Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: UNIPROT:P04637 (p53)
 77,613 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Loss of heterozygosity occurring on various chromosomes has been described in the majority of human tumors. The targets of frequent or consistent subchromosomal deletions are believed to be tumor suppressor genes. We examined 72 esophageal tumors (46 squamous cell carcinomas and 26 adenocarcinomas) for loss of heterozygosity at the p53, Rb, APC, MCC, and DCC loci. Inclusion of these tumor suppressor genes in the allelic deletions was directly ascertained by performing polymerase chain reaction at polymorphic sites within the genes. Loss of heterozygosity occurred in 55% of informative cases at p53, in 48% of informative cases at Rb, in 66% at APC, in 63% at MCC, and in 24% at DCC. Ninety-three % of tumors informative at all loci (fully informative) lost heterozygosity of at least one locus. A high percentage of fully informative tumors (71%) also lost heterozygosity at more than one locus. There were no significant differences among histological types in the prevalence of loss of heterozygosity at any locus. There were correlations of losses involving MCC versus DCC, Rb, and p53. These data suggest that (a) allelic deletions including these tumor suppressor genes are important in the formation and/or progression of most esophageal cancers; (b) allelic deletions involving MCC may not occur independently of deletions involving other tumor suppressor genes; and (c) the accumulation of multiple allelic deletions involving specific tumor suppressor genes may be important in most esophageal tumorigenesis or tumor evolution.
 ...
PMID:Loss of heterozygosity involves multiple tumor suppressor genes in human esophageal cancers. 142 99

For colorectal carcinomas, the rate of tumor development is proportional to the fourth to sixth power of elapsed time, suggesting that four to six independent events are necessary. Although similar calculations have not been made for HBV-associated HCCs, it is likely that this is also the case for HCCs, since individuals with persistent HBV infection do not usually develop HCC until they are 45 or greater years old. As evidence for specific genetic and epigenetic changes in HCCs accumulate, the important players in multistep hepatocarcinogenesis are becoming clearer. However, even though Myc family oncogenes are clearly implicated in woodchuck HCC, similar integrations have not been found in human HCCs. Therefore, although rodent and human systems have many similarities, we must realize that important differences may also exist. Regarding tumor suppressor genes, the evidence for p53 alterations in HCC is strong. A growing body of evidence suggests further that alterations in the retinoblastoma gene and one or more tumor suppressor genes on chromosome 11 are also involved in HCC. HBV integrations may certainly play a role in the generation of chromosome aberrations leading to loss of tumor suppressor alleles, since chromosomes 11 and 17 are the most common integration sites. Finally, the role of X proteins as participants in malignant transformation has been demonstrated for certain immortalized, nontransformed hepatocytes. Altered autocrine mechanisms of cell growth control, possibly involving IGF-II, are clearly implicated in HCC. Paracrine mechanisms for the control of hepatocyte growth and differentiated functions may also be altered as a result of the synthesis and secretion of a complex array of interleukins, HGF, and basic and acidic FGFs by cells in the inflammatory and cirrhotic lesions of precancerous livers. Whether the order of molecular changes in the hepatocyte is important for malignant progression is presently not clear. What is clear, however, is that hepatocarcinogenesis involves alterations in the concerted action of protooncogenes, growth factor, and tumor suppressor genes. How these factors interact will provide a more complete understanding of the mechanism or mechanisms of hepatic oncogenesis.
 ...
PMID:Cellular and molecular mechanisms of hepatocarcinogenesis. 143 79

The multistep development of haematopoietic malignancies, like other neoplasms, reflects sequential mutations that either activate proto-oncogenes or disrupt tumour suppressor genes. In a few spontaneous leukaemias or lymphomas, more than one mutation has now been identified, and the experimental analysis of oncogene co-operation is advancing rapidly via retroviral gene delivery and characterization of transgenic mice bearing oncogenes. In transgenic models, tumorigenesis can be accelerated by introducing another oncogene or by using a retrovirus as an insertional mutagen to identify cellular genes that collaborate with the transgene. Leukaemogenesis can be promoted by some ten pairs of oncogenes. The myc nuclear oncoprotein, for example, can collaborate with cytoplasmic oncoproteins such as ras, raf, bcl-2, pim-1 and v-abl, as well as with nuclear products such as bmi-1 or the tumour suppressor p53. The genes in such partnerships seem to provide complementary functions. For example, myc seems to prevent cells from becoming quiescent, whereas bcl-2 blocks programmed cell death; and others, for example ras, may diminish growth factor requirements. The products of genes that collaborate may lie on separate signal transduction pathways, leading to distinct nuclear targets. Key targets are postulated to be regulators of the cell cycle, especially the cyclins and associated kinases that govern progression in the G1 phase.
 ...
PMID:Oncogene co-operation in leukaemogenesis. 145 Nov 8

Li-Fraumeni syndrome is a rare autosomal dominant susceptibility to a variety of cancers including carcinomas of the breast and the adrenal cortex, tumors of brain and muscle tissue, and leukemias. Affected individuals develop cancer at a young age and often at multiple primary sites. A study has been conducted into the genetic basis of cancer in a particular Li-Fraumeni syndrome family. Examination of p53 as a candidate susceptibility gene revealed that, in two affected individuals, there was an aberrant larger transcript of 3.6 kilobases present in both tumor and constitutional material in addition to the normal-sized 2.8-kilobase transcript. The additional transcript was not found in three unaffected family members. S1 nuclease mapping localized the insertion toward the 5' end of the p53 transcript near exons 4 and 5, and sequencing revealed a point mutation in the splice donor site of intron 4 in the germ-line of the two affected individuals, which accounted for the presence of the larger transcript. The same splicing mutation was also detected in two obligate carriers and was not found in two unaffected individuals. As no mutations were detected in exons 5-8 in either tumor examined, the second p53 allele was most likely lost during tumorigenesis in both tumors. The demonstration of a germ-line splicing mutation in affected individuals from a Li-Fraumeni syndrome family provides for a novel mechanism of p53 inactivation not seen previously in other affected families, in whom the mutations have all been missense.(ABSTRACT TRUNCATED AT 250 WORDS)
 ...
PMID:Germ-line splicing mutation of the p53 gene in a cancer-prone family. 146 11

We examined 100 breast cancers for retinoblastoma (Rb) and p53 protein expression by immunohistochemistry using the PMG3.245 and PAb 1801 antibodies. We assessed percentages of reactive cells and their intensity, as well as staining patterns. The results were correlated with neu protein reactivity and a panel of variables, including age, tumor size and type, nuclear grade, estrogen receptor/progesterone receptor content, and lymph node status. Retinoblastoma protein negativity, either partial or complete, was noted in 47% of cases. Surprisingly, a relatively stronger Rb reaction was seen in some high nuclear grade tumors. p53 positivity was found in 23% of cases and was a significant predictor of Rb loss. p53 also was correlated with poorly differentiated (nuclear grade III) neoplasms and neu expression but not with negative ER status. Tissue distribution profiles for Rb-negative and p53-positive cells were variable in this series, with both uniform and heterogeneous patterns observed. This suggests that Rb and p53 alterations may represent early or late events in transformation. Our findings further implicate Rb and p53 derangements in mammary oncogenesis.
 ...
PMID:Retinoblastoma and p53 gene product expression in breast carcinoma: immunohistochemical analysis and clinicopathologic correlation. 146 76

The putative tumor suppressor gene p53 plays a key role in the regulation of cell proliferation. Functional loss of p53 protein through mutation or viral oncogene-complexing can result in p53 protein overexpression detectable by immunocytochemistry, which in turn has been associated with markers of poor prognosis in some cancers. We report here an analysis of p53 overexpression in fixed, embedded specimens from 81 prospectively collected head and neck tumors, both benign and malignant, including 55 squamous cell carcinomas, using monoclonal pAb1801. Sixty-two percent of the squamous cell carcinomas from the head and neck region overexpressed p53, whereas none of the benign tumors or adjacent normal tissues overexpressed p53. Overexpression of p53 was strongly associated (p < 0.01, two-tailed chi-square) with a histologic malignancy grading scale previously shown to have prognostic capabilities. We conclude that p53 overexpression is one of the most common abnormalities identified in head and neck cancer, and may be a useful marker in the study of multistep progression of tumorigenesis.
 ...
PMID:Overexpression of p53 in head and neck cancer. 146 14

Tumorigenesis is thought to be a multistep process in which genetic alterations accumulate to bring about the neoplastic phenotype. Colorectal tumors appear to arise as a result of the mutational activation of oncogenes coupled with the inactivation of several tumor suppressor genes. We have found frequent allelic deletions of specific portions of chromosomes 5, 17, and 18 which presumably harbor suppressor genes. The target of allelic loss events on chromosome 17 has been shown to be the p53 gene, which is frequently mutated not only in colon cancer but in several other tumor types as well. Candidate suppressor genes have also recently been identified on chromosomes 18 and 5. The DCC gene on chromosome 18q encodes a protein with significant sequence similarity to neural cell adhesion molecules and other related cell surface glycoproteins. Alterations of this gene may interfere with normal cell growth and differentiation by disrupting cell-cell or cell-substrate interactions. Two genes (MCC and APC) on chromosome 5q have also recently been identified and partially cloned. These genes are located in a region tightly linked to familial adenomatous polyposis (FAP). While MCC mutations have been found only in sporadic colon tumors, APC mutations have been identified in sporadic tumors as well as the germline of patients with FAP. Studies are currently in progress to increase our understanding of how alterations of these genes affect colorectal tumor cell growth.
 ...
PMID:Suppressor gene alterations in the colorectal adenoma-carcinoma sequence. 146 93

To study the oncogenesis of human esophageal carcinoma, the presence of DNA sequences homologous to several DNA tumor viruses and the expression of oncogenes and growth factor genes were examined in two esophageal carcinoma cell lines of Chinese origin, CE48T/VGH and CE81T/VGH. Southern blot analyses failed to detect sequences homologous to hepatitis B virus (HBV), Epstein-Barr virus (EBV), herpes simplex virus type 2 (HSV-2), cytomegalovirus (CMV) or human papilloma virus (HPV) genomes. Northern blot analyses revealed that c-myc, c-src, c-H-ras, c-abl, c-sis, and p53 genes were expressed. In addition, transcripts of transforming growth factor alpha (TGF alpha), TGF beta, and platelet derived growth factor A (PDGF A) genes were detected. These studies suggest that DNA tumor viruses may not be involved in the carcinogenesis of esophageal carcinoma. However, cooperation among different oncogenes and the production of growth factors may play an important role in that carcinogenesis.
 ...
PMID:Absence of genomes of DNA tumor viruses and expression of oncogenes and growth factors in two esophageal carcinoma cell lines of Chinese origin. 147 73

A polymerase chain reaction (PCR)-mediated RNase protection analysis was performed to detect subtle genetic alterations of p53 in medullary thyroid carcinoma (MTC) and pheochromocytoma. None of the 30 pheochromocytomas showed abnormal RNase protection patterns. Only one of 32 MTCs showed an abnormal pattern, and subsequent DNA sequencing of the PCR product revealed that it had a G to C transversion in codon 49 that resulted in a change from aspartic acid to histidine. However, this was a sporadic MTC with no specific clinicopathological characteristics. On the basis of a previous report that genes on chromosome 17p were not deleted in MTCs and were relatively infrequently deleted in pheochromocytomas, our results suggest that the p53 gene is not involved in tumorigenesis of MTC or pheochromocytoma.
 ...
PMID:Inactivation of the p53 gene is not required for tumorigenesis of medullary thyroid carcinoma or pheochromocytoma. 148 23

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.
 ...
PMID:Role of proto-oncogene activation in carcinogenesis. 148 40


<< Previous 1 2 3 4 5 6 7 8 9 10 Next >>