UMLS:C0017636 - FACTA Search

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Query: UMLS:C0017636 (glioblastoma)
18,345 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The chromosomal localization of satellite DNA in two tissue culture lines derived -rom malignant mouse CNS tumors was investigated by in situ hybridization of 3H single-stranded satellite DNA purified by isopynic centrifugation in alkaline CSC1. Both tumors were glioblastomas originally induced by a methylcholanthrene implantation into the cerebrum of C3H mice; both displayed aneuploid chromosomal constitutions. One of these glioblastomas (TC 541) revealed labelling only of centromeric portions of the chromosomes even in cells containing greater than 200 chromosomes and thus it had a pattern of satellite distribution comparable to that of normal cells. The other glioblastoma (TC 509), that produced C-type particles and had a decrease in satellite DNA, displayed interstitial and telomeric label in some chromosomes in addition to labelling of the centromeres. "Hoechst 33258" fluorescence showed some interstitial and telomeric bright bands as well as centromeric bright regions, though to be consistent with in situ studies. The localization of satellite DNA to the chromosome arms and its possible relation to C-type virus is discussed.
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PMID:Localization of mouse satellite DNA on chromosomes of experimentally induced glioblastomas; non-centromeric lable in one glioblastoma producing C-type particles. 17 13

Karyotypic analysis of 54 malignant human gliomas (5 anaplastic astrocytomas, 43 glioblastoma multiformes, 3 gliosarcomas, 2 giant cell glioblastomas, 1 anaplastic mixed glioma) has demonstrated that 12 tumors contained normal stemlines or only lacked one sex chromosome. The 42 tumors with abnormal karyotypes included 38 tumors which could be completely analyzed. Six of these 38 cases had near-triploid or near-tetraploid stemlines and 32 had near-diploid stemlines. Statistically significant numerical deviations in the near-diploid group were gains of chromosome 7 (26 of 32; P less than 0.001), and losses of chromosome 10 (19 of 32; P less than 0.001). Double minutes occurred in 18 of 32 near diploid tumors. The distribution of structural abnormalities was analyzed statistically by comparing the incidence of breakpoint in each chromosomal arm to the expected value based on chromosomal arm length. This analysis demonstrated that structural abnormalities of 9p and 19q were significant statistically (P less than 0.005 and P = 0.02, respectively). Although chromosome 1, 6p, the centromeric region of chromosome 11, 13q, and 15q were also frequently involved in structural abnormalities, the incidence of these breaks did not reach statistical significance. This demonstration of specific chromosomal abnormalities in near-diploid gliomas provides the basis for the investigation of genes which may be quantitatively or qualitatively altered in these neoplasms.
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PMID:Specific chromosomal abnormalities in malignant human gliomas. 333 11

Selected childhood and adult neoplasm exemplify fundamental differences in their propensity for genomic change. DNA replication is essential for the formation of neuroepithelial tumors, probably because the genome can be remodeled. Nonetheless, several differentiated and stable childhood neoplasms retain their nuclear controls for differentiation. In contrast, rapidly arising gliomas often show a variety of phenotypic changes. Genomic plasticity and instability allow gliomas to flexibly adapt to new environments. Gene changes (in DNA) can be limited in childhood tumors whereas more widespread genetic changes in malignant gliomas indicate a fundamental alteration in many chromosome regions. Can such regions be defined? We used one repeated DNA sequence (TTAGGG)n, present at the end of all normal human chromosomes, to investigate chromosome termini in more detail. Pulsed-field gel electrophoresis showed this region can be unusually variable, as several other multilocus probes did not reveal comparable changes. Because telomeres form unique chromosomal structures, and are thought to provide essential signals to position chromosomes in the interphase nucleus, it was pertinent to assess these regions by in situ hybridization. Many telomeric domains localized at variable as well as interior nuclear positions in glioma cells. These positions, which are presumably abnormal, may be generated by the DNA variants observed. Such position changes may contribute to the more general 'disorder' observed in glioma nuclei. Other chromosome domains with a unique DNA-protein structure may define additional genomic loci that are preferentially modified in neoplasia. A fundamental understanding of chromosome structure should clarify the problem of multilocus instability in glioblastoma.
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PMID:Genomic stability and instability in different neuroepithelial tumors. A role for chromosome structure? 796 83

Loss of heterozygosity on chromosome 10 is considered to be associated with the progression of glioblastomas. Two closely related regions have recently been proposed to contain the glioblastoma suppressor locus on chromosome 10q25-26; a 1 cM region between the polymorphic (CA)n-repeat markers D10S587 and D10S216, and an area of 5 cM between the markers D10S221 and D10S209. To confirm and further delineate this region, we analyzed 51 glioblastomas and 11 intermediate and low-grade gliomas for loss of heterozygosity on chromosome 10. 47/62 mostly malignant gliomas displayed complete loss of chromosome 10 and nine tumors were unaltered, whereas four glioblastomas and two low-grade oligodendrogliomas had partial loss on distal 10q. With these six tumors, we constructed a deletion map with increased marker density at 10q25-26 which shows two centromeric breakpoints at the markers D10S587 and D10S216, thus only confirming the distal, but not the proximal candidate glioblastoma suppressor locus. Two out of four low-grade oligodendrogliomas displayed partial deletions on 10q25-26. This suggests that deletion on chromosome 10 is not merely a late event in the progression of glioblastomas, but could play a role earlier in the development of gliomas.
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PMID:New deletion in low-grade oligodendroglioma at the glioblastoma suppressor locus on chromosome 10q25-26. 928 95

The PTEN (MMAC1) gene, which has been identified as a tumor suppressor gene at 10q23.3, is mutated in multiple malignant tumors, including glioblastomas [J. Li et al., Science (Washington DC), 275: 1943-1947, 1997; P. A. Steck et al., Nat. Genet., 15: 356-362, 1997]. Among tumors of the central nervous system, loss of 10q is not restricted to glioblastomas but is also common in atypical and anaplastic meningiomas. Therefore, we have investigated 36 glioblastomas and 34 meningiomas (2 benign, 17 atypical, and 15 anaplastic meningiomas) for loss on 10q, as well as deletion, mutation, and expression of PTEN. Analysis of eight microsatellites from 10q revealed loss of heterozygosity (LOH) in 25 of 36 glioblastomas (69%). Twenty-three of these tumors demonstrated LOH at all informative loci. Two glioblastomas showed LOH restricted to markers located distally to PTEN, with breakpoints mapping telomeric to D10S541 and D10S185. One glioblastoma demonstrated evidence of homozygous deletion of PTEN by differential PCR analysis. PTEN mutations were detected in 9 of 36 glioblastomas (25%). Seven of these tumors showed LOH at all informative loci from 10q, indicating complete loss of wild-type PTEN. Although loss of 10q was detected by comparative genomic hybridization and/or LOH analysis in 14 of the 34 meningiomas investigated (41%), none of these tumors showed evidence of PTEN mutations or homozygous gene deletions. Our findings corroborate that PTEN is inactivated in a subset of glioblastomas. However, the lack of detectable PTEN alterations in a considerable fraction of glioblastomas and all meningiomas with 10q loss strongly supports the hypothesis that at least one additional tumor suppressor gene is located on 10q.
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PMID:Mutation of the PTEN (MMAC1) tumor suppressor gene in a subset of glioblastomas but not in meningiomas with loss of chromosome arm 10q. 942 52

Little is known about the relationship between genetic recombination mechanisms and loss of tumour suppressor genes in solid tumours. Here, we demonstrate deletion and truncation of both p53 alleles in a primary human glioblastoma and a derived cell line as the combined result of a t(17;20) reciprocal translocation and a 1.1 Mbp genomic deletion on chromosome 17p, starting in intron 4 of the p53 gene and ending at the telomeric CA-repeat marker D17S960. These results (i) suggest that genetic instability can lead to loss of tumour suppressor gene function in solid cancers, (ii) provide mapping of one such recombination event at the nucleotide level, and (iii) establish the orientation of the p53 gene on chromosome 17 as: centromere 5'-3'-telomere.
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PMID:Genetic instability leads to loss of both p53 alleles in a human glioblastoma. 946 57

Cowden disease, a dominantly inherited syndrome characterized by a variety of proliferative lesions and predisposition to breast and thyroid cancer, has recently been linked to the polymorphic marker D10S215 on chromosome segment 10q23. Loss of heterozygosity in prostate cancer is linked to the same marker, whereas loss of heterozygosity in glioblastoma, endometrial cancer, and other malignancies also localizes to this region. Most recently, a putative tumor suppressor gene (PTEN/MMAC1) has been identified in the region between D10S215 and an adjacent, more telomeric marker (D10S541) and was found to be altered in breast cancers, prostate cancers, and glioblastomas. We examined 22 invasive breast cancers for loss of heterozygosity in the 10q23 region and found loss in 41% (9/22). There were two distinct regions of loss, including one near the D10S541 marker, with an approximately equal frequency of deletion in each. The observed pattern of deletion is consistent with the presence of a tumor suppressor gene between D10S215 and D10S541. Most of the poorly differentiated carcinomas in the case collection showed loss of heterozygosity in the region near D10S215, suggesting that this loss correlates with a poor prognosis.
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PMID:Sporadic breast cancers exhibit loss of heterozygosity on chromosome segment 10q23 close to the Cowden disease locus. 949 29

Malignant glioblastomas grow very rapidly and are generally resistant to either DNA-damaging drugs or gamma-irradiation. If tumor cells could be made more susceptible to cell death with treatments, this would clearly represent a significant improvement in the success of treatment. Recently, telomerase has become a focus of interest among oncologists as a target for treating cancer cells. Telomerase elongates telomeric DNA repeats (TTAGGG)n and is important in protecting and replicating DNA. The vast majority of tumor cells, indeed, express telomerase activity whereas normal somatic cells, except for a few cells, do not. Since telomerase is essential for protecting DNA, we may be able to make tumors more sensitive to treatments with DNA-damaging drugs by inhibiting telomerase activity. In this study, we used cis-diamminedichloroplatinum (cisplatin)-sensitive U87-MG cells and cisplatin-resistant U251-MG of human malignant glioblastoma cell lines. U87-MG cells did not express telomerase activity, whereas telomerase was highly detected in U251-MG cells. Interestingly, inhibition of telomerase with an antisense telomerase expression vector not only decreased telomerase activity but also increased susceptibility to cisplatin-induced apoptotic cell death in U251-MG cells. These findings suggest that treatment with antisense telomerase may represent a new chemosensitisation for tumors resistant to anticancer drugs.
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PMID:Inhibition of telomerase increases the susceptibility of human malignant glioblastoma cells to cisplatin-induced apoptosis. 961 33

It has been repeatedly suspected that telomere shortening might be one possible trigger of the p53-dependent cell cycle arrest, although the mechanism of this arrest remained unclear. Telomeres in human cells under mild oxidative stress accumulate single-strand damage faster than interstitial repetitive sequences. In MRC-5 fibroblasts and U87 glioblastoma cells, which both express wild-type p53, oxidative stress-mediated production of single-strand damage in telomeres is concomitant to the accumulation of p53 and p21 and to cell cycle arrest. This response can be modeled by treatment of cells with short single stranded telomeric G-rich DNA fragments. The arrest is transient in U87 cells. Recovery from it is accompanied by up-regulation of telomerase activity and elongation of telomeres. Overexpression of mutated p53 is sufficient to reverse the phenotype of inhibition as well as the delayed activation of telomerase. These data suggest that the production of G-rich single stranded fragments during the course of telomere shortening is sufficient to trigger a p53 dependent cell cycle arrest.
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PMID:Telomere shortening triggers a p53-dependent cell cycle arrest via accumulation of G-rich single stranded DNA fragments. 1049 64

Telomerase is a ribonucleoprotein complex that elongates telomeric DNA and appears to play an important role in cellular immortalization of cancers. Because telomerase is expressed in the vast majority of malignant gliomas but not in normal brain tissues, it is a logical target for gliomaspecific therapy. The telomerase inhibitor GRN163, a 13-mer oligonucleotide N3'-->P5' thio-phosphoramidate (Geron Corporation, Menlo Park, Calif.), is complementary to the template region of the human telomerase RNA subunit hTR. When athymic mice bearing U-251 MG human brain tumor xenografts in their flanks were treated intratumorally with GRN163, a significant growth delay in tumor size was observed (P < 0.01 in all groups) as compared to the tumor size in mice receiving a mismatched oligonucleotide or the carrier alone. We also investigated biodistribution of the drug in vivo in an intracerebral rat brain-tumor model. Fluorescein-labeled GRN163 was loaded into an osmotic minipump and infused directly into U-251 MG brain tumors over 7 days. Examination of the brains revealed that GRN163 was present in tumor cells at all time points studied. When GRN163 was infused into intracerebral U-251 MG tumors shortly after their implantation, it prevented their establishment and growth. Lastly, when rats with larger intracerebral tumors were treated with the inhibitor, GRN163 increased animal survival times. Our results demonstrate that the antitelomerase agent GRN163 inhibits growth of glioblastoma in vivo, exhibits favorable intracerebral tumor uptake properties, and prevents the growth of intracerebral tumors. These findings support further development of this compound as a potential anticancer agent.
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PMID:Antitumor effects of specific telomerase inhibitor GRN163 in human glioblastoma xenografts. 1527 14

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