UMLS:C0027819 - FACTA Search

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Query: UMLS:C0027819 (neuroblastoma)
27,800 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The cyclin dependent kinase inhibitors p16 and p18 were investigated in neuroblastoma. Only one of 19 neuroblastoma cell lines, an adriamycin-resistant variant, and none of 5 primary neuroblastoma, was deleted for p16 while its parental drug sensitive cell line is p16 intact. The region of deletion minimally extended centromeric to include p15, and telomeric to interferon-beta. This is the first report of a p16 gene alteration in neuroblastoma. No p16 gene hypermethylation or mutations were found. No homozygous deletions of p18 in these samples were found, although several instances of loss of heterozygosity are suspected. No p18 point mutations were detected. We conclude that (1) neither p16 nor p18 are likely involved in the pathogenesis of neuroblastoma; and (2) the role of p16, or another 9p21 gene, in the development of drug resistance warrants further investigation.
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PMID:The p16 and p18 tumor suppressor genes in neuroblastoma: implications for drug resistance. 866 86

We reported previously that loss of heterozygosity (LOH) on chromosomes 2q, 9p and 18q frequently occurs in neuroblastoma and that patients with 9p LOH in the tumors showed statistically significant association with an advanced stage of the disease and poor prognosis. To determine the role of chromosome 9 loss in neuroblastoma, we performed deletion mapping of chromosome 9 in 80 cases of neuroblastoma using 11 polymorphic microsatellite markers and a restriction fragment length porymorphism marker. LOH at one or more loci on chromosome 9 was detected in 33 of 80 cases (41%). Chromosome 9p was lost in 24 of 80 cases (32%), whereas chromosome 9q was lost in 18 of 80 cases (23%). There were two commonly deleted regions mapped to 9p21 between the D9S171 marker and the IFNB1 marker and 9q34-qter distal to the D9S176 marker. In addition, patients with LOH at 9p21 but not at 9q34-qter in the tumors showed statistically significant association with poor prognosis (P = 0.023). Because the commonly deleted regions at 9p21 includes the p16 (CDKN2A) gene, the status of the p16 gene was further examined in 80 fresh tumors and 19 cell lines of neuroblastoma. A missense mutation was detected at codon 52 in a fresh tumor. The p16 gene was not expressed in 13 of 19 cell lines (72%), and 5 of the 13 cell lines displayed methylation of the CpG island surrounding the first exon of the p16 gene. These results suggest that the p16 gene is a candidate tumor suppressor gene for neuroblastoma, and its inactivation may contribute to the progression of neuroblastoma.
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PMID:Deletion map of chromosome 9 and p16 (CDKN2A) gene alterations in neuroblastoma. 904 Nov 93

Neuroblastoma is one of the most frequent tumors in infancy. We analyzed 26 neuroblastomas, two ganglioneuromas, and a neuroblastoma metastasis for mutations and homozygous deletions of the p16 (or MTS1 or CDKN2) gene by means of the polymerase chain reaction (PCR) in combination with the single-strand conformation polymorphism (SSCP) technique and by multiplex PCR analysis. We detected mobility shifts in the SSCP gels in seven cases in the 3 half of exon 2 (named exon 2C) of the p16 gene. By PCR amplification of this particular region and SacII restriction enzyme digestion, we confirmed that those cases had a known polymorphism at codon 140 of the p16 gene. Neither mutations nor homozygous deletions were detected. Our results confirm those of Beltinger et al. (Cancer Res 55:2053-2055, 1995), which showed no p16 mutations or homozygous deletions in 18 primary neuroblastomas and nine tumor-derived cell lines. We conclude that the common pattern of p16 inactivation by homozygous deletion or mutation does not seem to be relevant to the development of neuroblastomas.
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PMID:Mutational analysis of the p16 gene in human neuroblastomas. 911 82

The genes responsible for the development of neuroblastoma following in vivo deletion or mutation are largely unknown. We have performed loss of heterozygosity studies on a series of 24 Portuguese primary neuroblastomas using 6 polymorphic markers located at chromosome 9p21 spanning the p16/MTS1/CDKN2, p15/MTS2/CDKN2B, and the interferon alpha and beta genes. Loss of heterozygosity was observed in 4 of the 24 tumors (17%), a somewhat lower percentage than a previous study that identified patients by a mass screening program. A correlation was also observed between 9p21 LOH and 1p36 LOH in our group of tumors. Two distinct regions of 9p21 deletion were observed: one located in the region adjacent to the markers D9S162 and D9S1747 and a second located centromerically of the p16 gene near the D9S171 marker. The latter region is exclusive of the p16 gene. This result suggests the presence of at least one other tumor suppressor gene at 9p21, apart from the p16 and p15 genes, which may be of importance to the development of neuroblastoma.
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PMID:Loss of heterozygosity at chromosome 9p21 in primary neuroblastomas: evidence for two deleted regions. 921 21

Distinction between benign adrenal cortical proliferative lesions and adrenal cortical carcinoma has been approached by a combination of histological, immunohistochemical, and macroscopical parameters. Modern imaging studies allow detection of small adrenal cortical lesions that may be incorrectly diagnosed. Differentiation between benign and malignant tumors of the adrenal cortex was attempted by microdissection of nine cases of adrenal cortical hyperplasia, 10 cortical adenomas, and 18 adrenal cortical carcinomas with subsequent polymerase chain reaction (PCR) amplification for loss of heterozygosity (LOH) of five microsatellites of putative tumor suppressor gene loci: p53 gene (17p), the neuroblastoma candidate gene (1p), the p16 gene (9p), the von Hippel Lindau gene (3p), and the retinoblastoma gene (13q). None of the hyperplastic lesions or cortical adenomas showed LOH of any of the gene markers used. Conversely, genetic changes were observed in 61% (11 of 18) of the cases of carcinoma. Forty-four percent of the lesions showed LOH for p53 (7 of 16). LOH of 1p, 3p, and 9p were seen in 22%, 22%, and 26%, respectively. LOH of the retinoblastoma gene was seen in 80% or four of five of the informative cases studied. We conclude that LOH studies may be used to distinguish malignant from nonmalignant adrenal cortical proliferations. Relative infrequency of LOH in 3p may furthermore help to differentiate adrenal lesions from clear cell carcinomas of the kidney.
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PMID:Utilization of molecular genetics in the differentiation between adrenal cortical adenomas and carcinomas. 959 77

We previously reported that loss of heterozygosity (LOH) on chromosome 9p21 correlates with poor prognosis of neuroblastoma and the p16 gene is not expressed in approximately two thirds of neuroblastoma cell lines. Here we demonstrated that p16 expression was induced by 5-aza-2-deoxycytidine treatment in cell lines with 5' CpG island methylation but not in cell lines without methylation. Furthermore, the cell cycle of neuroblastoma cell lines significantly delayed with accumulation of cells in G1 phase by transfection of a wild-type p16 expression vector. These results indicate that p16 is inactivated in part by DNA methylation and its expression is involved in the growth of neuroblastoma cells in vitro. To assess the biological and clinical significance of p16 expression in primary tumors, we undertook immunohistochemical analysis in 74 paraffin sections of neuroblastomas. p16 protein was undetectable in 45 of 74 cases (61%) and lack of p16 expression significantly correlated with poor prognosis of patients and advanced stage of the disease. There was no correlation between loss of p16 expression and N-myc amplification in these tumors. These results indicate that inactivation of the p16 gene is involved in the progression of neuroblastoma independently of N-myc amplification.
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PMID:The p16 (CDKN2A) gene is involved in the growth of neuroblastoma cells and its expression is associated with prognosis of neuroblastoma patients. 987 29

Alterations of the p16 gene in neuroblastoma are very rare. Pronounced expression of p16 at both the transcript and protein levels, however, was observed in 7 of 19 (39%) neuroblastoma cell lines and 2 of 6 (33%) primary neuroblastoma samples. As p16 expression is tightly controlled in a feedback loop with Rb, we investigated the possibility that changes in p16 expression were reflective of alterations of the downstream components in the G1 regulatory pathway. Two cell lines and one primary sample highly expressing p16 were shown to harbor CDK4 amplification. The cyclin D2 gene was infrequently expressed in neuroblastoma cell lines and did not correlate with p16 expression. Slight variations in the expression of CDK6, cyclins D1, D3 and E; and E2F1 and E2F2 among the cell lines were observed, without apparent correlation with p16 status. No mutations to the p16-binding site of CDK4 and CDK6 nor any mutations to the coding region of p16 itself were identified in neuroblastoma cell lines. Despite frequent N-myc amplification in these cell lines, no relationship with this gene was observed either. All cell lines contained Rb protein with varying degrees of phosphorylation, which bears no correlation with p16 expression. Overall, alterations of the G1 pathway in neuroblastoma included relatively frequent p16 expression and infrequent CDK4 amplification and cyclin D2 expression. Despite a reported feedback relationship between p16 expression and Rb/G1 deregulation, p16 expression in neuroblastoma cell lines is independent of Rb gene and phosphorylation status and, in contrast to other cell lines where expression of p16 leads to G1/S arrest, neuroblastoma cell lines proliferate in the presence of elevated levels of p16.
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PMID:Frequent deregulation of p16 and the p16/G1 cell cycle-regulatory pathway in neuroblastoma. 993 45

Retinoic acid (RA) induces cell cycle arrest and differentiation of human neuroblastoma (NB) cells. Typically, NB cells differentiate along the neuronal lineage, but quiescent, "flat" cell types frequently have been described after treatment with differentiating agents. Two indistinguishable subclones of the cell line SK-N-SH, SK-N-SH-N (SH-N) and SK-N-SH-F (SH-F), display dramatically different responses to RA. In SH-N, RA induces neuronal differentiation, but in SH-F it transforms the small neuroblastic cells into large, flattened, epithelium-like cells. Here we analyze the mechanistic basis for the different effects of RA in the two NB subclones. First, we show that the flattened RA-treated SH-F expresses markers of cells undergoing replicative senescence. Inhibition of DNA synthesis by RA is significantly more rapid in SH-F than in SH-N. SH-F, which expresses basal amounts of p16(INK4A), responds to RA with elevation of p18(INK4C), marked down-regulation of cyclin D1, and swift inhibition of cyclin D-dependent kinases (cdks). Conversely, after addition of RA, SH-N retains cell cycling due to high expression of cyclin D1, the absence of Ink4 inhibitors, and accumulation of p21(Cip1). These changes result in sustained cdk activity. Accordingly, overexpression of p21(Cip1) but not p16(INK4A) induces neuronal differentiation of untreated NB cells. We propose that rapid inhibition of cdks by RA in NB leads to early cell cycle arrest, prevents neuronal differentiation, and results in a senescence-like state.
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PMID:Distinct mechanisms of cell cycle arrest control the decision between differentiation and senescence in human neuroblastoma cells. 1148 96

p16 regulates the G(1)-S cell cycle transition by inhibiting the cyclin D-cyclin-dependent kinase (CDK)4/CDK6-mediated phosphorylation of retinoblastoma protein (pRb). We examined the possible derangement of the p16-CDK/cyclin D-pRb pathway in 40 primary neuroblastomas including 18 samples in the unfavorable stages (C and D) and 22 in the favorable stages (A, B, and Ds) by PCR, reverse transcription-PCR, Western blot, and immunohistochemistry and correlated the results with clinical outcome. No samples harbored alterations of the p16 gene. Interestingly, the samples in the unfavorable stages exhibited expression of p16 mRNA and protein more frequently than those in the favorable stages [mRNA, 9 of 18 (50%) versus 2 of 22 (9%), P = 0.006; protein, 5 of 16 (31%) versus 0 of 18 (0%), P = 0.013]. Alterations of the downstream components of the pathway were infrequent. pRb was deregulated in the majority of samples investigated [27 of 33 (82%), 24 with hyperphosphorylated pRb and 3 with no pRb protein]. The phosphorylation status of pRb did not correlate with p16 protein expression, suggesting that the elevated p16 protein may not be functioning properly to regulate the pathway. Among patients of all stages, p16 expression was significantly associated with a lower overall survival. There was no overexpression of MDM2, and loss of p14(ARF) expression and p53 mutation were infrequent events. Taken together, these findings suggest that up-regulated p16 expression may represent a unique feature of aggressive neuroblastoma.
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PMID:p16/p14(ARF) cell cycle regulatory pathways in primary neuroblastoma: p16 expression is associated with advanced stage disease. 1170 66

Aberrant promoter methylation of tumor suppressor genes has not been fully investigated in pediatric tumors. Therefore, we examined the methylation status of nine genes (p16(INK4A), MGMT, GSTP1, RASSF1A, APC, DAPK, RARbeta, CDH1 and CDH13) in 175 primary pediatric tumors and 23 tumor cell lines using methylation-specific PCR. We studied the major forms of pediatric tumors--Wilms' tumor, neuroblastoma, hepatoblastoma, medulloblastoma, rhabdomyosarcoma, osteosarcoma, Ewing's sarcoma, retinoblastoma and acute leukemia. The most frequently methylated gene in both primary tumors and cell lines was RASSF1A (40, 86%, respectively). However, the rates of RASSF1A methylation in individual tumor types varied from 0 to 88%. RASSF1A methylation was tumor specific and was absent in adjacent non-malignant tissues. Methylation of the other genes was relatively rare in tumors and non-malignant tissues (less than 5%). Neuroblastoma patients with methylation of RASSF1A were significantly older than patients without methylation (P=0.008). There was no relationship between methylation status and other clinico-pathologic parameters. We treated six cell lines lacking RASSF1A mRNA with 5-aza-2'deoxycytidine to examine the relationship between methylation and transcriptional silencing. In five of six cell lines, restoration of RASSF1A mRNA was confirmed by RT-PCR. Our findings indicate that aberrant promoter methylation of RASSF1A may contribute to the pathogenesis of many different forms of pediatric tumors.
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PMID:Aberrant promoter methylation and silencing of the RASSF1A gene in pediatric tumors and cell lines. 1208 24

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