Quantitative morphological analysis of embryonic cockroach (Periplaneta americana) brain neurons developing in vitro.

Neurons dissociated from the brain of embryonic cockroaches (Periplaneta americana) can be maintained in culture for several weeks. The survival as well as the progressive organization of the neurons into a complex network was studied during a 5-week period under different culture conditions. About 10% of the dissociated cells adhered to the culture dish. This figure remained constant throughout the culture. The cell diameter ranged from 10 to 20 microns and did not change significantly over time in culture. Whereas only a few cells exhibited neurites at the start of the culture, the number of cells exhibiting neurites increased to reach about 99% after 2 weeks. The different cells were then connected to each other, forming a network, which became more and more complex. The number of cells per cluster as well as the length and the diameter of the "connectives" that linked the different clusters were found to increase with time. The morphology of individual neurons within the network was visualized after intracellular injection of biocytin. Labeling with antibodies raised against serotonin or GABA indicated that neurons were able to differentiate and to acquire specific neurotransmitter fates. The serotonergic phenotype was found to appear progressively throughout the culture, in parallel with the formation of the network. Cell density, addition of fetal calf serum, and ecdysone were shown to influence the development of the network.

Selectivity of the major histocompatibility complex class II presentation pathway of cortical thymic epithelial cell lines.

Major histocompatibility complex (MHC) restriction of the immune response is established during positive selection of T cells in the thymus. This occurs mainly through interactions of T cell receptor of developing thymocytes with MHC/peptide ligands on cortical thymic epithelial cells (TEC). An ongoing controversy concerns the origin and the role of peptides involved in the positive selection of thymocytes. Evidence provided here shows that processing of MHC class II complexes in cortical TEC differs from that of medullary TEC. Removal of the invariant chain associated with MHC class II complexes was rapid and complete in medullary TEC which present peptides from both exogenous and cytosolic origin. In cortical TEC, a large fraction of class II dimers remained associated with a 10-12-kDa fragment of invariant chain (Ii). Incomplete removal of Ii correlated with the inability of cortical TEC to present peptides from exogenous origin. However, presentation of peptides from cytosolic proteins by cortical TEC remained possible. Thus, most peptides from exogenous proteins may be excluded from participating in positive selection of CD4+ T cells by a mechanism limiting Ii breakdown.