brain areas. In parallel, glial cell astrocytes exert a broad control of brain tissue homeostasis and metabolism, modulate synaptic transmission and contribute to brain information processing in a dynamic interaction with neurons that is finely regulated in time and space. As most studies have focused on glutamatergic neurons and excitatory transmission, our knowledge of functional interactions between GABAergic interneurons and astrocytes is largely defective. Here, we critically discuss the currently available literature that hints at a potential relevance of this specific signalling in brain function. Astrocytes can respond to GABA through different mechanisms that include GABA receptors and transporters. GABA-activated astrocytes can, in turn, modulate local neuronal activity by releasing gliotransmitters including glutamate and ATP. In addition, astrocyte activation by different signals can modulate GABAergic neurotransmission. Full clarification of the reciprocal signalling between different GABAergic interneurons and astrocytes will improve our understanding of brain network complexity and has the potential to unveil novel therapeutic strategies for brain disorders. BackgroundOur knowledge of how the brain computes incoming sensory signals and governs our cognitive and motor functions has faced an exponential increase in the last decades. This was made possible thanks to a number of technological advances in molecular biology, brain imaging and optogenetics. It is now clear that the complexity of brain activity relies on fast dynamic interactions between different cell types that are finely and constantly regulated in time and space. The greatest challenge for neuroscientists is represented by the speed, the number and the heterogeneity of cellular signals that relentlessly occur in our brain. Over the last years our understanding of the functional role of two heterogeneous cell populations, i.e. GABAergic interneurons and astrocytic glial cells, has been marked by a significant improvement. Whether and how these cell types interact with each other and what functional significance such a signalling may have in the brain network remain, however, largely undefined.Astrocytes are the major class of glial cells in the brain and play essential roles in brain homeostasis and metabolism. They are coupled in a syncytium through gap junctions and exert a homeostatic control of the extracellular space by regulating the pH, the water content and the extracellular concentration of different neurotransmitters and ions. In addition, astrocytes supply neurons with nutrients, trophic factors, cytokines and neuromodulators [1,2], contributing to the neurovascular coupling mechanism [3,4] and to the defensive reaction to tissue insult. Only recently the role of astrocytes has been extended to functions that were once considered an exclusive domain of neurons, such as short-and longterm modul...

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Section: Astrocytes Activated By Non-gabaergic Signals Modulate Gabaementioning

confidence: 77%

Section: Astrocytes Activated By Non-gabaergic Signals Modulate Gabaementioning

confidence: 99%

Section: Astrocytes Activated By Non-gabaergic Signals Modulate Gabaementioning

confidence: 99%

Section: Astrocytes Activated By Non-gabaergic Signals Modulate Gabaementioning

confidence: 99%

See 2 more Smart Citations

GABAergic interneuron to astrocyte signalling: a neglected form of cell communication in the brain

Losi

Mariotti

Carmignoto

2014

Phil. Trans. R. Soc. B

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“…Their results demonstrate that astrocytes may play a crucial role in spike timing dependent processes with important implications for neurological diseases. Le Meur et al (2012) use whole-cell recordings in rat acute brain slices and electron microscopy to test whether hippocampal astrocytes release the inhibitory transmitter GABA. They observe that slow transient inhibitory currents share characteristics with the slow NMDA receptor-mediated currents shown previously to result from astrocytic glutamate release.…”

mentioning

confidence: 99%

Biophysically based Computational Models of Astrocyte ~ Neuron Coupling and their Functional Significance

2014

Frontiers Research Topics

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Neuroscientists are becoming increasingly interested in modeling brain functions however, capturing underlying biophysical mechanisms requires plausible, biologically realistic models at the cellular level. Moreover, the (often conflicting) demands of biological realism and computational tractability have to be accommodated. Recent publications highlight the interaction of astrocytes with multiple synapses: if we are to fully appreciate this dynamic and coordinated interplay between cells, then more research on bidirectional communication between astrocytes and neurons is required. For example, a better understanding of astrocyte-neuron coupling may lead to providing building blocks for studying the regulatory capability of astrocytic networks on a larger scale. This special topic presents nine papers which cover a range of issues from computational models of astrocyte-neuron interactions to the role of astrocytes in neurological disorders.In the paper by Gordleeva et al. (2012) the basic physiological functions of tripartite synapses and astrocytic regulation at the level of neural network activity is considered. The paper concludes that astrocytes support homeostatic regulation of network activity by modulating neural networks into a bistable regime of activity with two stable firing levels and spontaneous transitions between them. The comprehensive review article by Volman et al. (2012) deals with the premise that pathways for astrocyte-neuron interaction can enhance the information processing capabilities of brains, yet in other circumstances may lead the brain on the road to pathological ruin. The paper focuses on existing computational models of astrocytic involvement in epileptogenesis and their relevance to existing physiological data. Similarily, Min et al. (2012) review recent experimental literature on astrocyte-neuron interactions and discuss the dynamic effects of astrocytes on neuronal excitability and short-and long-term synaptic plasticity. Their paper also addresses potential computational functions of astrocyte-neuron interactions in the brain, in particular how astrocytes may enhance the computational power of neuronal networks in previously unexpected ways. In the paper by Allam et al. (2012) a computational model is extended to show that glial transporters modulate synaptic transmission mediated by ionotropic AMPA and NMDA receptors at glutamatergic synapses. Their results demonstrate that astrocytes may play a crucial role in spike timing dependent processes with important implications for neurological diseases. Le Meur et al. (2012) use whole-cell recordings in rat acute brain slices and electron microscopy to test whether hippocampal astrocytes release the inhibitory transmitter GABA. They observe that slow transient inhibitory currents share characteristics with the slow NMDA receptor-mediated currents shown previously to result from astrocytic glutamate release. Their results provide quantitative characteristics of astrocyte-to-neuron GABAergic signaling and suggest that all principal n...

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Insights into the release mechanism of astrocytic glutamate evoking in neurons NMDA receptor‐mediated slow depolarizing inward currents

Gómez-Gonzalo

Zehnder

Requie

et al. 2018

Glia

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The gliotransmitter glutamate in different brain regions modulates neuronal excitability and synaptic transmission through a variety of mechanisms. Among the hallmarks of astrocytic glutamate release are the slow depolarizing inward currents (SICs) in neurons mediated by N-methyl-d-aspartate receptor activation. Different stimuli that evoke Ca elevations in astrocytes induce neuronal SICs suggesting a Ca -dependent exocytotic glutamate release mechanism of SIC generation. To gain new insights into this mechanism, we investigated the relationship between astrocytic Ca elevations and neuronal SICs in mouse hippocampal slice preparations. Here we provide evidence that SICs, occurring either spontaneously or following a hypotonic challenge, are unchanged in the virtual absence of Ca signal changes at astrocytic soma and processes, including spatially restricted Ca microdomains. SICs are also unchanged in the presence of Bafilomycin A1 that after prolonged slice incubation depletes glutamate from astrocytic vesicles. We also found that hemichannels and TREK family channels-that recent studies proposed to mediate astrocytic glutamate release - are not involved in SIC generation. SICs are reduced by the volume-sensitive anion channel antagonists diisothiocyanatostilbene-2,2'-disulfonic acid (DIDS), quinine and fluoxetine, suggesting a possible contribution of these channels in SIC generation. Direct measurements of astrocytic glutamate release further confirm that hypotonicity-evoked gliotransmission is impaired following DIDS, quinine and fluoxetine while the exocytotic release of glutamate-that is proposed to mediate synaptic transmission modulation by astrocytes-remains unaffected. In conclusion, our data provide evidence that the release of glutamate generating SICs occurs independently on exocytotic Ca -dependent glutamate release mechanism.

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GABA release by hippocampal astrocytes

Cited by 80 publications

References 58 publications

GABAergic interneuron to astrocyte signalling: a neglected form of cell communication in the brain

GABAergic interneuron to astrocyte signalling: a neglected form of cell communication in the brain

Biophysically based Computational Models of Astrocyte ~ Neuron Coupling and their Functional Significance

Insights into the release mechanism of astrocytic glutamate evoking in neurons NMDA receptor‐mediated slow depolarizing inward currents

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