Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0017638 (glioma)
30,880 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Previous studies have suggested that structural abnormalities involving the short arm of chromosome 9 are frequently associated with gliomas. The alpha-, beta-, and omega-interferon (IFNA, IFNB1, and IFNW, respectively) and the methylthioadenosine phosphorylase (MTAP) genes have been mapped to the short arm of chromosome 9, band p22. Homozygous deletions of these genes have been reported in many leukemia- and glioma-derived cell lines. In this report, we present a detailed analysis of partial and complete homozygous or hemizygous deletions of DNA sequences on 9p in human cell lines and primary tumor samples of glioma patients. Ten of 15 (67%) glioma-derived cell lines had hemizygous or homozygous deletion of IFN genes or rearrangement of sequences around these genes, while 13 of 35 (37%) primary glioma tumor samples had hemizygous (8 tumors) or homozygous (5 tumors) deletion of the IFN genes. The shortest region of overlap of these deletions maps in the interval between the centromeric end of the IFN gene cluster and the MTAP gene. In the cell lines and primary tumors examined, these gross genomic alterations were seen only in association with high grade or recurrent gliomas. Our observations confirm that loss of DNA sequences on 9p, particularly the IFN genes, occurs at a significant frequency in gliomas, and may represent an important step in the progression of these tumors. These results are consistent with a model of tumorigenesis in which the development or progression of cancer involves the loss or inactivation of a gene or several genes that normally act to suppress tumorigenesis. One such gene may be located on 9p; this gene may be closely linked to the IFN genes. Nevertheless, loss of the IFN genes, when it occurs, may play an additional role in the progression of these tumors.
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PMID:Molecular analysis of deletions of the short arm of chromosome 9 in human gliomas. 156 21

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

Deletions of 9p21-22, that frequently include the alpha-, beta- and omega-IFN gene cluster, are common in malignant diseases such as acute lymphocytic leukemia, malignant melanoma and malignant glioma. There is also evidence to support the role of a gene(s) on chromosome 9p21 in predisposition for familial malignant melanoma. Although initial studies implicated that the IFN genes could serve as tumor suppressor genes, there is now data, mainly based on estimations of minimum region of overlap for the deletions, indicating that the relevant tumor suppressor gene is located centromeric of the alpha-, beta-, omega-IFN gene cluster.
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PMID:Chromosome 9 short arm deletions in malignant diseases. 750 46

Chromosome 19q harbors a tumor suppressor gene that is involved in astrocytoma, oligodendroglioma and mixed glioma tumorigenesis. We had previously mapped this gene to an approximately 5 megabase region of chromosome 19q13.2-13.3 between APOC2 and HRC. To narrow the location of this tumor suppressor further, we studied 138 gliomas for loss of allelic heterozygosity at six microsatellite polymorphisms between APOC2 and HRC, including a newly described polymorphism in the ERCC2 gene. Allelic loss occurred in 48 gliomas (35%), including 25 of 41 oligodendroglial tumors (61%). Four cases had proximal breakpoints within the APOC2-HRC region, two telomeric to ERCC2 and two telomeric to D19S219. In addition, one of the latter tumors had an interstitial deletion between D19S219 and D19S112, a distance of only 425 kilobases surrounding the DM (myotonic dystrophy) gene. These findings suggest that the glioma tumor suppressor on chromosome 19q maps to 19q13.3, telomeric to D19S219 and perhaps centromeric to D19S112. The data exclude a number of candidate genes from 19q13.2-13.3, including a putative phosphatase gene and the DNA repair/metabolism genes ERCC1, ERCC2 and probably LIG1.
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PMID:Chromosome 19q deletions in human gliomas overlap telomeric to D19S219 and may target a 425 kb region centromeric to D19S112. 766 49

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

The frequent allelic loss of chromosome 19q in human gliomas suggests that 19q harbors a tumor suppressor gene that is integral to glioma tumorigenesis. Our initial deletion mapping of this gene localized the common region of deletion to the distal long arm, 19q13.2-13.4. To bracket the putative tumor suppressor gene further, we have studied this region in 55 gliomas, using loss of heterozygosity studies for 11 well mapped, highly informative microsatellite polymorphisms that cover this area: D19S178; BCL3; APOC2; ERCC1; DM; D19S112; HRC; D19S246; KLK; D19S180; and D19S254 (from centromeric to telomeric). Twenty astrocytic, oligodendroglial, and mixed gliomas had deletions affecting this region. Of nine partial deletions, two cases maintained heterozygosity at APOC2 while showing allelic loss at the more telomeric markers, ERCC1 and DM, while five cases maintained heterozygosity at HRC but lost the more centromeric markers, D19S112 and DM. Nine cases lost the entire D19S178 to D19S254 region. Three astrocytic gliomas, including one with an interstitial deletion, had terminal deletions of 19q13.4. The minimum area of overlap shared by the interstitial deletions is between APOC2 and HRC, including ERCC1, DM, and D19S112. These findings suggest that the glioma tumor suppressor gene maps to an approximately 8-cM/5-megabase region on 19q13.2-13.3 between the proximal marker APOC2 and the distal marker HRC. Among the DNA repair/DNA metabolism genes on chromosome 19q, ERCC1, LIG1, and perhaps ERCC2 are within the common area of deletion; XRCC1 is centromeric and is therefore excluded as a candidate.
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PMID:The putative glioma tumor suppressor gene on chromosome 19q maps between APOC2 and HRC. 806 76

Deletions of the 9p-localized type-I interferon (IFN) genes and adjacent loci often occur during the development of malignant glioma. We have applied restriction fragment length polymorphism and microsatellite analysis to 12 loci covering this region of 9p and 3 loci on 9q in 74 human glial tumor tissues to define and further localize the smallest region of hemizygous or homozygous deletion common to the tumors. Three regions of homozygous deletion were evident among the panel of tumors; only one of these, however, residing between D9S171 and the IFN alpha/omega gene cluster, was involved in multiple cases (13 glioblastomas). Hemizygous deletion of this same region was observed in an additional 27 tumors. In total these data indicate the frequent inactivation of a novel tumor suppressor gene residing adjacent to and centromeric of the type-I IFN genes in malignant gliomas.
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PMID:A common region of homozygous deletion in malignant human gliomas lies between the IFN alpha/omega gene cluster and the D9S171 locus. 820 29

A panel of glial tumors consisting of 11 low grade gliomas, 9 anaplastic gliomas, and 29 glioblastomas were analyzed for loss of heterozygosity by examining at least one locus for each chromosome. The frequency of allele loss was highest among the glioblastomas, suggesting that genetic alterations accumulate during glial tumor development. The most common genetic alteration detected involved allele losses of chromosome 10 loci; these losses were observed in all glioblastomas and in three of the anaplastic gliomas. In order to delineate which chromosome 10 region or regions were deleted in association with glial tumor development, a deletion mapping analysis was performed, and this revealed the partial loss of chromosome 10 in eight glioblastomas and two of the anaplastic gliomas. Among these cases, three distinct regions of chromosome 10 were indicated as being targeted for deletion: one telomeric region on 10p and both telomeric and centromeric locations on 10q. These data suggest the existence of multiple chromosome 10 tumor suppressor gene loci whose inactivation is involved in the malignant progression of glioma.
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PMID:Loss of heterozygosity in malignant gliomas involves at least three distinct regions on chromosome 10. 837 May 84

The bax protein regulates apoptosis in a cellular pathway that involves both bcl-2 and p53, two molecules associated with human glioma tumorigenesis. We therefore evaluated the possibility that BAX functions as a glioma tumor suppressor gene. Somatic cell hybrid panels, fluorescence in situ hybridization and cosmid mapping localized the BAX gene to 19q13.3, approximately 300 kb centromeric to HRC. Thus BAX maps to the region of chromosome 19 most frequently deleted in gliomas. Routine and pulsed-field gel electrophoresis/Southern blotting studies, however, failed to reveal large-scale deletions or rearrangements of the BAX gene in gliomas. In addition, single strand conformation polymorphism analysis of all six BAX exons and flanking intronic sequences did not disclose mutations in 20 gliomas with allelic loss of the other copy of 19q. A C/T polymorphism was detected in intron 3 and was common in the general population. Therefore, although BAX maps to the glioma candidate region on the long arm of chromosome 19, BAX is probably not the 19q glioma tumor suppressor gene.
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PMID:The BAX gene maps to the glioma candidate region at 19q13.3, but is not altered in human gliomas. 864 Jul 22

Allelic loss studies have suggested that a glioma tumor suppressor gene resides in a 425-kb region of chromosome 19q, telomeric to D19S219 and centromeric to D19S112. Exon amplification of a cosmid contig spanning this region yielded four exons with high homology to a rat protein serine-threonine phosphatase from a cosmid approximately 100 kb telomeric to D19S219. Isolation of a near full-length cDNA from a human fetal brain cDNA library revealed a protein serine-threonine phosphatase with a tetratricopeptide motif, almost identical to human PPP5C (PP5) and highly homologous to rat PPT. Northern blotting demonstrated expression in most tissues, including brain. Primary and cultured gliomas were studied for genetic alterations in this gene using pulsed-field gel electrophoresis, routine Southern blots, and genomic DNA-and RNA-based single-strand conformation polymorphism analysis. Genomic alterations were were not detected in any of the gliomas, and all studied gliomas expressed the gene, suggesting that this phosphatase is not the putative chromosome 19q glioma tumor suppressor gene.
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PMID:Cloning of a highly conserved human protein serine-threonine phosphatase gene from the glioma candidate region on chromosome 19q13.3. 866 4


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