Role of human chromosome 11 in determining surface antigenic phenotype of normal and malignant cells. Somatic cell genetic analysis of eight antigens, including putative human Thy-1.

The expression of eight serologically and biochemically distinct human cell surface antigens defined by monoclonal antibodies was examined on a panel of rodent-human somatic cell hybrids. Cosegregation was observed for human chromosome 11, and surface expression of all eight antigens was studied. Serological analysis of hybrids containing defined segments of human chromosome 11 permitted the regional assignment of genes controlling antigens JF23 (90 kD glycoprotein), G344 (25 kD), T43 (85 kD), A124, and NP13 to chromosome 11pter-q13, and of genes controlling Q14 (130 kD), MC139 (35 kD), and K117 (25 kD) to chromosome 11q13-qter. K117, the putative human Thy-1 antigen, was expressed at high levels in chromosome 11-containing hybrids constructed with mouse neuroblastoma cells, but showed little or no expression in hybrids constructed with mouse L cells. A similar pattern of expression in hybrids was found for MC139, an antigen shared by neuroectoderm-derived cells and normal and malignant T lymphocytes. T43 is a marker of malignant tumors (but not benign tumors) derived from a number of T43- epithelia, and the regional assignment of the T43 locus on chromosome 11 raises questions about its possible involvement in the specific rearrangements of this chromosome seen in human malignancies.

Gene amplification-associated cytogenetic aberrations and protein changes in vincristine-resistant Chinese hamster, mouse, and human cells.

We carried out cytogenetic studies of four Chinese hamster, mouse, and human cell lines selected for high levels of resistance (500- to 4,000-fold) to vincristine (VCR) by a multistep selection procedure. All cells examined contained gene amplification-associated metaphase chromosome abnormalities, either homogeneously staining regions (HSRs), abnormally banding regions (ABRs), or double-minute chromosomes (DMs); control actinomycin D- and daunorubicin-resistant hamster lines did not exhibit this type of chromosomal abnormality. VCR-resistant Chinese hamster sublines exhibited both increased synthesis of the protein V19 (Mr 19,000; pl = 5.7) and increased concentrations of V19 polysomal mRNA. When VCR-resistant cells were grown in drug-free medium, level of resistance, synthesis of V19, and amount of V19 mRNA declined in parallel with mean length of the HSR or mean number of DMs per cell. Cross-resistance studies indicate that VCR-resistant cells have increased resistance both to antimitotic agents and to a wide variety of agents unrelated to VCR in chemical structure and/or mechanism of action. Our studies of tubulin synthesis in Chinese hamster cells indicate no overproduction of tubulin or presence of a mutant tubulin species. Comparison with antifolate-resistant Chinese hamster cells known to contain amplified dihydrofolate reductase genes localized to HSRs or ABRs strongly suggests that the HSRs, ABRs, or DMs of the Vinca alkaloid-resistant sublines likewise represent cytological manifestations of specifically amplified genes, possibly encoding V19, involved in development of resistance to VCR.

Metaphase chromosome anomaly: association with drug resistance and cell-specific products.

Large, homogeneously staining chromosome regions which lack the longitudinal differentiation ordinarily revealed by cytogenetic "banding" methods have been found in antifolate-resistant Chinese hamster cells and also in human neuroblastoma cells established in vitro. The drug-resistant cells are characterized by excessive production of the target enzyme, dihydrofolate reducatase, while the human neuroblastoma cells have phenotypes of normal neuronal cells. The homogeneously staining region appears to represent a novel metaphase chromosome anaomaly which may have functional significance in cells with specialized properties.

Human melanoma proteoglycan: expression in hybrids controlled by intrinsic and extrinsic signals.

Human malignant melanoma cells express specific chondroitin sulfate proteoglycans (mel-CSPG) on the surface, both in vivo and in vitro. Melanocytes in normal skin show no detectable mel-CSPG but can be induced to express the antigen when cultured in the presence of cholera toxin and the tumor promoter 12-O-tetradecanoylphorbol-13-acetate. Most other cell types do not express mel-CSPG either in vivo or in vitro. A study was designed to examine regulatory signals controlling mel-CSPG expression. The gene encoding mel-CSPG was mapped to human chromosome 15, and this chromosome was introduced into rodent cells derived from distinct differentiation lineages. Three types of mel-CSPG--expressing hybrids were found: (i) hybrids derived from human melanomas; (ii) hybrids derived from human cells that do not express mel-CSPG; and (iii) hybrids derived from human cells expressing mel-CSPG that are antigen-negative but that are induced to express mel-CSPG when cultured on extracellular matrix instead of plastic surfaces. Thus, mel-CSPG expression can be controlled both through intrinsic signals, provided by the differentiation program of the rodent fusion partner, and through extrinsic signals, provided by specific cell-matrix interactions.

Loss of one HuD allele on chromosome #1p selects for amplification of the N-myc proto-oncogene in human neuroblastoma cells.

In human neuroblastoma tumors, amplification of the N-myc proto-oncogene and loss of all or part of the short arm of chromosome #1 are both associated with a poor prognosis. Accruing evidence indicates that it is the absence of one allele of the HuD (ELAVL4) gene, encoding the neuronal-specific RNA-binding protein HuD and localized to 1p34, that is linked to amplification. In 12 human neuroblastoma cell lines, N-myc amplification correlates with loss of one HuD allele and decreased HuD expression. Transfection experiments demonstrate that modulating HuD expression affects N-myc gene copy number as well as expression. Introduction of a sense HuD construct into two N-myc amplified cell lines considerably increases N-myc expression whereas gene copy number decreases. Conversely, expression of antisense HuD in N-myc nonamplified SH-SY5Y cells reduces HuD and N-myc mRNA levels even as cells show amplification of the N-myc gene. Thus, N-myc gene copy number is modulated by alteration of HuD expression. We propose that haploinsufficiency of HuD due to chromosome #1p deletion in neuroblastoma selects for cells that amplify N-myc genes. Application of these findings could lead to more effective therapies in the treatment of those patients with the worst prognosis.

Gene rearrangement: a novel mechanism for MDR-1 gene activation.

Drug resistance, a major obstacle to cancer chemotherapy, can be mediated by MDR-1/P-glycoprotein. Deletion of the first 68 residues of MDR-1 in an adriamycin-selected cell line after a 4;7 translocation, t(4q;7q), resulted in a hybrid mRNA containing sequences from both MDR-1 and a novel chromosome 4 gene. Further selection resulted in amplification of a hybrid gene. Expression of the hybrid mRNA was controlled by the chromosome 4 gene, providing a model for overexpression of MDR-1. Additional hybrid mRNAs in other drug-selected cell lines and in patients with refractory leukemia, with MDR-1 juxtaposed 3' to an active gene, establishes random chromosomal rearrangements with overexpression of hybrid MDR-1 mRNAs as a mechanism of acquired drug resistance.

A novel chromosome abnormality in human neuroblastoma and antifolate-resistant Chinese hamster cell lives in culture.

Four cell lines, SK-N-SH, SK-N-MC, SK-N-BE(2), and IMR-32, established in vitro from tumor tissue of patients with neuroblastoma were analyzed by trypsin-Giemsa banding methods. In two of the lines a large, abnormally staining chromosome region was observed. This "homogeneously staining region" (HSR) was considerably longer than any of the bands present in normal human cells and, as revealed by both G- and Q-banding, stained with an intermediate intensity. It was located on chromosomes No 6, 10, 17, or 19 of the SK-N-BE(2) cell line and on chromosome No 1 of the IMR-32 line. In concurrent studies, long HSR's were also observed in Chinese hamster sublines that had been exposed to and had developed high levels of resistance to methotrexate or methasquin and high levels of activity of target enzyme dihydrofolate reductase. For several sublines with the highest levels of enzyme activity, approximately 2% of the total cell protein was dihydrofolate reductase. Of 13 independently derived sublines with acquired resistance to antifolate, only those 7 with greater than 100-fold increases in enzyme activity consistently exhibited HSR's. These regions comprised 2-5% of the total length of the chromosome complement and were specifically localized, as demonstrated by G-banding. Analysis of chromosome replication patterns of the HSR in human neuroblastoma and in drug-resistant Chinese hamster cells by tritiated thymidine radioautography indicated that the long, abnormally staining region replicated relatively rapidly and synchronously and terminated replication before the midpoint of the S phase. The HSR thus appeared to represent a novel chromosome abnormality that may be present in cells with specialized functions. Drug-resistant Chinese hamster cells were characterized by overproduction of target enzyme, whereas human neuroblastoma cells had phenotypes of normal neuronal cells. Whether the HSR is transcriptionally active was not elucidated.

Coordinate morphological and biochemical interconversion of human neuroblastoma cells.

This study was undertaken to determine whether the two type of cells (one neuroblast-like and the other epithelial in appearance) of the human neuroblastoma line SK-N-SH in culture undergo morphological interconversion, whether conversion is bidirectional, and whether there are coordinate neurochemical changes. Phenotypic analysis of serially isolated neuroblast clones (SH-SY, SH-SY5, SH-SY5Y) revealed conversion to epithelial-like cells. Conversely, conversion also was promoted from an epithelial-like clone (SH-EP) to neuroblastic subclones. Cell origin could be verified because of a marker chromosome specific to SH-EP. Only neuroblastic subclones of SH-EP contained activities for tyrosine hydroxylase and dopamine-beta-hydroxylase, enzymes unique to catecholamine neurons; epithelial-like cells lacked activities for these enzymes. These findings indicate a coordinate morphological and biochemical interconversion of neuroblastoma SK-N-SH cells and reveal a plasticity in phenotypic expression in malignant neuronal cells.

Membrane-mediated drug resistance and phenotypic reversion to normal growth behavior of Chinese hamster cells.

Development of resistance to actinomycin D, daunomycin, or vincristine in Chinese hamster cells growing in vitro resulted in reversion to or retention of normal phenotypes in comparison to spontaneously transformed drug-sensitive parent populations. Sublines resistant or cross-resistant to actinomycin D showed reduced uptake of antibiotic in proportion to degree of resistance. The cells with acquired resistance were either weakly tumorigenic or nontumorigenic when tested in the cheek pouches of weanling Syrian hamsters treated with cortisone. In contrast, parent cells and several amethopterin (methotrexate)-resistant sublines produced many tumors. Antibiotic- and Vinca-alkaloid-resistant cell lines showed oriented growth patterns often associated with the behavior of normal cells in culture; antibiotic-sensitive, tumorigenic lines had morphologic characteristics of malignant cells. The altered cell membrane properties that accompanied development of resistance or cross-resistance to actinomycin D appeared to account also for the lower oncogenic potential and greater cell adhesiveness of resistant cells relative to their malignant counterparts.

Characterization of human neuroblastoma cell lines established before and after therapy.

Six new cell lines have been established from human neuroblastomas. Cell line SMS-KAN, from primary tumor before therapy, and line SMS-KANR, from bone marrow after chemotherapy and radiotherapy, were established from the same patient. Cell lines SMS-KCN (from primary tumor before any therapy) and SMS-KCNR (from bone marrow after chemotherapy) were established from another patient. Two other lines (SMS-MSN and SMS-SAN) were established from different patients before any therapy was given. Cell lines established from recurrent disease after chemotherapy (SMS-KANR and SMS-KCNR) had significantly shorter doubling times and increased plating efficiencies compared to those of cell lines derived from the same patient before chemotherapy (SMS-KAN and SMS-KCN). All cell lines contained tyrosine hydroxylase, aromatic L-amino acid decarboxylase, and dopamine-beta-hydroxylase. Measurable amounts of choline acetyltransferase were also detected in SMS-KAN and SMS-KANR. Karyotype analysis showed all cell lines except SMS-MSN to be pseudodiploid with modal numbers of 46 and deletions of the short arm of chromosome 1; SMS-MSN had a modal number of 57-58 chromosomes. All cell lines had double-minute chromosomes, except SMS-KANR, which had abnormally banding regions. These new cell lines provide in vitro models of neuroblastoma suitable for the study of differences in neuroblastoma cell populations before chemotherapy as compared to the cell populations that proliferate after therapy.

Differential collagen biosynthesis by human neuroblastoma cell variants.

Two morphologically distinct types of cells have been observed in cultures of human neuroblastoma cells. One, designated N-type, is composed of small neuroblast-like cells; the other, designated S-type, is composed of large, substrate-adherent cells. To obtain additional information on the nature of these two phenotypes, we have investigated the collagen biosynthesis in several clones of human neuroblastoma cells with N-type, S-type, or mixed morphology, using acrylamide gel electrophoresis, ion exchange chromatography, and Northern and Southern blots. A direct correlation between the proportion of cells with S-type morphology and the amount of collagen secreted was observed, with the largest amount of collagen being produced by clones composed exclusively of S-type cells. Type I trimer and type III collagens were the two major isotypes secreted by these cells. The absence of secretion of the alpha 2(I) collagen chain was associated with absence of RNA coding for this protein chain. The pro-alpha 2 gene of type I collagen was found highly methylated in these cells. Our data indicate that the presence of S-type cells in neuroblastoma cultures represents a differentiation of these neural crest-derived neuroblastic cells into glial cells such as Schwann cells.

Chromosomal localization of three genes coamplified in the multidrug-resistant CHRC5 Chinese hamster ovary cell line.

At least five gene classes are amplified in the multidrug-resistant CHO cell line CHRC5. Protein products have been identified for two classes; class 2 codes for the large membrane P-glycoprotein, whereas class 4 encodes the small cytoplasmic calcium-binding protein sorcin (V19). By DNA analysis we have shown previously that these five genes are linked in two groups: class 1 + 2 + 3; and class 4 + 5. By use of in situ hybridization with complementary DNAs derived from the resistant cell line we demonstrate here that genes from both linkage groups are amplified and situated together in each of two different chromosomal regions of the resistant Chinese hamster cell line. The positions of the amplicons correspond to cytogenetically identified homogeneously staining regions in an altered 7q+ chromosome and in a rearranged Z-7 [t(3;4)] chromosome. The native genes were mapped both in the CHRC5 line and in a normal diploid Chinese hamster cell strain, CHNF 86. We confirm the position of the class 2 gene on 1q26 and we show that class 4 and 5 genes are located in the same region of 1q. We conclude that the gene classes 2, 4, and 5 are closely juxtaposed in the normal Chinese hamster genome and comprise one amplicon in resistant cells. Our results are compatible with the hypothesis that multidrug resistance is due to overexpression of P-glycoprotein genes and that the other genes amplified in the CHRC5 line are coamplified because they happen to lie close to the P-glycoprotein genes.

Phenotypic diversification in human neuroblastoma cells: expression of distinct neural crest lineages.

Previous studies of the human neuroblastoma cell line SK-N-SH had demonstrated the presence of and phenotypic interconversion (transdifferentiation) between two morphologically and biochemically distinct cell types: N (neuroblastic) cells with properties of noradrenergic neurons and S (substrate-adherent) cells with properties of melanocytes. Current studies have sought to test the generality of these findings among other cultured human neuroblastoma cell lines and to define further the S-cell phenotype and that of a newly identified, morphologically intermediate, I-type cell. Morphologically homogeneous populations (clonal sublines or subpopulations) of N, S, and I cells were isolated from five additional neuroblastoma cell lines and analyzed biochemically for neuronal, glial, and melanocytic marker enzyme activities and norepinephrine uptake. Immunoblot techniques were used to detect intermediate filament proteins (neurofilament protein, vimentin, glial fibrillary acidic protein) and fibronectin. All N-type cells exhibited neuronal marker enzyme activities, specific uptake of norepinephrine, and presence of one or more neurofilament proteins. S-type cells generally lacked neuronal characteristics but contained, instead, tyrosinase activity (a melanocytic marker enzyme), vimentin, and fibronectin. This combination of attributes is suggestive of a multipotent embryonal precursor cell of the neural crest. I-type cells differentially expressed both S- and N-cell properties and could represent either a stem cell or an intermediate in the transdifferentiation process. Studies of the biological significance of human neuroblastoma cell transdifferentiation and the molecular mechanisms underlying this process may be of relevance to the biological and clinical behavior of this tumor in the patient.

Chromosomal organization of amplified genes in multidrug-resistant Chinese hamster cells.

Six independently derived multidrug-resistant Chinese hamster cell lines selected with vincristine, daunorubicin, actinomycin D, or colchicine were probed by in situ hybridization techniques with the cloned cDNA, p5L-18, to chromosomally localize known or presumed amplified P-glycoprotein genes. One or two clusters of amplified genes were demonstrable in all of the highly resistant sublines and were localized to homogeneously staining regions and/or abnormally banding regions, gene amplification-associated cytogenetic abnormalities, on eight different chromosomes. Analysis of trypsin-Giemsa banded karyotypes revealed additional, multiple chromosomal rearrangements that were apparently nonspecific. Mapping studies localized the native P-glycoprotein gene(s) to the region q23 to 31 (most probably band 26) on the long arm of chromosome 1 of normal Chinese hamster bone marrow fibroblasts and normal chromosome 1 homologues in resistant cells. Southern blot analysis of restriction endonuclease fragments indicated the amplification of one or both of (at least) two wild-type nonallelic genes in four of the lines and the presence in one line (DC-3F/DMM XX) of a unique 5.0-kilobase BamHI fragment resulting from a recombinational event during amplification. Comparison with the cytogenetic data indicated no correlation between restriction patterns generated by EcoRI, HindIII, PstI, or BamHI and chromosomal location of amplified genes. However, the only sublines in which the homogeneously staining region or abnormally banding region is positioned at 1q26 (at or near the site of the native gene) exhibit either alterations in gene structure (DC-3F/DM XX) or in regulation of gene expression (DC-3F/AD X), suggesting a process more complex than simply amplification of the gene in loco.

Coordinate changes in neuronal phenotype and surface antigen expression in human neuroblastoma cell variants.

Human neuroblastoma cells growing in culture offer a unique opportunity to study proliferating human cells with a neuronal phenotype. We have previously identified several neuroblastoma cell lines which show spontaneous conversion (N/S interconversion) between two morphologically distinct cell types: neuroblastic (N-type) cells and variant, substrate-adherent (S-type) cells resembling cultured glial or mesenchymal cells. In the present study, we have used molecular markers to confirm the neuronal phenotype of N-type cells and to demonstrate that S-type cells have a nonneuronal phenotype. Furthermore, we have used these markers, including a series of cell surface differentiation antigens, to compare S-type neuroblastoma cells with a wide range of cultured epithelial, mesenchymal, and neuroectodermal cells. The results suggest that N/S interconversion represents an ordered transition between two neuroectodermal differentiation programs rather than random phenotypic instability of cultured cells; S-type variant cells show a molecular phenotype most closely resembling the phenotype of cultured ectomesenchymal cells; and in vitro variant formation of human neuroblastomas may provide an experimental model for the observed in vivo transition of some malignant neuroblastomas into benign ganglioneuromas.

Radiation-induced murine leukemia ERLD in cell culture.

The lymphoblastic leukemia ERLD, induced by radiation in a C57BL/6 mouse, was established in culture. Three cell lines, ERLD/Y3, ERLD/T ERLD/Two, have been in culture for nearly three years. Their isolation and growth depended upon the presence of 2-mercaptoethanol, glutamine, and asparagine in the medium. The cell lines, except ERLD/T, possess the TL antigen, a characteristic of ERLD and of other murine leukemia cells in vivo and of normal thymus cells of certain mouse strains, but not of C57BL/6. A distinctive submetacentric marker chromosome is also common to ERLD and the derived cell lines. The successful establishment of ERLD in culture provides a malignant thymocyte-related cell system for studies in nutrition and immunobiology.

Brain-derived neurotrophic factor protects neuroblastoma cells from vinblastine toxicity.

Brain-derived neurotrophic factor (BDNF) and its receptors are necessary for the survival and development of many neuronal cells. Because BDNF and TrkB are expressed in many poor-prognosis neuroblastoma (NB) tumors, we evaluated the role of BDNF in affecting sensitivity to chemotherapeutic agents. We investigated the effects of activation of the BDNF-TrkB signal transduction pathway in two NB cell lines, 15N and SY5Y. 15N cells lack the high-affinity receptor p145TrkB and express BDNF; 15N cells were used along with 15N-TrkB cells, a subline transfected with a TrkB expression vector. In cytotoxicity assays, 15N-TrkB cells were consistently 1.4-2 fold more resistant to vinblastine than 15N cells. Drug accumulation assays showed a 50% reduction in[3H]vinblastine accumulation in 15N-TrkB cells compared with control 15N cells. Addition of 30 ng/ml BDNF resulted in a reduction to 46% of control in 15N cells and a reduction to 28% of control in 15N-TrkB cells. SY5Y cells were chosen as a second model because they lack both endogenous BDNF and TrkB expression. p145TrkB expression is induced by 1 nM retinoic acid. Vinblastine accumulation was not significantly affected by 1 nM retinoic acid in SY5Y cells. Addition of 30 ng/ml BDNF decreased [3H]vinblastine accumulation to 58% of control in SY5Y cells and decreased [3H]vinblastine accumulation to 62% of control in TrkB-expressing SY5Y cells. Although an increase in BDNF expression in seen in multidrug-resistant sublines of SY5Y and BE(2)-C NB cells, the protective effect of BDNF in vinblastine toxicity may be unrelated to mdr-1, because the activity of other agents transported by P-glycoprotein was not affected. There was no increase in mdr-1 expression in 1 nM RA SY5Y cells and 15N-TrkB cells, as assessed by Northern blot analysis. In addition to the effects of BDNF on vinblastine cytotoxicity and accumulation, there was an inhibition in the ability of vinblastine to depolymerize tubulin in BDNF-treated cells. Thus, BDNF and TrkB may partially rescue NB cells from vinblastine toxicity and thereby may contribute to a more chemoresistant phenotype.

Low frequency of ras gene mutations in neuroblastomas, pheochromocytomas, and medullary thyroid cancers.

Little is known about the prevalence and significance of ras gene activation in neural crest tumors such as neuroblastomas, pheochromocytomas, and medullary thyroid cancers (MTCs). Therefore, we analyzed DNA from 10 human neuroblastoma cell lines and 10 primary human pheochromocytomas for activating mutations in N-ras, H-ras, and K-ras. We also studied DNA from 24 primary neuroblastomas and 10 MTCs for N-ras mutations. ras genes were analyzed by direct sequencing of specific DNA fragments amplified by the polymerase chain reaction. With the exception of the SK-N-SH cell line, the examined ras gene sequences were normal in all the neuroblastomas, pheochromocytomas, and MTCs tested. A single point mutation was identified at codon 59 (GCT(ala)----ACT(thr)) in one N-ras allele in an SK-N-SH subline. Interestingly, this mutation is different from the activating codon 61 mutation which resulted in the initial identification of N-ras from SK-N-SH DNA. Therefore, we analyzed the sequences of earlier passages and sublines of the SK-N-SH cell line, but mutations at codon 59 or 61 were not detected, suggesting that neither mutation was present in the primary tumor. Our results indicate that N-ras mutations may occur spontaneously during in vitro passage of cell lines but rarely, if ever, occur in primary neuroblastomas, pheochromocytomas, and MTCs. In addition, we have not found H-ras or K-ras mutations in any neuroblastoma cell line or primary pheochromocytoma.

Regulation of Bcl-2 oncoprotein levels with differentiation of human neuroblastoma cells.

When established in culture, human neuroblastoma cell lines typically are comprised of heterogeneous cellular subpopulations, including neuroblastic (N-type), substrate-adherent (S-type), and intermediate (I-type) cells that can be distinguished by their characteristic morphologies and expression of differentiation-associated antigens. Here we examined the relative levels of the Bcl-2 oncoprotein in 15 clones derived from four different neuroblastoma cell lines. Among six clones isolated from the SK-N-SH line, levels of p26-Bcl-2 correlated with morphology and differentiation markers with the hierarchy of bcl-2 expression being: N-type cells > N/I-type > I-type > S-type. Furthermore, stimulation of one of the N-type clones, SH-SY5Y, with the phorbol ester, 12-O-tetradecanoylphorbol-13-acetate, induced differentiation toward a more neuronal-like phenotype and resulted in a 5- to 10-fold elevation in the relative levels of Bcl-2 protein. High relative amounts of p26-Bcl-2 protein were also found in an N-type clone derived from the SMS-KCN line. In two N-type clones derived from the LA-N-1 line, however, levels of Bcl-2 protein were only moderately elevated, and in one N-type clone from the SK-N-BE(2) line the levels of Bcl-2 protein were low. Thus, high relative levels of Bcl-2 oncoprotein are not a universal feature of N-type cells (three of six clones tested). In contrast, all 5 of the S-type clones evaluated contained relatively low levels of Bcl-2 protein, suggesting that these cells (which may represent embryonic precursors of Schwann, glial, and melanocytic cells) do not typically express the bcl-2 gene at high levels. Consistent with this inverse correlation between Bcl-2 protein levels and S-type characteristics, stimulation of an I-type clone derived from the SK-N-BE(2) line with 5-bromodeoxyuridine was accompanied by an accumulation of S-type cells in these cultures, decreased Bcl-2 protein, diminutions in the neuronal markers neurofilament-M and neuron-specific enolase, and an increase in the relative levels of the S-type marker proteins vimentin and beta-2-microglobulin. Conversely, stimulation of this I-type clone with retinoic acid resulted in an accumulation of N-type cells (which are thought to represent embryonic precursors of sympathetic neurons), decreased vimentin and beta-2-microglobulin, increased neurofilament-M, and a marked elevation in p26-Bcl-2.(ABSTRACT TRUNCATED AT 400 WORDS)

HuD, a neuronal-specific RNA-binding protein, is a putative regulator of N-myc pre-mRNA processing/stability in malignant human neuroblasts.

N-myc gene copy numbers and transcription rates are similar in N (neuroblastic, tumorigenic) and S (non-neuronal, non-tumorigenic) neuroblastoma cells with chromosomally integrated amplified N-myc genes. However, N cells show significantly higher N-myc mRNA levels than S cells. Therefore, post-transcriptional control of N-myc gene expression must differ between these cell types. Since no differences in N-myc mRNA half-life were found between N and S cells from two cell lines, steady-state levels of N-myc pre-mRNA processing intermediates were analysed. Results suggest that the differences in N-myc expression arise primarily at the nuclear post-transcriptional level. The neuronal-specific RNA-binding Hu proteins are present in cytoplasmic and nuclear fractions of N cells and one of them, HuD, binds specifically to both exonic and intronic N-myc RNA sequences. In sense and antisense HuD-transfected N cells, there are coordinate changes in HuD and N-myc expression levels. Thus, we propose that HuD plays a role in the nuclear processing/stability of N-myc pre-mRNA in N-type neuroblastoma cells.