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

Tumour progression is a fundamental feature of the biology of cancer. Cancers do not arise de novo in their final form, but begin as small, indolent growths, which gradually acquire characteristics associated with malignancy. In the brain, for example, low-grade tumours (astrocytomas) evolve into faster growing, more dysplastic and invasive high-grade tumours (glioblastomas). To define the genetic events underlying brain tumour progression, we analysed the p53 gene in ten primary brain tumour pairs. Seven pairs consisted of tumours that were high grade both at presentation and recurrence (group A) and three pairs consisted of low-grade tumours that had progressed to higher grade tumours (group B). In group A pairs, four of the recurrent tumours contained a p53 gene mutation; in three of them, the same mutation was found in the primary tumour. In group B pairs, progression to high grade was associated with a p53 gene mutation. A subpopulation of cells were present in the low-grade tumours that contained the same p53 gene mutation predominant in the cells of the recurrent tumours that had progressed to glioblastoma. Thus, the histological progression of brain tumours was associated with a clonal expansion of cells that had previously acquired a mutation in the p53 gene, endowing them with a selective growth advantage. These experimental observations strongly support Nowell's clonal evolution model of tumour progression.
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PMID:Clonal expansion of p53 mutant cells is associated with brain tumour progression. 131 19

Recent studies of the p53 tumor suppressor locus (designated TP53) in primary hepatocellular carcinoma (PHC) have identified a high frequency of codon 249 mutations. Due to the geographic location from which the samples were obtained and the substitution observed, the mutation was suggested to be attributable to aflatoxin B1 (AFB1) exposure. To determine the generality of this phenomenon, we have examined PHC tissues from 107 geographically and ethnically diverse sources. The frequency of p53 gene mutations was evaluated by using PCR/restriction-digest methods, GC-clamp (G+C-rich sequence) denaturing gradient gel electrophoresis, and DNA sequencing. The mutation rate observed in tumors from high-AFB1-exposure regions (25%) was more than double the rate observed in low-exposure regions (12%) but lower than the 50% frequency previously reported. Codon 249 mutations occurred at a much lower frequency than previously reported (2 of 107 samples examined). These results suggest that changes in DNA encoding p53 may not represent primary oncogenic effects but instead represent genetic changes related to tumor progression. High AFB1 levels may facilitate the generation of these progressional changes, but not by inducing a specific p53 gene mutation at codon 249 as previously reported.
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PMID:Low frequency of p53 mutations observed in a diverse collection of primary hepatocellular carcinomas. 132 3

Drug resistance in human cancer is associated with overexpression of the multidrug resistance (MDR1) gene, which confers cross-resistance to hydrophobic natural product cytotoxic drugs. Expression of the MDR1 gene can occur de novo in human cancers in the absence of drug treatment. The promoter of the human MDR1 gene was shown to be a target for the c-Ha-Ras-1 oncogene and the p53 tumor suppressor gene products, both of which are associated with tumor progression. The stimulatory effect of c-Ha-Ras-1 was not specific for the MDR1 promoter alone, whereas a mutant p53 specifically stimulated the MDR1 promoter and wild-type p53 exerted specific repression. These results imply that the MDR1 gene could be activated during tumor progression associated with mutations in Ras and p53.
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PMID:Modulation of activity of the promoter of the human MDR1 gene by Ras and p53. 134 76

Carcinogenesis is a multistage process that has been characterized both by the activation of cellular oncogenes and by the loss of function of tumor suppressor genes. Colorectal cancer has been associated with the activation of ras oncogenes and with the deletion of multiple chromosomal regions including chromosomes 5q, 17p, and 18q. Such chromosome loss is often suggestive of the deletion or loss of function of tumor suppressor genes. The candidate tumor suppressor genes from these regions are, respectively, MCC and/or APC, p53, and DCC. In order to further our understanding of the molecular and genetic mechanisms involved in tumor progression and, thereby, of normal cell growth, it is important to determine whether defects in one or more of these loci contribute functionally in the progression to malignancy in colorectal cancer and whether correction of any of these defects restores normal growth control in vitro and in vivo. To address this question, we have utilized the technique of microcell-mediated chromosome transfer to introduce normal human chromosomes 5, 17, and 18 individually into recipient colorectal cancer cells. Additionally, chromosome 15 was introduced into SW480 cells as an irrelevant control chromosome. While the introduction of chromosome 17 into the tumorigenic colorectal cell line SW480 yielded no viable clones, cell lines were established after the introduction of chromosomes 15, 5, and 18. Hybrids containing chromosome 18 are morphologically similar to the parental line, whereas those containing chromosome 5 are morphologically distinct from the parental cell line, being small, polygonal, and tightly packed. SW480-chromosome 5 hybrids are strongly suppressed for tumorigenicity, while SW480-chromosome 18 hybrids produce slowly growing tumors in some of the animals injected. Hybrids containing the introduced chromosome 18 but was significantly reduced in several of the tumor reconstitute cell lines. Introduction of chromosome 5 had little to no effect on responsiveness, whereas transfer ot chromosome 18 restored responsiveness to some degree. Our findings indicate that while multiple defects in tumor suppressor genes seem to be required for progression to the malignant state in colorectal cancer, correction of only a single defect can have significant effects in vivo and/or in vitro.
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PMID:Progression of colorectal cancer is associated with multiple tumor suppressor gene defects but inhibition of tumorigenicity is accomplished by correction of any single defect via chromosome transfer. 134 43

Receptor status, proliferative activity, loss of differentiation, inactivation of tumor suppressor genes, and overexpression of oncogenes are related events that may affect the prognosis of patients with breast cancer. Ninety-seven unselected breast carcinomas were immunostained for estrogen and progesterone receptors, Ki-67 proliferation-associated antigen, p53 tumor suppressor gene product (p53), and c-erbB-2 protein. Immunohistochemical results and clinical data were compared. Altered p53 expression (regarded as indirect indication of inactivating gene alterations) was found in 25.8% of cases and was associated with a high Ki-67 labeling index, high mitotic count, and high histologic grade, with c-erbB-2 overexpression, and with negative estrogen and progesterone receptor status. p53 immunostaining could be found also in cytologic samples and correlated with p53 immunoreactivity on frozen sections of the corresponding tumors. c-erbB-2 protein overexpression was seen in 24.7% of cases and was associated with p53 altered expression and negative receptor status. Double immunohistochemical staining showed p53 and c-erbB-2 immunoreactivity in the same cells. Median and mean +/- standard deviation Ki-67 labeling index values were 15 and 16.32 +/- 10.05, respectively. Ki-67 labeling index was correlated with high mitotic count and was positively associated with histologic grade, negative progesterone receptor status, and p53 expression. Estrogen receptor status was not associated with any histologic or clinical parameters, whereas progesterone receptor status was associated with grading. The direct relation of p53 protein alterations with c-erbB-2 overexpression may be interpreted in light of the multistep model of tumor progression. Cases with altered expression of both p53 and c-erbB-2 proteins could be interpreted as having lost one inhibitory control mechanism of cell proliferation and having gained one activator of the malignant potential. However, in comparing cases with the p53 + c-erbB-2 + phenotype with cases showing positivity for only one of these gene products, no association with higher stages was seen. Detection of p53 altered expression on cytologic samples of malignant tumors may have diagnostic relevance, and p53 immunostaining may prove to be an additional diagnostic criterion in cytologic diagnosis.
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PMID:p53 and c-erbB-2 protein expression in breast carcinomas. An immunohistochemical study including correlations with receptor status, proliferation markers, and clinical stage in human breast cancer. 135 56

p53 is a tumor suppressor gene that commonly undergoes mutations in human tumors, including lymphomas. Because p53 mutations are not restricted to a single locus, immunohistochemistry is useful to detect p53 expression and correlate this finding with lymphoma phenotype. Cryostat sections from 125 cases of lymphoma were analyzed for p53 expression using three different monoclonal antibodies (pAb 421, 1801, 240) which react with human cellular p53 and a common conformational epitope on mutant p53. A control antibody (pAb 246) reacts only with wild type p53 of murine origin and was negative in all cases. Tissue from 29 cases of lymphoid hyperplasia, including six from human immunodeficiency virus-positive (HIV+) patients, were negative for p53. p53 was predominantly localized in nuclei of high-grade lymphomas, including 14 of 46 cases of B cell immunoblastic lymphomas and two of five T cell immunoblastic lymphomas. p53 expression was relatively common in lymphomas from HIV+ patients, and unusual in intermediate and low-grade lymphomas of follicular center cell type. Low-grade lymphoma of small lymphocytic type disclosed p53+ large cells (paraimmunoblasts) that may play a role in tumor progression in this lymphoma subtype. p53 was also strongly expressed in the nuclei of Reed Sternberg cells from 19 of 37 cases of Hodgkin's disease, including six cases of mixed cellularity, and 13 cases of nodular sclerosing type. Immunohistochemical staining is a rapid method to identify p53 expression in lymphomas.
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PMID:Immunohistochemical analysis of p53 expression in malignant lymphomas. 146 98

Allelic loss and mutation of the p53 gene are common events of esophageal, gastric and colorectal cancers occurring from an early stage. Moreover, p53 mutation takes place in intestinal metaplasia and adenoma of the stomach. p53 mutation spectra differ among esophageal, gastric and colorectal cancers suggesting exposure to different endogenous and exogenous mutagens. The in vivo and in vitro results indicate that the clonal expansion of p53 mutant cell may be associated with tumor progression. Although wild type p53 transfection technique may provide for cancer therapy, there is a rather serious problem about it.
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PMID:[Significance of p53 gene abnormalities in carcinogenesis of human gastrointestinal tract]. 147 Jan 60

The accumulation of genetic damage in the forms of activated proto-oncogenes and inactivated tumor-suppressor genes is the driving force in the evolution of a normal cell to a malignant cell. For example, both the activation of ras oncogenes and the inactivation of several suppressor genes, including p53, have been observed in the development of human colon and lung tumors. Point mutations in key codons can activate ras proto-oncogenes and inactivate the p53 suppressor gene. Thus, several critical genes for tumorigenesis are potential targets for carcinogens and radiation that can induce point mutations at low doses. The ras proto-oncogenes are targets for many genotoxic carcinogens. Activation of the ras gene is an early event--probably the "initiating" step--in the development of many chemical-induced rodent tumors. ras Oncogenes are observed in more human tumors and at a higher frequency than any other oncogene, and activation of the proto-oncogene may occur at various stages of the carcinogenic process. Numerous proto-oncogenes other than the ras genes have been shown to be activated in human tumors and to a lesser extent in rodent tumors. Mechanisms that induce aberrant expression of proto-oncogenes are gene amplification and chromosomal translocation or gene rearrangement. Amplification of proto-oncogenes and possibly gene overexpression during the absence of gene amplification occur in the development of many human tumors. For a specific tumor type, amplification of any one proto-oncogene may occur at a low frequency, but the frequency of tumors in which at least one proto-oncogene is amplified can be much higher. Proto-oncogene amplification is usually associated with late stages of tumor progression; however, amplified HER2/neu has been observed in early clinical stages of mammary neoplasia. Activation of proto-oncogenes by chromosomal translocation has been detected at a high frequency in several hematopoietic tumors. Non-ras genes have been detected by DNA transfection assays in both human and rodent tumors. For example, ret and trk genes were found to be activated by gene rearrangements in human papillary thyroid carcinomas. Several potentially new types of oncogenes have also been detected by DNA transfection assays. The etiology of the genetic alterations observed in most human tumors is unclear at present. Examples of ras gene activation and those documented for mutations in the p53 gene demonstrate that exogenous conditions can induce oncogenic mutants of normal genes. The genetic alterations observed in most human tumors are probably generated by both spontaneous events and exogenous conditions.
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PMID:Role of proto-oncogene activation in carcinogenesis. 148 40

Tumorigenesis is a multistep process involving mutations of dominantly acting proto-oncogenes and mutations and loss-of-function mutations of tumor suppressor genes. Some of these mutations may be inherited, but most of them are acquired. Models for the sequential steps of the genetic changes involved in tumor development have been proposed for certain cancers, such as colon cancer. In the case of ovarian cancer, relatively little is known about the genetic events associated with the initiation or subsequent progression and metastases of the tumor. Cytogenetic analysis has revealed a high incidence of both structural and numerical chromosome changes, and the extent of these changes seems to increase with tumor progression. Oncogene activations of the proto-oncogenes K-ras, c-myc and c-erbB-2 have been found more frequently in aggressive ovarian tumors and may be associated with poor survival. Tumor-specific allele loss involving putative tumor suppressor genes has been observed for loci at chromosomes 11p, 17p, and 17q,--loci commonly deleted in other cancers too. A relatively high incidence of allelic loss on chromosome 6q appears to be specific to ovarian carcinoma. Familial breast/ovarian cancer has been suggested to map to chromosome 8q. Recently we have found a germ-line mutation in the tumor suppressor gene p53 in a family with breast- and ovarian cancers, indicating that this is the predisposing gene in this family. Genetic changes important for the etiology of ovarian cancers seem to involve both somatic mutations of oncogenes and somatic or germ-line inactivation of tumor suppressor genes.
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PMID:Oncogenesis in ovarian cancer. 150 89

Cytogenetic alterations that characterize different histologic subtypes of soft tissue sarcomas have been identified. In a few situations, more precise chromosomal mapping has allowed identification of certain genes that may be involved in the development or tumor progression of sarcomas. Careful family histories must be elicited in sarcoma patients. While "cancer families" are rarely identified when screening close relatives of sarcoma patients, the discovery of the currently known tumor suppressor gene syndromes associated with germ line retinoblastoma gene and p53 gene defects were made possible by their association with sarcomas. Optimal management of primary sarcomas includes function-sparing complete resection and radiotherapy. Innovative radiotherapy, utilizing radiation sensitizers or brachytherapy, may increase local control in patients with unresectable tumors. New drugs are needed. Epirubicin and other anthracycline analogues do have significant activity; however, no other novel drugs have documented efficacy. Dose intensity is being explored with sarcoma trials providing the "vehicle" to evaluate new cytokines. Several mechanisms of doxorubicin resistance have been identified in cell lines and fresh tumors, including alterations in glutathione peroxidase activity and MDR-1 gene expression. These observations need to be taken to the clinic.
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PMID:Advances in the diagnosis and management of sarcomas. 151 Oct 24


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