Establishment of mouse-immortalized hybrid clones expressing characteristics of differentiated neurons derived from the cerebellar and brain stem regions

Two clonal immortalized neurons designated CL8c47 and CL8a5.2 were established by somatic cell fusion between a hypoxanthine phosphoribosyltransferase (HPRT^?) deficient neuroblastoma N18TG2 and newborn mouse cerebellar/brain stem neurons. In the serum-containing medium without extra differentiating agents, both clones exhibited a morphology of differentiated neurons. They contained high levels of glutamate but no gamma-aminobutyric acid (GABA). The CL8a5.2 clone synthesized choline aceryltransferase and serotonin. In immunocytochemical studies, both clones expressed 200 kD neurofilament protein neuron-specific enolase, microtubule-associated protein 2 (MAP2), tau protein, neuronal cell adhesion molecule (N-CAM), HNK-1, Thy-1.2, saxitoxin-binding sodium channel protein, and glutamate. Synaptophysin immunoreactivity was identified in the neuritic terminals of CL8c4.7 cells. Most of these antigens were barely detectable on N18TG2 cells. Electrophysiologically, both clones generated action potentials in response to electrical stimuli. The hybrid clones that express characteristics of differentiated neurons derived from the cerebellar and brain stem regions might be invaluable for the study of the molecular basis of neuronal differentiation and degeneration in these regions. © 1992 John Wiley & Sons, Inc.     

The Cloning and Characterization of Chick Tyrosinase from a Novel Embryonic cDNA Library

Very little is known about the genes involved in the regulation of avian skin and feather pigmentation. In mammals, two gene families have been identified as being important for the regulation of melanin biosynthesis. To isolate the avian equivalents of these families, we have generated an embryonic chick melanocyte cDNA library. Neural crest cells from 500 black chick embryos were cultured under conditions supportive of melanocyte differentiation and proliferation. A cDNA library was constructed and screened with a mouse tyrosinase cDNA probe. Nineteen clones were obtained, seven of which cross-hybridized to a mouse tyrosinase cDNA on Southern blots. The longest of these clones, B8.3 (1.9 kb), was sequenced and found to share 99.7% nucleotide and 99.8% amino acid sequence homology to a reported chick tyrosinase cDNA. Both Northern blot analysis andin situhybridization demonstrated that clone B8.3 was expressed in the retinal pigment epithelium of chick embryos. Our results suggest therefore that the cDNA library described here may allow the cloning of novel melanogenic genes.     

Cellular Acetylcholine Content and Neuronal Differentiation

Abstract: N18TG2 neuroblastoma clone is defective for biosynthetic neurotransmitter enzymes; its inability to establish functional synapses is overcome in the neuroblastoma × glioma 108CC15, where acetylcholine synthesis is also activated. These observations suggest a possible relation between the ability to produce acetylcholine and the capability to advance in the differentiation program and achieve a fully differentiated state. Here, we report the characterization of several clones after transfection of N18TG2 cells with a construct containing a cDNA for rat choline acetyltransferase (ChAT). The ability of these clones to synthesize acetylcholine is demonstrated by HPLC determination on cellular extracts. In the transfected clones, northern blot analysis shows increased expression of mRNAs for a specific neuronal protein associated with synaptic vesicles, synapsin I. Fiber outgrowth of transfected clones is also evaluated to establish whether there is any relation between ChAT levels and morphological differentiation. This analysis shows that the transfected clone 1/2, not expressing ChAT activity, displays a very immature morphology, and its ability to extend fibers also remains rather poor in the presence of "differentiation" agents such as retinoic acid. In contrast, clones 2/4, 3/1, and 3/2, exhibiting high ChAT levels, display higher fiber outgrowth compared with clone 1/2 in both the absence and the presence of differentiating agents.     

Analysis of neuron-like differentiation of human bone marrow mesenchymal stem cells

The objective of the study was to evaluate differentiation of human bone marrow mesenchymal stem cells into true or pseudo neurons after treating with chemical induction medium in vitro. The morphological changes were assessed using interference contrast microscopy. Immunocytochemistry and Western blotting were performed using neuronal markers. Further evaluation was conducted with proteomic profiling, DNA microarray analysis and the whole-cell patch clamp test. After three hours of treatment with chemical induction medium, nearly three-fourths of the hMSCs changed to cells with a neuronal phenotype. The results of immunocytochemistry and Western blotting showed a high expression of neuronal markers in these cells at 3 h which decreased at 24 h. The proteomics analysis showed no change of proteins related to neuronal differentiation. DNA microarray showed downregulation of neuron related genes. The patch clamp test was unable to demonstrate any similarity to true neurons. Our findings suggest that neuron-like cells derived from chemical induction of hMSCs are not the genuine neurons as they resemble true neurons phenotypically but are different in genotypic and electrophysiological characteristics.     

Establishment of mouse-immortalized hybrid clones expressing characteristics of differentiated neurons derived from the cerebellar and brain stem regions.

Two clonal immortalized neurons designated CL8c4.7 and CL8a5.2 were established by somatic cell fusion between a hypoxanthine phosphoribosyltransferase-(HPRT-) deficient neuroblastoma N18TG2 and newborn mouse cerebellar/brain stem neurons. In the serum-containing medium without extra differentiating agents, both clones exhibited a morphology of differentiated neurons. They contained high levels of glutamate but no gamma-aminobutyric acid (GABA). The CL8a5.2 clone synthesized choline acetyltransferase and serotonin. In immunocytochemical studies, both clones expressed 200 kD neurofilament protein, neuron-specific enolase, microtubule-associated protein 2 (MAP2), tau protein, neuronal cell adhesion molecule (N-CAM), HNK-1, Thy-1.2, saxitoxin-binding sodium channel protein, and glutamate. Synaptophysin immunoreactivity was identified in the neuritic terminals of CL8c4.7 cells. Most of these antigens were barely detectable on N18TG2 cells. Electrophysiologically, both clones generated action potentials in response to electrical stimuli. The hybrid clones that express characteristics of differentiated neurons derived from the cerebellar and brain stem regions might be invaluable for the study of the molecular basis of neuronal differentiation and degeneration in these regions.     

Molecular characterization of mitocalcin, a novel mitochondrial Ca2+-binding protein with EF-hand and coiled-coil domains

Here we have identified and characterized a novel mitochondrial Ca2+-binding protein, mitocalcin. Western blot analysis demonstrated that mitocalcin was widely expressed in mouse tissues. The expression in brain was increased during post-natal to adult development. Further analyses were carried out in newly established neural cell lines. The protein was expressed specifically in neurons but not in glial cells. Double-labeling studies revealed that mitocalcin was colocalized with mitochondria in neurons differentiated from 2Y-3t cells. In addition, mitocalcin was enriched in the mitochondrial fraction purified from the cells. Immunohistochemical studies on mouse cerebellum revealed that the expression pattern of mitocalcin in glomeruli of the internal granular and molecular layers was well overlapped by the distribution pattern of mitochondria. Immunogold electron microscopy showed that mitocalcin was associated with mitochondrial inner membrane. Overexpression of mitocalcin in 2Y-3t cells resulted in neurite extension. Inhibition of the expression in 2Y-3t cells caused suppression of neurite outgrowth and then cell death. These findings suggest that mitocalcin may play roles in neuronal differentiation and function through the control of mitochondrial function.     

Modulation of acetylcholinesterase and voltage-gated Na(+) channels in choline acetyltransferase- transfected neuroblastoma clones

Neurotransmitters appear early in the developing embryo and may play a role in the regulation of neuronal differentiation. To study potential effects of acetylcholine production in neuronal differentiation, we used the FB5 subclone of N18TG2 murine neuroblastoma cells stably transfected with cDNA for choline acetyltransferase. We tested whether the forced acetylcholine production can modify the expression or the cellular localization of different neuronal markers. We studied the activity, localization, and secretion of acetylcholinesterase in view of its possible role in the modulation of the morphogenetic action of acetylcholine and of its proposed role of a regulator of neurite outgrowth. FB5 cells are characterized by a high level of acetylcholinesterase, predominantly released into the culture medium. Acetylcholinesterase secretion into the medium was lower in choline acetyltransferase-transfected clones than in nontransfected and antisense-transfected controls. Moreover, sequential extraction of acetylcholinesterase revealed that detergent-extracted, i.e., membrane-associated, activity was higher in the transfected clones expressing choline acetyltransferase activity than in both control groups. These observations suggest that a shift occurs in the utilization of acetylcholinesterase in choline acetyltransferase-transfected clones from a secretion pathway to a pathway leading to membrane localization. In addition, the choline acetyltransferase-positive clones showed higher densities of voltage-gated Na(+) channels and enhanced high-affinity choline uptake, suggesting the accomplishment of a more advanced differentiated neuronal phenotype. Finally, binding experiments demonstrated the presence of muscarinic acetylcholine receptors in all examined clones. This observation is consistent with the proposed existence of an autocrine loop, which may be important for the enhancement in the expression of neurospecific traits.     

抑制消减杂交和辐射小鼠血虚模型筛选"四物汤"诱导表达的基因

应用抑制性消减杂交技术构建受辐射小鼠血虚模型在中药四物汤诱导前后消减cDNA库,并从中克隆鉴定出与四物汤药效相关基因。从受辐射小鼠四物汤诱导前后骨髓细胞中提取mRNA并合成cDNA,分别作为tester和driver进行消减杂交及抑制性PCR,将PCR产物与载体连接构建cDNA库,高效电转化大肠杆菌进行库扩增,随机挑取其中的克隆进行酶切、测序分析。成功构建了具有高消减效率的受辐射小鼠四物汤诱导前后的消减cDNA库。库挑选得到512个阳性克隆。随机挑取30个插入片段测序,生物信息学分析结果显示大部分与红细胞分化、骨髓组织修复、结构重建有密切关系,其中8个为新基因片段。应用抑制性消减杂交技术所构建的受辐射小鼠四物汤诱导前后cDNA消减库为大批量筛选、克隆四物汤药效特异性相关基因奠定了基础。并从分子水平上发现四物汤对抑制凋亡、促进骨髓组织修复和结构重建、诱导红细胞分化的基因具有调节作用,可能和四物汤补血作用有关。     

Expanded CTG repeats inhibit neuronal differentiation of the PC12 cell line

Myotonic dystrophy (DM) is a dominant neuromuscular disorder caused by the expansion of trinucleotide CTG repeats in the 3-untranslated region (3'-UTR) of the MtPK gene. Although DM-associated mental retardation suggests that neuronal functions are disturbed by the expansion mutation, the effect of this alteration in neuronal cells has not been approached. In this study we established stable transfectans of PC12 neuronal cell line expressing the reporter gene CAT alone (empty-vector clone) or fused to the MtPK 3'-UTR with 5, 60, or 90 CTG repeats (CTG5, CTG60, and CTG90 clones, respectively). CTG90 cells exhibited a suppression of NGF-induced neuronal differentiation while empty-vector, CTG5 and CTG60 clones differentiated normally. CTG90 cells displayed normal activation of early differentiation markers, ERK1/2, but the up-regulation of the late marker MAP2 was dramatically reduced. Our neuronal cell system provides the first information of how the mutant MtPK 3'-UTR mRNA affects neuronal functions.     

Two Lyt-2 polypeptides arise from a single gene by alternative splicing patterns of mRNA

The Lyt-2/3 molecule is a glycoprotein expressed on T lymphocytes and has classically been considered a marker for the cytotoxic/suppressor T cell subset. It has been postulated to be a receptor for class I major histocompatibility complex proteins. We have used a cDNA clone encoding the analogous human protein, Leu-2/T8, to isolate mouse cDNA clones, which were used as probes to isolate mouse genomic clones. By transfection we have shown that the mouse homologue of Leu-2/T8 is Lyt-2 and not Lyt-3. We have further demonstrated that two Lyt-2 polypeptide chains are encoded by a single gene and result from alternative modes of mRNA splicing. The nucleotide sequence of cDNA clones encoding each of these polypeptide chains has been determined and shows the difference between the two Lyt-2 polypeptide chains to be in the lengths of their cytoplasmic tails.     

BHK-21-derived cell lines that produce basic fibroblast growth factor, but not parental BHK-21 cells, initiate neuronal differentiation of neural crest progenitors.

We present evidence that basic fibroblast growth factor (bFGF)-producing cells stimulate primary differentiation of neurons from neural crest progenitors. Baby hamster kidney (BHK-21) cells were stably cotransfected with plasmid pSV2/neo, which contains the gene conferring resistance to the neomycin analog G418 and expression vectors containing the human bFGF cDNA. Various clones, which differed in their bFGF production levels, were isolated. Homogeneous neural crest cells were cultured on monolayers of bFGF-producing, BHK-21-derived cell lines. While the parental BHK-21 cells, which do not produce detectable bFGF, had poor neurogenic ability, the various bFGF-producing clones promoted a 1.5- to 4-fold increase in neuronal cell number compared to the parental cells. This increase was correlated with the levels of bFGF produced by the different transfected clones, which ranged between 2.3 and 140 ng/mg protein. In contrast, no stimulation of neuronal differentiation was observed when neural crest cells were grown on monolayers of parental BHK cells transfected with plasmid pSV2/neo alone, or on a parental BHK-derived clone, which secretes high amounts of recombinant vascular endothelial growth factor (VEGF). Furthermore, the neuron-promoting ability of bFGF-producing cells could be mimicked by addition of exogenous bFGF to neural crest cells grown on the parental BHK line. A similar treatment of neural crest cells grown on laminin substrata, instead of BHK cells, resulted in increased survival of non-neuronal cells, but not of neurons (see also Kalcheim, C. 1989, Dev. Biol. 134, 1-10). Taken together, these results suggest that bFGF stimulates neuronal differentiation of neural crest cells by a cell-mediated signalling mechanism.     

Expression profile identifies novel genes involved in neuronal differentiation

In the presence of NGF, PC12 cells extend neuronal processes, cease cell division, become electrically excitable, and undergo several biochemical changes that are detectable in developing sympathetic neurons. We investigated the expression pattern of the apoptosis-related genes at each stage of neuronal differentiation using a cDNA microarray containing 320 apoptosis-related rat genes. By comparing the expression patterns through time-series analysis, we identified candidate genes that appear to regulate neuronal differentiation. Among the candidate genes, HO2 was selected by real-time PCR and Western blot analysis. To identify the roles of selected genes in the stages of neuronal differentiation, transfection of HO2 siRNA in PC12 cells was performed. Down-regulation of HO2 expression causes a reduction in neuronal differentiation in PC12 cells. Our results suggest that the HO2 gene could be related to the regulation of neuronal differentiation levels.     

一种新的人端粒相关锌指蛋白cDNA的克隆及鉴定

In order to isolate novel genes related to early human embryo development and differentiation, a directional cDNA library was constructed from 3-week-old human embryo. Single-pass DNA sequence analysis was used to sequence 47 randomly picked low-abundance cDNA clones. This approach led us to select a clone, L30, showing significant homology with the telomeric-associated DNA and zinc finger protein genes. It is about 3.8 kb in length and contains an open reading frame of notable length within 5'-region, and a tailing signal of AAUAAA and poly (A+) with 39 A in 3'-region. The gene was transcribed in human embryo by Northern blot hybridization and assigned to human chromosome 12 by in situ hybridization.     

Differentiation patterns of mouse embryonic stem cells and induced pluripotent stem cells into neurons

Mouse embryonic stem (ES) cells and induced pluripotent stem (iPS) cells have the ability to differentiate in vitro into various cell lineages including neurons. The differentiation of these cells into neurons has potential applications in regenerative medicine. Previously, we reported that a chick dorsal root ganglion (DRG)-conditioned medium (CM) promoted the differentiation of mouse ES and iPS cells into neurons. Here, we used real-time PCR to investigate the differentiation patterns of ES and iPS cells into neurons when DRG-CM was added. DRG-CM promoted the expression levels of βIII-tubulin gene (a marker of postmitotic neurons) in ES and iPS cells. ES cells differentiated into neurons faster than iPS cells, and the maximum peaks of gene expression involved in motor, sensory, and dopaminergic neurons were different. Rho kinase (ROCK) inhibitors could be very valuable at numerous stages in the production and use of stem cells in basic research and eventual cell-based therapies. Thus, we investigated whether the addition of a ROCK inhibitor Y-27632 and DRG-CM on the basis of the differentiation patterns promotes the neuronal differentiation of ES cells. When the ROCK inhibitor was added to the culture medium at the initial stages of cultivation, it stimulated the neuronal differentiation of ES cells more strongly than that stimulated by DRG-CM. Moreover, the combination of the ROCK inhibitor and DRG-CM promoted the neuronal differentiation of ES cells when the ROCK inhibitor was added to the culture medium at day 3. The ROCK inhibitor may be useful for promoting neuronal differentiation of ES cells.     

Isolation of a large number of novel mammalian genes by a differential cDNA library screening strategy.

As part of the ongoing human and mouse genome projects, the aim of this study was to isolate novel, previously uncharacterized, genes from mouse testis. Two approaches were compared for their effectiveness in isolating novel genes: random, vs differential, complementary DNA (cDNA) cloning methods. In the differential approach, only the cDNA clones containing rare sequences (as determined by preliminary clone hybridization) are further analyzed; in the random approach, cDNA clones are isolated at random from the cDNA library. More than two hundred cDNA clones altogether were analyzed, using a PCR-mediated amplification and sequencing strategy. A comparison of these sequences to nucleic acid and protein sequence databases, revealed that 84% of the isolated rare cDNA clones represented new, previously uncharacterized mouse genes. In contrast, less than 63% of the cDNA clones isolated at random from cDNA libraries, contained novel genes. Thus, the probability of isolating new, previously uncharacterized, mammalian genes from cDNA libraries can be markedly improved by focusing efforts on clones containing rare sequences.     

ES cell neural differentiation reveals a substantial number of novel ESTs

We have used a method for synchronously differentiating murine embryonic stem (ES) cells into functional neurons and glia in culture. Using subtractive hybridization we isolated approximately 1200 cDNA clones from ES cell cultures at the neural precursor stage of neural differentiation. Pilot studies indicated that this library is a good source of novel neuro-embryonic cDNA clones. We therefore screened the entire library by single-pass sequencing. Characterization of 604 non-redundant cDNA clones by BLAST revealed 96 novel expressed sequence tags (ESTs) and an additional 197 matching uncharacterized ESTs or genomic clones derived from genome sequencing projects. With the exception of a handful of genes, whose functions are still unclear, most of the 311 known genes identified in this screen are expressed in embryonic development and/or the nervous system. At least 80 of these genes are implicated in disorders of differentiation, neural development and/or neural function. This study provides an initial snapshot of gene expression during early neural differentiation of ES cell cultures. Given the recent identification of human ES cells, further characterization of these novel and uncharacterized ESTs has the potential to identify genes that may be important in nervous system development, physiology and disease. Electronic Publication     

Molecular cloning of a differentiation-related mRNA in the adipogenic cell line 1246.

The 1246 cell line is a C3H mouse teratoma-derived adipogenic cell line that can proliferate and differentiate in defined medium. We have constructed a recombinant phage library containing complementary DNAs (cDNAs) prepared from mRNA of differentiated 1246 cells. This library was screened using a differential hybridization technique. We have isolated five different cDNA clones corresponding to mRNAs that are induced during adipogenesis of 1246 cells and one cDNA clone corresponding to mRNA that is decreased during adipogenesis. Among the mRNAs expressed during adipose differentiation, some are not expressed in undifferentiated cells, whereas some are expressed at very low levels under these conditions. Moreover, the level of induction during differentiation and the temporal expression of the mRNAs corresponding to these cDNAs varied. Our results indicate that one of the cDNA clones isolated, called 154, which selects a 2.2-kilobase mRNA, was induced 100-fold at a very early time during the onset of the differentiation program in 1246 cells and also in adipocyte precursors in primary culture. Direct sequencing of 154 cDNA insert revealed no homology with sequences in GenBank and PIR protein databases. The expression of 154 mRNA was stimulated by accelerators of differentiation such as dexamethasone and isobutylmethylxanthine and inhibited by tumor necrosis factor alpha, transforming growth factor beta, and epidermal growth factor, which are known inhibitors of 1246 cell differentiation. In addition, 154 mRNA level in adipocytes was down-regulated by tumor necrosis factor alpha, but not by transforming growth factor beta or epidermal growth factor. These results suggest that the increase in 154 mRNA expression is related to the onset of adipose differentiation. Further analysis of this clone should allow characterization of a novel protein induced early during the process of differentiation.     

ERK-mediated production of neurotrophic factors by astrocytes promotes neuronal stem cell differentiation by erythropoietin

Erythropoietin (EPO), a hematopoietic factor, is also required for normal brain development, and its receptor is localized in brain. Our previous study showed that EPO promotes differentiation of neuronal stem cells into astrocytes. Since astrocytes have influence on the neuronal function, we investigated whether EPO-activated astrocytes could stimulate differentiation of neuronal stem cells into neurons. EPO did not promote neuronal differentiation of neuronal stem cells isolated from 17 day embryos, however, neuronal differentiation was promoted when the neuronal stem cells were co-cultured with astrocyte isolated from post neonatal (Day 1) rat brain. Moreover, neuronal differentiation was further promoted when the neuronal stem cells were cultured with astrocyte culture medium treated by EPO (10U/ml) showing increase of morphological differentiation, and expression of neuronal differentiation marker proteins, neurofilament, and tyrosine hydroxylase. The promoting effect of EPO-treated astrocyte medium was also found in the differentiation of PC12 cells. EPO-promoted morphological differentiation of neuronal stem cells as well as astrocytes was dose dependently reduced by treatment with anti-EPO receptor antibodies in culture with astrocyte culture medium. To clarify whether EPO itself or via production of well-known neurotropic factor could promote neuronal cell differentiation, we determined the level of neurotropic factors in the EPO-treated astrocytes. Compared to untreated astrocytes, EPO-treated astrocytes increased about 2-fold in beta-NGF and 3-4-fold in BMP2, but did not increase BNDF and NT-3 levels. Since the previous study showed that extracellular signal-regulated kinase (ERK) is involved in activation of astrocytes by EPO, we determined whether generation of neurotrophic factor may also be involved with the ERK pathway. In the presence of ERK inhibitor, PD98059, the generation of beta-NGF was diminished in a dose dependent manner consistent with the inhibiting effect on neuronal differentiation. These data demonstrate that EPO promotes neuronal cell differentiation through increased release of beta-NGF and BMP2 from astrocytes, and this effect may be associated with ERK pathway signals.     

Activin A induces neuronal differentiation and survival via ALK4 in a SMAD-independent manner in a subpopulation of human neuroblastomas

Activin A is a multifunctional homo-dimeric protein that belongs to the transforming growth factor (TGF)-β superfamily. In neurons, activin has neuroprotective effects both in vitro and in vivo, but it inhibits neuronal differentiation in some cell lines. Here we report that activin A can promote neuronal differentiation in particular cases. We examined activin A-induced neuronal differentiation and survival in a selected subpopulation of a human neuroblastoma cell line, SK-N-SH, grown in low-serum (differentiation-inducing) conditions. Activin A caused dramatic neurite outgrowth, and increased the expression of neuronal markers and the transactivation of dopamine β-hydroxylase. We demonstrated that the activin A signal is transduced through the activin A type 1 receptor, ALK4, and transactivates several TGF-β target genes in a SMAD-independent manner. That is, activin A did not induce the phosphorylation of SMAD2/3, the interaction of SMAD2/3 with SMAD4, the binding of SMAD2/3 to the promoter of TGF-β target genes, or the accumulation of SMAD2/3 in the nucleus. These results suggest that, in particular cases, activin A can induce neuronal differentiation and support neuronal survival in vitro. These findings may reflect previously unknown functions of activin A in neuronal cells in vivo.