Abstract
Two recent reports propose that the depolarizing action of GABA in the immature brain is an artifact of in vitro preparations in which glucose is the only energy source. The authors argue that this does not mimic the physiological environment because the suckling rats use ketone bodies and pyruvate as major sources of metabolic energy. Here, we show that availability of physiologically relevant levels of ketone bodies has no impact on the excitatory action of GABA in immature cultured hippocampal neurons. Addition of β-hydroxybutyrate (BHB), the primary ketone body in the neonate rat, affected neither intracellular calcium elevation nor membrane depolarizations induced by the GABA-A receptor agonist muscimol, when assessed with calcium imaging or perforated patch-clamp recording, respectively. These results confirm that the addition of ketone bodies to the extracellular environment to mimic conditions in the neonatal brain does not reverse the chloride gradient and therefore render GABA hyperpolarizing. Our data are consistent with the existence of a genuine “developmental switch” mechanism in which GABA goes from having a predominantly excitatory role in immature cells to a predominantly inhibitory one in adults.
Highlights
GABA is the primary inhibitory neurotransmitter in the mature brain
The progressive increase in KCC2 activity coupled with a decrease in activity of NKCC1 is commonly referred to as the developmental ‘‘GABAergic switch’’ in which GABA gradually becomes inhibitory as neurons mature [4,5]
Hippocampal neurons were cultured from pups on the day of birth and Ca2+ imaging was conducted on days 1–3 in vitro (DIV) following a previously published protocol [24,25]
Summary
GABA is the primary inhibitory neurotransmitter in the mature brain. in immature cells, GABA induces cell membrane depolarization by opening of the GABA-A receptor channel, a chloride-permeable ionophore [1]. GABA is excitatory because the cells express high levels of the NKCC1 cotransporter relative to the KCC2 cotransporter [4,5]. The elevated intracellular [Cl2] establishes a transmembrane Cl2 equilibrium potential (ECl) that is positive with respect to the resting potential. In this condition, opening of the GABA-A channels leads to an efflux of Cl2 and, membrane depolarization. Activity of the KCC2 cotransporter increases, and as it extrudes Cl2, KCC2 reduces intracellular [Cl2] and establishes an ECl that is negative with respect to the resting membrane potential. In mature neurons, opening of GABA-A receptor channels allows Cl2 to enter the cell and hyperpolarize the membrane [5]. Extensive converging evidence has revealed the critical role of GABA-mediated excitation in initiation of calcium-sensitive signaling cascades that control DNA synthesis, proliferation, migration, neuronal differentiation and cell-to-cell communication [6,7,8,9,10,11,12,13]
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