Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: UMLS:C0027819 (neuroblastoma)
 27,800 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Although pediatric solid tumors are cytogenetically less well characterized than childhood leukemias, an understanding of the role of chromosomal changes in the development of these neoplasms is emerging. The major clinical importance of chromosome analysis today is diagnostic. Especially in small cell round cell tumors of childhood, the unique karyotypic patterns that characterize some of the differential diagnostic entities make it possible to determine with a high degree of certainty which type of cancer the child has. Molecular studies have revealed that almost all retinoblastomas show homozygous loss of function of the RB1 gene in 13q14. At the cytogenetic level, however, aberrations of 13q are seen in less than 25% of retinoblastomas; instead, the presumably progression-related i(6p) and aberrations leading to gain of 1q predominate, each being present in one-third of the tumors. Twenty percent of cytogenetically aberrant Wilms' tumors show structural rearrangements, often deletions, of 11p13 and 11p15, where the WT1 and WT2 genes map. Other frequent changes are trisomy 12 and duplication of 1q. The most common (80%) cytogenetic abnormality in neuroblastoma is loss of distal 1p, a chromosome segment thought to harbor at least two tumor-suppressor genes of importance in tumorigenesis. Double minute chromosomes or homogeneously staining regions are present in one-third of all neuroblastomas and are associated with MYCN amplification. Loss of 1p material or MYCN amplification predicts a poor outcome. The most common (30%) chromosomal aberration in primitive neuroectodermal tumors of the central nervous system is i(17q). The formation of this isochromosome may help inactivate a tumor-suppressor gene located distal to the TP53 locus on 17p. No specific chromosome abnormality has been detected in gliomas, but monosomy 22 and rearrangements leading to loss of 1p and gain of 1q are recurrent. Few hepatoblastomas with chromosomal changes have been reported, but several potential primary aberrations have been described, including +2, +20, and duplication 8q. In Ewing's sarcoma, t(11;22)(q24;q12) is the primary aberration, with trisomy 8 and gain of 1q being frequent secondary changes. Fibrosarcomas in children often carry only numeric aberrations, especially trisomy for chromosomes 11, 20, 17, and 8. Most osteosarcomas are cytogenetically complex, and no specific abnormality has been detected; the single most common change is loss of chromosome 13, which is observed in half the tumors. In contrast, the low-malignancy parosteal osteosarcomas often display supernumerary ring chromosomes as the sole karyotypic deviation. The cytogenetic profiles of rhabdomyosarcomas differ among the various morphologic subtypes.(ABSTRACT TRUNCATED AT 400 WORDS)
 ...
PMID:Cytogenetic analysis in the examination of solid tumors in children. 794 9

Recurrent genetic alterations different from the alteration of the RB1 gene on chromosome 13q14 have been described in retinoblastoma, including structural alterations on the short arm of chromosome 1 and amplification of the N-MYC oncogene. These two genetic alterations are major prognostic factors in neuroblastoma, another embryonic neuro-ectodermal tumour. In order to assess the frequency of these alterations and their possible association with clinical parameters in retinoblastoma, we studied a series of 46 retinoblastoma tumour samples. Ploidy was assessed by flow cytometry, N-MYC copy number was evaluated by a spot-blot procedure using the pNb-1 probe and loss of heterozygosity was investigated by PCR analysis at mini- and microsatellites located on the short arm of chromosome 1. Most tumours were in the diploid or near diploid range; only one case exhibited tetraploidy. N-MYC amplification was observed in only one of the 45 tumours. Loss of heterozygosity on the short arm of chromosome 1 was observed in 9/43 tumours (21%); in particular, its incidence was higher in metastatic than in localised disease (P < 0.05). We suggest that alterations of one or several genes on chromosome 1p might play a role in the oncogenesis or progression of retinoblastoma. Analysis of the long term follow-up of these and additional patients should determine the prognostic value of this parameter.
 ...
PMID:N-MYC amplification, loss of heterozygosity on the short arm of chromosome 1 and DNA ploidy in retinoblastoma. 869 69

The proto-oncogene MYCN is often amplified in human neuroblastomas. The assumption that the amplification contributes to tumorigenesis has never been tested directly. We have created transgenic mice that overexpress MYCN in neuroectodermal cells and develop neuroblastoma. Analysis of tumors by comparative genomic hybridization revealed gains and losses of at least seven chromosomal regions, all of which are syntenic with comparable abnormalities detected in human neuroblastomas. In addition, we have shown that increases in MYCN dosage or deficiencies in either of the tumor suppressor genes NF1 or RB1 can augment tumorigenesis by the transgene. Our results provide direct evidence that MYCN can contribute to the genesis of neuroblastoma, suggest that the genetic events involved in the genesis of neuroblastoma can be tumorigenic in more than one chronological sequence, and offer a model for further study of the pathogenesis and therapy of neuroblastoma.
 ...
PMID:Targeted expression of MYCN causes neuroblastoma in transgenic mice. 921 16

MYCN is a biologically and clinically important oncogene in human neuroblastoma as genomic amplification reliably predicts for aggressive tumor behavior and a poor prognosis. However, the mechanism by which MYCN amplification and overexpression contributes to a highly malignant phenotype remains obscure. ID2 is a dominant inhibitor of the RB1 tumor suppressor gene product and recently was suggested to be a direct transcriptional target of MYCN. Overexpression of Id2 protein has thus been postulated to result in functional inactivation of retinoblastoma in MYCN-amplified neuroblastomas, offering a potential explanation for the undifferentiated and highly proliferative nature of most MYCN-amplified neuroblastomas, as well as the paucity of retinoblastoma pathway mutations observed in clinical samples. We therefore sought to determine the likelihood that ID2 overexpression is associated with MYCN amplification and overexpression in human neuroblastoma. ID2 was not differentially expressed in 39 primary neuroblastoma specimens analyzed by oligonucleotide array-based expression analysis, and there was no correlation with MYCN expression levels. ID2 mRNA and protein expression was highly variable and independent of MYCN amplification status and mRNA expression in 10 human-derived neuroblastoma cell lines. In addition, ID2 mRNA expression was not associated with MYCN gene amplification status (P = 0.15) or MYCN expression (r = 0.22) in 131 separate diagnostic primary neuroblastoma samples analyzed by real-time quantitative RT-PCR. These data suggest that transcriptional regulation of ID2 by the MycN oncoprotein is unlikely to be a seminal molecular event resulting in a highly malignant neuroblastoma phenotype.
 ...
PMID:ID2 expression is not associated with MYCN amplification or expression in human neuroblastomas. 1267 Sep 15

Pediatric neurogenic tumors include primitive neuroectodermal tumors (PNETs), especially medulloblastoma; ependymomas and choroid plexus papillomas; astrocytomas; retinoblastoma; and sympathetic neuroblastoma. Meningiomas and nerve sheath tumors, although uncommon in childhood, are also significant because they can result from exposures of children to ionizing radiation. Specific chromosomal loci and specific genes are related to each of these tumor types. Virtually all these genes appear to act as tumor suppressor genes, which are inactivated in tumor cells by mutations or by chromosomal loss. In genetically engineered mice, some genes that are clearly associated with specific human tumors (e.g., RB1 in retinoblastoma and NF2 in meningiomas and schwannomas) have no such effect. Other genetic constructs in mice involving the genes p53, ptc1, and Nf1 have produced tumors remarkably similar to some of the human pediatric neoplasms. Some of these tumors become clinically apparent after only a few weeks, while the mice are still juveniles, especially when two or more tumor suppressor genes are inactivated in the same genetic construct. Conversely, at least one genetic pathway in rodents involving point mutation in the coding region of a transforming gene (neu in malignant schwannomas) does not appear to operate in any human tumors. The nervous system is markedly susceptible to experimental carcinogenesis during early life in rodents, dogs, primates, and other nonhuman species, and there is no obvious reason why this generalization should not also apply to humans. However, except for therapeutic ionizing radiation, no physical, chemical, or biological cause of human pediatric nervous system tumors is known. The failure of experimental transplacental carcinogenesis to mirror human pediatric experience more closely may reflect the need for multiple mutational events in target cells, and for experimental carcinogens that are capable of causing the full spectrum of mutations that occur in cancer-related genes in pediatric neurogenic tumors.
 ...
PMID:Causation of nervous system tumors in children: insights from traditional and genetically engineered animal models. 1531 89

The review by D.T. Hughes examined the role of cytogenetics in cancer research in 1964. Despite the technical limitations of the day, he highlighted a number of known abnormalities which were to turn out to be crucial in our understanding of cancer genetics over the subsequent 40 years. These included the Philadelphia translocation and the Burkitt's lymphoma-associated marker chromosomes. In addition, he mentioned that a deleted chromosome had been observed in an example of retinoblastoma and double-minute chromosomes in neuroblastoma. The study of these events led to the identification of the key genes involved (BCR, ABL, C-MYC, RB1 and N-MYC) and served as models for substantial further work. We review some of the technical advances in the field of molecular cytogenetics and show how they can be applied to the events reviewed by Hughes.
 ...
PMID:Understanding cancer at the chromosome level: 40 years of progress. 587 19

Despite considerable research into the etiology of neuroblastoma, the molecular basis of this disease has remained elusive. In contrast to the absence of expression of the known tumor suppressor CDKN2A (also known as p16 and INK4A) in a wide variety of tumor types we have found in previous studies that CDKN2A protein is paradoxically highly expressed in many advanced stage neuroblastomas and unrelated to RB1 status. In the present study, we sought to identify the mechanistic relationships that might influence CDKN2A expression and negate its influence on tumor cell proliferation. In this regard, we examined the role of the tumor-suppressor gene CDKN1B (also known as p27 and Kip1) and the oncogene ID2 in relationship to CDKN2A expression, MYCN amplification, and neuroblastoma pathogenesis in 17 neuroblastoma cell lines and 129 samples of primary tumors of all stages. All neuroblastoma cell lines expressed the ID2 transcript and protein. However, although the majority of primary neuroblastomas also expressed the ID2 transcript, expression of the ID2 protein was undetectable or only barely detectable, regardless of transcript expression. In both cell lines and primary tumors, ID2 expression was independent of both CDKN2A and MYCN expression. In primary neuroblastomas, CDKN1B protein was expressed in significantly fewer advanced-stage neuroblastomas than early-stage neuroblastomas, but its expression had no relationship with CDKN2A expression or MYCN amplification. We concluded that the paradoxical expression of CDKN2A in neuroblastoma cannot be explained by inactivation of the tumor-suppressor gene CDKN1B or overexpression of the oncogene ID2. We further concluded that ID2 is not a target of MYCN regulation nor is it a prognostic factor for neuroblastoma. Finally, the loss of CDKN1B in advanced-stage neuroblastoma suggests this protein may play a role in the neuroblastoma disease process.
 ...
PMID:Expression profiles and clinical relationships of ID2, CDKN1B, and CDKN2A in primary neuroblastoma. 1539 Jan 83

RB1-inducible Coiled-Coil 1 (RB1CC1) has been shown to be a novel tumor suppressor regulating RB1 expression. Neuronal abundance of RB1CC1 is reported to contribute to the non-proliferating enlarged cell phenotype through the maintenance of RB1 and mTOR. To clarify whether RB1CC1 insufficiency is involved in neuronal atrophy and Alzheimer's pathology, we investigated modifications of RB1CC1 as a possible cause of atrophy or death through the disturbance of mTOR signaling in Neuro-2a neuroblastoma cells. We also evaluated the correlation between RB1CC1 and mTOR signaling in a series of Alzheimer's brain tissues. Though RB1CC1 introduction enhanced neurite growth, RNAi-mediated knockdown of RB1CC1 or rapamycin treatment caused neurite atrophy and apoptosis due to mTOR signaling reduction in the differentiated Neuro-2a cells. Both TSC1 and RB1CC1 were equally functional and maintained mTOR signaling, indicated by phospho-S6 (Ser240/244) expression in 69% of Alzheimer's (9/13 cases) and 100% of normal brains (6/6 cases). However, scanty RB1CC1 expression, less than TSC1, caused phospho-S6 disappearance in 31% of Alzheimer's tissues (4/13 cases). These findings suggest that RB1CC1 insufficiency may result in mTOR signaling repression through unbalanced TSC1 abundance and may induce neuronal atrophy. These observations may have implications for the pathogenesis of Alzheimer's disease.
 ...
PMID:RB1CC1 insufficiency causes neuronal atrophy through mTOR signaling alteration and involved in the pathology of Alzheimer's diseases. 1770 18

Analysis of hereditary and nonhereditary retinoblastoma led to the formulation of the two-hit hypothesis of cancer in the early 1970s. The two-hit hypothesis was validated in the 1980s when both copies of the RB1 gene were shown to be mutated in hereditary and nonhereditary retinoblastoma. However, consistent genetic abnormalities other than RB1 mutations suggest that additional events may be required for the formation of these malignant tumors. For example, MYCN amplification has long been known to occur in both retinoblastoma and neuroblastoma tumors and is strongly associated with poor prognosis in neuroblastoma. The DEAD box gene, DEAD box 1 (DDX1), is often coamplified with MYCN in both these childhood tumors. Here, we examine possible roles for DDX1 overexpression in retinoblastoma and neuroblastoma.
 ...
PMID:Role of DEAD box 1 in retinoblastoma and neuroblastoma. 1792 23

Uncontrolled cell cycle entry, resulting from deregulated CDK-RB1-E2F pathway activity, is a crucial determinant of neuroblastoma cell malignancy. Here we identify neuroblastoma-suppressive functions of the p19-INK4d CDK inhibitor and uncover mechanisms of its repression in high-risk neuroblastomas. Reduced p19-INK4d expression was associated with poor event-free and overall survival and neuroblastoma risk factors including amplified MYCN in a set of 478 primary neuroblastomas. High MYCN expression repressed p19-INK4d mRNA and protein levels in different neuroblastoma cell models with conditional MYCN expression. MassARRAY and 450K methylation analyses of 105 primary neuroblastomas uncovered a differentially methylated region within p19-INK4d. Hypermethylation of this region was associated with reduced p19-INK4d expression. In accordance, p19-INK4d expression was activated upon treatment with the demethylating agent, 2'-deoxy-5-azacytidine, in neuroblastoma cell lines. Ectopic p19-INK4d expression decreased viability, clonogenicity and the capacity for anchorage-independent growth of neuroblastoma cells, and shifted the cell cycle towards the G1/0 phase. p19-INK4d also induced neurite-like processes and markers of neuronal differentiation. Moreover, neuroblastoma cell differentiation, induced by all-trans retinoic acid or NGF-NTRK1-signaling, activated p19-INK4d expression. Our findings pinpoint p19-INK4d as a neuroblastoma suppressor and provide evidence for MYCN-mediated repression and for epigenetic silencing of p19-INK4d by DNA hypermethylation in high-risk neuroblastomas.
...
PMID:p19-INK4d inhibits neuroblastoma cell growth, induces differentiation and is hypermethylated and downregulated in MYCN-amplified neuroblastomas. 2510 50


1 2 Next >>