Excitatory GABA Responses in Embryonic and Neonatal Cortical Slices Demonstrated by Gramicidin Perforated-Patch Recordings and Calcium Imaging

Owens, David F.; Boyce, Leslie H.; Davis, Marion B. E.; Kriegstein, Arnold R.

doi:10.1523/jneurosci.16-20-06414.1996

Cited by 665 publications

(602 citation statements)

References 54 publications

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“…Both the time course and the magnitude of the developmental decreases in [Cl − ] i reported by Clomeleon are consistent with previous estimates based on electrophysiological measurements (Owens et al, 1996) and the expression profiles of NKCC1 and KCC2 (Rivera et al, 1999;Stein et al, 2004;Yamada et al, 2004;Rivera et al, 2005). Some of these studies showed a rather large variability, both within a given preparation as well as among different cell types, consistent with our finding of a wide distribution of [Cl − ] i between individual neurons from young mice ( …”

Section: Clomeleon Reports Neuronal [Cl − ] Isupporting

confidence: 92%

“…A switch in GABAergic transmission, from depolarization to hyperpolarization, during neuronal development has been demonstrated in many studies (Ben-Ari et al, 1989;Cherubini et al, 1991;Owens et al, 1996) (Fig. 5b, top).…”

Section: Measurement Of Resting [Clmentioning

confidence: 66%

“…It was later established that the shift from depolarizing GABA responses in young animals to hyperpolarizing responses in adult animals correlated with changes of the equilibrium potential of Cl − towards more negative potentials (Cherubini et al, 1991;Owens et al, 1996), with the onset of the expression of Cl − -extruding transporters such as KCC2 (Rivera et al, 1999), and with a decrease in the expression of Cl − -accumulating transporters such as NKCC1 (Yamada et al, 2004). However, the presumed decrease in [Cl − ] i occurring during development has not yet been visualized in brain slices or in vivo.…”

Section: Clomeleon Reports Neuronal [Cl − ] Imentioning

confidence: 99%

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Imaging synaptic inhibition in transgenic mice expressing the chloride indicator, Clomeleon

et al. 2006

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Section: Clomeleon Reports Neuronal [Cl − ] Isupporting

confidence: 92%

Section: Measurement Of Resting [Clmentioning

confidence: 66%

Section: Clomeleon Reports Neuronal [Cl − ] Imentioning

confidence: 99%

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Imaging synaptic inhibition in transgenic mice expressing the chloride indicator, Clomeleon

et al. 2006

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“…To the best of our knowledge, most immature cells that can migrate also accumulate intracellular Cl − and are, thus, well equipped to release KCl and to shrink, whereas there is no net force that drives Cl − out of the cell in most differentiated neurons. Because of the active accumulation of Cl − , immature neurons (Owens et al, 1996) and neuronal stem cells in the ventricular zone (LoTurco et al, 1995) depolarize in response to GABA, whereas differentiated neurons, which no longer move, either hyperpolarize or stabilize their membrane potential (Bormann et al, 1987). Although it is proposed that this depolarizing GABA response might be important physiologically in the context of synapse development (Ben Ari et al, 2004) we suggest that these cells might utilize GABA-gated Cl − channels to adjust their cell volume because they are still migrating through the brain.…”

Section: Discussionmentioning

confidence: 99%

A role for ion channels in glioma cell invasion

McFerrin¹,

2005

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Many cells, including neuronal and glial progenitor cells, stem cells and microglial cells, have the capacity to move through the extracellular spaces of the developing and mature brain. This is particularly pronounced in astrocyte-derived tumors, gliomas, which diffusely infiltrate the normal brain. Although a significant body of literature exists regarding signals that are involved in the guidance of cells and their processes, little attention has been paid to cell-shape and cell-volume changes of migratory cells. However, extracellular spaces in the brain are very narrow and represent a major obstacle that requires cells to dynamically regulate their volume. Recent studies in glioma cells show that this involves the secretion of Cl − and K + with water. Pharmacological inhibition of Cl − channels impairs their ability to migrate and limits tumor progression in experimental tumor models. One Cl − -channel inhibitor, chlorotoxin, is currently in Phase II clinical trials to treat malignant glioma. This article reviews our current knowledge of cell-volume changes and the role of ion channels during the migration of glioma cells. It also discusses evidence that supports the importance of channel-mediated cell-volume changes in the migration of immature neurons and progenitor cells during development. New unpublished data is presented, which demonstrates that Cl − and K + channels involved in cell shrinkage localize to lipid-raft domains on the invadipodia of glioma cells and that their presence might be regulated by trafficking of these proteins in and out of lipid rafts.

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“…However, under various conditions GABA facilitates neuronal depolarization, including human epileptogenesis (Cohen et al, 2002), after neuronal injury (van den Pol et al, 1996) and during normal early brain development (Ben-Ari et al, 1989;Khazipov et al, 2001;Owens et al, 1996). In the immature brain, activation of GABA A depolarizes the neuron membrane, and within the first and second postnatal weeks of life in mice E Cl À shifts toward a hyperpolarizing potential thereby leading to inhibitory GABA-mediated responses.…”

Section: Introductionmentioning

confidence: 99%

A Sensitive Period of Mice Inhibitory System to Neonatal GABA Enhancement by Vigabatrin is Brain Region Dependent

Levav-Rabkin

Melamed

Clarke

et al. 2009

Neuropsychopharmacol

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Neurodevelopmental disorders, such as schizophrenia and autism, have been associated with disturbances of the GABAergic system in the brain. We examined immediate and long-lasting influences of exposure to the GABA-potentiating drug vigabatrin (GVG) on the GABAergic system in the hippocampus and cerebral cortex, before and during the developmental switch in GABA function (postnatal days P1-7 and P4-14). GVG induced a transient elevation of GABA levels. A feedback response to GABA enhancement was evident by a short-term decrease in glutamate decarboxylase (GAD) 65 and 67 levels. However, the number of GAD65/67-immunoreactive (IR) cells was greater in 2-week-old GVG-treated mice. A long-term increase in GAD65 and GAD67 levels was dependent on brain region and treatment period. Vesicular GABA transporter was insensitive to GVG. The overall effect of GVG on the Cl À co-transporters NKCC1 and KCC2 was an enhancement of their synthesis, which was dependent on the treatment period and brain region studied. In addition, a short-term increase was followed by a long-term decrease in KCC2 oligomerization in the cell membrane of P4-14 hippocampi and cerebral cortices. Analysis of the Ca 2 + binding proteins expressed in subpopulations of GABAergic cells, parvalbumin and calbindin, showed region-specific effects of GVG during P4-14 on parvalbumin-IR cell density. Moreover, calbindin levels were elevated in GVG mice compared to controls during this period. Cumulatively, these results suggest a particular susceptibility of the hippocampus to GVG when exposed during days P4-14. In conclusion, our studies have identified modifications of key components in the inhibitory system during a critical developmental period. These findings provide novel insights into the deleterious consequences observed in children following prenatal and neonatal exposure to GABA-potentiating drugs.

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Excitatory GABA Responses in Embryonic and Neonatal Cortical Slices Demonstrated by Gramicidin Perforated-Patch Recordings and Calcium Imaging

Cited by 665 publications

References 54 publications

Imaging synaptic inhibition in transgenic mice expressing the chloride indicator, Clomeleon

Imaging synaptic inhibition in transgenic mice expressing the chloride indicator, Clomeleon

A role for ion channels in glioma cell invasion

A Sensitive Period of Mice Inhibitory System to Neonatal GABA Enhancement by Vigabatrin is Brain Region Dependent

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