Depolarization promotes GAD 65-mediated GABA synthesis by a post-translational mechanism in neural stem cell-derived neurons.

Neuronal activity regulates neurogenesis and neuronal differentiation in the mammalian brain. The commencement of neurotransmitter expression establishes the neuronal phenotype and enables the formation of functional connectivity between neurons. In addition, release of neurotransmitters from differentiating neurons may modulate the behaviour of neural precursors. Here, we show that neuronal activity regulates gamma-aminobutyric acid (GABA) expression in neurons generated from stem cells of the striatum and adult subventricular zone (SVZ). Differentiating neurons display spontaneous Ca2+ events, which are voltage-gated calcium channel (VGCC) dependent. Depolarization increases both the frequency of Ca2+ transients and the amount of Ca2+ influx in differentiating neurons. We show that depolarization-dependent GABA expression is regulated by the amplitude and not by the frequency of Ca2+ influx. Brief activation of VGCCs leads to Ca2+ influx that in turn promotes a rapid expression of GABA. Depolarization-dependent GABA expression does not require changes in gene expression. Instead, it involves cAMP-dependent protein kinase (PKA) and Ca2+ and phospholipid-dependent protein kinase (PKC) signalling. Activity increases the number of glutamic acid decarboxylase (GAD) 65-immunoreactive neurons in a PKA-dependent manner, without altering the expression of GAD 65, suggesting that depolarization promotes recruitment of GAD 65 by a post-translational mechanism. In line with this, depolarization does not permanently increase the expression of GABA in neurons derived from neural stem cells of the embryonic striatum, cortex and adult SVZ. Thus, neuronal activity does not merely accelerate neuronal differentiation but it may alter the mechanism of GABA synthesis in newly generated neurons.

Activity requires soluble amyloid precursor protein alpha to promote neurite outgrowth in neural stem cell-derived neurons via activation of the MAPK pathway.

It is known that activity modulates neuronal differentiation in the adult brain but the signalling mechanisms underlying this process remain to be identified. We show here that activity requires soluble amyloid precursor protein (sAPP) to enhance neurite outgrowth of young neurons differentiating from neural stem cells. Inhibition of sAPP secretion and anti-APP antibodies both abolished the effect of depolarization on neurite outgrowth, whereas exogenous sAPPalpha, similar to depolarization, induced neurite elongation. Depolarization and sAPPalpha both required active N-methyl-D-aspartic acid receptor (NMDAR) and mitogen-activated protein kinase (MAPK)/extracellular signal-regulated kinase (ERK) recruitment to induce neurite outgrowth. However, depolarization and sAPPalpha played different roles in modulating this signalling cascade. Depolarization induced ERK phosphorylation with fast kinetics via activation of NMDAR. By contrast, acute application of sAPPalpha did not lead to ERK activation. However, continuous generation of sAPPalpha was necessary for depolarization-induced ERK phosphorylation, indicating that sAPPalpha promotes MAPK/ERK recruitment by an indirect mechanism. In addition, we found that blockade of NMDAR down-regulated APP expression, whereas depolarization increased sAPPalpha, suggesting that activity may also act upstream of sAPP signalling by regulating the amount of cellular APP and extracellular sAPPalpha. Finally, we show that soluble amyloid precursor-like protein 2 (sAPLP2), but not sAPLP1, is functionally redundant to sAPP in promoting neurite outgrowth and that soluble members of the APP family require membrane-bound APP to enhance neurite outgrowth. In summary, these experiments indicate a novel role of APP family members in activity-dependent neuronal differentiation.