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)

Neuroblastoma is a childhood solid tumor composed of primitive cells derived from precursors of the autonomic nervous system. This neoplasm has the highest rate of spontaneous regression of all cancer types and has been noted to undergo spontaneous and chemically induced differentiation into elements resembling mature nervous tissue. As such, neuroblastoma has been a prime model system for the study of neuronal differentiation and the process of cancer cell maturation. In this paper we review those agents that have been described to induce the differentiation of neuroblastoma, with an emphasis on the effects and possible mechanisms of action of a group of related compounds, the retinoids. With this model system and the availability of subclones that are both responsive and resistant to chemically induced differentiation, fundamental questions regarding the mechanisms and processes underlying cell maturation have become more amenable to in vitro study.
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PMID:Human neuroblastoma cell lines as models for the in vitro study of neoplastic and neuronal cell differentiation. 253 24

We assessed fluorescence in situ hybridization (FISH) as an alternative to Southern blot analysis for determination of N-myc gene amplification in neuroblastoma. In the 44 pediatric solid tumor cell lines examined (20 neuroblastomas), the mean number of N-myc copies determined by FISH correlated closely with Southern blot results. There was wide intercellular variability in gene copy number in tumors that had evidence of amplification; however, tumors judged to be non-amplified completely lacked any cells with high N-myc copy number. FISH provided reliable estimates of N-myc amplification in 12 clinical samples even when the percentage of tumor was low. The other advantages of FISH over Southern blot analysis were speed and technical simplicity, ability to discern heterogeneous gene amplification among tumor cells in the same specimen, and capacity to determine the source of the amplified N-myc signal, whether extrachromosomal double-minute chromosomes, expanded intrachromosomal regions, or chromosome 2 aneuploidy. We conclude that FISH would refine the analysis of N-myc amplification in neuroblastoma and thus improve the assignment of patients to prognostic groups based on this unfavorable risk factor.
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PMID:Detection of N-myc gene amplification by fluorescence in situ hybridization. Diagnostic utility for neuroblastoma. 768 92

There are major differences between tumors in children and adults, viz. the incidence of tumor types, the predisposition of certain organs and tissues (e.g. sympathetic nervous tissue, kidney, and soft tissues) to develop tumors, problems related to tumor classification, and the biologic behavior of childhood malignancies, which are usually characterized by high rates of proliferation activity. A large number of new entities, especially in soft tissue tumors, have been published over the past years, including nodular mesothelial hyperplasia, which is a tumor-like lesion derived from peritoneal macrophages; infantile myofibromatosis, which can mimic leiomyosarcoma; intermediate grade fibrohistiocytic tumors, like dermatofibrosarcoma protuberans-related giant-cell fibroblastoma, plexiform fibrohistiocytic tumor and angiomatoid malignant fibrous histiocytoma displaying evidence of myogeneous differentiation; finally, the high-grade intraabdominal desmoplastic small cell tumor. With modern methods we can gain better insights into the biology of tumors. For example, tumors of the Ewing's sarcoma family have in common a characteristic t(11; 22) chromosomal translocation, the Ewing's sarcoma (EWS) (22q12) gene rearrangement, and the MIC2 gene. The EWS gene rearrangement is not restricted to tumors of the Ewing's sarcoma family (classic Ewing's sarcoma and malignant peripheral neuroectodermal tumor), however, but occurs in malignant melanoma of the soft tissue and in intraabdominal desmoplastic small cell tumor. Rhabdomyosarcomas (RMS) can be divided into two basic types with different prognoses: embryonal RMS, including botryoid and spindle-cell variants, and alveolar RMS, including the solid variant. The prognosis of alveolar RMS is poorer than that of classic embryonal RMS, mainly due to early tumor dissemination in alveolar RMS. The prognosis of neuroblastoma is mainly based on chromosomal and molecular biologic findings. Structural chromosome 1 abnormalities, double minute chromosomes, homogeneously staining regions, N-myc amplifications, and DNA diploidy are indications for an unfavorable outcome. Despite progress in childhood solid tumor pathology, many questions remain open, including those relating to basic chromosomal defects in germ cell tumors and the obscure nature of tumor heterogeneity.
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PMID:New entities, concepts, and questions in childhood tumor pathology. 854 1

Disseminated neuroblastoma frequently show a very poor prognosis. N-myc gene amplification, 1p deletion and lack of CD44 gene expression, are all genetic factors associated with the disease's dissemination. Human neuroblastoma xenografts in nude mice has permitted to characterize, in disseminated neuroblasts, oncogenes overexpression, inactivation of tumor suppressor genes as well as detoxifying genes activation which contributes to increase cellular resistance to chemotherapy. These genetic abnormalities permit to propose a nosology of this very aggressive pediatric solid tumor. Hopefully, this genetic classification could be of great value for new therapeutic approaches.
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PMID:[Oncogenic factors of metastatic dissemination in neuroblastoma]. 975 69

The antitumor efficacy of the synthetic benzamide derivative MS-27-275 (MS-275), an inhibitor of histone deacetylation [T. Suzuki et al., J. Med. Chem., 42: 3001-3003, 1999], was evaluated in a series of pediatric solid tumor cell lines, including neuroblastoma, rhabdomyosarcoma, Ewing's sarcoma (EWS), retinoblastoma, medulloblastoma, undifferentiated sarcoma (US), osteosarcoma, and malignant rhabdoid tumors. Treatment with MS-275 results in an increase in acetylation of histones within 4 h of drug exposure. The cell lines were treated with various concentrations of MS-275 for 3 days and incubated with [(3)H]thymidine for 20 h before cell harvest. MS-275 inhibited [(3)H]thymidine uptake in a dose-dependent manner in all tumor cell lines examined. The IC(50) ranged from 50 nm in the D283 medulloblastoma cell line to 1.3 micro M in the US. A common feature of MS-275 treatment of pediatric tumor cell lines was induction of p21mRNA. However, the effects on cell cycle were diverse because in some cases MS-275 induced an increase in G(1) or G(2), whereas in others, there was an induction of apoptosis. In EWS, the EWS/fli chimeric transcription factor created by the t(11;22) suppresses transforming growth factor (TGF) betaRII transcription, however, MS-275 was able to induce an increase in TGF-betaRII mRNA and restore TGF-beta signaling. Using xenograft orthotopic models of US, EWS, and neuroblastoma, we find that the growth of established tumors is inhibited in mice treated with MS-275.
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PMID:MS-27-275, an inhibitor of histone deacetylase, has marked in vitro and in vivo antitumor activity against pediatric solid tumors. 1241 35

KIF1a is a member of the kinesin superfamily proteins that are microtubule-dependent molecular motors involved in important intracellular functions such as organelle transport and cell division. We previously determined the structure of the human KIF1Bbeta gene, which was found to be a homologue of the murine Kif1bbeta, and demonstrated that the human KIF1Bbeta is a causative gene of Charcot-Marie-Tooth disease type 2A although we did not prove that it is a tumor suppressor gene of neuroblastoma. Here, we identified another isoform of the human KIF1B gene, KIF1Balpha. The KIF1Balpha and KIF1Bbeta are alternative splicing products of the KIF1B gene located on 1p36.2. The KIF1Balpha is distinct from KIF1Bbeta in the C-terminal cargo-binding domain; however, they have the same N-terminal motor domain. We found that the transcript of approximately 7.8 kb of KIF1Balpha was expressed in several tissues, especially in skeletal muscle, by Northern blot analysis. To determine whether this gene is one of the candidate tumor suppressor genes for neuroblastoma (NB) or other pediatric solid tumors, we performed mutational screening of KIF1Balpha in 25 NB, 9 rhabdomyosarcoma, 12 Ewing sarcoma and 24 other pediatric solid tumor cell lines. Using RT-PCR single-strand conformation polymorphism analysis and direct sequencing we detected a missense mutation (M807I) in 1 NB cell line (SK-N-SH), 3 silent mutations in 2 NB cell lines and 1 primitive neuroectodermal tumor cell line, respectively. RT-PCR analysis revealed that KIF1Balpha was obviously expressed in almost all of the tumor cell lines examined except NB-1. Furthermore, real-time quantitative RT-PCR showed that there was no significant difference in KIF1Balpha expression between 14 early-stage (stage I and II) and 14 advanced-stage (stage III and IV) NB fresh tumor specimens. These results suggest that KIF1Ba in addition to KIF1Bbeta may not be a candidate tumor suppressor gene for NB.
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PMID:Genomic structure and mutational analysis of the human KIF1Balpha gene located at 1p36.2 in neuroblastoma. 1288 11

Neuroblastoma is the most common pediatric solid tumor. Although many allelic imbalances have been described, a bona fide tumor suppressor gene for this disease has not been found yet. In our study, we analyzed 2 genes, PTEN and DMBT1, mapping 10q23.31 and 10q25.3-26.1, respectively, which have been found frequently altered in other kinds of neoplasms. We screened both genes for homozygous deletions in 45 primary neuroblastic tumors and 12 neuroblastoma cell lines. Expression of these genes in cell lines was assessed by RT-PCR analysis. We could detect 2 of 41 (5%) primary tumors harboring PTEN homozygous deletions. Three of 41 (7%) primary tumors and 2 of 12 cell lines presented homozygous losses at the g14 STS on the DMBT1 locus. All cell lines analyzed expressed PTEN, but lack of DMBT1 mRNA expression was detected in 2 of them. We tried to see whether epigenetic mechanisms, such as aberrant promoter hypermethylation, had any role in DMBT1 silencing. The 2 cell lines lacking DMBT1 expression were treated with 5-aza-2'-deoxycytidine; DMBT1 expression was restored in only one of them (MC-IXC). From our work, we can conclude that PTEN and DMBT1 seem to contribute to the development of a small fraction of neuroblastomas, and that promoter hypermethylation might have a role in DMBT1 gene silencing.
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PMID:Homozygous deletion and expression of PTEN and DMBT1 in human primary neuroblastoma and cell lines. 1499 73

Neuroblastoma stands out among pediatric solid tumors because of its relative frequency, intriguing natural history, prognostic biologic features, and therapeutic challenges. It is the most common extracranial pediatric solid tumor and the most common neoplasm in infancy; >90% of the approximately 600 cases diagnosed annually in the United States are in children < or = 5 y old. Screening programs of infants show that many cases escape detection because of spontaneous regression or maturation into benign lesions. Origin from precursors of the sympathetic nervous system accounts for (a) primary sites in adrenal glands and in paraspinal locations from neck to pelvis and (b) high urinary levels of catecholamines in >90% of cases. This embryonal neoplasm often encases vascular structures and, unlike most solid cancers, usually presents with substantial metastatic disease (bone, bone marrow, lymph nodes, liver; spread to lung or brain is rare). Hence, defining disease status requires CT (or MRI), bone scan, metaiodobenzylguanidine (MIBG) scan, bone marrow tests, and urine catecholamine measurements. The natural history is strikingly variable but is largely predictable from clinical and biologic features. The latter are critical for distinguishing low-risk (90% survival) from high-risk ( approximately 25%-30% survival) subsets, allowing identification of patients who, despite a favorable clinical profile (e.g., localized tumor), are likely to develop lethal metastatic disease, versus patients who have an ominous clinical profile (e.g., widespread disease) but are likely to survive, sometimes with little or no cytotoxic therapy.
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PMID:Neuroblastoma: a disease requiring a multitude of imaging studies. 1523 64

This study was conducted to determine the outcome of patients who develop a second neoplasm after radiotherapy (RT) for a childhood solid tumor. From 1956 to 1998, 429 children with a malignant solid tumor were treated at a single radiation oncology facility. The medical records and radiotherapy charts were reviewed to determine if the patient developed a secondary neoplasm after treatment for malignancy. Twenty-three (5.4%) patients developed a secondary neoplasm. There were 12 males and 11 females with a median age at RT of 6.6 years (range, 2 months to 20 years). There were 14 malignant neoplasms in 13 (3.0%) and 14 benign neoplasms in 11 patients (2.6%). The types of initial solid tumors treated with RT were Ewing sarcoma in 6, Wilms tumor in 6, medulloblastoma in 5, neuroblastoma in 3, and other in 3. Median RT dose was 45 Gy (range, 12.3 to 60 Gy) using 4 MV in 9, 1.25 MV in 8, 250 KV in 4, and 6 MV photons in 1 patient. One child was treated using 15-MeV electrons. Fourteen had chemotherapy. Median follow-up was 23.2 years (range, 5.3 to 44.4 years). For the 14 malignant neoplasms, the median time interval from initial tumor to second malignancy was 10.1 years. The 14 second malignant neoplasms (SMN) were osteosarcoma in 3, breast carcinoma in 2, melanoma in 2, malignant fibrous histiocytoma in 1, dermatofibrosarcoma in 1, leiomyosarcoma in 1, mucoepidermoid carcinoma in 1, colon cancer in 1, chronic myelogenous leukemia in 1, and basal cell carcinoma in 1. Ten of the 14 SMN (71%) were at the edge or inside the RT field. The 5- and 10-year overall survival rate after diagnosis of an SMN was 69.2%; it was 70% for children with a SMN at the edge or inside the RT field and 66.7% for those outside of the RT field. The 14 benign neoplasms appeared at a median time of 16.9 years and included cervical intraepithelial neoplasia in 3, osteochondroma in 3, thyroid adenoma in 1, duodenal adenoma in 1, lipoma in 1, cherry angioma in 1, uterine leiomyoma in 1, ovarian cystadenofibroma in 1, and giant cell tumor in 1. Only 5 (36%) of the 14 benign tumors occurred in the RT field, with osteochondroma being the most common. Of 189 deaths occurring in 429 patients, only 3 (1.6%) were secondary to radiation-induced malignancy. Not all SMN in children receiving RT occur in the irradiated field. More than two-thirds of children with a radiation-induced malignancy are alive 10 years after the diagnosis of a SMN.
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PMID:Secondary neoplasms after radiotherapy for a childhood solid tumor. 1580 94

Neuroblastoma is a pediatric solid tumor with high morbidity and mortality in association with particular high-risk biological and clinical features (such as MYCN proto-oncogene amplification or advanced tumor stage). Such high-risk neuroblastomas may be initially responsive to cytoreductive therapies, yet the majority will ultimately demonstrate de novo or acquired chemoresistance leading to tumor progression and death. Insight into the genetic alterations responsible for these phenotypes are beginning to be gained, and subversion of inherent programmed cell death pathways is a common theme. Intact apoptosis pathways protect cells against neoplastic transformation and provide the mechanisms by which cytotoxic agents exert their effects. When these pathways are abolished through alterations in the cell death machinery, they complement deregulated oncogenes to promote tumor initiation and therapy resistance. Currently, therapeutic intensity for high-risk neuroblastoma has been advanced to near-tolerance with only modest gains in survival, and it is likely that further improvements in outcome will require innovative approaches that target key regulatory pathways that potentiate currently available therapies. Efforts to abrogate the cancer cell 'survival bias' engendered by alterations in death pathways are now a major focus in experimental cancer therapeutics, and their application to the problem of high-risk neuroblastoma form the basis of this review. These include agents that activate death receptors (TRAIL-agonists) or restore DISC competency (CDDO, DNA methyltransferase and HDAC inhibitors); reduce pro-survival Bcl2 homologues (Oblimersen sodium [AS-Bcl2], AS-Mcl1) or deliver a pro-apoptotic BH3 protein burden (BH3 peptides, gossypol, ABT737); or repress IAPs (Smac/Diablo peptides, AS-XIAP, AS-Survivin). As our knowledge of apoptosis dysregulation in neuroblastoma evolves, the possibilities for pro-apoptotic therapeutics seems not only promising, but a realistic adjunct to conventional treatments.
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PMID:Targeting programmed cell death pathways with experimental therapeutics: opportunities in high-risk neuroblastoma. 1592 59

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