DIFFERENTIATION OF NEUROBLASTOMA, GLIOMA, AND HYBRID CELLS IN CULTURE AS MEASURED BY THE SYNTHESIS OF SPECIFIC PROTEIN SPECIES: EVIDENCE FOR NEUROBLAST-GLIOBLAST RECIPROCAL GENETIC REGULATION

Abstract— Protein species from differentiating neuroblastoma, glioma, and hybrid neuroblastoma-glioma cell lines in cell culture were separated and identified initially in the first dimension by the use of isoelectric focusing gels and were further separated in the second dimension by SDS-acrylamide gels. There were two main classes of proteins identified: proteins which were dominantly expressed in neuroblastoma and also in hybrid cell cultures, and proteins which were expressed in glioma and also hybrid cell cultures. In general, proteins were identified which were significantly expressed in neuroblastoma cells and much reduced in glioma cultures, and also conversely so. The hybrid cell line expressed many of the neuroblastoma-type proteins and relatively fewer of the glioma type proteins. A specific protein species (2) was identified in hybrid cells and was not present in either parental neuroblastoma or glioma cultures. Protein z was expressed however by the co-culturing of neuroblastoma and glioma cells suggesting its induction is dependent on a soluble factor. Protein z in hybrid cells was demonstrated in both stained gels and by autoradiography. Chromosome analysis of hybrid cells confirmed the presence of both rat and mouse chromosomes. It is suggested that similar neuronal-glial interaction may be functional in the intact brain, and that similar reciprocal modulation between neurons and glia may be a central mechanism of differentiation in the nervous system.     

PPARbeta agonists trigger neuronal differentiation in the human neuroblastoma cell line SH-SY5Y

Neuroblastomas are pediatric tumors originating from immature neuroblasts in the developing peripheral nervous system. Differentiation therapies could help lowering the high mortality due to rapid tumor progression to advanced stages. Oleic acid has been demonstrated to promote neuronal differentiation in neuronal cultures. Herein we report on the effects of oleic acid and of a specific synthetic PPARbeta agonist on cell growth, expression of differentiation markers and on parameters responsible for the malignancy such as adhesion, migration, invasiveness, BDNF, and TrkB expression of SH-SY5Y neuroblastoma cells. The results obtained demonstrate that many, but not all, oleic acid effects are mediated by PPARbeta and support a role for PPARbeta in neuronal differentiation strongly pointing towards PPAR ligands as new therapeutic strategies against progression and recurrences of neuroblastoma.     

Differentiation of the SH-SY5Y Human Neuroblastoma Cell Line

Having appropriate in vivo and in vitro systems that provide translational models for human disease is an integral aspect of research in neurobiology and the neurosciences. Traditional in vitro experimental models used in neurobiology include primary neuronal cultures from rats and mice, neuroblastoma cell lines including rat B35 and mouse Neuro-2A cells, rat PC12 cells, and short-term slice cultures. While many researchers rely on these models, they lack a human component and observed experimental effects could be exclusive to the respective species and may not occur identically in humans. Additionally, although these cells are neurons, they may have unstable karyotypes, making their use problematic for studies of gene expression and reproducible studies of cell signaling. It is therefore important to develop more consistent models of human neurological disease. The following procedure describes an easy-to-follow, reproducible method to obtain homogenous and viable human neuronal cultures, by differentiating the chromosomally stable human neuroblastoma cell line, SH-SY5Y. This method integrates several previously described methods^1-4 and is based on sequential removal of serum from media. The timeline includes gradual serum-starvation, with introduction of extracellular matrix proteins and neurotrophic factors. This allows neurons to differentiate, while epithelial cells are selected against, resulting in a homogeneous neuronal culture. Representative results demonstrate the successful differentiation of SH-SY5Y neuroblastoma cells from an initial epithelial-like cell phenotype into a more expansive and branched neuronal phenotype. This protocol offers a reliable way to generate homogeneous populations of neuronal cultures that can be used for subsequent biochemical and molecular analyses, which provides researchers with a more accurate translational model of human infection and disease.     

Activity-dependent gene regulation in conditionally-immortalized muscle precursor cell lines

Skeletal muscle contractile activity has been implicated in many aspects of muscle cell differentiation and maturation. Much of the research in this area has depended upon costly and labor-intensive cultures of isolated primary muscle cells because widely available immortalized muscle cell lines often do not display a high level of either spontaneous or stimulated contractile activity. We sought to develop conditionally-immortalized skeletal muscle cell lines that would provide a source of myofibers that exhibit robust spontaneous contractile activity similar to primary muscle cultures. Using a tetracycline-regulated retroviral vector expressing a temperature-sensitive T-antigen to infect primary myoblasts, we isolated individual clonal muscle precursor cell lines that have characteristics of activated satellite cells during growth and rapidly differentiate into mature myotubes with spontaneous contractile activity after culture in non-transformation-permissive conditions. Comparison of these cell lines (known as rat myoblast-like tetracycline (RMT) cell lines) to primary cell cultures revealed that they share a wide variety of morphological, physiological, and biochemical characteristics. Most importantly, the time-course and extent of activity-dependent gene regulation observed in primary cell culture for all genes tested, including subunits of the nicotinic acetylcholine receptor (nAChR), muscle specific kinase (MuSK), and myogenin, is reproduced in RMT lines. These immortalized cell lines are a useful alternative to primary cultures for studying muscle differentiation and molecular and physiological aspects of electrical activity in muscle fibers.     

Differentiation of neuroblastoma cells by chick gizzard extract

Cholinergic neuroblastoma NS20Y cells were differentiated by the chicken gizzard extract. They were first inoculated into a glass culture bottle and the aggregated cells which grew in the suspension culture were collected. The aggregated cells (round and immature neuroblastoma cells) were seeded on a polyornithinecoated plastic dish, and the effect of various agents on the differentiation of the neuroblastoma was investigated. When gizzard extract from chicken was added to the culture, many flat cells with neurites emerged around the cell aggregates within 24 h. The flat cells could evoke action potentials with high frequency (in 70% cells). Cyclic GMP levels in the treated cultures were much lower than that in the control culture, and remained continuously lower during 2 days culture. The factor responsible for the differentiation of neuroblastoma cells was rich in the chick gizzard among extracts or conditioned media from various tissues tested. A similar effect was observed by the addition of dibutyryl cyclic AMP or prostaglandin E₁ plus theophylline over a slower time course. The factor in gizzard extract was trypsin-sensitive and heat-labile. The molecular size was estimated to be about 12 s.     

Deposition of Basement Membrane Proteins in Attachment and Neurite Formation of Cultured Murine C-1300 Neuroblastoma Cells

The deposition of the basement membrane glycoproteins, laminin, fibronectin, and type IV procollagen was studied by indirect immunofluorescence microscopy during the attachment and differentiation of murine C-1300 neuroblastoma cells. A typical cytoplasmic perinuclear staining for the basement membrane antigens was seen both in undifferentiated and differentiated cells. Freshly seeded suspended cells lacked surface fluorescence but in two hours after plating, distinct punctate laminin deposits became discernible on the ventral surface of the cells. Notably, in sparsely seeded undifferentiated cultures, the cell-associated extracellular laminin deposits could only be detected under the primary attaching cells, whereas daughter cells in clonal cell colonies lacked such fluorescence. In cultures induced to neurite formation with dibutyryl cyclic AMP, laminin deposition was also detected in association with the growing cytoplasmic extensions. No distinct differences were found between the secreted proteins of cultures of differentiated and nondifferentiated neuroblastoma cells, but the patterns of fucosylation of high-molecular weight proteins in the two cultures were markedly different. We conclude that cultured neuroblastoma cells both synthesize, secrete and deposit laminin. The distribution of laminin during neuroblastoma cell attachment and neurite extension suggests that this glycoprotein may be involved in cell–to–substratum interactions in C-1300 cell cultures.     

Differentiation, proliferation and adhesion of human neuroblastoma cells after treatment with retinoic acid

Because of the known property of spontaneous regression in stage IVS of neuroblastoma all attempts are made to elucidate whether differentiation inducers possibly could be applied for neuroblastoma therapy. Here we examined the influence of retinoic acid (RA) in vitro on differentiation, proliferation and adhesion of 10 permanent and 4 primary cell lines as well as of several SCID-mouse tumour transplants. In general, after RA treatment morphologically different cell types which are characteristic for neuroblastoma cells have changed. N (neuronal)-type cells prolonged their neuronal processes, whereas S (epithelial, substrate-adherent, Schwann cell-like)-type cells lost their adherence to substratum and became apoptotic. Additionally, the reactions of all neuroblastoma cell lines with monoclonal antibodies against beta-tubulin (for neuronal cells) and glial fibrillary acidic protein (for epithelial cells) were determined. The anti-proliferative effect of all-trans-RA as well as 13-cis-RA was more profound in S-type cells (up to 40% in primary cell lines). To elucidate the role of adhesion molecules during neuronal cell differentiation, we have analysed the adhesion of neuroblastoma cells on poly-D-lysin-precoated plates under RA influence. While N-type cells displayed an increased adhesion, all S-type cell lines as well as all primary cell lines exhibited a reduced adhesion (IMR-5 and IMR-32: p < 0.001; JW, SR and PM: p < 0.05). RA treatment increased predominantly the tested antigens (HCAM, ICAM-1, NCAM, PECAM-1, VCAM-1, cadherin, FGF-R, IGF-R, NGF-R, TGF-beta/1, NF200, NF160, NF68, NSE, HLA-ABC) in all cell lines independently of their phenotypes (TGF-beta/1: p < 0.001; NF68: p < 0.01; PECAM-1 and NGF-R: p < 0.05). In recultured SCID-mouse-passaged tumour cells antigens were down-regulated (FGF-R: p < 0.01), but increased again after RA influence (TGF-beta/1: p < 0.05). In summary, the RA differentiation model demonstrates the possibility to interfere in cell adhesion and to diminish growth potential both in N-type as well as S-type neuroblastoma cells.     

Surface glycosaminoglycans as a differentiation cofactor in neuroblastoma cell cultures.

The possible role of surface glycosaminoglycans (GAGs) in neuronal maturation occuring in neuroblastoma cultures has been investigated. GAGs of neuroblastoma cells, grown in suspension and monolayer, were labelled with 3H-glucosamine and 35S-sulfate. Neuron maturation, following cell adhesion to culture dishes, is accompanied by an increased ability of the cells to retain heparan sulfate (HS) on their surface, which is otherwise lost into the culture medium. The role of surface HS as a cofactor of cellular differentiation is discussed.     

The effects of serine protease inhibitors on morphological differentiation of murine neuroblastoma cells (NB 15)

Morphological differentiation of neuroblastoma cells (NB15) was induced by cAMP effectors in the presence and absence of serine protease inhibitors. In all conditions tested, the percent differentiation was inhibited by protease inhibitors antipain, diisopropylfluorophosphate (DFP), leupeptin, and soybean trypsin inhibitor (SBTI). The level of morphological differentiation obtained in medium containing fetal calf serum was significantly less than the percent differentiation obtained with serum-free medium alone, so serum-free medium was the principal method of induction and comparisons were made to control uninduced cultures or cultures induced with the phospho-diesterase inhibitor R020–1724. Secreted or cell surface caseinolytic protease activity was higher in differentiating cells than in control cultures and was inhibited by the serine protease inhibitors. The effects of the protease inhibitors on growth and differentiation are discussed.     

Noggin maintains pluripotency of human embryonic stem cells grown on Matrigel

Objective:  Spontaneous differentiation of human embryonic stem cell (hESC) cultures is a major concern in stem cell research. Physical removal of differentiated areas in a stem cell colony is the current approach used to keep the cultures in a pluripotent state for a prolonged period of time. All hESCs available for research require unidentified soluble factors secreted from feeder layers to maintain the undifferentiated state and pluripotency. Under experimental conditions, stem cells are grown on various matrices, the most commonly used being Matrigel.
Materials and Methods:  We propose an alternative method to prevent spontaneous differentiation of hESCs grown on Matrigel that uses low amounts of recombinant noggin. We make use of the porosity of Matrigel to serve as a matrix that traps noggin and gradually releases it into the culture to antagonize bone morphogenetic proteins (BMP). BMPs are known to initiate differentiation of hESCs and are either present in the conditioned medium or are secreted by hESCs themselves.
Results:  hESCs grown on Matrigel supplemented with noggin in conditioned medium from feeder layers (irradiated mouse embryonic fibroblasts) retained both normal karyotype and markers of hESC pluripotency for 14 days. In addition, these cultures were found to have increased cell proliferation of stem cells as compared to hESCs grown on Matrigel alone.
Conclusion:  Noggin can be utilized for short term prevention of spontaneous differentiation of stem cells grown on Matrigel.     

In vitro long-term development of cultured inner ear stem cells of newborn rat

The adult mammalian auditory receptor lacks any ability to repair and/or regenerate after injury. However, the late developing cochlea still contains some stem-cell-like elements that might be used to regenerate damaged neurons and/or cells of the organ of Corti. Before their use in any application, stem cell numbers need to be amplified because they are usually rare in late developing and adult tissues. The numerous re-explant cultures required for the progressive amplification process can result in a spontaneous differentiation process. This aspect has been implicated in the tumorigenicity of stem cells when transplanted into a tissue. The aim of this study has been to determine whether cochlear stem cells can proliferate and differentiate spontaneously in long-term cultures without the addition of any factor that might influence these processes. Cochlear stem cells, which express nestin protein, were cultured in monolayers and fed with DMEM containing 5% FBS. They quickly organized themselves into typical spheres exhibiting a high proliferation rate, self-renewal property, and differentiation ability. Secondary cultures of these stem cell spheres spontaneously differentiated into neuroectodermal-like cells. The expression of nestin, glial-fibrillary-acidic protein, vimentin, and neurofilaments was evaluated to identify early differentiation. Nestin expression appeared in primary and secondary cultures. Other markers were also identified in differentiating cells. Further research might demonstrate the spontaneous differentiation of cochlear stem cells and their teratogenic probability when they are used for transplantation.     

Histochemical demonstration of an increase in acetylcholinesterase in established lines of human and mouse neuroblastomas by nerve growth factor.

Cells of three established lines of human neuroblastoma and an established line of C1300 mouse neuroblastoma were grown in control medium or in experimental medium containing mouse nerve growth factor (NGF). Cultures were stained histochemically for acetylcholinesterase (AChE) during log growth and at confluency. Human neuroblastoma cells grown in medium containing NGF were morphologically more differentiated and they were stained much more intensely for AChE during both phases of growth than were cells in control cultures. The enzyme was distributed over cell bodies and neurites. Neuroblastoma cells of the mouse line were not stimulated to form neurites by NGF, but they were more intensely stained for acetylcholinesterase than cells grown in control medium. These observations support earlier findings that NGF stimulates differentiation of human and mouse neuroblastoma cells in vitro.     

Expression of a specific neuronal protein, 14-3-2, during in vitro differentiation of neuroblastoma cells

Expression of the neuronal marker 14-3-2 or NSE (neuron-specific enolase) has been studied during in vitro differentiation of cells in culture. The 14-3-2 protein of neuroblastoma cells is immunologically identical with that found in mouse brain extract. The lack of detectable 14-3-2 in cultures of non-neuronal lines shows that this protein, as has been already shown in vivo, is also a specific marker of neurons in vitro. The presence of 14-3-2 in a differentiated hypothalamic clone—but not in its presumptive precursor—indicates selective initial derepression of 14-3-2. Moreover, modulation of the amount of 14-3-2 already present in dividing neuroblastoma cells is related to the confluent phase of growth or morphological differentiation of neuroblasts. Both mechanisms may be related to the mechanisms underlying initial differentiation and subsequent maturation of neurons in vivo. In dividing neuroblastoma cells modulation of the basal level of 14-3-2 is not necessarily associated with expression of the morphological differentiation, but seems generally concomitant with an arrest of cell division.     

Retinoic acid-induced differentiation of human neuroblastoma: a cell variant system showing two distinct responses

Retinoic acid (RA) has been shown to induce the differentiation of human neuroblastoma cells in vitro. In this study, we describe two variants of the SK-N-SH human neuroblastoma cell line that have dramatically different responses to RA. RA induces neuronal-like differentiation characterized by extensive neurite outgrowth, thick neurite bundles, and large cellular aggregates of SK-N-SH-N (SH-N) cells. In contrast, RA treatment of SK-N-SH-F (SH-F) cultures transforms the small neuroblast cells into large flattened, fibroblastic or epithelial-like cells. Karyotype analysis verified that the SH-N and SH-F cultures were derived from a common precursor cell. Confirmation of their markedly different responses to RA was obtained by metabolic labelling of glycoproteins and SDS-PAGE analysis. While both sublines showed very similar Coomassie-labelled protein bands and glycoprotein profiles in control cultures, dramatic differences between the lines were revealed following RA treatment. In contrast to their similar protein profiles, untreated SH-N and SH-F cells had quite different patterns of ganglioside biosynthesis in that GM3 was detected in SH-F cells but not in SH-N, while GM1 was only detected in SH-N. Cellular RA binding protein (CRABP) was detected in both SH-F and SH-N cells and their RA-transformed derivatives. These results demonstrate heterogeneity in the response to RA of neuroblastoma cells derived from a common origin that cannot be accounted for by differences in CRABP content. The SH-N and SH-F neuroblastoma sublines should provide a useful system for further studies of the molecular processes through which RA exerts its differentiation-inducing activity on this type of tumor.     

Phenotypic differentiation of aphidicolin-selected human neuroblastoma cultures after long-term exposure to nerve growth factor

Human neuroblastoma SH-SY5Y (SY5Y) cultures, exposed to murine 7 S nerve growth factor (NGF) for 5 weeks and selected with aphidicolin (Aph) for 1 week, acquire several properties indicative of mature peripheral nerve cells. The mitotic activity of treated cultures decreases prior to Aph selection and ultimately reaches a level approximately 3% that of untreated cultures by Week 4 of treatment. The measured plasma membrane resting potential of the cells increases from -5 mV for untreated cells to -(45-56) mV for NGF/Aph-treated cells. Intracellular stores of monoamines are increased as determined by histochemical staining, and levels of neuron-specific enolase antigen increase as a result of NGF/Aph treatment. The resulting outgrowth of neurites is extensive and large bundles of processes commonly exceed 300 micron in length. NGF/Aph-treated cells acquire a dependence upon NGF for survival; however, with continued administration of NGF, the cultures appear to be capable of surviving indefinitely. Retinoic acid will also promote certain aspects of a differentiated phenotype under similar culture conditions. As judged by these criteria, cells of the SY5Y human neuroblastoma cell line have the potential for phenotypic and irreversible differentiation in vitro and can survive for prolonged periods under these culture conditions.     

EFFECTS OF ALUMINUM SALTS ON CULTURED NEUROBLASTOMA CELLS

Experimental induction of neurofibrillary tangles was demonstrated several years ago in the central nervous system of rabbits injected with aluminum salts. In the current studies, neuroblastoma cells, capable of morphologic and biochemical differentiation in monolayer culture, have been exposed to medium containing aluminum phosphate; such treatment resulted in an abundant accumulation of 100 Å neurofilaments after 6 days of continous exposure to the aluminum salt. While growth rates and incorporation of radioactive thymidine in treated cells remained similar to controls, total cellular protein, and incorporation of radioactive leucine were significantly increased. Paradoxically, when the protein content of aluminum-treated cultures was maximal, these cultures contained about 20 per cent less ribosomal RNA per cell than in control cultures. In addition, activity of an important neuronal protein, i.e. acetylcholinesterase, was depressed in treated cultures to a level below control values. Both temporal and morphologic similarities between treated neuroblastoma cultures and animals injected with aluminum salts suggest that the observed changes in macromolecular synthesis in cell culture are relevant to in vivo studies.     

Aggregation of microtubule initiation sites preceding neurite outgrowth in mouse neuroblastoma cells.

By examining microtubule regrowth using immunofluorescence with antibody to tubulin, we have studied the structure and intracellular localization of microtubule initiation sites in undifferentiated and differentiated mouse neuroblastoma cells. The undifferentiated cells are round and lack cell processes. They contain an average of 12 initiation sites per cell. Each of these sites, which are located near the cell nucleus, initiates the growth of several microtubules in a radial formation. In contrast to the undifferentiated cells, neuroblastoma cells stimulated to differentiate by serum deprivation are asymmetrical, containing one or two very long neurites. These cells have a single, large microtubule initiation center which can be visualized not only by immunofluorescence but by phase-contrast and differential interference microscopy as well. The initiation site measures 3-4 mu in diameter and is located in the cell body along a line defined by the neurite. During cell differentiation, the large initiation, the large initiation center seems to be formed by the aggregation of many smaller sites. This process procedes neurite extension by about 24 hr. The growth of microtubules from this center appears to be highly oriented, since most microtubules initially grow into the neurite processes rather than into the cell interior. Thus major changes in the structure and location of microtubule initiation sites occur during the differentiation of neuroblastoma cells. Similar changes are likely to be involved in alterations in the morphology of other cell types.     

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.     

Reverse Engineering the Neuroblastoma Regulatory Network Uncovers MAX as One of the Master Regulators of Tumor Progression

Neuroblastoma is the most common extracranial tumor and a major cause of infant cancer mortality worldwide. Despite its importance, little is known about its molecular mechanisms. A striking feature of this tumor is its clinical heterogeneity. Possible outcomes range from aggressive invasion to other tissues, causing patient death, to spontaneous disease regression or differentiation into benign ganglioneuromas. Several efforts have been made in order to find tumor progression markers. In this work, we have reconstructed the neuroblastoma regulatory network using an information-theoretic approach in order to find genes involved in tumor progression and that could be used as outcome predictors or as therapeutic targets. We have queried the reconstructed neuroblastoma regulatory network using an aggressive neuroblastoma metastasis gene signature in order to find its master regulators (MRs). MRs expression profiles were then investigated in other neuroblastoma datasets so as to detect possible clinical significance. Our analysis pointed MAX as one of the MRs of neuroblastoma progression. We have found that higher MAX expression correlated with favorable patient outcomes. We have also found that MAX expression and protein levels were increased during neuroblastoma SH-SY5Y cells differentiation. We propose that MAX is involved in neuroblastoma progression, possibly increasing cell differentiation by means of regulating the availability of MYC:MAX heterodimers. This mechanism is consistent with the results found in our SH-SY5Y differentiation protocol, suggesting that MAX has a more central role in these cells differentiation than previously reported. Overexpression of MAX has been identified as anti-tumorigenic in other works, but, to our knowledge, this is the first time that the link between the expression of this gene and malignancy was verified under physiological conditions.