NTera 2 Cells: A human cell line which displays characteristics expected of a human committed neuronal progenitor cell

We have identified a human cell line with a phenotype resembling committed CNS neuronal precursor cells. NTera 2/cl.D1 (NT2/D1) cells expressed nestin and vimentin, intermediate filament (IF) proteins expressed in neuroepithelial precursor cells, as well as MAP1b, a microtubule-associated protein (MAP) expressed in human neuroepithelium. NT2/D1 cells also expressed the cell adhesion molecules NCAM and N-cadherin which are thought to be important in cellcell interactions within the neuroepithelium. These NT2/D1 cells also expressed small amounts of NF-L, α-internexin, NF-M, and MAP2c, indicating that they are committed to a neuronal fate. Previous studies have shown that, following RA treatment, a proportion of NT2/D1 cells terminally differentiate into neurons and that this occurs via an asymmetric stem cell mode of differentiation. In light of the identification of the neuroepithelial phenotype of NT2/D1 cells we decided to examine more closely the relationship of in vitro neurogenesis in NT2/D1 cells, during RA treatment to that of neurons in vivo. Three days after RA treatment, islands of NT2/D1 cells showed increased expression of neurofilament proteins and increased phosphorylation of NF-M. By 10–14 days, these cells began to resemble neurons morphologically, i.e., with rounded cell bodies and processes. These neuronal cells were clustered into clumps which rested on top of a layer of progenitor cells. In this upper layer, the neurons began to express MAP2b and tau and extinguished their expression of mestin. Recently, we developed a method for obtaining pure cultures of neurons from RA treated NT2/D1 cells. The phenotype of these postmitotic neurons is clearly dissociated from that of the untreated NT2/D1 cells. Given the data obtained in this study and the characterization of the neurons derived from NT2/D1 cells, we propose that NT2/D1 cells are a committed human neuronal precursor cell line which retains some stem cell characteristics and is capable only of terminal differentiation into neurons. © 1993 Wiley-Liss, Inc.     

Reduction of connexin43 expression and dye-coupling during neuronal differentiation of human NTera2/clone D1 cells

Gap junctions are plasma membrane specializations that allow direct communication among adjoining cells. We used a human pluripotential teratocarcinoma cell line, NTera-2/clone D1 (NT2/D1), as a model to study gap junctions in CNS neurons and their neuronal precursors. These cells were differentiated following retinoic acid (RA) treatment for 4 weeks and antiproliferative agents for 3 weeks, respectively, to yield post-mitotic CNS neuronal (NT2-N) cells. The cytoplasmic RNA was isolated from NT2/D1 cells both before and during RA treatment and from differentiated neurons (NT2-N cells). These RNA samples were examined using Northern blot analysis with cDNA probes specific for connexin26, −32, and −43. Connexin26 and −32 mRNAs were absent in NT2/D1 and NT2-N cells. Connexin43 mRNA was expressed at high levels in NT2/D1 cells before RA treatment, but it decreased significantly during RA induction. There was no detectable connexin43 mRNA in NT2-N cells. Western blot analysis confirmed the expression of connexin43 protein in NT2/D1 cells before and during RA treatment. The protein profile detected in Western blot analysis indicated two bands representing different phosphorylation states of connexin43. Our immunocytochemistry results did not show connexin26 and −32 immunoreactivity in NT2/D1 and NT2-N cells. However, we detected connexin43 immunoreactivity in NT2/D1 cells with a decreasing pattern upon RA induction. Both Western blotting and immunocytochemistry confirmed the absence of connexin43 protein in NT2-N cells. NT2/D1 cells passed calcein readily to an average of 18 cells, confirming the functionality of gap junctions in these cells. The extent of dye-coupling decreased about 78% when NT2/D1 cells were RA treated for 4 weeks. NT2-N differentiated neurons did not pass dye to the adjacent cells. We conclude that both connexin43 expression and dye coupling capacity decrease during neuronal differentiation of NT2/D1 cells. J. Neurosci. Res. 49:19–31, 1997. © 1997 Wiley-Liss Inc.     

Synthesis and regulation of apolipoprotein E during the differentiation of human neuronal precursor NT2/D1 cells into postmitotic neurons

Recently, we showed expression of apolipoprotein E (apoE) in human neuronal-type cells such as neuroblastoma SK N SH-SY 5Y cells. In this model, a negative effect of neuronal differentiation on apoE synthesis was suspected. To check this hypothesis, we studied the regulation of apoE in human postmitotic neurons. The presence of apoE was investigated in undifferentiated human teratocarcinoma NT2/D1 (NT2) cells and during their differentiation into postmitotic hNT neurons induced by retinoic acid (RA) treatment. Before differentiation, apoE protein and mRNA were detected in NT2 cells by Western blotting and RT-PCR experiments. Immunofluorescence study showed that apoE was present in all cells. For longer times of RA treatment (3 weeks), the apoE labeling became heterogeneous: only some cells were immunopositive and among them were some differentiating cells in which apoE was located in both cellular body and neuritic process. Interestingly, terminally differentiated hNT cells no longer expressed apoE. These results demonstrate that neuronal precursor and differentiating cells were able to synthesize apoE while the fully neuronal differentiation exerted a negative effect on apoE neuronal expression. Our results are compatible with a weak expression of apoE in neurons of adult brains.     

Contact with astroglial membranes induces axonal and dendritic growth of human CNS model neurons and affects the distribution of the growth-associated proteins MAP1B and GAP43

The development of morphological complexity of CNS neurons is thought to be regulated by extracellular factors and cellular contact. To analyze the role of contact with astroglia in this process and to determine the intraneuronal mechanisms involved, an in vitro system was developed where terminally differentiated and polar human CNS model neurons (NT2-N neurons) were cultured on a layer of mouse astrocytes or isolated membrane fractions in chemically defined medium. Morphometric analysis revealed that physical contact with living astrocytes increased the lengths of axonal and dendritic processes and lead to an increased number of branch points. Contact with astrocytes also resulted in a redistribution of the growth-associated proteins MAP1b and GAP-43 toward the growth cones of NT2-N neurons. Astrocyte-contact did not lead to a maturation of the neurons as would be detected by an increased expression of tau isoforms containing the adult-specific exons 2 and 3. Culture on immobilized membrane fractions prepared from astrocytes also increased the morphological complexity of the neurons in a qualitatively similar manner. The results indicate that physical contact with astrocyte membranes increases the morphological complexity of CNS model neurons through a mechanism that involves a redistribution of growth-associated proteins to neuronal growth cones. NT2-N neurons may provide a useful cellular model to analyze cytoskeletal mechanisms during the development of terminally differentiated and polar human neurons.     

Coexpression of nestin in neural and glial cells in the developing human CNS defined by a human-specific anti-nestin antibody

The presence of the intermediate filament protein nestin has been the predominant marker used to describe stem and progenitor cells in the mammalian CNS. In this study, a 998-bp fragment in the 3' region of the nestin mRNA was cloned from human fetal brain cells (HFBC). The nucleotide sequence of the cloned cDNA revealed 21 differences with the previously published human nestin sequence, resulting in 17 amino acid changes. A 150-amino-acid fragment derived from the cloned nestin cDNA was coupled to glutathione S-transferase and used as an immunogen to generate a rabbit polyclonal antiserum that selectively detects human nestin. HFBC that proliferated in response to basic fibroblast growth factor incorporated 5-bromo-2'-deoxyuridine into their nuclei and immunostained for nestin, indicating nestin expression in proliferating CNS progenitor cells. In all cell cultures, nestin costained with the neuroepithelial cell marker vimentin. A small subset of nestin-stained cells (1-2%) immunostained with neuronal marker MAP-2 during the first week and after 4 weeks in culture. However, during the first week in culture, approximately 10-30% of the total cell population of HFBC stained for the glial cell marker GFAP, and nearly all coimmunostained for nestin. After 4 weeks in culture, a subset of GFAP-positive cells emerged that no longer costained with nestin. These results describe nestin expression not only in CNS progenitor cells but also in the cells which were in transition from a progenitor stage to glial differentiation. Collectively, these data suggest a differential temporal regulation of nestin expression during glial and neuronal cell differentiation.     

Pure, postmitotic, polarized human neurons derived from NTera 2 cells provide a system for expressing exogenous proteins in terminally differentiated neurons.

NTera 2/cl.D1 (NT2) cells, a human teratocarcinoma cell line, were manipulated following retinoic acid treatment to yield greater than 95% pure cultures of neuronal cells (NT2-N cells). The commitment of NT2-N cells to a stable neuronal phenotype is irreversible as judged by the lack of mitotic activity or phenotypic reversion over a period of 2 months in culture. Furthermore, NT2-N cells express a variety of neuronal markers including many neuronal cytoskeletal proteins, secretory markers, and surface markers. NT2-N cells resemble primary neuronal cultures from rodents morphologically and in density of process outgrowth and, like primary neurons, go on to elaborate processes that differentiate into axons and dendrites. This culture method yields sufficient highly differentiated postmitotic NT2-N cells for both biochemical and molecular biological studies. Indeed, when undifferentiated NT2 cells were stably transfected with a beta-galactosidase (beta-gal) expression plasmid, beta-gal expression was shown to be present in both undifferentiated NT2 and postmitotic NT2-N cells. Thus, the ability to transfect expression plasmids into undifferentiated NT2 cells will allow the introduction of normal and mutant gene products into cells that can then be induced to become stable, postmitotic human neurons. We conclude that NT2 cells and NT2-N cells represent a unique model system for studies of human neurons, and a novel vehicle for the expression of diverse gene products in terminally differentiated polarized neurons.     

Long-term integration and neuronal differentiation of human embryonal carcinoma cells (NT era-2) transplanted into the caudoputamen of nude mice

NTera-2 (NT2) cells are a human embryonal carcinoma (EC) cell line derived from a teratocarcinoma that differentiate exclusively into postmitotic neurons in vitro following retinoic acid (RA) treatment. Like other EC cell lines, NT2 cells rapidly form lethal tumors following transplantation into peripheral sites or many regions of the brain. However, when grafts are confined to the caudoputamen (CP), the NT2 cells differentiate into postmitotic neuronlike cells and do not form lethal tumors. To examine the long-term fate of such grafts, we studied NT2 cell transplants in the CP of nude mice that survived for > 1 year. NT2 cells in these grafts acquired molecular markers of fully mature neurons including the low, middle, and high molecular weight neurofilament proteins, microtubule-associated protein 2, tau, and synaptophysin. Furthermore, neuronlike cells in long-term CP grafts formed synaptic structures, and their processes became myelinated, whereas tyrosine hydroxylase (TH)-positive neuronlike cells in the grafts increased with progressively longer postimplantation survival times. Soluble extracts of the adult mouse CP augmented TH expression in RA-treated NT2 cells in vitro. These data suggest that the adult mouse CP is a source of factor(s) that inhibits tumor formation and induce a catecholaminergic neuronal phenotype in these human NT2 cells in vivo and in vitro. Identification of these factors could accelerate efforts to elucidate mechanisms that regulate progenitor cell fate and the commitment of neurons to specific neurotransmitter phenotypes. © 1996 Wiley-Liss, Inc.     

Involvement of NOS3 in RA‐Induced neural differentiation of human NT2/D1 cells

Nitric oxide (NO) plays a key role in neurogenesis as a regulator of cell proliferation and differentiation. NO is synthesized from the amino acid L‐arginine by nitric oxide synthases (NOS1, NOS2, and NOS3), which are encoded by separate genes and display different tissue distributions. We used an in vitro model of RA‐induced neural differentiation of NT2 cells to examine which of the three NO‐synthesizing enzymes is involved in this process. The results revealed a transient induction of NOS3 (known as the constitutively expressed endothelial nitric oxide synthase; eNOS) during the time course of the RA treatment. The peak of gene expression and the nuclear presence of NOS3 protein coincided with cell cycle exit of NT2‐derived neuronal precursors. The subsequent analysis of cytosine methylation and histone H3 acetylation of the human NOS3 5′ regulatory sequences indicated that epigenetic modifications, especially upstream of the proximal promoter (?734 to ?989, relative to exon 2 TSS at +1), were also taking place. NOS1 was expressed only in the differentiated neurons (NT2‐N), whereas NOS2 was not expressed at all in this cellular model. Thus, a burst of NO production, possibly required to inhibit neural cell proliferation, was generated by the transient expression of NOS3. This pattern of gene expression, in turn, required epigenetic remodeling of its regulatory region. Published 2012 Wiley Periodicals, Inc.     

In vitro induction and in vivo expression of bcl-2 in the hNT neurons.

Bcl-2 encodes membrane-associated proteins that suppress programmed cell death in cells of various origins. Compelling evidence suggests that bcl-2 is also involved in neuronal differentiation and axonal regeneration. The human Neuro-Teratocarcinoma (hNT) neurons constitute a terminally differentiated human neuronal cell line that is derived from the Ntera-2/clone D1 (NT2) precursors upon retinoic acid (RA) treatment. After transplantation into the central nervous system (CNS), the hNT neurons survive, engraft, maintain their neuronal identity, and extend long neurite outgrowth. We were particularly interested in the intracellular determinants that confer these post-transplant characteristics to the hNT neurons. Thus, we asked whether the hNT neurons express bcl-2 after transplantation into the rat striatum and if RA induction of the neuronal lineage is mediated by bcl-2. The grafted hNT neurons were first identified using three different antibodies that recognize human-specific epitopes, anti-hMit, anti-hNuc, and NuMA. After a 1-month post-transplant survival time, NuMA immunostaining revealed that 12% of the hNT neurons survived the transplantation. These neurons extended long neuritic processes within the striatum, as demonstrated using the human-specific antibody against the midsize neurofilament subunit HO14. Importantly, we found that 85% of the implanted hNT neurons expressed bcl-2 and that the in vitro induction of the neuronal lineage from the NT2 precursors with RA resulted in an upregulation of bcl-2 expression. Together, these data suggest that the differentiation of the hNT neurons to a neuronal lineage could be mediated at least partially by bcl-2.     

Retinoic acid induces cholinergic differentiation of NTera 2 human embryonal carcinoma cells

Retinoic acid (RA), a natural metabolite of vitamin A, influences the survival and neurotransmitter phenotype of several classes of vertebrate neurons during development. We now report that RA induces a subpopulation of NTera 2/clone D1 (NT2) human embryonal carcinoma cells to differentiate into postmitotic cells with cholinergic properties (NT2-N cells). After growth for 6 days in the presence of RA (10 μM) low levels of the acetylcholine-synthesizing enzyme choline acetyltransferase (ChAT) were detected in NT2 cell cultures. ChAT activity in the NT2 cell cultures continued to increase for at least an addition 22 days to a final activity of 50 pmol ACh synthesized/min/mg protein. Immunohistochemical staining of RA-treated cultures demonstrated that only those cells with a neuronal morphology (NT2-N cells) expressed the human ChAT protein. Since such cells comprised a small proportion (∼20%) of the population, the ChAT activity per neuronal cell was estimated to approach 250–300 pmol ACh/min/mg protein. Cultures composed of >95% NT2-N cells had significantly lower ChAT specific activities and this could be increased by either ciliary neurotrophic factor or leukemia inhibitory factor, but not by nerve growth factor. We conclude that NT2 cells provide a system in which to study the molecular events that underlie neurotransmitter choice during the differentiation of human cholinergic neurons.     

In vitro induction and in vivo expression of bcl-2 in the hNT neurons

Bcl-2 encodes membrane-associated proteins that suppress programmed cell death in cells of various origins. Compelling evidence suggests that bcl-2 is also involved in neuronal differentiation and axonal regeneration. The human Neuro-Teratocarcinoma (hNT) neurons constitute a terminally differentiated human neuronal cell line that is derived from the Ntera-2/clone D1 (NT2) precursors upon retinoic acid (RA) treatment. After transplantation into the central nervous system (CNS), the hNT neurons survive, engraft, maintain their neuronal identity, and extend long neurite outgrowth. We were particularly interested in the intracellular determinants that confer these post-transplant characteristics to the hNT neurons. Thus, we asked whether the hNT neurons express bcl-2 after transplantation into the rat striatum and if RA induction of the neuronal lineage is mediated by bcl-2. The grafted hNT neurons were first identified using three different antibodies that recognize human-specific epitopes, anti-hMit, anti-hNuc, and NuMA. After a 1-month post-transplant survival time, NuMA immunostaining revealed that 12% of the hNT neurons survived the transplantation. These neurons extended long neuritic processes within the striatum, as demonstrated using the human-specific antibody against the midsize neurofilament subunit HO14. Importantly, we found that 85% of the implanted hNT neurons expressed bcl-2 and that the in vitro induction of the neuronal lineage from the NT2 precursors with RA resulted in an upregulation of bcl-2 expression. Together, these data suggest that the differentiation of the hNT neurons to a neuronal lineage could be mediated at least partially by bcl-2.     

Changes of gene expression profiles during neuronal differentiation of central nervous system precursors treated with ascorbic acid

Ascorbic acid (AA) has been shown to increase the yield of dopaminergic (DA) neurons derived from basic fibroblast growth factor (bFGF)-expanded mesencephalic precursors. To understand the molecular mechanisms underlying this phenomenon, we used cDNA microarray analysis to examine differential expression of neuronal genes following AA treatment. The putative precursor cells were isolated from E13 rat ventral mesencephalons and expanded in the presence of bFGF. Cells were incubated in mitogen-free media supplemented with 200 microM AA or were left untreated as a control, and total RNA was isolated at different time points (expansion stage and 1, 3, and 6 days after induction of differentiation) and subjected to cDNA microarray analysis. Differentiation was evaluated by Western blot analysis and immunocytochemistry of neuron-specific markers. AA treatment of the mesencephalic precursors increased the expression of neuronal (MAP2) and astrocytic (glial fibrillary acidic protein) markers and the percentage of tyrosine hydroxylase (TH)-positive cells. The microarray analysis revealed that 12 known genes were up-regulated and 20 known genes were down-regulated in expansion-stage AA-treated cells. Six days after the induction of differentiation, AA-treated cells showed up-regulation of 48 known genes and down-regulation of 5 known genes. Our results identified several proteins, such as transferrin, S-100, and somatostatin, as being differentially regulated in AA-treated mesencephalic precursors. This novel result may lead to a better understanding of the molecular mechanisms underlying the AA-induced differentiation of mesencephalic precursors into DA neurons and may form the basis for improved DA neuronal production for treatment of Parkinson's disease patients.     

Expression of TGF-beta type II receptors in the olfactory epithelium and their regulation in TGF-alpha transgenic mice

Numerous in vitro studies of neurogenesis of olfactory receptor neurons (ORNs) suggest that transforming growth factor (TGF)-beta promotes the maturation/differentiation of olfactory progenitors. We demonstrate that in vivo both mature and immature ORNs, and possibly a basal neuronal progenitor cell, express the TGF-beta type II receptor (TGF-betaRII), suggesting that these cells are targets for TGF-beta signaling. In a previous study of neurogenesis in the OE of TGF-alpha overexpressing transgenic (T) mice, we observed an apparent reduction in the expression of olfactory marker protein (OMP), a marker of terminal differentiation in ORNs in T mice compared to nontransgenic (NT) littermate controls; this was confirmed by Western blotting and immunohistochemistry. In contrast, there was no apparent difference between T and NT mice in the intensity of immunoreactivity for a neuronal marker, protein gene product 9.5. Because TGF-alpha overexpression has been reported to affect TGF-beta signaling in other epithelia, we compared the expression of the TGF-beta type II receptor (TGF-betaRII) in T and NT mice. The intensity of TGF-betaRII immunoreactivity on ORNs was substantially reduced in T compared to NT mice. Similar reductions in TGF-betaRII expression in vomeronasal receptor neurons and in other epithelia in the nasal cavity of T mice were also observed. Taken together, these results indicate that TGF-beta signaling regulates terminal differentiation of ORNs in vivo and suggest ways in which interactions between TGF-alpha and TGF-beta signaling pathways may interact in the OE.     

Erythropoietin up-regulates SOCS2 in neuronal progenitor cells derived from SVZ of adult rat

We examined the effects of EPO on expression of suppressor of cytokine signaling 2 (SOCS2) and found that treatment of neural progenitor cells derived from the adult subventricular zone (SVZ) with recombinant human EPO (rhEPO) stimulated progenitor cell differentiation into neurons, but not astrocytes. Quantitative RT-PCR revealed that SOCS2 mRNA levels were increased in the progenitor cells treated with rhEPO. Immunostaining showed that neurons but not astrocytes were SOCS2 immunoreactive. Incubation of the progenitor cells with rhEPO in the presence of a neutralizing antibody against EPO abolished the effects of EPO on neuronal differentiation and expression of SOCS2. Our data suggest that up-regulation of SOCS2 in neuronal progenitor cells derived from the adult SVZ may regulate EPO enhanced neuronal differentiation.