3alpha,5alpha-Tetrahydroprogesterone (allopregnanolone) and gamma-aminobutyric acid: autocrine/paracrine interactions in the control of neonatal PSA-NCAM+ progenitor proliferation.

The earliest identified neonatal neural progenitors are cells that express the polysialylated form of the neural cell adhesion molecule (PSA-NCAM). One of these progenitors is the early PSA-NCAM+ progenitor (ePSA-NCAM+ progenitor; Gago et al. [2003] Mol Cell Neurosci 22:162-178), which corresponds to a multipotential cell with a default differentiation through glial lineages. The ePSA-NCAM+ progenitor can synthesize the neurosteroid progesterone (PROG) and its reduced metabolite 3alpha,5alpha-tetrahydroprogesterone (3alpha,5alpha-THP, or allopregnanolone; Gago et al. [ 2001] Glia 36:295-308). The latter is a potent positive allosteric modulator of gamma-aminobutyric acid type A (GABAA) receptors. In the present work, we demonstrate that PROG and 3alpha,5alpha-THP both stimulate ePSA-NCAM+ progenitor proliferation. PROG exerted its mitogenic effect indirectly, through its conversion to 3alpha,5alpha-THP, since it could be abolished by an inhibitor of the 5alpha-reductase (L685-273) and mimicked by 3alpha,5alpha-THP. A dose-response curve revealed a bell-shaped effect of 3alpha,5alpha-THP on ePSA-NCAM+ progenitor proliferation, with greatest stimulation at nanomolar concentrations. The mitogenic effect of 3 alpha,5 alpha-THP was mediated by GABAA receptors, insofar as it could be blocked by the selective antagonist bicuculline. ePSA-NCAM+ progenitors indeed expressed mRNAs for GABAA receptor subunits, and GABA enhanced cell proliferation, an effect that was also bicuculline sensitive. Moreover, these cells synthesized GABA, which was involved in a tonic stimulation of their proliferation. These results reveal complex autocrine/paracrine loops in the control of ePSA-NCAM+ progenitor proliferation, involving both neurosteroid and GABA signaling, and suggest a novel key role for 3alpha,5alpha-THP in the development of the nervous system.

Serotonergic regulation of the GABAergic transmission in the rat basal ganglia.

The GABAergic neurons represent a major neuronal population in the basal ganglia. Although alterations in serotonin (5-HT) transmission are associated with neurodegenerative diseases involving these regions, the influence exerted by 5-HT afferents on GABAergic populations remains poorly understood. Here, we examined the consequences of 5,7-dihydroxytryptamine-induced lesion of 5-HT neurons on glutamic acid decarboxylase (GAD) activity, mRNA expression of the two isoforms of the enzyme, GAD65 and GAD67, GABA uptake, and extracellular GABA levels in the striatum. The 5-HT depletion produced an increase in GAD activity without modifying GAD65 and GAD67 mRNA levels, suggesting that 5-HT acts at the posttranscriptional level to regulate striatal GABA synthesis. No change in GAD activity was measured in the main striatal target structures, the globus pallidus and substantia nigra. Striatal GABA uptake and extracellular levels of GABA measured under basal conditions in freely moving rats were maintained in a normal range following 5-HT deprivation. By contrast, depolarization-induced increases in extracellular levels of GABA were larger in the striatum of 5-HT-deprived rats than in controls, which may be accounted for by an increase in a releasable pool of GABA due to increased synthesis rate. Together, these results suggest that 5-HT afferents may exert a phasic inhibitory control on striatal GABA transmission. Therefore, a decrease in striatal 5-HT transmission in disease states, such as Parkinson's disease, may contribute to pathological changes in striatal GABA neuron activity by increasing their reactivity to depolarizing stimuli.

Glutamate transport alteration triggers differentiation-state selective oxidative death of cultured astrocytes: a mechanism different from excitotoxicity depending on intracellular GSH contents.

Recent evidence has been provided for astrocyte degeneration in experimental models of neurodegenerative insults associated with glutamate transport alteration. To determine whether astrocyte death can directly result from altered glutamate transport, we here investigated the effects of L-trans-pyrrolidine-2,4-dicarboxylate (PDC) on undifferentiated or differentiated cultured rat striatal astrocytes. PDC induced death of differentiated astrocytes without affecting undifferentiated astrocyte viability. Death of differentiated astrocytes was also triggered by another substrate inhibitor but not by blockers of glutamate transporters. The PDC-induced death was delayed and apoptotic, and death rate was dose and treatment duration-dependent. Although preceded by extracellular glutamate increase, this death was not mediated through glutamate receptor stimulation, as antagonists did not provide protection. It involves oxidative stress, as a decrease in glutathione contents and a dramatic raise in reactive oxygen species preceded cell loss, and as protection was provided by antioxidants. PDC induced a similar percentage of GSH depletion in the undifferentiated astrocytes, but only a slight increase in reactive oxygen species. Interestingly, undifferentiated astrocytes exhibited twofold higher basal GSH content compared with the differentiated ones, and depleting their GSH content was found to render them susceptible to PDC. Altogether, these data demonstrate that basal GSH content is a critical factor of astrocyte vulnerability to glutamate transport alteration with possible insights onto concurrent death of astrocytes and gliosis in neurodegenerative insults.