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

A novel gene, RTVP-1, which shows significant sequence identity to the mammalian testis-specific proteins, a family of plant pathogenesis-related proteins and the vespid venom allergen, antigen-5, has been isolated from a cDNA library of the human glioblastoma brain tumor cell line, U-251 MG. The highest degree of sequence identity was with the human testis-specific protein, TPX1 (38.7% over 119 amino acids). Northern hybridization analysis revealed that in fetal tissue RTVP-1 RNA was detected only in the kidney, but its expression was ubiquitous in adult tissues including brain. Multiple mRNAs encoded by RTVP-1 were highly expressed in a panel of cell lines from nervous system tumors arising from glia, although expression was low or absent in nonglial-derived nervous system tumor cell lines.
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PMID:RTVP-1, a novel human gene with sequence similarity to genes of diverse species, is expressed in tumor cell lines of glial but not neuronal origin. 897 56

A novel gene was identified recently at chromosome 10q23, named PTEN or MMAC1, and based on several criteria it was designated as a potential human tumor suppressor gene. Loss of heterozygosity affecting this region of 10q is observed in several cancer types, especially glioblastoma, and inactivating mutations of the PTEN/MMAC1 gene are found in some of these cancers as well as cell lines and xenografts. Breast cancer is among the tumor types in which mutations are documented, and germline mutations of the gene appear to be responsible for the rare autosomal dominant familial cancer syndrome known as Cowden disease, which includes breast cancer among its clinical features. To further determine the role that PTEN/MMAC1 mutations may play in breast tumorigenesis, the entire coding region was screened for mutations in 54 unselected primary breast cancers. Two mutations were identified, a somatic 2-bp deletion in an apparently sporadic breast cancer, and a germ-line 4-bp deletion in a breast cancer patient with a clinical history consistent with Cowden disease. These data indicate that somatic mutations of PTEN/ MMAC1 occur in only a small fraction of primary breast cancers and confirm the role of this gene in the etiology of Cowden disease. Evidence is also presented suggesting that numerous polymorphisms and missense variants exist in the PTEN/MMAC1 transcript.
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PMID:Mutation analysis of the putative tumor suppressor gene PTEN/MMAC1 in primary breast carcinomas. 928 66

We have identified two novel human genes homologous to BAI1 (brain-specific angiogenesis inhibitor 1), an angiogenesis inhibitor that is a candidate for involvement in development of glioblastoma. Like BAI1, these two genes, designated BAI2 and BAI3, were specifically expressed in brain, and are likely to be expressed in the same type of cells. However, in spite of similar tissue specificity among the three BAI genes, only BAI1 is transcriptionally regulated by p53. BAI3 expression was absent in two of nine glioblastoma cell lines examined and was significantly reduced in three of the remaining seven. These data suggest that members of this novel gene family may play important roles in suppression of glioblastoma. BAI1, BAI2 and BAI3 were mapped to 8q24, 1p35 and 6q12, respectively.
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PMID:Cloning and characterization of BAI2 and BAI3, novel genes homologous to brain-specific angiogenesis inhibitor 1 (BAI1). 953 23

The loss of large segments or an entire copy of chromosome 10 is the most common genetic alteration in human glioblastomas. To address the biological and molecular consequences of this chromosomal alteration, we transferred a human chromosome 10 into a glioma cell clone devoid of an intact copy. The hybrid cells exhibited an altered cellular morphology, a decreased saturation density, and a suppression of both anchorage-independent growth and tumor formation in nude mice. The hybrids also expressed the recently identified candidate tumor suppressor gene MMAC1/PTEN. To further identify gene products that may be involved in glioma progression, a subtractive hybridization was performed between the human glioblastoma cells and the phenotypically suppressed hybrid cells to identify differentially expressed gene products. Sixty-one clones were identified, with nine clones being preferentially expressed in the hybrid cells. Four cDNA clones represented markers of differentiation in glial cells. Two cDNA clones shared homology with platelet derived growth factor-alpha and the insulin receptor, respectively, both genes previously implicated in glioma progression. A novel gene product that was expressed predominantly in the brain, but which did not map to chromosome 10, was also identified. This clone contained an element that was also present in three additional clones, two of which also exhibited differential expression. Consequently, the presence of a functional copy of chromosome 10 in the glioma cells results in differential expression of a number of gene products, including novel genes as well as those associated with glial cell differentiation.
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PMID:Differentially expressed gene products in glioblastoma cells suppressed for tumorigenicity. 958 58

Loss of heterozygosity for 10q23-26 is seen in over 80% of glioblastoma multiforme tumors. We have used a positional cloning strategy to isolate a novel gene, LGI1 (Leucine-rich gene-Glioma Inactivated), which is rearranged as a result of the t(10;19)(q24;q13) balanced translocation in the T98G glioblastoma cell line lacking any normal chromosome 10. Rearrangement of the LGI1 gene was also detected in the A172 glioblastoma cell line and several glioblastoma tumors. These rearrangements lead to a complete absence of LGI1 expression in glioblastoma cells. The LGI1 gene encodes a protein with a calculated molecular mass of 60 kD and contains 3.5 leucine-rich repeats (LRR) with conserved flanking sequences. In the LRR domain, LGI1 has the highest homology with a number of transmembrane and extracellular proteins which function as receptors and adhesion proteins. LGI1 is predominantly expressed in neural tissues, especially in brain; its expression is reduced in low grade brain tumors and it is significantly reduced or absent in malignant gliomas. Its localization to the 10q24 region, and rearrangements or inactivation in malignant brain tumors, suggest that LGI1 is a candidate tumor suppressor gene involved in progression of glial tumors.
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PMID:A novel gene, LGI1, from 10q24 is rearranged and downregulated in malignant brain tumors. 987 93

Gene amplification is known to occur frequently in human glioma. Recently we reported cloning of a novel gene termed glioma-amplified sequence 16 (GAS16) by microdissection-mediated cDNA capture. In this article, we demonstrate that GAS16 results from an alternative splicing process of the Ku70 binding protein 3 (KUB3) that is essential for DNA double-strand break repair. The alternative splice product was found in glioblastoma and in normal fetal brain. We determined the amplification frequency of KUB3 in glioma with different grading. We analyzed a total of 102 glioma primary tumors and found KUB3 to be amplified in 12/82 (14%) glioblastomas, 4/13 anaplastic astrocytomas (30%), and 2/4 astrocytomas, but in none of three pilocytic astrocytomas. Northern blot analysis of glioblastoma shows a strong correlation between KUB3 amplification and overexpression. Amplification of KUB3 appears to be independent of other genetic changes frequently associated with the development of gliomas, including EGFR amplification, LOH of TP53, and LOH of chromosome 10. The KUB3 amplification and overexpression may interfere with the function of KUB3 in the DNA-PK complex involved in the maintenance of genome stability and reduction of mutation frequency.
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PMID:KUB3 amplification and overexpression in human gliomas. 1157 79

Glioblastoma is the most frequent brain tumor and accounts for approximately 50--60% of all astrocytic tumors. Many chromosome alterations have been described in glioblastoma, but only for a few alterations were the genes identified and linked to genetic pathways in glioblastoma development. To contribute to the identification of novel genes involved in glioblastoma development we used a combined immunological and molecular screening approach. Here we report the identification and expression analysis of a novel gene from human chromosome 6q12 that is considered to be the third member of a family of PHD finger containing genes and is termed PHF3. PHF3 is ubiquitously expressed in normal tissues including brain, but its expression is significantly reduced or lost in glioblastoma, glioblastoma cell lines, anaplastic astrocytomas and astrocytomas. The PHF3 protein sequence contains several protein motifs frequently found in transcription factors. One of those motifs is a PHD finger, also termed LAP motif and known to bind large portions of DNA. Another region of the protein revealed a high homology to the transcription factor TFIIS, especially to a region that is necessary for the Polymerase II binding properties of TFIIS. Combining these results, PHF3 is a novel member of a large class of regulatory proteins containing a LAP motif, and loss of its expression in glioblastoma may contribute to glioma development.
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PMID:PHF3 expression is frequently reduced in glioma. 1185 69

Using the technique of differential hybridization of a human fetal brain library, we have identified a novel gene, brain 2 (BR-2). This gene is expressed in normal brain but has low or no expression in human oligodendrogliomas and other brain tumor samples. We have cloned and sequenced the full-length cDNA corresponding to this gene. A data base search for the nucleotide sequence homology was performed for BR-2. BR-2 sequence showed strong homolog to a human genomic clone from chromosome 2. Moderate sequence homology was observed between BR-2 and an EST from a human placenta library. Multiple tissue dot blot analysis indicated that the BR-2 gene is expressed in a number of tissues including brain, heart, lung, placenta, lymph node, trachea and kidney. The BR-2 gene is also expressed in fetal heart, spleen and lung tissue. An extremely high level of BR-2 expression is observed in the left atrium of the heart. Low or no expression of BR-2 expression is observed in sixteen human cancer cell lines. RT-PCR analysis indicated that the BR-2 gene is expressed at high levels in two of the five normal brain tissue samples analyzed. Except for low expression in one oligodendroglioma, no expression of BR-1 gene was observed in eight anaplastic astrocytomas and glioblastoma multiforme tissue samples. Four of nine glioblastoma tumor cell lines did show a low level of BR-2 expression. On the basis of its expression and sequence, we conclude that BR-2 is a novel gene with unique expression properties in human brain tumors.
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PMID:Molecular characterization of a novel BR-2 gene that is down-regulated in human low grade glioma tumors. 1201 33

Using the technique of differential hybridization of a human fetal brain library, we identified a novel gene, brain 1 (BR-1). This gene is expressed in normal brain but has low or no expression in human gliomas. We have cloned and sequenced the full-length cDNA corresponding to this gene. A data base search for the nucleotide sequence homology was performed for BR-1. The BR-1 sequence showed strong homology to a human genomic clone from chromosome 2. Moderate sequence homology was observed between BR-1 and an expressed sequence tag (EST) from a human placenta library. Three different regions of BR-1 also showed homology to a mouse EST that is similar to EL-10 gene. Sequence analysis indicated that the protein sequence for BR-1 has one tyrosine kinase phosphorylation site and two N-myristoylation sites. Northern blot analysis indicated that the BR-1 gene is expressed in heart, placenta, lung, liver, skeletal muscle, kidney and pancreas. A low level of expression of BR-1 is observed in the cerebellum, cerebral cortex, spinal cord, occipital lobe and putamen. The BR-1 gene is also expressed in fetal brain, liver and kidney. Low expression of BR-1 gene was observed in a number of non-brain tumor cell lines. RT-PCR analysis indicated that the BR-1 gene was expressed in non-neoplastic (epilepsy specimens) but not in six oligodendrogliomas and three oligoastrocytoma tumor samples analyzed. BR-1 was not expressed in either seven low grade gliomas or eight grade IV glioblastoma tumor tissue samples analyzed. Three glioblastoma cell lines did show low expression of the BR-1 gene. On the basis of its expression properties, we conclude that BR-1 is a potential novel tumor suppressor gene.
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PMID:Cloning, sequencing and expression analysis of a novel gene BR-1 that is expressed in normal human brain tissue but not in glioma tumor samples. 1201 46

Using the technique of differential hybridization of a human fetal brain library, we have identified a novel gene, brain 3 (BR-3). This gene is not expressed in normal human brain tissue samples but is expressed at high levels in human low-grade glioma tissue samples. We have cloned and sequenced the full-length cDNA corresponding to this gene. Data base search analysis indicated that the BR-3 gene has strong homology to a genomic sequence present on chromosome 1 but no homology to expressed genes. Open reading frame analysis has indicated the presence of a 71 amino acids long protein sequence. A data base search for the protein sequence homology showed no similarity to known sequences. Expression analysis of BR-3 indicated that it is expressed at high level in six out of seven low-grade glioma samples analyzed. In addition low levels of BR-3 gene expression was observed in six out of seven anaplastic astrocytoma tissue samples analyzed. BR-3 expression was observed in four of eight glioblastoma samples analyzed. Expression analysis of normal human tissues indicated that it is expressed in kidney, skeletal muscle, lung, spleen and heart. No expression of the BR-3 gene was observed in brain, liver or testes tissue. To understand the role of the BR-3 gene in cancer in general, we studied its expression in other cancer cell lines. Except for lung and ovarian carcinoma, the BR-3 gene is expressed in breast carcinoma, colon adenocarcinoma, prostatic adenocarcinoma, and pancreatic adenocarcinoma tissue samples. On the basis of its sequence, unique expression pattern, we conclude that BR-3 gene product may play a critical role in the genesis of human gliomas tumors.
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PMID:Molecular characterization of a novel human brain tumor-associated gene BR-3. 1216 25


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