Expression of two parental imprinted miRNAs improves the risk stratification of neuroblastoma patients.

Age at diagnosis, stage, and MYCN amplification are the cornerstones of the risk-stratification score of neuroblastoma that enables defining patients at low- and high risk. Refinement of this stratification is needed to optimize standard treatment and to plan future clinical trials. We investigated whether two parental imprinted miRNAs (miR-487b and miR-516a-5p) may lead to a risk score with a better discrimination.

GALNT9 gene expression is a prognostic marker in neuroblastoma patients.

Background: The enzymes encoded by the GALNT [UDP-N-acetyl-α-d-galactosamine:polypeptide N-acetylgalactosaminyltransferase (GALNAC-T)] gene family catalyze the first step of O-glycosylation. Little is known about the link between expression of the genes encoding GALNAC-T enzymes and tumor progression in neuroblastoma, a pediatric cancer that can be classified as either low or high risk. We assessed the expression of genes in the GALNT family in a large cohort of neuroblastoma patients and characterized members of this family that might be used as new prognostic markers.

Loss of the malignant phenotype of human neuroblastoma cells by a catalytically inactive dominant-negative hTERT mutant.

Telomerase, a ribonucleoprotein complex mainly composed of the reverse transcriptase catalytic subunit (human telomerase reverse transcriptase, hTERT) and the RNA component (hTR), is a key enzyme of cancer progression. That aggressive stage 4-neuroblastoma expressed high levels of telomerase activity, whereas favorable tumors had no or little telomerase expression and activity, prompted us to investigate the role of this enzyme in this tumor model of altered proliferation, neuronal differentiation, and apoptosis. A human MYCN-amplified neuroblastoma cell line (IGR-N-91) was engineered to stably express either the normal hTERT protein (WT-hTERT) or a catalytically inactive dominant-negative mutant of this protein (DN-hTERT).

CDK Inhibitors Roscovitine and CR8 Trigger Mcl-1 Down-Regulation and Apoptotic Cell Death in Neuroblastoma Cells.

Neuroblastoma (NB), the most frequent extracranial solid tumor of children accounting for nearly 15% of all childhood cancer mortality, displays overexpression of antiapoptotic Bcl-2 and Mcl-1 in aggressive forms of the disease. The clinical phase 2 drug roscovitine (CYC202, seliciclib), a relatively selective inhibitor of cyclin-dependent kinases (CDKs), and CR8, a recently developed and more potent analog, induce concentration-dependent apoptotic cell death of NB cells (average IC(50) values: 24.2 µM and 0.

Netrin-1 acts as a survival factor for aggressive neuroblastoma.

Neuroblastoma (NB), the most frequent solid tumor of early childhood, is diagnosed as a disseminated disease in >60% of cases, and several lines of evidence support the resistance to apoptosis as a prerequisite for NB progression. We show that autocrine production of netrin-1, a multifunctional laminin-related molecule, conveys a selective advantage in tumor growth and dissemination in aggressive NB, as it blocks the proapoptotic activity of the UNC5H netrin-1 dependence receptors. We show that such netrin-1 up-regulation is a potential marker for poor prognosis in stage 4S and, more generally, in NB stage 4 diagnosed infants.

p73alpha isoforms drive opposite transcriptional and post-transcriptional regulation of MYCN expression in neuroblastoma cells.

MYCN activation, mainly by gene amplification, is one of the most frequent molecular events in neuroblastoma (NB) oncogenesis, and is associated with increased malignancy and decreased neuronal differentiation propensity. The frequency of concomitant loss of heterozygosity at the 1p36.3 locus, which harbours the p53 anti-oncogene homologue TP73, indicates that MYCN and p73 alterations may cooperate in the pathogenesis of NB.

Expression of C-terminal deleted p53 isoforms in neuroblastoma.

The tumor suppressor gene, p53, is rarely mutated in neuroblastomas (NB) at the time of diagnosis, but its dysfunction could result from a nonfunctional conformation or cytoplasmic sequestration of the wild-type p53 protein. However, p53 mutation, when it occurs, is found in NB tumors with drug resistance acquired over the course of chemotherapy. As yet, no study has been devoted to the function of the specific p53 mutants identified in NB cells.

Differential regulation of p73 variants in response to cisplatin treatment in SH-SY5Y neuroblastoma cells.

The present study aims to investigate the role of p73 in response to cisplatin treatment in p53 wild-type neuroblastoma SH-SY5Y cells. Results showed that cisplatin induced a dose-dependent up-regulation of p53, p73, and a number of p53-responsive genes. Interestingly, endogenous Deltaexon2p73-expression was down-regulated by cisplatin treatment.

[Micro-RNA and oncogenesis].

MicroRNA are endogenous molecules which negatively regulate the expression of a variety of genes. These tiny non coding RNA molecules--18 to 25 nucleotides in length--repress, with efficiency and specificity- translation of target mRNA into protein, according to a process akin to RNA interference. MiRNA are critical in the development of plants and mammals since they play a key role on proteins which regulate the strict spatiotemporal control of each tissue.

Wnt-5a gene expression in malignant human neuroblasts.

Neuroblastoma (NB), an embryonal malignancy, poses a major challenge in pediatric oncology for the treatment of disseminated forms. Here, we report the decrease of Wnt-5a gene expression in high-risk NB (HR-NB) as well as in cultured metastatic neuroblasts. Wnt-5a is a member of the Wnt signaling pathway which is mainly associated with patterning decisions in the embryonic nervous system.

The neurogene BTG2TIS21/PC3 is transactivated by DeltaNp73alpha via p53 specifically in neuroblastoma cells.

The p53 gene and its homologue p73 are rarely mutated in neuroblastoma. In recent studies, we showed that overexpression of DeltaNp73alpha, an isoform lacking the N-terminal transactivation (TA) domain, surprisingly induces p53 protein accumulation in the wild-type (wt) p53 human neuroblastoma line SH-SY5Y. As can be expected owing to its dominant-negative effect, DeltaNp73alpha inhibits Waf1/p21 gene expression, but equally importantly, it upregulates BTG2TIS21/PC3, another p53 target gene.

[Interrelations between p73 and p53: a model, neuroblastoma].

Homologies in sequence and gene organization of p53 and their relatives, p73 and p63, suggest similar biological functions. However differences exist between the p53 family members. Indeed in human tumors p53 is often mutated while p63 and p73 are very rarely mutated.

Differential response of p53 target genes to p73 overexpression in SH-SY5Y neuroblastoma cell line.

p73, the first p53 gene homologue, encodes an array of p73 proteins including p73 alpha full-length (TAp73 alpha) and amino-truncated isoforms (Delta Np73 alpha), two proteins with opposite biological functions. TAp73 alpha can induce tumor suppressive properties, while Delta Np73 alpha antagonizes p53 as well as TAp73 in a dominant-negative manner. In human malignant neuroblasts, p53 protein is wild-type but known to be excluded from the nucleus, therefore disabling its function as a tumor suppressor.

When p53 needs p73 to be functional - forced p73 expression induces nuclear accumulation of endogenous p53 protein.

In human neuroblastoma (NB), wild type p53 protein does not elicit its archetypal human tumor suppressive activity so far described. To elucidate this alteration, substantial investigations using NB cell lines have underscored p53 protein nuclear localization defect and/or inappropriate conformation, but no definitive evidence has been provided so far. p73, the first homologue of the p53 gene, locates at the 1p36.

[A new view on p53 protein cytoplasmic sequestration].

In human tumors, p53 inactivation occurs frequently by mutation, and possibly also by nuclear exclusion of wt p53. First reported by Uta Moll in 1992, p53 "cytoplasmic sequestration" has been thoroughly studied to elucidate molecular mechanism of this process, using neuroblastoma cell lines as model. An American team at the Columbia University has just isolated the cytoplasmic protein Parc [Nikolaev, Cell] which specifically binds to p53 and anchors it, so that the "guardian of the genome" cannot play its role in the nucleus.

MYCN enhances P-gp/MDR1 gene expression in the human metastatic neuroblastoma IGR-N-91 model.

Despite intensive high-dose chemotherapy and autologous hematopoietic stem cell transplantation, disseminated neuroblastoma (NB) frequently proves to be chemosensitive but not chemocurable, and more often so in NB-presenting MYCN amplification. To assess the direct relationship between the MYCN oncogene and chemoresistance acquisition during NB metastatic dissemination, we have studied MYCN and MDR1 genes using the human IGR-N-91 ectopic xenograft metastatic model. This characterized experimental in vitro model includes human neuroblasts derived from a subcutaneous primary tumor xenograft, disseminated blood cells, myocardium, and bone marrow (BM) metastatic cells.

TP53 family members and human cancers.

Based on gene sequence homologies, a p53 (TP53) gene family become apparent with the addition of the most recently identified p63 (TP73L; formerly TP63) and p73 (TP73) genes to the already known p53. The p53 gene encodes for a unique protein eliciting well-known tumor suppressor gene (TSG) properties that mediate cellular response to DNA damage, e.g.

DeltaN-p73alpha accumulates in human neuroblastic tumors.

Neuroblastic tumors (NTs), occurring in early childhood, display a wide spectrum of differentiation. Recurrent deletions involving the p73 locus are frequently observed in undifferentiated NTs. To address the question of the possible implication of p73 in neuroblastic differentiation, we investigated the status of the expression of this gene in a panel of differentiated and undifferentiated tumors.