Hypoxia induces up-regulation of progranulin in neuroblastoma cell lines

Progranulin (PGRN) is a widely expressed multifunctional protein, involved in regulation of cell growth and cell cycle progression with a possible involvement in neurodegeneration. We looked for PGRN regulation in three different human neuroblastoma cell lines, following exposure to two different stimuli commonly associated to neurodegeneration: hypoxia and oxidative stress. For gene and protein expression analysis we carried out a quantitative RT-PCR and western blotting analysis. We show that PGRN is strongly up-regulated by hypoxia, through the mitogen-actived protein kinase (MAPK)/extracellular signal-regulated kinase (MEK) signaling cascade. PGRN is not up-regulated by H(2)O(2)-induced oxidative stress. These results suggest that PGRN in the brain could exert a protective role against hypoxic stress, one of principal risk factors involved in frontotemporal dementia pathogenesis.     

Retinoic acid treatment of human neuroblastoma cells is associated with decreased N-myc expression

Cells from human neuroectodermal tumors (retinoblastoma and neuroblastoma) and from neuroblastoma cell lines express a gene, N-myc, which is frequently amplified in these tumors. We report here that N-myc mRNA content is markedly decreased in cells of a neuroblastoma cell line (LA-N-5) following differentiation induced with retinoic acid. Exposure of the cells to retinoic acid induced morphologic changes consistent with neuronal differentiation, and led to a 75% decrease in expression of N-myc mRNA. These results suggest that N-myc expression is intimately related to an undifferentiated phenotype in neuroblastoma cells, and support other studies which relate N-myc expression to the malignant phenotype in neuroblastoma tumors.     

N-myc down regulates neural cell adhesion molecule expression in rat neuroblastoma.

In human neuroblastoma, amplification of the N-myc oncogene is correlated with increased metastatic ability. We recently showed that transfection of the rat neuroblastoma cell line B104 with an N-myc expression vector resulted in an increase in metastatic ability and a significant reduction in the expression of major histocompatibility complex class I antigens. We examined whether N-myc causes additional phenotypic changes in these cells. We showed that expression of N-myc leads to a dramatic reduction in the levels of neural cell adhesion molecule (NCAM) polypeptides and mRNAs. Spontaneous revertants of the high N-myc phenotype were found to have regained significant levels of NCAM expression, indicating that the continued expression of N-myc is required to maintain the low NCAM phenotype. NCAM was not reduced in B104 cells transfected with the neomycin resistance vector alone, and other neuronal markers were not specifically reduced in N-myc-transfected B104 cells. As NCAM functions in cell-cell adhesion, decreased NCAM expression could contribute significantly to the increased metastatic potential of N-myc-amplified neuroblastomas.     

Piceatannol promotes apoptosis via up-regulation of microRNA-129 expression in colorectal cancer cell lines

Piceatannol, a naturally occurring analog of resveratrol, has been confirmed as an antitumor agent by inhibiting proliferation, migration, and metastasis in diverse cancer. However, the effect and mechanisms of piceatannol on colorectal cancer (CRC) have not been well understood. This study aimed to test whether piceatannol could inhibit growth of CRC cells and reveal its underlying molecular mechanism.     

N-myc expression switched off and class I human leukocyte antigen expression switched on after somatic cell fusion of neuroblastoma cells.

Neuroblastomas often show amplification and high expression of the N-myc oncogene. N-myc expression could be explained as a consequence of gene amplification, but an alternative possibility is that expression primarily results from the inactivation or loss of some factor that normally represses the N-myc gene. To test this idea, we fused N-myc-overexpressing neuroblastoma cell lines with lines that do not express N-myc. In the resulting hybrids, N-myc expression turned out to be switched off, although amplified N-myc copies were still present. This suggests that N-myc overexpression in neuroblastomas results, at least in part, from the inactivation of a suppressor gene that is present in normal cells. In rat neuroblastomas, it has been found that N-myc can switch off class I major histocompatibility complex (MHC) expression. Therefore, we analyzed in our hybrid cells whether suppression of N-myc results in reexpression of human class I MHC genes. Because this was found to be the case, the picture emerges of a hierarchic pathway that connects a putative tumor-suppressor gene with the expression of N-myc and consequently of class I MHC, thus affecting the potential immunogenic properties of neuroblastomas.     

Characterization of DNA rearrangements of N-myc gene amplification in three neuroblastoma cell lines by pulsed-field gel electrophoresis

We characterized N-myc gene amplification in three human neuroblastoma cell lines (IMR-32, TGW, GOTO). Rearrangements in long-range regions surrounding amplified N-myc genes were examined by pulsed-field gel electrophoresis. Since rare-cutting enzymes completely digested DNA at the middle of the N-myc gene, we were able to construct a physical map upstream and downstream of the germline N-myc gene, and to obtain information on restriction sites surrounding amplified N-myc genes. This method enables us to envisage the organization of amplified units over a long range. Digestion patterns differed considerably among the germline and the three cell lines, but were simple in each case. We estimated that the minimal distance between neighboring N-myc genes is at least several hundred kilobases. Our data suggest that amplification units contain several DNA fragments derived from ditterent loci, but that they are homogeneous.     

Plasma membrane redox activity correlates with N-myc expression in neuroblastoma cells.

In different neuroblastoma cell lines and transfected clones, an increasing plasma membrane redox activity correlates with amplification and enhanced expression of the N-myc oncogene. Furthermore, plasma membrane redox activity is partially inhibited by retinoic acid in neuroblastoma cells with multiple copies of the N-myc oncogene but not in neuroblastoma cells with only one copy of this gene.     

Excision of N-myc from chromosome 2 in human neuroblastoma cells containing amplified N-myc sequences.

Amplification of one of three growth-stimulating myc genes is a common method by which many tumor types gain a proliferative advantage. In metastatic human neuroblastoma, the amplification of the N-myc locus, located on chromosome 2, is a dominant feature of this usually fatal pediatric cancer. Of the many models proposed to explain this amplification, all incorporate as the initial step either disproportionate overreplication of the chromosomal site or recombination across a loop structure. The original locus is retained within the chromosome in the overreplication models but is excised in the recombination models. To test these models, we have used somatic cell hybrids to separate and analyze the chromosomes 2 from a neuroblastoma cell line containing in vivo amplified N-myc. Our results demonstrate that N-myc is excised from one of the chromosomes, suggesting that deletion is a requisite part of gene amplification in a naturally occurring system.     

Characterization of N-myc amplification units in human neuroblastoma cells.

A set of DNA clones comprising 48 independent HindIII fragments (215 kilobases of sequence) was derived from the N-myc amplification unit of the neuroblastoma cell line NGP. These clones were used to investigate N-myc amplification units in NGP cells and 12 primary neuroblastoma tumors. Three parameters were evaluated: (i) the number of rearrangements from germ line configuration that had occurred during the amplification process; (ii) the homogeneity of amplification units within individual tumors; and (iii) the conservation of amplified sequences among different tumors. The results indicated that remarkably few rearrangements had occurred during amplification, that the amplification units within any one tumor were quite homogeneous, and that although each tumor contained a unique pattern of amplified DNA fragments, there was considerable similarity between the amplification units of different tumors. In particular, the amplification units were strikingly similar over a contiguous domain of at least 140 kilobases surrounding the N-myc structural gene.     

Identification of a FXIIIA variant in human neuroblastoma cell lines

FXIII is a transglutaminase consisting of two catalytic (FXIIIA) and two non-catalytic subunits (FXIIIB) in plasma, where this enzyme is responsible for stabilizing fibrin clots. Although possible functions of intracellular FXIIIA have been proposed, these remain to be established. We show that a 40 kDa protein species of FXIIIA is present in the human neuroblastoma cell lines SH-SY5Y and LAN5. These data reveal the presence of a new uncharacterised variant of FXIIIA, possibly due to an alternative splicing, in nervous cells.     

Down-regulation of endothelial cell growth inhibitors by enhanced MYCN oncogene expression in human neuroblastoma cells.

Recent evidence indicates that the genetic alterations of the multistage process of malignant transformation appear to activate tumor neovascularization by altering the balance between stimulators and inhibitors of angiogenesis. In the present study, we have attempted to define the effect of enhanced MYCN oncogene expression on the profile of endothelial cell growth modulators in neuroblastoma cells. We report here that conditioned medium of human neuroblastoma cells with normal MYCN expression contains three inhibitors of endothelial cell proliferation, which appear to be novel proteins as judged by their physicochemical, immunological and biological properties. All three inhibitors are diminished or become undetectable upon experimental increase of MYCN expression. Our results suggest that enhanced MYCN expression in human neuroblastoma cells alters the angiogenic balance by down-regulating endothelial cell growth inhibitors but leaving the expression of the stimulators unaffected. These data shed light on the molecular mechanisms linking the genetic changes of malignant transformation with initiation of tumor angiogenesis. Moreover, our observations might explain the poor prognosis of human neuroblastomas following MYCN oncogene amplification through initiation of angiogenesis and subsequent tumor growth and spread.     

Expression of HOX homeogenes in human neuroblastoma cell culture lines

Mammalian genes containing a class-I homeobox (HOX genes) are highly expressed in the embryonic nervous system. As a first step towards the molecular analysis of the role these genes play in neural cells, we studied the expression of four human HOX genes in five neuroblastoma (NB) cell lines - SK-N-BE, CHP-134, IMR-32, SK-N-SH and LAN-1 - during the process of differentiation induced by treatment with retinoic acid (RA). The four genes, HOX1D, 2F, 3E and 4B, located at corresponding positions in the four HOX loci, share a high degree of sequence similarity with the Drosophila Deformed homeotic gene and constitute a homology group, group 10. One of these genes, HOX1D, is not expressed in the cells used, whereas the other three are highly expressed in untreated and RA-induced NB cells, even though the expression pattern in the various lines is slightly different for the three genes. Our analysis reveals a complex and specific expression pattern in these lines, paving the way to an identification of different NB-cell populations by means of specific HOX gene expression schemes. On the other hand, in every line studied, morphological maturation toward a neuronal differentiated phenotype appears to be associated with increased HOX gene expression.     

Absence of MGST1 mRNA and protein expression in human neuroblastoma cell lines and primary tissue

A recent study identified a haplotype on a small region of chromosome 12, between markers D12S1725 and D12S1596, shared by all patients with familial neuroblastoma (NB). We previously localized the human MGST1 gene, whose gene product protects against oxidative stress, to this very same chromosomal region (12p112.1–p13.33). Owing to the chromosomal location of MGST1; its roles in tumorigenesis, drug resistance, and oxidative stress; and the known sensitivity of NB cell lines to oxidative stress, we considered a role for MGST1 in NB development. Surprisingly there was no detectable MGST1 mRNA or protein in either NB cell lines or NB primary tumor tissue, although all other human tissues, cell lines, and primary tumor tissue examined to date express MGST1 at high levels. The mechanism behind the failure of NB cells and tissue to express MGST1 mRNA is unknown and involves the failure of MGST1 pre-mRNA expression, but does not involve chromosomal rearrangement or nucleotide variation in the promoter, exons, or 3' untranslated region of MGST1. MGST1 provides significant protection against oxidative stress and constitutes 4 to 6% of all protein in the outer membrane of the mitochondria. As NB cells are extremely sensitive to oxidative stress, and often used as a model system to investigate mitochondrial response to endogenous and exogenous stress, these findings may be due to the lack of expression MGST1 protein in NB. The significance of this finding to the development of neuroblastoma (familial or otherwise), however, is unknown and may even be incidental. Although our studies provide a molecular basis for previous work on the sensitivity of NB cells to oxidative stress, and possibly marked variations in NB mitochondrial homeostasis, they also imply that the results of these earlier studies using NB cells are not transferable to other tumor and cell types that express MGST1 at high concentrations.     

Ectopic expression of Flt3 kinase inhibits proliferation and promotes cell death in different human cancer cell lines

Stable ectopic expression of Flt3 receptor tyrosine kinase is usually performed in interleukin 3 (IL-3)-dependent murine cell lines like Ba/F3, resulting in loss of IL-3 dependence. Such high-level Flt3 expression has to date not been reported in human acute myeloid leukemia (AML) cell lines, despite the fact that oncogenic Flt3 aberrancies are frequent in AML patients. We show here that ectopic Flt3 expression in different human cancer cell lines might reduce proliferation and induce apoptotic cell death, involving Bax/Bcl2 modulation. Selective depletion of Flt3-expressing cells occurred in human AML cell lines transduced with retroviral Flt3 constructs, shown here using the HL-60 leukemic cell line. Flt3 expression was investigated in two cellular model systems, the SAOS-2 osteosarcoma cell line and the human embryonic kidney HEK293 cell line, and proliferation was reduced in both systems. HEK293 cells underwent apoptosis upon ectopic Flt3 expression and cell death could be rescued by overexpression of Bcl-2. Furthermore, we observed that the Flt3-induced inhibition of proliferation in HL-60 cells appeared to be Bax-dependent. Our results thus suggest that excessive Flt3 expression has growth-suppressive properties in several human cancer cell lines.     

Nerve growth factor-induced differentiation of human neuroblastoma and neuroepithelioma cell lines

A series of neuroepithelioma and neuroblastoma cell lines were screened for nerve growth factor (NGF)-induced differentiation. All three neuroepithelioma cell lines and all nine neuroblastoma cell lines with amplified N-myc oncogene did not show any apparent NGF-induced differentiation. However, neurite extension was observed for three of six neuroblastoma cell lines with single-copy N-myc oncogene. The three responsive lines had a neuronal phenotype (short processes) which was enhanced by the addition of NGF. The three nonresponsive cell lines were flat without any processes. The addition of NGF to the responsive cell lines resulted in an up-regulation of neurofilament mRNA expression. Peripherin and synapsin, two markers of terminal neuronal differentiation, were not induced. There was little effect of NGF on the rate of cell growth or colony formation on soft agar. Binding of NGF to eight of the cell lines was analyzed by the method of Scatchard. Two responsive neuroblastoma cell lines and one nonresponsive neuroepithelioma cell line expressed both low- and high-affinity binding sites. Two nonresponsive neuroblastoma cell lines expressed only a small number of high-affinity binding sites, and two other nonresponsive neuroblastoma cell lines did not detectably bind NGF. Hence, NGF-induced differentiation is confined to a particular class of neural-related tumors, and, even for these cell lines, differentiation is incomplete.     

Variant human neuroblastoma cell lines resistant to the differentiation-inducing effect of interferon-gamma

Human recombinant interferon, (rIFN)-gamma, induced a human neuroblastoma cell line GOTO to differentiate, but neither rIFN-alpha A nor -beta did. To elucidate the mechanism of this rIFN-gamma-specific differentiation-inducing effect, we established two rIFN-gamma-resistant variant GOTO clones. They were insensitive to the growth-inhibitory and differentiation-inducing effect of 1 X 10(3) IU/ml rIFN-gamma. They were slightly sensitive to the growth-inhibitory effect of rIFN-gamma (2 X 10(4) IU/ml). Parental GOTO cells were very insensitive to the antivesicular stomatitis virus (VSV) effect of all three types of rIFNs and even 2 X 10(4) IU/ml rIFN-gamma could not inhibit the cytopathic effect of 5 TCID50 VSV by 50%. The degree of this insensitivity was the same in the variant GOTO cells as in the parental GOTO cells.     

Retinoic acid- and staurosporine-induced bidirectional differentiation of human neuroblastoma cell lines.

The differentiation pattern of two related human neuroblastoma cell lines, SK-N-SHF and SK-N-SHN, induced by retinoic acid and staurosporine was studied. Immunohistochemical and electron microscopic examination of the cells indicated that the SHF variant could undergo differentiation along a melanocytic route when treated with retinoic acid and to neuronal cells when treated with retionic acid and staurosporine together. Treatment of SHN cells with either or both these agents caused neuronal differentiation. The melanocytic pathway was characterized in part by the flattening of the cells, the appearance of melanocytic antigens and various forms of melanosomes, an increase in tyrosinase activity, and the absence of neuronal marker proteins. The neuronal route was typified by the development of long neuritic processes containing microtubules and numerous neurosecretory granules as well as by immunohistochemical reactions for neural cell adhesion molecule, synaptophysin, and neurofilament proteins. The significance of these results is discussed in terms of the differentiation responses of neuroblastoma cells to chemical agents as well as some of the factors involved in the regulation of phenotype expressions of these cells.