Using clonal cell lines isolated from murine neuroblastoma C1300, we investigated the mitochondrial changes related to neuronal differentiation and, more generally, the role played by the mitochondrion in this phenomenon. By different approaches (measurement of the mitochondrial mass, immunoquantification of specific mitochondrial proteins, or incorporation of Rhodamine 123), the differentiation of the inducible clone, N1E-115, was found associated with an important increase of the cellular content in mitochondria. This increase could be observed with differentiating N1E-115 cells maintained in suspension, i.e. under conditions where neurite outgrowth is prevented but other early stages of (biochemical) differentiation continue to occur. That these mitochondrial changes are likely to be correlated with these stages of neuronal differentiation, rather than with simple progression to the postmitotic stage, stems from comparative experiments with clone N1A-103, a neuroblastoma cell line variant that becomes postmitotic after induction but fails to differentiate and shows no modification in its cellular content in mitochondria. In accordance with these observations, chloramphenicol prevents differentiation when added together with the inducer. This effect is probably related to the inhibition of mitochondrial translation rather than to modification of the bioenergetic needs because oligomycine, a potent inhibitor of the mitochondrial ATP synthetase, shows no effect on neurogenesis. As a working hypothesis and in keeping with independently published models, we postulate that products resulting from mitochondrial translation could be involved in the organization of the cytoskeleton or of certain membrane components whose rearrangements should be the prerequisite or the correlates to early stages of neuronal differentiation.
Peripherin (formerly the Y protein) is found in the peripheral nervous system. This Triton-insoluble protein is characterized by its isoelectric point (5.6), its apparent molecular weight (56,000 daltons) and its peptidic map. Peripherin was also observed in a mouse neuroblastoma cell line, NIE 115, where its expression appeared regulated by the presence of an inducer of morphological differentiation. In order to analyze more precisely this control, the presence of peripherin was investigated in several neuroblastoma cell lines which exhibit different morphological patterns of differentiation and in the rat pheochromocytoma PC 12 cell line. Differentiation of these cells was induced with 1-methylcyclohexane carboxylic acid (CCA) and nerve growth factor (NGF), respectively. Peripherin was found in these different cell lines. Moreover, the cellular amount of peripherin appraised by [35S]-methionine incorporation was significatively increased in differentiated cells. In contrast, other cytoskeletal components did not undergo a similar raise. The level at which the control of the peripherin content takes place was studied in a cell-free translation system. Poly(A)-rich RNAs extracted from growing or differentiated NIE 115 cells directed the synthesis of similar amounts of peripherin in a reticulocyte lysate. In contrast, polysomes prepared from differentiated cells and the corresponding polysomal RNA programmed in vitro the synthesis of twice more peripherin than polysomes or polysomal RNA from growth-phase cells. Since peripherin synthesis is enhanced 5 times in living cells, it seems probable that the cellular amount of peripherin is controlled partly at the translational level and partly at the turn-over level.
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