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)

Inactivating mutations of the retinoblastoma gene (RB) are found in a wide variety of tumour cells. Replacement of wild-type RB can suppress the tumorigenicity of some of these cells, suggesting that the RB protein (Rb) may negatively regulate cell growth. As activation of c-myc expression promotes cell proliferation and blocks differentiation, it may positively regulate cell growth. The c-myc protein is localized in the nucleus and can physically associate with RB protein in vitro, hence c-myc may functionally antagonize RB function. Microinjection of Rb in G1 phase reversibly arrests cell-cycle progression. Here we co-inject RB protein with c-myc, EJ-ras, c-fos or c-jun protein. Co-injection of c-myc, but not EJ-ras, c-fos or c-jun, inhibits the ability of Rb to arrest the cell cycle. The c-myc does not inhibit the activity of another tumour supressor, p53 (ref. 12). Thus, c-myc and RB specifically antagonize one another in the cell.
 ...
PMID:Abrogation by c-myc of G1 phase arrest induced by RB protein but not by p53. 143 95

In human lung cancers, alterations of both a dominant oncogene (ras) and a tumor suppressor gene (p53) have been identified. Polymerase chain reaction (PCR) analysis of mRNA was used to amplify the c-Ki-ras-2 and p53 genes from Syrian golden hamsters. The PCR products were confirmed by predicted-size analysis, probing with nonradioactive (biotin-labeled) oligonucleotides, and direct sequencing. Lung tumors were produced in hamsters by repeated injections of 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK). Of six tumors examined, three (50%) had mutations in codon 12 of Ki-ras. Examination of the conserved regions of p53 revealed no mutations. We conclude that NNK-induced carcinogenesis in the hamster results in characteristic alterations of Ki-ras but may not necessarily involve the p53 gene.
 ...
PMID:Mutational analysis of a dominant oncogene (c-Ki-ras-2) and a tumor suppressor gene (p53) in hamster lung tumorigenesis. 144 20

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

The frequencies of mutations in the p53 tumor-suppressor gene and ras proto-oncogenes were investigated systematically in surgically resected oral squamous-cell carcinomas (SCCs) using single-strand conformation polymorphism (SSCP) and/or dot-blot hybridization analysis of DNA fragments which had been amplified by the polymerase chain reaction (PCR). p53 gene mutations, within the region of exons 5 to 8, were detected in 17 out of 27 (63%) tumor specimens. The role of p53 mutations in cell-line establishment was investigated. p53 gene mutations were detected in 5 out of 6 tissue samples from which cell lines were established and in 4 out of 5 specimens from which cell lines could not be established, suggesting that the presence of p53 gene mutations is not by itself sufficient for cell-line establishment. Tumor samples were also analyzed for point mutational activation of the ras proto-oncogenes. One out of 30 (3%) tumors showed an activating point mutation in codon 12 of H-ras, this being consistent with reports from Europe and USA but not with any from India. Compared to frequencies of the other genetic changes so far reported for oral SCC, the p53 mutations have been observed most often to undergo genetic change. p53 gene mutation is thus intimately involved in the genesis of oral SCC and consequently should be useful as a marker for the diagnosis of this neoplasm.
 ...
PMID:The p53 tumor-suppressor gene and ras oncogene mutations in oral squamous-cell carcinoma. 145 26

There are many reports of cell lines being established from human oral squamous-cell carcinomas but apparently none of cell lines from dysplastic or "pre-malignant" oral mucosa. We describe here the isolation and characterization of a cell line, DOK (dysplastic oral keratinocyte), from a piece of dorsal tongue showing epithelial dysplasia. The tissue was obtained from a 57-year-old man who was a heavy smoker prior to the appearance of a white patch on his tongue. Eleven years later a squamous-cell carcinoma developed at the site and was excised. Subsequently the remaining dysplasia was removed, and it was from a piece of this that the primary cell cultures which eventually gave rise to DOK were initiated. The DOK line has been single-cell cloned and is apparently immortal. It grows in the absence of 3T3 feeder cells, is anchorage-dependent for growth and is non-tumorigenic in nude mice. The keratin profile of the cells shows a striking similarity to that of the original tongue dysplasia. The karyotype of DOK is aneuploid and complex. By PCR and oligonucleotide hybridization on dot blots, codons 12, 13 and 61 of Ha-ras, Ki-ras and N-ras in DNA extracted from DOK cells were shown to be normal. Immunohistochemistry showed no abnormal, i.e., elevated expression of the onco-suppressor protein p53. Because of its origin and partially transformed phenotype, DOK presents an opportunity to study whether specific carcinogens associated with tobacco and areca nut can cause malignant transformation of oral keratinocytes in vitro.
 ...
PMID:DOK, a cell line established from human dysplastic oral mucosa, shows a partially transformed non-malignant phenotype. 145 32

In cells transformed by mutant mouse p53 plus ras, the former protein is found to be complexed with the heat-shock protein cognate hsc70. To determine whether hsc70 can directly affect neoplastic transformation, nonestablished rat embryo fibroblasts (REF) were transfected with rat genomic hsc70 DNA in conjunction with various oncogenes. We report here that the hsc70 gene could efficiently suppress focus induction by mutant p53 plus ras, as well as by myc plus ras. No inhibitory effect of hsc70 was detectable in assays monitoring the ability of REF to be immortalized by mutant p53, arguing against a nonspecific deleterious effect of the hsc70 genomic clone on REF survival and proliferation. Lines generated in the presence of the hsc70 plasmid produced augmented levels of hsc70. Plasmids encoding only short NH2-terminal fragments of hsc70 could also, in some cases, partially reduce oncogene-mediated focus formation. However, a maximal inhibitory effect required the production of a functional hsc70 protein. The data presented here raise the possibility that hsc70 may be directly involved in the modulation of oncogene-mediated transformation.
 ...
PMID:The gene for the rat heat-shock cognate, hsc70, can suppress oncogene-mediated transformation. 146 7

Multistage carcinogenesis involves genotoxic as well as non-genotoxic mechanisms. The importance of genotoxic events in human carcinogenesis is apparent from the analysis of tumours: for example, five to six genetic alterations can be found in most malignant colorectal tumours. While such measurable "footprints" (e.g. ras, p53 mutations) can be left in tumours by genotoxic events, non-genotoxic events cannot directly generate them. Thus, the lack of specific indicators of non-genotoxic events in carcinogenesis makes the identification of non-genotoxic carcinogens difficult. It is also important to emphasize that apparent "genotoxic" endpoints (mutations, chromosome aberrations) could be induced by "non-genotoxic" agents through indirect mechanisms (e.g. induced cell proliferation and/or genomic instability, oxidative damage, deamination of 5-methyl cytosine). This emphasizes the need for differentiating "events" from the actual "activities" of chemicals and the difficulty of classification of carcinogens into genotoxic and non-genotoxic. One of the best models for the study of interaction of genotoxic and non-genotoxic mechanisms during carcinogenesis is a two-stage carcinogenesis system using mouse skin, rat liver or cultured cells. Molecular analysis of tumours produced on mouse skin by the classical initiation-promotion protocol indicates that the mutation spectra of oncogenes, e.g. Ha-ras, are determined by initiating (genotoxic) and not by promoting (non-genotoxic) agents. However, since usually no tumours appear without the application of tumour-promoting agents, the manifestation of genotoxic events (Ha-ras mutation) is dependent on the action of non-genotoxic agents. Using a BALB c 3T3 two-stage cell transformation system, we have now succeeded in confirming this and have quantitated the initiation and promotion events. These studies may help us not only in understanding mechanisms of carcinogenesis but also in developing molecular quantitative risk assessment in terms of multistage carcinogenesis.
 ...
PMID:Interaction and distinction of genotoxic and non-genotoxic events in carcinogenesis. 147 Dec 13

Cesium-137 gamma rays were used to transform rat embryo cells (REC) which were first transfected with activated c-myc or c-Ha-ras oncogenes to produce immortal cell lines (REC:myc and REC:ras). When exposed to 6 Gy of 137Cs gamma rays, some cells became morphologically transformed with focus formation frequencies of approximately 3 x 10(-4) for REC:myc and approximately 1 x 10(-4) for REC:ras, respectively. Cells isolated from foci of gamma-ray-transformed REC:myc (REC:myc:gamma) formed anchorage-independent colonies and were tumorigenic in nude mice, but foci from gamma-ray-transformed REC:ras (REC:ras:gamma) did not exhibit either of these criteria of transformation. Similar to the results with gamma irradiation, we observed a sequence-dependent phenomenon when myc and ras were transfected into REC, one at a time. REC immortalized by ras transfection were not converted to a tumorigenic phenotype by secondary transfection with myc, but REC transfected with myc were very susceptible to transformation by subsequent ras transfection. This suggests that myc-immortalized cells are more permissive to transformation via secondary treatments. In sequentially transfected REC, myc expression was high whether it was transfected first or second, whereas ras expression was highest when the ras gene was transfected secondarily into myc-containing REC. Molecular analysis of REC:ras:gamma transformants showed no alterations in structure of the transfected ras or of the endogenous ras, myc, p53, or fos genes. The expression of ras and p53 was increased in some isolates of REC:ras:gamma, but myc and fos expression were not affected. Similarly, REC:myc:gamma transformants did not demonstrate rearrangement or amplification of the transfected or the endogenous myc genes, or of the potentially cooperating Ha-, Ki-, or N-ras genes. Northern hybridization analysis revealed increased expression of N-ras in two isolates, REC:myc:gamma 33 and gamma 41, but no alterations in the expression of myc, raf, Ha-ras, or Ki-ras genes in any REC:myc transformant. DNA from several transformed REC:myc:gamma cell lines induced focus formation in recipient C3H 10T1/2 and NIH 3T3 cells. The NIH 3T3 foci tested positive when hybridized to a probe for rat repetitive DNA. A detailed analysis of the NIH 3T3 transformants generated from REC:myc:gamma 33 and gamma 41 DNA failed to detect Ha-ras, Ki-ras, raf, neu, trk, abl, fms, or src oncogenes of rat origin.(ABSTRACT TRUNCATED AT 400 WORDS)
 ...
PMID:Rat embryo cells immortalized with transfected oncogenes are transformed by gamma irradiation. 147 53

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

Molecular epidemiology is increasingly being applied in studies of cancer risks derived from exposure to environmental carcinogens of both endogenous and exogenous origins. Analytical methods have been developed that are capable of detecting and quantifying levels of covalent adducts of several important classes of carcinogens with cellular DNA and blood proteins. Methods of sufficient sensitivity and specificity to detect ambient levels of exposure are in current use. These are being used in studies related to tobacco use (polycyclic aromatic hydrocarbons, aromatic amines, tobacco-specific nitrosamines); dietary exposures (aflatoxins, N-nitrosamines, heterocyclic amines); medicinal exposures (cisplatin, alkylating agents, 8-methoxypsoralen, ultraviolet photoproducts); occupational exposures (aromatic amines, polycyclic aromatic hydrocarbons, oxides of ethylene and styrene, and vinyl chloride); and oxidative damage (8-hydroxyguanine, thymine glycol). Methodologic improvements together with their expanded use in feasibility studies continue to produce results that support the validity of this approach for detecting and quantifying exposure to carcinogens. Genetic markers are also being used to detect early biological responses in efforts to link carcinogen exposure to initiating events in the carcinogenesis process. These include, in addition to traditional cytogenetic markers (e.g., chromosomal aberrations, sister chromatid exchange, micronuclei), other alterations in chromosomal structure such as restriction fragment length polymorphisms, loss of heterozygosity, and translocation markers. Specific genetic changes have recently been identified as critical molecular events in the initiation and development of many cancers. Important among these are activation of oncogenes, especially those of the ras family, and inactivation of tumor-suppressor genes (e.g., p53 and Rb) by point mutations and/or chromosomal deletions and other structural changes. Although some of these changes are known to occur in chemically induced tumors of experimental animals, the possible role of chemical carcinogens in the induction of genetic abnormalities in human cancers has yet to be determined. Continuing investigations employing the methods of molecular epidemiology promise to provide further evidence concerning these relationships. Future investigations employing newly developed molecular biological methods, in particular those based on polymerase chain reaction amplification of DNA, to identify alterations in DNA and chromosomal structure, combined with methods for characterizing exposure to carcinogens and early effects, have great potential for further elucidating the role of genotoxic agents in the etiology of human cancers and also for the development of strategies for their prevention.
 ...
PMID:Molecular epidemiology in cancer risk assessment and prevention: recent progress and avenues for future research. 148 46


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