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)

Polycomb group proteins are implicated in embryogenesis and carcinogenesis through transcriptional regulation of target genes. ASXL1 and ASXL2 genes, encoding Polycomb group protein with ASXN and ASXM domains, are human homologs of Drosophila additional sex combs (asx) gene. Exons 2-13 of the ASXL2 gene are fused to exons 1-14 of the MYST3 gene in a case of therapy-related myelodysplastic syndrome due to t(2;8)(p23.3;p11.2). Here, we identified the ASXL3 gene, a novel human homolog of Drosophila asx, by using bioinformatics. ASXL3 gene, consisting of 12 exons, was located within human genome sequences RP11-562H1 (AC023192.8), RP11-265C19 (AC090989.8), and RP11-470B24 (AC010798.9). Complete coding sequence of human ASXL3 cDNA was determined by assembling EST BE145544, exons 4-11, and 5'-truncated KIAA1713 cDNA (AB051500.2). Partial coding sequence of mouse Asxl3 cDNA was derived from 3'-truncated C230079D11 cDNA (AK082659.1). Human ASXL3 mRNA was expressed in pancreatic islet, testis as well as in neuroblastoma, head and neck tumor. Human ASXL3 protein (2248 aa) with ASXN, ASXM and PHD domains was the third member of the human ASXL family. The region between ASXM and PHD domains was divergent among ASXL family members. Proline-rich domain was located within the divergent region of ASXL3, but not within that of ASXL1 and ASXL2. ASXL3-DTNA locus at chromosome 18q12.1 and ASXL2-DTNB locus at 2p23.3 were paralogous regions within the human genome. ASXL3 was a predicted cancer-associated gene, just like ASXL1 and ASXL2. This is the first report on identification and characterization of the ASXL3 gene.
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PMID:Identification and characterization of ASXL3 gene in silico. 1513 7

Neuroblastoma is a neural crest-derived neoplasm of infancy with poor outcome in patients with advanced disease. The oncogenic transcription factor PAX5 is an important developmental regulator and is implicated in the pathogenesis of several malignancies. Screening of neuroblastoma cell lines revealed PAX5 expression in a malignant subset of neuroblastoma cells, so-called 'N-type' cells, but not in the more benign 'S-type' neuroblastoma cells. PAX5 expression was also detected in small cell lung cancer, an aggressive tumor of neural crest origin. Based on this observation we hypothesized that there could be a relationship between PAX5 expression and the more malignant phenotype of N-type cells. Stable PAX5 expression was established in several clones of the S-type cell line CA-2E. A noticeable difference in morphology of these transfectants was observed and there was also a significant increase in the proliferation rate. Moreover, PAX5 expressing clones gained the ability to form colonies in a soft agar assay, a marker of tumorigenicity. Down-regulation of PAX5 in several N-type cell lines and one small cell lung cancer cell line utilizing small interfering RNA resulted in a significant decrease in growth rate. Taken together we propose PAX5 as an important factor for the maintenance of the proliferative and tumorigenic phenotype of neuroblastoma. Our data, together with a recent study on the role of PAX genes in cancer suggest that PAX5 and other PAX transcription factors might be valuable targets for cancer therapy.
Carcinogenesis 2004 Oct
PMID:The PAX5 oncogene is expressed in N-type neuroblastoma cells and increases tumorigenicity of a S-type cell line. 1515 32

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.
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PMID:Causation of nervous system tumors in children: insights from traditional and genetically engineered animal models. 1531 89

Telomeres are nucleoprotein complexes located at the end of eukaryotic chromosomes. They have essential roles in preventing terminal fusions, protecting chromosome ends from degradation, and in chromosome positioning in the nucleus. These terminal structures consist of a tandemly repeated DNA sequence (TTAGGG in vertebrates) that varies in length from 5 to 15 kb in humans. Several proteins are attached to this telomeric DNA, some of which are also involved in different DNA damage response pathways, including Ku80, Mre11, NBS and BLM, among others. Mutations in the genes encoding these proteins cause a number of rare genetic syndromes characterized by chromosome and/or genetic instability and cancer predisposition. Deletions or mutations in any of these genes may also cause a telomere defect resulting in accelerated telomere shortening, lack of end-capping function, and/or end-to-end chromosome fusions. This telomere phenotype is also known to promote chromosomal instability and carcinogenesis. Therefore, it is essential to understand the interplay between telomere biology and genome stability. This review is focused in the dual role of chromosome fragility proteins in telomere maintenance.
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PMID:Telomere dysfunction in genome instability syndromes. 1534 4

Lipid-modified soluble proteins Hedgehog (SHH, DHH and IHH) and WNT (WNT1, WNT2, WNT2B, WNT3, etc.) share distantly related mechanisms for ligand modification as well as for signaling through seven-transmembrane protein with Frizzled domain. Hedgehog and WNT signaling pathways network together during embryogenesis and carcinogenesis. Dispatched 1 (DISP1) and Dispatched 2 (DISP2) are human homologs for Drosophila Dispatched implicated in the release of lipid-anchored Hedgehog from producing cells. Here, we identified and characterized Dispatched 3 (DISP3) gene by using bioinformatics. DISP3 complete coding sequence was determined by assembling BU170953 EST and KIAA1337 uncharacterized cDNA. DISP3 gene at human chromosome 1p36.22 was linked to D1S2667 microsatellite maker and TERE1 gene, whose locus is associated with prostate cancer, bladder cancer, and liver cancer. DISP3 mRNA was expressed in human embryonic stem (ES) cells, brain, testis, lung carcinoid, neuroblastoma, retinoblastoma and brain tumor. DISPH1 domain with five transmembrane regions (codon 452-637 of DISP3) and DISPH2 domain with four transmembrane regions (codon 1116-1319 of DISP3) were identified as novel domains conserved between DISP3 (1392 aa) and DISP1. The region around DISPH1 and DISPH2 domains of DISP3 protein was the Patched homologous region conserved among Patched family members and DISP family members. Because DISP3 and DISP1 are multi-span transmembrane proteins with the Patched homologous region, DISP3 is predicted to be implicated in the release of lipid-anchored secreted proteins. This is the first report on identification and characterization of the DISP3 gene.
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PMID:Identification and characterization of DISP3 gene in silico. 1564 43

The hypermethylation of CpG islands within gene promoter regions is an epigenetic phenomenon that is often, but not always, associated with the transcriptional silencing of downstream genes and contributes to carcinogenesis. We have determined the pattern of methylation of several genes involved in distinct biological pathways, including cell proliferation and apoptosis, in neuroblastoma and in the nonmalignant ganglioneuroma. The purpose of this work was to search for epigenetic signatures that could be associated with defined clinical and biological parameters and that, in prospective, could identify specific risk categories among the patients. We have analysed 31 malignant neuroblastoma with or without MYCN amplification and 13 benign ganglioneuroma and we have observed dramatic differences in the methylation pattern of five genes (CASP8, 14.3.3sigma, DeltaN-p73, RASSF1A and DCR2) between these tumors indicating that this phenomenon is not tissue-specific and can be considered as cancer-dependent. Furthermore, the methylation pattern of 14.3.3sigma, RASSF1A and of an intragenic segment of CASP8 was significantly different between MYCN amplified and single copy neuroblastoma suggesting a specific role of epigenetic alterations in aggressive neuroblastoma.
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PMID:Distinct CpG methylation profiles characterize different clinical groups of neuroblastic tumors. 1604 64

Neuroblastoma is the most frequent extracranial solid malignancy of childhood with a high mortality in advanced tumour stages. The hallmark of neuroblastoma is its clinical and biological heterogeneity. The molecular mechanisms leading to favourable or unfavourable tumour behaviour are still speculative. However, amplification of the oncogene MYCN and expression of the neurotrophin receptor TrkB are known to contribute to a highly malignant phenotype. To define the mechanisms through which TrkB may mediate neuroblastoma progression, we stably expressed this receptor in the neuroblastoma cell lines SH-SY5Y and SK-N-AS. The transfectants, but not the controls, had an increased invasive potency both, in vitro and in vivo, as demonstrated by Matrigel-invasion and chorioallantoic membrane assays, respectively. The retinoic acid-induced TrkB expression in parental SH-SY5Y cells was also associated with enhanced cell invasiveness. The TrkB mediated invasiveness involved the upregulation of the hepatocyte growth factor (HGF) and its receptor c-Met, resulting in an autocrine loop. Inhibition of HGF activity by anti-HGF neutralizing antibodies or disabling the function of c-Met by small interfering RNA suppressed the TrkB-induced invasiveness. The enhanced TrkB expression was associated with a significant increase in the secretion of various matrix-degrading proteases. Immunostaining and real-time RT-PCR analysis of tumour specimens demonstrated coordinated expression of TrkB and HGF/c-Met in experimental and primary neuroblastomas. We conclude that TrkB expression in neuroblastoma cells results in an increase in their invasive capability via upregulated expression of HGF/c-Met and enhanced activity of proteolytic networks.
Carcinogenesis 2005 Dec
PMID:The neurotrophin receptor TrkB cooperates with c-Met in enhancing neuroblastoma invasiveness. 1605 41

SNAI1, SNAI2, and SNAI3 genes, encoding transcriptional repressors implicated in epithelial mesenchymal transition (EMT), are human homologs of Drosophila snail (sna) and slug genes. SNAI1 represses transcription of CDH1 (E-cadherin) gene. SNAI2 induces the first phase of EMT, including desmosome dissociation, cell spreading, and initiation of cell separation. Because SNAI family proteins are implicated in EMT during embryogenesis and carcinogenesis, SNAI family genes are potent targets of pharmacogenomics. Here, comparative genomics analyses and comparative proteomics analyses on SNAI family orthologs were performed. Rat Snai3 gene, consisting of three exons, was identified within rat genome sequence AC111791.4. Zebrafish snai1a (NM_131066.1) was identified as SNAI1 ortholog. Chicken ChEST362l17 (CR407272.1), Xenopus slug (AF368041.1), and zebrafish zgc92564 (NM_001008581.1) were identified as SNAI2 orthologs. Chicken snail (NM_ 205142.1), Xenopus snail (BC056857.1), and zebrafish snai1b (NM_130989.1) were identified as SNAI3 orthologs. SNAI1 orthologs consisted of SNAG domain and four zinc finger (ZNF) domains, while SNAI2 and SNAI3 orthologs consisted of SNAG domain and five ZNF domains. Based on the integromics analyses, SNAI2 orthologs were found to be more conserved than SNAI1 and SNAI3 orthologs. SNAI1 mRNA was expressed in placenta, neuroblastoma, and diffuse type gastric cancer. SNAI2 mRNA was expressed in placenta, melanocyte, embryonic stem (ES) cells, leiomyosarcoma, neuroblastoma, and glioblastoma. SNAI3 mRNA was expressed in B cells. Expression of SNAI3 mRNA was repressed due to the existence of anti-sense single-exon transcript. SNAI1, functioning as E-cadherin repressor, is implicated in the malignant infiltrating phenotype of diffuse type gastric cancer through the induction of EMT or fibroblastoid transformation.
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PMID:Comparative genomics on SNAI1, SNAI2, and SNAI3 orthologs. 1614 76

Minichromosomal maintenance protein 7 (MCM7) is an essential component of the replication helicase complex (MCM2-7) required for DNA replication. Although this function is highly conserved among eukaryotes, additional functions for the MCM molecules continue to be described. Minichromosomal maintenance protein 7 is a marker for proliferation and is upregulated in a variety of tumors including neuroblastoma, prostate, cervical and hypopharyngeal carcinomas. To further investigate the general role of MCM7 in tumorigenesis, we generated a mouse model with deregulated MCM7 expression targeted to the basal layer of the epidermis using the keratin 14 (K14) promoter (K14.MCM7). When subjected to a two-stage chemical carcinogenesis protocol (dimethylbenz[alpha]anthracene (DMBA) initiation with 12-ortho-tetradecanoylphorbol-13-acetate promotion), K14.MCM7 mice showed significantly increased incidence and prevalence of tumor development relative to controls. Furthermore, within 40 weeks of treatment over 45% K14.MCM7 mice exhibited tumors that had converted to squamous cell carcinomas versus none in the control group. As predicted from previous skin carcinogenesis studies using DMBA as the initiating agent, Ras mutations where found in more than 90% of tumors isolated from K14.MCM7 mice. Whereas previous studies have shown that MCM7 is useful as a proliferation marker, our data suggest that deregulated MCM7 expression actively contributes to tumor formation, progression and malignant conversion.
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PMID:Deregulated minichromosomal maintenance protein MCM7 contributes to oncogene driven tumorigenesis. 1651 15

VEGF, Hedgehog, FGF, Notch, and WNT signaling pathways network together for vascular remodeling during embryogenesis, tissue regeneration, and carcinogenesis. VEGFA (VEGF), VEGFB, VEGFC, VEGFD (FIGF) and PGF (PlGF) are VEGF family ligands for receptor tyrosine kinases, including VEGFR1 (FLT1), VEGFR2 (KDR) and VEGFR3 (FLT4). Bevacizumab (Avastin), Sunitinib (Sutent) and Sorafenib (Nexavar) are anti-cancer drugs targeted to VEGF signaling pathway. TCF/LEF binding sites within the promoter region of human VEGF family members were searched for by using bioinformatics and human intelligence (Humint). Because four TCF/LEF-binding sites were identified within the 5'-promoter region of human VEGFD gene within AC095351.5 genome sequence, comparative genomics analyses on VEGFD orthologs were further performed. ASB9-ASB11-VEGFD locus at human chromosome Xp22.2 and ASB5-VEGFC locus at human chromosome 4q34 were paralogous regions within the human genome. Human VEGFD mRNA was expressed in lung, small intestine, uterus, breast, neural tissues, and neuroblastoma. Mouse Vegfd mRNA was expressed in kidney, pregnant oviduct, and neural tissues. Chimpanzee VEGFD promoter, cow Vegfd promoter, mouse Vegfd promoter and rat Vegfd promoter were identified within NW_121675.1, AC161065.2, AL732475.6 and AC130036.3 genome sequences, respectively. Three out of four TCF/LEF-binding sites within human VEGFD promoter were conserved in chimpanzee VEGFD promoter, and one in cow Vegfd promoter. TCF/LEF-binding site, not conserved in human VEGFD promoter, occurred in cow, mouse and rat Vegfd promoters. At least five out of six bHLH-binding sites within human VEGFD proximal promoter region were conserved in chimpanzee VEGFD proximal promoter region, while only one in cow Vegfd proximal promoter region. Together these facts indicate that relatively significant promoter evolution occurred among mammalian VEGFD orthologs. Human VEGFD was characterized as a potent target gene of WNT/beta-catenin signaling pathway. VEGFD, implicated in angiogenesis and lymphatic metastasis, is a pharmacogenomics target in the field of oncology.
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PMID:Comparative integromics on VEGF family members. 1668 60

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