Differentiation-associated apoptosis of neural stem cells is effected by Bcl-2 overexpression: impact on cell lineage determination.

Apoptosis is an integral part of neural development. To elucidate the importance of programmed cell death on cell lineage determination we utilized murine PCC7-Mzl cells, a model system for neural differentiation. Treatment of pluripotent PCC7-Mzl stem cells with 0.1 microM all-trans retinoic acid (RA) causes a cease of proliferation and an initiation of differentiation into neurons, glial cells and fibroblasts. Simultaneously, a fraction of the cell culture (ca. 25%) dies within 24 h by apoptosis. We transfected PCC7-Mzl cells with the human bcl-2 cDNA and generated PCC7-Mz-Bcl-2 cell lines expressing two- to tenfold higher levels of Bcl-2 than parental cells. Overexpression of Bcl-2 resulted in hypophosphorylation of the retinoblastoma (Rb) protein and consequently prolonged the doubling time of the culture from 18 h to 23 h. RA-induced apoptosis was drastically reduced to 3 to 15% depending on the level of Bcl-2 expression. RA-induced caspase activation, cytochrome c release from the mitochondria to the cytosol and DNA fragmentation was completely blocked. Furthermore, treating Bcl-2 cultures with ceramide (10 microM), a second messenger mediating the RA-initiated death signal in parental cells, no longer caused DNA laddering. Bcl-2 overexpression did not interfere with the potential of PCC7-Mz cells to develop into neurons, glial cells and fibroblasts. However, the relative distribution of cell types in the culture was shifted such that the fraction of neurons was reduced to half (from 60 to 30%) with a concomitant increase in the number of glial and fibroblastoid cells. Furthermore, Bcl-2-overexpressing neurons, but not neurons of parental or mock-transfected PCC7-Mzl cultures, were able to grow as single cells.

Production of ceramides causes apoptosis during early neural differentiation in vitro.

To investigate signal transduction pathways leading to apoptosis during the early phase of neurogenesis, we employed PCC7-Mz1 cells, which cease to proliferate and begin to differentiate into a stable pattern of neurons, astroglial cells, and fibroblasts upon incubation with retinoic acid (RA). As part of lineage determination, a sizable fraction of RA-treated cultures die by apoptosis. Applying natural long-chain C(16)-ceramides as well as membrane-permeable C(2)/C(6)-ceramide analogs caused apoptosis, whereas the biologically nonactive C(2)-dihydroceramide did not. Treating PCC7-Mz1 stem cells with a neutral sphingomyelinase or with the ceramidase inhibitor N-oleoylethanolamine elevated the endogenous ceramide levels and concomitantly induced apoptosis. Addition of RA caused an increase in ceramide levels within 3-5 h, which reached a maximum (up to 3.5-fold of control) between days 1 and 3 of differentiation. Differentiated PCC7-Mz1 cells did not respond with ceramide formation and apoptosis to RA treatment. The acidic sphingomyelinase contributed only weakly and the neutral Mg(2+)-dependent and Mg(2+)-independent sphingomyelinases not at all to the RA-mediated production of ceramides. However, ceramide increase was sensitive to the ceramide synthase inhibitor fumonisin B(1), suggesting a crucial role for the de novo synthesis pathway. Enzymatic assays revealed that ceramide synthase activity remained unaltered, whereas serine palmitoyltransferase (SPT), a key enzyme in ceramide synthesis, was activated approximately 2.5-fold by RA treatment. Activation of SPT seemed to be mediated via a post-translational mechanism because levels of the mRNAs coding for the two SPT subunits were unaffected. Expression of marker proteins shows that ceramide regulates apoptosis, rather than differentiation, during early neural differentiation.

The protein kinase C (PKC) substrate GAP-43 is already expressed in neural precursor cells, colocalizes with PKCeta and binds calmodulin.

Expression of the growth-associated protein of 43-kDa (GAP-43), which is described as a postmitotic, neuron-specific major protein kinase C (PKC) substrate, was investigated in the murine embryonic carcinoma cell line PCC7-Mz1 which develops into a brain-tissue-like pattern of neuronal, fibroblast-like and astroglial cells upon stimulation with all-trans retinoic acid (RA). GAP-43 expression was very low in stem cells, but increased on mRNA and protein level within the 12 h after differentiation was initiated. While the P1 promoter of the GAP-43 gene gave rise to a 1.6-kb mRNA and was already active at a very low level in PCC7-Mz1 stem cells, transcription of the P2 promoter, which resulted in a 1.4-kb mRNA, was completely blocked in stem cells but increased rapidly after RA treatment. Within the first 2 days of neural differentiation, GAP-43 was localized with the cytoplasmic membrane and the Golgi complex of proliferating neural precursor cells. Then, GAP-43 was translocated to the growth cones and neurites, and from day 6, when neurons began to acquire polarity, the protein was found in the axons. GAP-43 was never detected in the non-neuronal PCC7-Mz1 derivatives, i.e. in fibroblasts or glial cells. In the foetal rat brain (prenatal day F11), GAP-43 was expressed in the optic stalk, the lense plakode and in the postmitotic neurons of the marginal zone of the hindbrain. Moreover, in a layer between the ventricular and marginal zone of the hindbrain (F13) and forebrain (F15), GAP-43 was already expressed in mitotic neural precursor cells. In PCC7-Mz1 cultures, 2 days after addition of RA, GAP-43 became phosphorylated upon activation of PKC, and colocalized specifically with the novel PKC isoform eta. Phosphorylation of GAP-43 caused a disruption of its complex with calmodulin. These data demonstrate that GAP-43 is already a functional PKC substrate in prolific neuronal precursor cells, and may participate in neuronal cell lineage determination.

Retinoic acid induces apoptosis-associated neural differentiation of a murine teratocarcinoma cell line.

Incubation with all-trans retinoic acid (RA) induces PCC7-Mz1 embryonic carcinoma cells to cease proliferation and to develop into a tissue-like pattern of neuronal, astroglial, and fibroblast-like derivatives over a period of several days. Concomitant with the induction of differentiation by RA, a sizable fraction of the Mz1 stem cells detaches and dies, with the maximal level of cell death achieved after 10 h of RA treatment. This RA-induced cell death fulfills all criteria of apoptosis, including nuclear condensation, intranucleosomal DNA degradation, expression of cysteine aspases (caspases), and the formation of apoptotic bodies. Apoptosis could be suppressed by the pan-caspase inhibitor zVAD-fmk (benzyloxycarbonyl-valinyl-alaninyl-aspartyl fluoromethyl ketone). Induction of apoptosis required at least 2 h of incubation with RA and followed the same RA concentration (EC50 = 10(-7) M RA) and time dependence as the induction of differentiation as delineated by the expression of the neuron-specific protein kinase C substrate GAP-43. RA-induced apoptosis increased with the plating density of PCC7-Mz1 cells. This effect was not due to deprivation of an essential nutrient or factor from the medium because apoptosis was not significantly affected by an increase of the concentration of fetal calf serum. In addition to RA, apoptosis could be induced by DNA-damaging treatment (UV light, cisplatin, methanesulfonic acid methyl ester) and cell cycle-arresting agents (hydroxyurea) as well as by serum depletion. Because inhibition of transcription and translation caused cell death efficiently even in the presence of serum, the synthesis of apoptosis-inhibiting factors by the cultured cells is indicated. Neither ApoI/Fas antibody nor glutamate induced apoptosis. Mz1 cells that have entered a differentiation pathway in response to RA treatment become increasingly less sensitive to apoptosis. This may be due in part to the expression of the bcl-2 proto-oncogene, which was detectable on the mRNA and protein level beginning 4 days after the addition of RA. The intracellular signaling pathway leading to apoptosis does not involve conventional or novel members of the protein kinase C gene family. Neither activation of protein kinase C by phorbol esters (phorbol 12,13-dibutyrate) nor inhibition by specific inhibitors (GF109203X, Gö 6976) and long-term treatment with phorbol 12,13-dibutyrate, in the presence or absence of RA, significantly influenced the amount or rate of apoptosis of PCC7-Mz1 cells. We conclude that the apoptotic activity following RA treatment of cultured PCC7-Mz1 cells probably is controlled by the same cascade of gene regulatory events that govern the early cell lineage determinations in this in vitro model system of neural development.