Astrocyte-regulated synaptogenesis: an in vitro ultrastructural study.

Striatal neurons from E15 rat embryos were dissociated, plated at low cell density on polyornithine or on astrocyte monolayers derived from the striatum (homotopic) or mesencephalon (heterotopic), and cultured in a chemically defined medium. Dendrites developing in homotopic co-cultures could reach a state of maturation allowing the establishment of synapses with axons from mesencephalic explants. This culture system thus partially reproduces the in vivo conditions in which striatal neurons developing in an homotopic glial environment can serve as synaptic targets for afferent mesencephalic axons.

Astrocyte-regulated GABA-ergic striatal neurons development: an in vitro ultrastructural study.

Striatal neurons from E15 rat embryos were dissociated, plated at low cell density on polyornithine or on astrocyte monolayers derived from the striatum (homotopic) or mesencephalon (heterotopic), and cultured in a chemically defined medium. After 2 to 10 days neurons could be divided in 3 classes according to their cell body diameter: small, medium or large. The percentage of small neurons which was very high 60% for GABAergic neurons on polyornithine after 2 days in vitro was reduced to 35% on mesencephalic astrocytes and to less than 20% on striatal astrocytes. The decrease in the number of small cells was paralleled by an increase in the number of multipolar medium size cells whereas the percentages of bipolar medium size and large neurons remained constant (55 and 4% respectively). All results obtained with the general neuronal population were replicated with the GABAergic sub-population which accounted for more than 50% of total neuronal population. These experiments confirm the beneficial influence of homotopic astrocytes on neuronal differentiation and on dendrite growth.

In vitro regulation of neuronal morphogenesis and polarity by astrocyte-derived factors.

Mesencephalic neurons were cultured from 2 to 5 days in mesencephalic (CM Gmes) or striatal (CM Gstr) astrocyte conditioned media or in the soluble (S100) and insoluble (P100) fractions prepared from these media by ultracentrifugation. CM Gmes as well as all soluble fractions induced dendritic and axonal elongation, whereas CM Gstr and the insoluble fractions promoted axonal growth only. The study of the shape of the neuronal cell bodies and the measurement of their adhesion to the substratum revealed that axons elongated under low adhesion conditions, but that dendrite growth was highly dependent upon adhesion and spreading of the neuronal soma. This different dependency of axonal and dendritic elongation upon spreading is explained by a model in which we consider the respective viscosities of axons and dendrites. From these observations and speculations we propose that axons and dendrites have different modes of elongation and that the primary effect of the astrocyte-derived factors capable of regulating neuronal polarity is to modify the adhesion of the neurons to their culture substratum.

Cyclic AMP reduces adhesion of isolated neuronal growth cones from developing rat forebrain to an astrocytic cell line from embryonic mouse striatum.

We have recently shown that isolated neuronal growth cones from developing rat forebrain possess an appreciable activity of adenylate cyclase, producing cyclic adenosine monophosphate, which can be stimulated by various neurotransmitter receptor agonists and by forskolin [Lockerbie R. O., Hervé D., Blanc G., Tassin J. P. and Glowinski J. (1988) Devl Brain Res. 38, 19-25]. In the present study, we have investigated the effect of cyclic adenosine monophosphate in an in vitro adhesion assay established between [3H]GABA-labelled isolated growth cones and a Simian virus-40 transformed astrocytic cell line from embryonic mouse striatum. Adhesion of the isolated growth cones onto the astrocytic clone increased steadily up to about 45 min before it began to level off at ca 16-18% of total [3H]GABA-labelled isolated growth cones added. Adhesion of the isolated growth cones onto the astrocytic clone was much superior to that seen on polyornithine and, in particular, on non-treated tissue culture wells. Adhesion "at plateau" was independent of both temperature and extracellular Ca2+ and was markedly reduced (ca 50%) by trypsin pre-treatment of the isolated growth cones. Pre-treatment of the isolated growth cones with either forskolin or lipophilic analogues of cyclic adenosine monophosphate attenuated adhesion in a time- and concentration-dependent manner. Approximately 30% reduction in adhesion to the astrocytic clone "at plateau" was observed after a 15 min pre-treatment of the isolated growth cones with forskolin at 10(-4) M or cyclic adenosine monophosphate analogues at 10(-3) M. A cyclic guanosine monophosphate analogue was without effect on adhesion of isolated growth cones. Scanning electron microscope analysis showed that isolated growth cones pre-treated with either cyclic adenosine monophosphate analogues or forskolin had a simpler morphology when attached to the astrocytic clone than isolated growth cones under control conditions. Pre-treatment of the isolated growth cones with low concentrations of cyclic adenosine monophosphate analogues increased protein kinase activity, measured using an exogenous histone phosphate acceptor, to a level which could not be further stimulated by cyclic adenosine monophosphate. Pre-treatment with a cyclic guanosine monophosphate analogue produced the same effect but only at much higher concentrations than those required for cyclic adenosine monophosphate analogues.

Region-specific neuro-astroglial interactions: ultrastructural study of the in vitro expression of neuronal polarity.

Mesencephalic neurons were cultured for 2 days on mesencephalic or striatal astrocyte monolayers. The morphology of these neurons was studied in electron microscopy. The number of dendritic profiles was higher on mesencephalic astrocytes (homotopic neuro-astroglial co-cultures) than on striatal astrocytes (heterotopic co-cultures). This increase in the number of dendrites correlated with a more mature aspect of the neurons. Striatal neurons were also cultured on the astrocytic monolayers. The state of maturation of these neurons was more advanced, and the number of their dendrites was higher on striatal than on mesencephalic astrocytes. These results confirm and extend the fact that neuronal maturation and dendritic growth can be regulated through region-specific neuro-astroglial interactions (Denis-Donini et al., 1984; Chamak et al., 1987).

[Role of neuro-astroglial interactions in the in vitro maturation of embryonic mesencephalic neurons: electron microscopic and radioautographic study]. / Rôle des interactions neuro-astrogliales dans la maturation in vitro des neurones mesencéphaliques embryonnaires: étude en microscopie électronique et par radioautographie.

Embryonic mouse neurons from the mesencephalon were plated on astrocyte monolayers from the mesencephalon and the striatum. Using ultrastructural criteria, it is shown that neuronal maturation and dendritic outgrowth are stimulated when neurons and astrocytes derive from the same structure. This is true for the dopaminergic neurons visualized by autoradiography after 3H-DA uptake. It is also true for the non-DA neurons present in these cultures. This finding raises the possibility that astrocytes synthetize specific neuronotrophic agents which act primarily upon regionally co-located neuronal subpopulation.

Two simian virus 40 (SV40)-transformed cell lines from the mouse striatum and mesencephalon presenting astrocytic characters. III. A light and electron microscopic study.

In two preceding papers we described the cloning of two astrocytic cell lines by simian virus 40 (SV40) transformation of embryonic mouse mesencephalon (F7-Mes) and striatum (F12-Str). The characterization of these lines as belonging to the astrocytic lineage is based on pharmacological, immunocytochemical and physiological data. Here we present quantitative and qualitative data on the morphological aspects of these two astrocytic clones observed under light and electron microscopy. We show that the clones present ultrastructural characters reminiscent of the morphology of young astrocytes. On one hand, they are rather similar to primary astrocytes in culture; on the other, they differ both from a clonal fibroblastic cell line (BT2) and from embryonic mouse fibroblasts in primary culture. These astroblastic clones display 4 morphologically different cell populations which we called types I, II, III and IV. Types II and III are very similar and represent the most predominant cells; their morphologies strongly remind of that of astroblasts. Type I corresponds to glioblasts and does not account for more than 15-20% of the total population. Type IV, which is very similar to differentiated velamentous astrocytes, normally represent ca. 5% of the cells. However, when the transformed cells are treated with mitomycin or mitomycin + dibutyryl cyclic AMP (dbcAMP), the proportion of type IV cells increases very much (up to more than 50% of the cells) while types I, II and III become less numerous. Morphological analysis therefore confirms that the two cell lines derived from the SV40 transformation of 14-day-old embryonic mesencephalic and striatal cells belong to the astrocytic lineage. Moreover, it seems that they can differentiate in vitro in cell culture conditions either spontaneously or under the action of pharmacological treatments known to enhance normal astrocyte maturation.