Gliogenesis in organotypic tissue culture of the spinal cord of the embryonic mouse. II. Autoradiographic studies

Organotypic rat cerebellar slice culture as a model to analyze the molecular pharmacology of GABAA receptors

The preservation of the neuronal circuitry in rat cerebellar slice cultures provides an advantage in monitoring the development and characterizing the pharmacology of GABA(A) receptor subtypes. Sprague-Dawley rats, 8-11 days of age, were decapitated, their cerebella were cut into 400-microm slices and transferred into culture dishes. Cell viability and organotypic cerebellar organization of the culture remained well preserved up to 3 weeks. Autoradiographic procedures were introduced in these advanced culture technique and employed [(3)H]Ro 15-4513 in the absence and presence of 10 microM diazepam to visualize all benzodiazepine (BZD) and diazepam-insensitive (DIS) binding sites, respectively. Since expression of the alpha6 subunit variant of the GABA(A)/BZD receptor is restricted to the cerebellar granule cells and the BZD receptor agonist diazepam has very low affinity for this subunit, changes in DIS [(3)H]Ro 15-4513 binding sites during cultivation time can be attributed to changes in alpha6 subunit expression. A time-dependent development of total and DIS [(3)H]Ro 15-4513 binding sites were observed in the culture with a trend towards an increase in GABA(A) receptor alpha6 subunit levels during the first week. These findings suggest that explant preparations can be used to examine morphological changes in rat cerebellar slices. In addition, these preparations can be utilized to study the pharmacological effects of GABA(A)/BZD selective drugs on postnatal development of GABA(A) receptors in rat cerebellum.

A rapid procedure for the preparation of oligodendrocyte-enriched cultures from rat spinal cord

Spinal cords and cerebra from 7-day-old rat pups were compared as tissue sources for the isolation of oligodendrocytes and for studies on the development of these cells in culture. After 1 day in culture the serum-containing medium was replaced by a chemically-defined medium, which contained a cocktail of hormones that stimulated oligodendrocyte development. The cultures were characterized with various immunocytochemical markers; monoclonal A2B5 for bipotential glial progenitor cells, anti-galactocerebroside (GC) serum for oligodendrocytes, and anti-glial fibrillary acidic protein (GFAP) serum for astrocytes. The number of positive cells was counted and expressed as a percentage of total cells. At 1 day in culture the cell cultures from spinal cord contained 30% GC+ cells, increasing to 90% after 7 days in culture. In cultures derived from cerebra the percentage of GC+ cells was always lower than in cultures from spinal cord. In cerebral cultures GFAP+ cells increased from 15% at 1 day in culture to 30% at 7 days in culture, whereas it remained low in spinal cord cultures. The activity of oligodendroglial marker enzyme 2',3'-cyclic-nucleotide 3'-phosphodiesterase was followed during development in culture. The specific activity increased rapidly in both types of culture but was more than threefold higher in cultures derived from spinal cord. This procedure yields, within one week and without subculture, primary glial cultures from rat spinal cord, that are highly enriched in oligodendrocytes (greater than or equal to 90%; 3.10(5) oligodendrocytes per rat pup).

Gliogenesis in organotypic tissue culture of the spinal cord of the embryonic mouse. I. Immunocytochemical and ultrastructural studies

The technique of organotypic tissue culture offers an opportunity to observe in vitro complex interactions among glial cells and neurons, leading to the formation of myelin. In the present and accompanying work a combined ultrastructural, immunocytochemical and autoradiographic approach was used in a detailed study of the process of gliogenesis. Using immunocytochemical and ultrastructural criteria, differentiation along the oligodendroglia cell line is seen to be initiated a few days later than along the astroglial line. The sequence and timing of oligodendroglial differentiation both ultrastructurally and chemically follow those described in vivo. Formation of myelin has been demonstrated only by oligodendrocytes in which there is continuity between the perikaryal plasmalemma and myelin membranes. Oligodendroglial maturation culminated with the formation of light, medium and dark oligodendrocytes. The periodic acid Schiff-positive, glial fibrillary acidic protein (GFAP)-negative process of radial glial cells at explantation become GFAP-positive within 3 days, as described in vivo. Many of the astrocytes appear to have been derived from radial glial cells. Large numbers of dark glial cells, similar to the so-called 'intermediate glial cells', were seen. These were found to be astrocytes whose appearance probably reflected reaction to explantation-induced injury.