UNIPROT:P04637 - FACTA Search

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Query: UNIPROT:P04637 (p53)
77,613 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Mutations in the p53 tumor suppressor gene are the most common genetic alterations found in diverse types of human cancer, including the primary malignant brain tumor, glioblastoma multiforme. To estimate the frequency of p53 mutations in human brain tumors, we screened 120 human primary brain tumors (59 astrocytic; 61 nonastrocytic) by the polymerase chain reaction-single-strand conformation polymorphism technique. Six astrocytic tumors (one anaplastic astrocytoma and five glioblastoma multiforme) were found to have putative p53 mutations. Direct sequencing of polymerase chain reaction-amplified deoxyribonucleic acid from these six tumors confirmed the presence of different point mutations in the conserved regions of the p53 gene. Allelic losses on chromosome 17p were detected in four (67%) of the six tumors with p53 mutations. p53 mutations were not detected in any of the 61 nonastrocytic brain tumors. Also, polymerase chain reaction-single-strand conformation polymorphism analysis of 74 leukocyte deoxyribonucleic acid samples from patients with astrocytic and nonastrocytic brain tumors failed to detect any germ-line p53 mutations. We conclude from these findings that p53 gene mutations in brain neoplasms are primarily limited to tumors of astrocytic origin and that the p53 gene mutations in sporadic astrocytomas are somatic in origin (i.e., nonprenatally determined).
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PMID:Frequency of p53 tumor suppressor gene mutations in human primary brain tumors. 790 34

To characterize some of the genetic events underlying the development of glioblastoma multiforme, the authors analyzed 65 astrocytic tumors (seven pilocytic astrocytomas, eight astrocytomas, 16 anaplastic astrocytomas, and 34 glioblastomas multiforme) for loss of heterozygosity for chromosome 17p, loss of heterozygosity for chromosomes 10p and 10q, amplification of the epidermal growth factor receptor (EGFR) gene, and amplification of the oncogenes N-myc, c-myc, and N-ras using Southern blot analysis. Alterations of the p53 gene (positive immunostaining for p53 protein in tumors with or without p53 gene mutations) in these 65 tumors were analyzed previously. None of the 65 tumors showed amplification or rearrangement of N-myc, c-myc, or N-ras oncogenes. The molecular analysis presented here demonstrates distinct variants of astrocytic tumors, with at least three genetic pathways leading to glioblastoma multiforme. One pathway was characterized by 43 astrocytomas with alterations in p53. Glioblastomas with p53 alterations may represent tumors that progress from lower-grade astrocytomas. This variant was more likely to show loss of chromosome 17p than tumors without p53 alterations (p < 0.04). Seventy-five percent of tumors with loss of one 17p allele demonstrated mutations in the p53 gene. Loss of chromosome 10 was associated with progression from anaplastic astrocytoma (13%) to glioblastoma (38%) (p < 0.04). Amplification of the EGFR gene was a rare (7%) but late event in tumor progression (p < 0.03). A second pathway was characterized by six astrocytomas without p53 alterations and may represent clinically de novo high-grade tumors. These tumors were more likely to show amplification of the EGFR gene (83%) than tumors with p53 alterations. Sixty percent of tumors with EGFR amplification also showed loss of chromosome 10; loss of chromosome 17p was infrequent in this variant. One or more alternative pathways were characterized by 16 astrocytomas without p53 alterations and with none of the genetic changes analyzed in this study. Glioblastomas are a heterogeneous group of tumors that may arise via multiple genetic pathways.
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PMID:Pathways leading to glioblastoma multiforme: a molecular analysis of genetic alterations in 65 astrocytic tumors. 805 51

Glial tumors of all grades and histological types from 72 adults and 48 children were analyzed for mutations of the TP53 gene, loss of heterozygosity (LOH) for 17p, and accumulation of TP53 protein to determine whether the incidence and type of TP53 alterations differ among tumors of different histological type and between tumors from adults and children. These tumors were also evaluated for LOH for chromosome 10 and for amplification of the epidermal growth factor receptor, C-MYC, N-MYC, GLI, platelet-derived growth factor receptor-alpha, and murine double minute 2 genes to determine the patterns of molecular alterations involved in the progression of these neoplasms. Seventeen of the 120 tumors contained mutations of the TP53 gene. One of the tumors with TP53 gene mutation was from one of the 48 patients less than 18 years of age. Twelve of the 17 tumors with mutations occurred among the 27 patients in the 18-45-year age group, while 4 tumors with mutations were among the 45 patients more than 45 years old. There was also an increased incidence of TP53 mutation in patients with anaplastic astrocytoma histology. However, no significant association between presence of TP53 mutation and patient survival was observed. These studies demonstrate that TP53 gene mutations are a common mechanism for glial cell neoplasms in the 18-45-year age group but are unrelated to progression and advanced histological grade. LOH for chromosome 10 and gene amplification, however, occurring in 82 and 40%, respectively, of glioblastoma multiforme, whether seen alone or along with TP53 gene alterations, are related to advanced histological grade of the tumor. In childhood gliomas, in contrast, TP53 gene alterations, LOH for 17p and 10q, and gene amplification are uncommon in tumors of all grades, suggesting that presently unknown mechanisms are responsible for the genesis and progression of these tumors.
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PMID:Alterations of the TP53 gene in human gliomas. 811 23

The immunohistochemical expression of p53 protein (p53) was examined in 52 patients out of a series of 66 patients with low-grade astrocytomas with long-term follow-up. All patients were also evaluated for several clinical and histological features, among which only preoperative Karnofsky score and the extent of surgery were statistically significant parameters to predict outcome on multivariate analysis. p53 accumulation was seen in 46.1% of patients, with a wide range of percentage of positive cells. Median survival for p53-positive and p53-negative patients was 41 and 37 months respectively. The survival curves of p53-positive and -negative patients were not statistically different. However, the curves showed a trend towards a more aggressive course in p53-positive patients beginning 3-4 years after surgery. Five years after diagnosis the survival estimate with the Kaplan-Meier method was 21.2% for patients with p53-positive tumours and 45.9% for patients with p53-negative tumours. This trend is not due to different distribution of major clinical prognostic factors (age, incomplete resection or Karnofsky status). The trend could be related to the time needed by the p53-positive clone to outgrow the rest of the p53-negative neoplastic cell population. This hypothesis is further supported by the fact that the five recurrences which were surgically removed (one anaplastic astrocytoma and four glioblastomas) derived from p53-positive tumours and were themselves intensely p53 positive.
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PMID:p53 protein in low-grade astrocytomas: a study with long-term follow-up. 812 92

The p53 gene was examined in a series of formalin-fixed paraffin-embedded astrocytic neoplasms of various types by polymerase chain reaction (PCR), single-strand conformation polymorphism analysis (SSCP), and direct sequencing of amplified DNA. PCR primers were designed to amplify three DNA fragments encompassing exons 5, 7, and 8 with splice sites, including all four mutational "hot spots" within this gene. SSCP was performed in a polyacrylamide gel containing 10% glycerol. Two mutations were found among the 20 high and intermediate grade adult astrocytomas studied by this sensitive screening technique and confirmed by sequencing of the PCR product. (1) An anaplastic astrocytoma disclosed a T-A transversion in Codon 246 giving rise to a methionine to lysine amino acid substitution. (2) A giant cell glioblastoma disclosed a G to A transition in Codon 285 resulting in a glutamic acid to lysine substitution. Both mutations were associated with loss of the normal allele. Twenty-three DNA fragments that disclosed no mutation by SSCP analysis were confirmed to be negative by direct sequencing of amplified DNA. No mutations were detected in a series of eight juvenile cerebellar astrocytomas, a biologically distinct form of low-grade astrocytoma. Mutations of the p53 gene may play an important pathogenetic role in a subset of human astrocytomas.
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PMID:Mutations in the p53 gene in human astrocytomas: detection by single-strand conformation polymorphism analysis and direct DNA sequencing. 841 89

Abnormalities of the p53 gene are the most common molecular change in human cancer. In the central nervous system, mutant p53 gene is frequently identified in the tumors with astrocytic differentiation. To investigate the relation between histologic subtypes and p53 protein overexpression, we examined 81 cases of astrocytic neoplasms (24 benign astrocytoma, 28 anaplastic astrocytoma and 29 glioblastoma multiforme) using the standard immunohistochemical method. All were formalin-fixed and paraffin-embedded tissue. The p53 immunoreactivity was found in 4/24 benign astrocytoma, 18/28 anaplastic astrocytoma, 22/29 glioblastoma multiforme. The degree of immunoreactivity closely correlated with histologic subtypes (p < 0.001). Overall p53 protein expression was most frequently detected in glioblastoma multiforme, but strong immunoreactivity (3+) was more frequently found in the anaplastic astrocytoma than in glioblastoma multiforme. Although the frequency of p53 protein expression is low, 4 benign astrocytoma showed distinct nuclear staining. In conclusion the malignant progression of astrocytic neoplasms may be associated with increasing expression of p53 protein.
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PMID:p53 protein overexpression in astrocytic neoplasms. 859 54

P53 immunohistochemistry in astrocytic tumors has usually been evaluated by the percentage of positive cells. However, in this study we analyzed the P53 immunopositive cells by their patterns of distribution. Formalin-fixed and paraffin-embedded sections from 38 patients with astrocytic tumors were examined. The distribution pattern of P53 immunostaining cells was divided into 3 types: negative, locally scattered, and diffuse clustering. There were 2 positive stains in 5 astrocytomas (40%), 12 positive in 24 anaplastic astrocytomas (50%), and 7 positive in 9 glioblastoma multiformes (78%). In astrocytomas, the positive cells were locally scattered. In anaplastic astrocytoma and GBM, the positive cells appeared locally scattered or as diffuse clustering. For the variant immunoreactive expression, the mean ages for patients with negative, locally scattered and diffusely clustered P53 immunostaining were as follows: 51.4, 52.6, and 28.4 years (P < 0.01), respectively. In anaplastic astrocytoma and GBM, the diffusely clustered pattern was more common in younger patients, whereas elderly patients in same groups tended to have few or no P53 immunopositive cells. Thus, our results implicate that clonal expansion of P53 immunopositive cells is associated with brain tumor progression.
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PMID:Immunohistochemical pattern of P53 protein in human astrocytic tumors. 867 33

Tumor growth depends on cell division and cell death. To investigate the role of apoptosis in tumor cell death, we examined 83 cases of glial tumors using in situ nonradioactive tailing of DNA breaks. In addition, since p53 protein may participate in the regulation of apoptosis in glioblastoma, we compared the apoptosis ratio (AR) with the labeling index (LI) of p53 protein immunopositivity. The AR in glial tumor parenchyma ranged from 0 to 1.4%: mean AR +/- standard deviation was 0.4 +/- 0.4% (range, 0-1.4) for glioblastoma, 0.3 +/- 0.3% (range, 0.01-0.83) for anaplastic astrocytoma, 0.1 +/- 0.1% (range, 0-0.41) for low-grade astrocytoma, 0.006 +/- 0.008% (range, 0-0.02) for pilocytic astrocytoma, 0.2 +/- 0.2% (range, 0-0.62) for oligodendroglioma and 0.003 +/- 0.004% (range, 0-0.01) for ependymoma. ARs were significantly higher in higher-grade astrocytic tumors than in lower-grade tumors (Mann-Whitney U test: P = 0.0003), although wide variability in each group resulted in overlapping between the groups. p53 protein immunopositivity (more than 25% of nuclei) was found in 15 of 32 glioblastoma cases, while in the remaining 17 none or only a low percentage (up to 6%) of the nuclei were positive. In p53 protein-positive cases mean AR (0.51 +/- 0.47%) was not significantly higher than that in p53 protein-negative cases (0.22 +/- 0.23%; P = 0.1681).
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PMID:Apoptosis in glial tumors as determined by in situ nonradioactive labeling of DNA breaks. 877 55

Glioblastoma multiforme, the most malignant human brain tumor, may develop de novo (primary glioblastoma) or through progression from low-grade or anaplastic astrocytoma (secondary glioblastoma). We present further evidence that primary and secondary glioblastomas constitute distinct disease entities which develop through the acquisition of different genetic alterations. We analyzed p53 mutations, p53 protein accumulation and epidermal growth factor receptor (EGFR) overexpression in 49 biopsies classified as primary or secondary glioblastoma according to clinical and histopathologic criteria. Patients with primary glioblastoma were selected on the basis of a clinical history of less than 3 months and histopathologic features of glioblastoma at the first biopsy (19 cases; mean age, 55 years). The diagnosis of secondary glioblastomas required at least two biopsies and clinical as well as histologic evidence of progression from low grade or anaplastic astrocytoma (30 cases; mean age, 39 years). DNA sequence analysis showed that p53 mutations were rare in primary glioblastomas (11%) while secondary glioblastomas had a high incidence of p53 mutations (67%), of which 90% were already present in the first biopsy. The incidence of p53 protein accumulation (nuclear immunoreactivity to PAb 1801) was also lower in primary (37%) than in secondary glioblastomas (97%). In contrast, immunoreactivity for the EGF receptor prevailed in primary glioblastomas (63%) but was rare in secondary glioblastomas (10%). Only one out of 49 glioblastomas showed EGFR overexpression and a p53 mutation. These data indicate that overexpression of the EGF receptor and mutations of the p53 tumor suppressor gene are mutually exclusive events defining two different genetic pathways in the evolution of glioblastoma as the common phenotypic endpoint.
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PMID:Overexpression of the EGF receptor and p53 mutations are mutually exclusive in the evolution of primary and secondary glioblastomas. 886 78

Glioblastoma multiforme (WHO Grade IV), the most malignant neoplasm of the human nervous system, develops rapidly de novo (primary glioblastoma) or through progression from low-grade or anaplastic astrocytoma (secondary glioblastoma). We recently reported that mutations of the p53 gene are present in more than two-thirds of secondary glioblastomas but rarely occur in primary glioblastomas, suggesting the presence of different genetic pathways (Watanabe et al, Brain Pathol 1996:6:217-24). In the present study, primary and secondary glioblastomas were screened by immunohistochemistry for MDM2 overexpression and by differential PCR for gene amplification. Tumor cells immunoreactive to MDM2 were found in 15 of 29 primary glioblastomas (52%), but in only 3 of 27 secondary glioblastomas (11%; P=0.0015). MDM2 amplification occurred in 2 primary (7%) glioblastomas but in none of the secondary glioblastomas. Only one out of 15 primary glioblastomas overexpressing MDM2 contained a p53 mutation. These results suggest that MDM2 overexpression with or without gene amplification constitutes a molecular mechanism of escape from p53-regulated growth control, operative in the evolution of primary glioblastomas that typically lack p53 mutations.
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PMID:Amplification and overexpression of MDM2 in primary (de novo) glioblastomas. 903 72

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