Identification of functional cAMP-dependent protein kinase in a 'neurite minus' mouse neuroblastoma cell line

We have characterized and quantitated the level of cAMP-dependent protein kinase in the NS-20, N1E-115, N-18 and N1A-103 mouse neuroblastoma clonal cell lines, and we have correlated the occurrence of functional cAMP-dependent protein kinase with the dibutyryl cAMP-induced differentiated functions in these cells. Our results demonstrate the presence of functional cAMP-dependent protein kinase in extracts of all four cell lines examined, including the 'neurite minus' N1A-103 cell line. Dibutyryl cAMP induced neurite outgrowth and acetylcholinesterase activity in the NS-20, N1E-115 and N-18 neuroblastoma cell lines, but not in the N1A-103 cell line. However, dibutyryl cAMP caused a 2-3-fold increase in the R1 regulatory subunit protein and cAMP-phosphodiesterase activity in the 'neurite minus' N1A-103 cells in a manner similar to that of the other three 'neurite positive' cell lines. These results suggest that the biochemical lesion(s) subserving the neurite-minus phenotype of the N1A-103 cells may be distal to the activation of cAMP-dependent protein kinase and is in a biochemical pathway distinct from the induction of R1 regulatory subunit protein and cAMP-phosphodiesterase activity.     

Tumor Necrosis Factor-α (TNF-α), Interferon-γ, and Interleukin-6 but Not TNF-β Induce Differentiation of Neuroblastoma Cells: The Role of Nitric Oxide

Abstract: Tumor necrosis factor-a (TNF-α), interferon-γ (IFN-7), and interleukin-6 (IL-6), but not TNF-β, can induce the in vitro differentiation of the neuroblastoma cell line N103 in a dose-dependent manner. Differentiation of N103 was accompanied by the arrest of cell growth and neurite formation. The induction of neuroblastoma cell differentiation by TNF-α and IFN-γ can be specifically inhibited by a nitric oxide (NO) synthase inhibitor, l -N^G-monomethylarginine. In contrast, the differentiation of N103 cells by IL-6 was not affected by l -N^G-monomethylarginine. These results indicate that TNF-α and IFN-γ, but not IL-6, induce the differentiation of neuroblastoma cells via NO. This is confirmed by the finding that the culture super- natants of N103 cells induced by TNF-α and IFN-γ, but not that by IL-6, contained high levels of NO₂⁻, the production of which was inhibited by l - N ^G-monomethylarginine. Furthermore, the differentiation of N103 cells can be induced directly in a dose-dependent manner by the addition of nitroprusside, a generator of NO, into the culture medium. These data therefore indicate that NO may be an important mediator in the induction of neuronal cell differentiation by certain cytokines such as TNF-α and IFN-γ and that neuronal cells, in addition to the macrophagelike brain cells, can be induced by immunological stimuli to produce large quantities of NO.     

Stimulation of Neurite Outgrowth in Neuroblastoma Cells by Neuraminidase: Putative Role of GM1 Ganglioside in Differentiation

Treatment of three neuroblastoma cell types in culture with neuraminidase resulted in enhanced neurite outgrowth. These included the mouse Neuro-2A and rat B104 and B50 lines. The morphological changes depended on the presence of exogenous Ca2+ and were accompanied by modest but statistically significant increases in 45Ca2+ influx. Neuraminidase-stimulated neuritogenesis was blocked by the B subunit of cholera toxin (cholera B) and anti-GM1 antibody, a finding suggesting the effect was due to an increased amount of GM1 on the cell surface. Cholera B also blocked the increase in 45Ca2+ influx. The mouse N1A-103 line, previously characterized as "neurite minus," did not respond to neuraminidase with either neurite outgrowth or enhanced Ca2+ influx. These results point to an influence of GM1 on neuritogenesis in cells with differentiation potential and suggest a mechanism involving modulation of Ca2+ flux.     

Biochemical differentiation of a murine ganglioneuroblastoma in tissue culture

A cell line derived from a murine ganglioneuroblastoma has been established in tissue culture. The highly refractile cells have round bodies and develop small processes. Their division time is 36 h under the conditions used. When the cells are grown to high densities, the acetyl cholinesterase activity increases four-fold, and is not affected by nerve growth factor. The behavior of this cell line was compared with C-1300, a murine neuroblastoma that has been cultured in many laboratories. These studies reveal three common features of the two tumors: (1) morphologic appearance in vitro does not correlate with appearance in vivo; (2) both tumors retain the ability to differentiate under appropriate conditions; and (3) biochemical differentiation can be expressed independent of morphology.     

Outcome of the p53-mediated DNA damage response in neuroblastoma is determined by morphological subtype and MYCN expression

Background: MYCN oncogene amplification occurs in 20-25% of neuroblastoma and is associated with a poor prognosis. We previously reported that MYCN amplified (MNA) p53 wild-type neuroblastoma cell lines failed to G1 arrest in response to irradiation, but this could not be attributed to MYCN alone. Hypothesis: Genes co-amplified with MYCN and/or the predominant cell type, neuronal (N) or substrate adherent (S) phenotypes determine the downstream response to DNA damage in neuroblastoma cell lines. Methods: The MYCN amplicons of five MNA and two non-MNA cell line were mapped using 50K Single Nucleotide Polymorphism (SNP) arrays. One MNA (NBL-W) and one non-MNA neuroblastoma cell line (SKNSH) were sub-cloned into N and S-type cells and the p53 pathway investigated after irradiation induced DNA damage. To determine the role of p53 it was knocked down using siRNA. Results: No genes with a potential role in cell cycle regulation were consistently co-amplified in the MNA cell lines studied. High MYCN expressing NBLW-N cells failed to G1 arrest following irradiation and showed impaired induction of p21 and MDM2, whereas low MYCN expressing NBLW-S cells underwent a G1 arrest with induction of p21 and MDM2. Conversely N type cells underwent higher levels of apoptosis than S type cells. Following p53 knockdown in SHSY5Y N-type cells there was a decrease in apoptosis. Conclusions: The downstream response to DNA damage in p53 wild-type neuroblastoma cell lines is p53 dependent, and determined both by the morphological sub-type and MYCN expression.     

Metabolism of two Go alpha isoforms in neuronal cells during differentiation

We have previously shown that undifferentiated N1E-115 neuroblastoma cells express only one isoform of Go alpha (pI = 5.8), whereas differentiated neuroblastoma cells expressed, in addition to this isoform, another Go alpha with a more acidic pI (5.55). Moreover, primary cultures of cerebellar granule cells, which are extremely well differentiated cells yielding a high density of synapses, expressed only a single Go alpha isoform with a pI of 5.55 (Brabet, P., Pantaloni, C., Rodriguez Martinez, J., Bockaert, J., and Homburger, V. (1990) J. Neurochem. 54, 1310-1320). In this report, using biosynthetic labeling with [35S]methionine and specific quantitative immunoprecipitation with a polyclonal antibody raised against the purified Go alpha protein, we have determined 1) the degradation rate of total Go alpha (sum of the two isoforms) in differentiated as well as in undifferentiated neuroblastoma cells and in cerebellar granule cells, 2) the degradation rates of each isoform in differentiated neuroblastoma cells. The t 1/2 for total Go alpha protein degradation was very different in the three neuronal cell populations and was 28 +/- 5 h (n = 5), 58 +/- 9 h (n = 5), and 154 +/- 22 h (n = 6) in undifferentiated, differentiated neuroblastoma, and granule cells, respectively. Using two-dimensional gel analysis of immunoprecipitates, we have also determined the individual t 1/2 for degradation of each Go alpha isoform in differentiated neuroblastoma cells, in which the two Go alpha isoforms were expressed. Results indicated that the two Go alpha isoforms exhibit similar t1/2 for degradation (49 +/- 5 h, n = 3). Thus, the t1/2 for degradation of the more basic Go alpha isoform is higher in differentiated neuroblastoma cells (49 +/- 5 h, n = 3) than in undifferentiated neuroblastoma cells (28 +/- 5 h, n = 5) which expressed only the more basic Go alpha isoform. It can be concluded that the degradation rate of the more basic Go alpha isoform is not a characteristic of the protein itself but depends on the state of the cell differentiation. The comparison between the t1/2 for degradation of the more acidic Go alpha isoform is differentiated neuroblastoma cells (51 +/- 6 h, n = 3) with that of cerebellar granule cells (154 +/- 22 h, n = 6) suggests that there is also a decrease in the degradation rate of the more acidic Go alpha isoform during differentiation.(ABSTRACT TRUNCATED AT 400 WORDS)     

Neuroblastoma Differentiation Involves the Expression of Two Isoforms of the α-Subunit of Go

The regulation of GTP-binding proteins (G proteins) was examined during the course of differentiation of neuroblastoma N1E-115 cells. N1E-115 cell membranes possess three Bordetella pertussis toxin (PTX) substrates assigned to alpha-subunits (G alpha) of Go (a G protein of unknown function) and "Gi (a G protein inhibitory to adenylate cyclase)-like" proteins and one substrate of Vibrio cholerae toxin corresponding to an alpha-subunit of Gs (a G protein stimulatory to adenylate cyclase). In undifferentiated cells, only one form of Go alpha was found, having a pI of 5.8 Go alpha content increased by approximately twofold from the undifferentiated state to 96 h of cell differentiation. This is mainly due to the appearance of another Go alpha form having a pI of 5.55. Both Go alpha isoforms have similar sizes on sodium dodecyl sulfate-polyacrylamide gels, are recognized by polyclonal antibodies to bovine brain Go alpha, are ADP-ribosylated by PTX, and are covalently myristylated in whole N1E-115 cells. In addition, immunofluorescent staining of N1E-115 cells with Go alpha antibodies revealed that association of Go alpha with the plasma membrane appears to coincide with the expression of the most acidic isoform and morphological cell differentiation. In contrast, the levels of both Gi alpha and Gs alpha did not significantly change, whereas that of the common beta-subunit increased by approximately 30% over the same period. These results demonstrate specific regulation of the expression of Go alpha during neuronal differentiation.     

Regulation of p27 in the process of neuroblastoma N2A differentiation

Neuronal differentiation implies morphological and biochemical changes to generate a specialized neuron. N2A neuroblastoma cells can be promoted to undergo differentiation associated to neurites outgrowth, a process linked to the arrest of cell division. Using N2A cells as a model, we investigated the detailed molecular aspects on the involvement of p27 in dibutyryl cAMP-induced neuronal differentiation. In the undifferentiated N2A phenotype, an unusually high level of accumulated p27 protein mass was evidenced. Data suggest that in proliferating cells, p27 could be sequestered by direct interaction with cyclin D1, thus preventing its inhibitory action on cell cycle Cdks. Studies also indicate that p27 is functionally active and that its loss of action on Cdks in proliferating cells is due to its strong association with cyclin D1. Therefore, when cell differentiation is triggered, the action of p27 on Cdks seems to depend on both p27 and cyclin D1 degradation during the early steps of differentiation followed by late events of re-synthesis of active p27. In this context, an overexpression of p27 after N2A transfection with a mouse p27 clone induces the outgrowth of neurites associated with a decrease in cyclin D1 expression. On the other hand, treatment of N2A undifferentiated cells with c-myc antisense oligonucleotides led to a decrease in p27 and cyclin D1 levels, similar events as those in early stages of cell differentiation. Studies suggest that blockage in c-myc expression triggers early events in neuronal differentiation. These studies are of the utmost importance to elucidate regulatory mechanisms of molecules that play a critical role in the transition from a proliferating phenotype to differentiated cells.     

Transition between isozymic forms of enolase during in vitro differentiation of neuroblastoma cells—II

An analysis of enolase expression during differentiation of neuroblastoma clones in homogeneous culture is presented. The enolases expressed in these neuroblast-like cells are identical to those of mouse brain with respect to the examined properties.Our biochemical investigation has premitted us to demonstrate formally that neuroblastoma cells undergo a transition from the embryonic αα form to the neuronal γγ form and contain both enolases as well as the αγ hybrid form during maturation. These results suggest that the same phenomenon must exist in vivo for neuroblasts. In neuroblastoma cells, an increase in both αγ and γγ neuron specific enolases is related to cell maturation and expression of the αγ form precedes that of the γγ form during differentiation. Modulation of neuronal enolase activities is similar in the various conditions of differentiation studied and appears not to be necessarily related with morphological differentiation, although concomitant with an arrest of cell division. The evolution of specific neuronal enolases in neuroblastoma cells parallels that observed in vivo, in brain from embryonic day 15 to post-natal day 7. Moreover, at least one treatment (dimethylsulfoxide) causes an important decrease in the high specific αα activity of these cells as occurs in vivo. This enolase can therefore also be considered as a biochemical marker for neuroblastoma maturation.As observed with other markers and other cell types, neuroblastoma cells in culture express an immature biochemical differentiation of the enolase isozymes.     

Differential effects of tumor necrosis factor on the growth and differentiation of neuroblastoma and glioma cells

We have studied the effect of tumor necrosis factor (TNF-alpha) on transformed neural and glial-derived cell lines. TNF-alpha at physiological doses was able to arrest the growth and inhibit DNA synthesis of N103 neuroblastoma cells. This phenomenon was accompanied by a morphological cell differentiation characterized by the outgrowth of neurites. By contrast, TNF-alpha induced an increase in the growth rate of C6 glioma cells and upon cytokine addition a higher number of C6 cells were found in the S + G2 phase of the cell cycle. C6 cells did not show morphological changes under this treatment. Analogous results were obtained with IFN-gamma. These neurotrophic and mitogenic effects of TNF-alpha suggest a putative role of this cytokine in the regeneration of brain tissue upon brain injury.     

ASK1 resistant neuroblastoma is deficient in activation of p38 kinase

Apoptosis Signal-regulating Kinase 1 (ASK1) is known to either induce apoptosis or differentiation in various cell lines of neuronal origin. We analyzed the effect of the constitutively active mutant of ASK1 (ASK1-Delta N) in an adenoviral vector in four neuroblastoma cell lines, two murine, C1300 and NXS2, and two human, SH-SY5Y and IMR-32. Already after 24 h upon infection, C1300 and SH-SY5Y cells arrested in growth when judged by [(3)H]thymidine incorporation, and the majority of the cells demonstrated apoptotic appearance, which was confirmed by DNA-laddering in gel electrophoresis. In contrast, NXS2 and IMR-32 cell lines remained unaffected. Immunoblotting revealed strongly phosphorylated p38 MAPK accompanied by weakly phosphorylated JNK in C1300 and SH-SY5Y, whereas none of these kinases were activated by adenoviruses expressing the kinase negative ASK1 mutant or beta-galactosidase. There was no expression of phosphorylated kinases in IMR-32 cells, but NXS2 showed a faint band of phosphorylated p38 MAPK. Addition of the p38 MAPK specific inhibitor, SB203580, protected C1300 and SH-SY5Y cells from apoptosis induced by ASK1-Delta N. The anti-neoplastic agent, paclitaxel, activates ASK1 and JNK, and promotes the in vitro assembly of stable microtubules. Addition of 10 nM paclitaxel sensitised the NXS2 cell line to ASK1-induced cell death. Our results indicate that ASK1 induces apoptosis in neuroblastoma cells mainly via the p38 MAPK pathway, and resistant neuroblastoma cells can be sensitised to ASK1 by paclitaxel.     

Neurite Extension and Increased Expression of R1 Cyclic AMP-Binding Protein in Ouabain-Resistant Neuroblastoma Mutants

Morphological and biochemical parameters of neuroblastoma differentiation were assessed in 12 clonal derivatives of the N-18 mouse neuroblastoma cell line selected for their ouabain-resistant (ouar) property. When cultured in a normal growth medium, nine of the 12 ouar cell lines exhibited a more complex pattern of neurite outgrowth than the parental N-18 cells. The morphological pattern most frequently observed with the ouar cells was the extension of several branched processes per cell. This pattern of spontaneous neurite outgrowth in the ouar cell lines can be correlated with an increase in expression of the 47,000-dalton RI cyclic AMP (cAMP)-binding protein. The growth rate, intracellular level of cAMP, and acetylcholinesterase activity of the ouar cell lines were not significantly different from those of the parental N-18 neuroblastoma cells. Treatment of the parental and ouar neuroblastoma cell lines with 1 mM N6, O2-dibutyryl cAMP promoted an elaborate pattern of neurite outgrowth and marked increases in acetylcholinesterase and RI cAMP-binding activities. The distinctive pattern of differentiation phenotype exhibited by the ouar cells and the dibutyryl cAMP-induced differentiated neuroblastoma cell suggests that these two protocols yielded different degrees of differentiation. Furthermore, our results suggest a linkage of the biochemical events underlying ouabain resistance and expression of differentiation phenotypes in the mouse neuroblastoma cells.     

Tubulin constancy during morphological differentiation of mouse neuroblastoma cells

Clonal cell lines N18 and N103 of the mouse neuroblastoma C1300 possess an undifferentiated neuroblast morphology under optimal growth conditions; however, when deprived of serum, N18 can be induced to extend long neurites. Although initial neurite outgrowth is rapid, very long fibers are found only after several days. Both initial outgrowths and established neurites contain microtubules; however, the number and density of these polymerized tubules increase markedly during this time. Optimum conditions have been established for assessing the colchicine-binding activity of neuroblastoma sonicates. A time-decay colchicine-binding assay was used to make a comparative study of the tubulin content of both undifferentiated and differentiated N18 as well as the nondifferentiating N103 and the rat glioma C6. Both morphologies of clone N18 possessed similar concentrations of tubulin (130-140 pmol/10(6) cells). Although cells of clone N103 contain 20% less tubulin than N18 cells, this is considerably more tubulin than is present in the glioma C6 (30 pmol/10(6) cells) which has a similar generation time. Quantitative densitometry of neuroblastoma extracts electrophoresed on SDS-polyacrylamide gels confirmed the constancy of tubulin. Radiolabeled proteins from neuroblastoma cells subjected to both growth conditions show that neurite outgrowth does not create a disproportionate demand for tubulin synthesis. Thus, the morphological differentiation of neuroblastoma cells probably reflects the regulation of tubulin storage and microtubule polymerization.     

The specific inhibitor of protein kinase C, 1-(5-isoquinolinylsulfonyl)-2-methylpiperazine (H7), induces morphological change and cell differentiation of human neural crest-derived cell lineages

It has been proved that inhibition of protein kinase C by 1-(5-isoquinolinylsulfonyl)-1-methylpiperazine (H7) induces morphological differentiation in murine neuroblastoma (nb) cell. Here we report that H7 is also active on human nb cell lines. The human nb cell had originally neuroblast-like (N) or intermediate (I) morphology. N and I type are thought to represent different stages of neuroblastoma differentiation. Neurite outgrowth was observed in N and I type morphology treating the cells with 7, 14 or 28 microM of H7. The results confirm previous observations and show that inhibition of PKC by H7 also promotes neuronal differentiation in human cell line variants.     

Induction of K-channel expression in a neuroblastoma cell line

Whole-cell currents were examined in mouse neuroblastoma cells of the N2AB-1 line. In standard culture medium, N2AB-1 cells exhibited large voltage-dependent Na currents but no discernible K currents. Treatment of N2AB-1 cells with either dimethylsulfoxide (DMSO) in low-serum medium or with retinoic acid (RA) caused the expression of delayed rectifier K currents. Currents from two types of K channel with single channel slope conductances of 15.0 pS and 6.4 pS were observed in outside-out patches from cells of both treatment groups. Thus, while N2AB-1 cells did not exhibit K currents under standard culture conditions, they did possess the gene(s) encoding K channels. The treatments caused other changes that were not directly linked to K-channel expression. RA treatment caused neurite extension in most, but not all, N2AB-1 cells; however, all RA-treated cells, including those without neurites, expressed K currents. RA treatment did not suppress cell division or cause hypertrophy. In contrast, treatment with DMSO/low serum suppressed cell division and caused cellular hypertrophy, but did not cause long neurites to form. Thus, the regulation of K channels was not coupled in a simple fashion to properties that have been associated with a differentiated neuronal phenotype: neurite elaboration, changes in cell size, and inhibition of cell division. These results suggest that N2AB-1 cells may be a good model system for investigating the processes regulating K-channel expression.     

Receptor for advanced glycation end products (RAGE) signaling induces CREB-dependent chromogranin expression during neuronal differentiation

Receptor for advanced glycation end products (RAGE) mediates neurite outgrowth and cell migration upon stimulation with its ligand, amphoterin. We show here that RAGE-dependent changes in cell morphology are associated with proliferation arrest and changes in gene expression in neuroblastoma cells. Chromogranin B, a component of secretory vesicles in endocrine cells and neurons, was found to be up-regulated by RAGE signaling during differentiation of neuroblastoma cells along with the two other members of the chromogranin family, chromogranin A and secretogranin II. Ligation of RAGE by amphoterin lead to rapid phosphorylation and nuclear localization of cyclic AMP response element-binding protein (CREB), a major regulator of chromogranin expression. Furthermore, inhibition of ERK1/2-Rsk2-dependent CREB phosphorylation efficiently inhibited up-regulation of chromogranin gene expression upon RAGE activation. To further study the effects of RAGE and amphoterin on cellular differentiation, we stimulated embryonic stem cells expressing RAGE or a signaling-deficient mutant of RAGE with amphoterin. Amphoterin was found to promote RAGE-dependent neuronal differentiation of embryonic stem cells characterized by up-regulation of neuronal markers light neurofilament protein and beta-III-tubulin, activation of CREB, and increased expression of chromogranins A and B. These data suggest that RAGE signaling is capable of driving neuronal differentiation involving CREB activation and induction of chromogranin expression.     

Morphological differentiation of neuroblastoma cells induced by dimethylsulfoxide

Morphological features of neuroblastoma cells grown in culture in the presence of dimethylsulfoxode (DMSO) were studied. Morphological differentiation, expressed as the appearance of long axon-like processes (neurites), an increase in size of the cells, and inhibition of cell division, was observed in neuroblastoma cells of line C 1300, subline N-18-TG₂A₁, incubated in medium containing 1% DMSO. In the early stages of culture in normal growth medium the cells possess primary features of morphological differentiation. Quantitative criteria for the development of these features depending on duration of culture in modified medium were worked out. An increase in the total length of the neurites of cells differentiating under the influence of DMSO is a linear function of time. The rate of growth of the neurites is 20.0±3.0 µ/h. The area of cross-section of the soma of the differentiated cells is 6–7 times greater than the corresponding parameter in the control. An increase in the DMSO concentration in the culture medium (1.5 and 2.0%) does not induce rapid growth of the neurites or an increase in size of the cell soma, but it does block mitosis. Characteristics of morphological differentiation of neuroblastoma cells are compared with probable functional changes in these cells.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 16, No. 4, pp. 519–527, July–August, 1984.