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)

By weighting the PCR reaction in favor of specificity for the target sequence in the beginning cycles and for continued efficient amplification of the sequence into later cycles, we were able to show an improvement in the specificity and quantity of amplified ras and p53 sequences. Increased purity and yield of specific products favorably enhanced post-PCR evaluation and interpretation of results using direct sequencing and single-stranded conformation polymorphism (SSCP) analysis when point mutations were present in DNA from tumor cell lines and tissues.
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PMID:PCR regimen for enhanced specificity and yield of targeted genomic DNA sequences: ras and p53. 149 Jan 75

The discovery of cancer-causing genes has provided us with the exciting opportunity to begin to understand the molecular pathology of ovarian cancer. Activation of several of these genes including HER-2/neu, myc, ras, and p53 has been described in some ovarian cancers (Table 2). In addition, some proto-oncogenes such as the EGF receptor (erbB) and the M-CSF receptor (fms) are expressed along with their respective ligands in some ovarian cancers. Finally, for every oncogene that has been studied in ovarian cancer, there are at least a half-dozen that remain unexplored. In the future, when we have a better understanding of the molecular pathology involved in the development of ovarian cancer, this may allow us to better diagnose and treat, and eventually prevent, ovarian cancer.
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PMID:Oncogenes in ovarian cancer. 150 Mar 87

The cellular p53 protein is so called because of its molecular weight as determined by SDS-polyacrylamide gel electrophoresis. It was originally classified as a nuclear oncogene product when it was shown by DNA transfection experiments that p53 is able to extend the lifespan of primary rodent cell cultures and to cooperate with an activated ras oncogene to achieve complete transformation of primary cells. However, there is now conclusive evidence that loss of normal p53 expression may be an important step in cell transformation and tumorigenesis. Furthermore, it has been shown that mutant p53 was used for the experiments demonstrating the immortalizing and transforming capacity of p53. Wild-type p53 seems to negatively regulate cell growth and division. So far, the basic function of p53 is not known. Biochemical variability seems to be a key feature of p53 and an understanding of biochemical variations in the p53 protein may contribute to an understanding of how p53 is regulated or how p53 may regulate cell proliferation. Thus, the present review will focus on the biochemical properties of p53.
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PMID:Biochemical properties of the growth suppressor/oncoprotein p53. 150 81

The molecular genetics of colorectal carcinoma are among the best understood of any common human cancer. Reported molecular genetic abnormalities involve tumor-suppressor genes that undergo inactivation (e.g., apc, mcc, dcc, p53, and possibly genes on chromosomes 8p, 1p, and 22q) and dominant-acting oncogenes (e.g., ras, src, and myc). Multiple clonal genetic abnormalities accumulate during the development of colorectal carcinoma in adenomas. Altered DNA methylation is an early event, and the specific genetic alterations occur in a preferential order. However, the clinical application of molecular genetics in patients who are at risk for or have colorectal carcinoma is in its infancy. Patients with a predisposition to colorectal carcinoma caused by inheritance of familial adenomatous polyposis can be identified by genetic analysis of the apc gene on chromosome 5q21. In patients who undergo curative resection of colorectal cancer, deletion of the p53 gene on chromosome 17p, deletion of the dcc gene on 18q, and high fractional allelic loss (fraction of nonacrocentric autosomal arms with deletion) in the primary tumor appear to indicate an increased likelihood of occult disseminated disease and thus a poor prognosis. Additional studies are needed to establish the role of the molecular genetics of colorectal carcinoma in the management of patients who are at risk for or already have neoplasia of the large bowel.
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PMID:Molecular genetics of colorectal carcinoma. 151 69

Increasing numbers of alterations have been found in protooncogenes (e.g., ras, myc), as well as tumor suppressor genes (e.g., p53, Rb) in various types of tumors. The multiple mutations cannot be explained by the spontaneous mutation rate. It has been suggested that mutator phenotypes leading to the accumulation of these mutations may be required in the early stages of tumorigenesis. To test this hypothesis, the entire coding region of DNA polymerase beta, a repair enzyme, mRNA from colorectal tumors, and corresponding normal mucosa were amplified by polymerase chain reaction, cloned, and sequenced. Mutations in the catalytic domain of DNA polymerase beta were detected in colorectal tumor specimens compared to the normal colorectal mucosa, placenta, and blood samples. Since these mutations changed the structure of polymerase beta, it is expected that the efficiency of the DNA repair system would be impaired and thus may account for the high mutation rate observed in colorectal carcinomas.
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PMID:DNA polymerase beta mutations in human colorectal cancer. 151 47

Tumorigenesis is thought to be a multistep process in which genetic alterations accumulate, ultimately producing the neoplastic phenotype. A model was proposed to explain the genetic basis of colorectal neoplasia that included several salient features. First, colorectal tumors appear to occur as a result of the mutational activation of oncogenes coupled with the inactivation of tumor-suppressor genes. Second, mutations in at least four or five genes are required to produce a malignant tumor. Third, although the genetic alterations often occur in a preferred sequence, the total accumulation of changes, rather than their chronologic order of appearance, is responsible for determining the tumor's biologic properties. Several different genetic alterations were identified that occur during colorectal tumorigenesis. Activational mutation of the ras oncogene was found in approximately 50% of colonic carcinomas and in a similar percentage of intermediate-stage and late-stage adenomas. Allelic deletions were discovered of specific portions of chromosomes 5, 17, and 18, which presumably harbor tumor-suppressor genes. The target of allelic loss events on chromosome 17 has been shown to be the p53 gene, which is mutated, not only in colonic cancer, but also in a large percentage of other human solid tumors. The gene dcc recently was identified; this candidate tumor-suppressor gene on chromosome 18 appears to be altered in colorectal carcinomas. The protein encoded by the dcc gene has significant sequence similarity to neural cell adhesion molecules and other related cell-surface glycoproteins. By mediating cell-cell and cell-substrate interactions, this class of molecules may have important functions in mediating cell growth and differentiation. Alterations of the dcc gene may interfere with maintenance of these controls and thus may play a role in the pathogenesis of colorectal neoplasia. Another candidate tumor-suppressor gene also was identified on chromosome 5, mcc (for mutated in colorectal cancers). The mcc genetic alterations include one tumor with somatic rearrangement of one mcc allele and several tumors with somatically acquired point mutations in the coding region. Studies currently are ongoing to (1) identify additional tumor-suppressor gene candidates, (2) increase our understanding of normal tumor-suppressor gene function, and (3) demonstrate the functional tumor-suppressor ability of these genes both in vivo and in vitro.
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PMID:Genetic alterations in the adenoma--carcinoma sequence. 151 27

Several genetic alterations that perturb normal cellular growth control mechanisms can cause cancers. These include point mutations, deletions, translocations, amplifications and gene rearrangements and occur primarily in two classes of interacting genes, oncogenes and tumor suppressor genes. While mutation or amplification of certain oncogenes can facilitate cell growth and tumor formation (Bishop, 1983, 1991; Hunter, 1991; Land, et al., 1983), loss or mutation of tumor suppressor genes, which normally inhibit these processes, can promote tumor formation (Knudson, 1985; Cavenee, et al., 1989; Marshall, 1991). Human skin tumors display multiple genetic alterations such as Ha-ras gene mutation and LOH, N-ras gene amplification, and mutations in p53 tumor suppressor gene. In most cases, the mutations in ras and p53 genes are localized to pyrimidine-rich sequences, particularly C-C sequences, which indicates that these sites are probably the targets for UV-induced DNA damage and subsequent mutation and transformation. Since UV radiation in sunlight is an environmental carcinogen it is important to understand the molecular mechanisms by which UV radiation induces human skin cancers. In addition, suitable animals models are available for comparative studies and risk assessment. By comparing the various genetic alterations detected in sunlight-induced human skin tumors with those present in UV-induced murine skin tumors, it may be possible to identify the carcinogen-related events that are involved in the multi-step process of carcinogenesis. Studies addressing these issues should provide further insights into the molecular mechanisms of UV carcinogenesis.
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PMID:Molecular alterations in human skin tumors. 152 30

The molecular genetic alterations in colorectal carcinoma are among the best understood of any common human cancer. Identified abnormalities include both dominant-acting oncogenes (ras, myc, src) and suppressor genes which undergo inactivation or deletion (deleted in colorectal carcinoma gene [DCC], p53, adenomatous polyposis coli gene [APC], and probably loci on chromosomes 1p and 22q). Accumulation of multiple abnormalities is evident in the adenoma-carcinoma sequence with a preferential order, and alteration of DNA methylation is an especially early event. Identification of molecular genetic markers useful for classification and staging of colorectal carcinoma is in its infancy. Deletion of the p53 gene on chromosome 17p, deletion of the DCC gene on 18q, and high fractional allelic loss (fraction of evaluable nonacrocentric autosomal arms with deletion) have been associated with distant metastases and with poorer prognosis in patients without initial evidence of disseminated disease. Additional studies are needed to determine the possible role of these alterations in clinical management.
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PMID:Molecular genetic alterations as potential prognostic indicators in colorectal carcinoma. 154 Sep

Twenty-five mouse lung tumors induced by a single urethan treatment in female A/J, BALB/c, and (A/J x C3H/He)F1 (AC3) mice were analyzed for the presence of mutations at codon 61 of the Ki-ras gene and for the expression of the surfactant protein A (SP-A), retinoblastoma (Rb), growth arrest-specific-3 (gas-3), p53, c-myc, and thymidylate synthase (TS) genes. Ki-ras codon 61 mutations were detected in 22 of 25 tumor samples without differences among strains. In comparison with normal lungs, all the tumors showed increased SP-A mRNA levels, indicating their derivation from alveolar type II pneumocytes or Clara cells. Rb and gas-3 transcripts were instead found in all tumors at about tenfold and about 20-fold reduced levels, respectively. No apparent structural alterations or loss of heterozygosity at the Rb locus was detected in any tumors. The p53 mRNA was observed without variation in quantity or size in lung tumors and normal tissue. A threefold to fivefold c-myc overexpression was observed, without amplification of the gene. TS expression was only slightly increased, indicating no great differences in cell proliferation between lung tumors and normal tissue. Our data suggest that the pathogenesis of urethan-induced lung tumors in mice involves specific and recurrent molecular alterations (Ki-ras mutations, decrease of Rb and gas-3 expression, and increase of c-myc expression) that could represent different steps in lung carcinogenesis.
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PMID:Multiple molecular alterations in mouse lung tumors. 155 14

Recent studies have provided the first clues as to the molecular mechanisms responsible for bladder carcinogenesis. Cytogenetic and molecular studies have demonstrated nonrandom changes of chromosomes 1, 5, 7, 9, 11, and 17. The finding of monosomy of chromosome 9 in early noninvasive lesions has initiated a search for a bladder-specific gene responsible for bladder oncogenesis. Activation of ras and erbB oncogenes has been reported, although the role that these changes play in bladder cancer is not yet understood. Inactivation of two well-characterized tumor suppressor genes, p53 and Rb, also appears to be important in the pathogenesis of bladder cancer, and evidence suggests that inactivation of p53 correlates with the acquisition by bladder cancer cells of the invasive phenotype. Although the picture is far from complete, it is clear that for the first time an understanding of the molecular events responsible for bladder cancer is possible, and that this information will have clinical impact on patients in the near future.
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PMID:Molecular biology of bladder cancer. 155 51


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