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)

Retinoblastoma (RB) and the familial adenomatous polyposis/colorectal cancer (FAP/CRC) complex provide well-characterised examples of multistage carcinogenesis and inheritance of a predisposition to cancer. Retinoblastoma appears to conform to the simple two-step model first proposed by Knudson. The gene responsible for RB, now called Rb1, has been located in chromosome region 13q14. The Rb1 gene has been cloned and subjected to extensive analysis. It is probable that the Rb1 gene product has a role in the regulation of transcription. The familial form of RB occurs as the result of a germline mutation of one of the copies of the Rb1 gene. Colorectal cancer, in contrast, appears to be the result of four or five steps involving both activation of oncogenes and inactivation of antioncogenes. The FAP gene has been located in chromosome region 5q21 by genetic linkage, and a candidate gene, MCC (mutated in colon cancer), has been cloned. Other mutations in previously-identified genes that have been identified as important in the genesis of CRC include the activation of p53 and of Ki-ras. A gene lying in chromosome region 18q which is deleted in colorectal cancer, and hence named DCC has been cloned. Its protein product has sequence homology to neural cell adhesion molecules and other related cell-surface glycoproteins. Delineation of the genes involved in the development of tumours such as RB and CRC provides insight into the mechanisms by which sequential mutations result in carcinogenesis.
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PMID:Multistage carcinogenesis in paediatric and adult cancers. 131 30

The gene for familial adenomatous polyposis coli (APC or FAP), which has previously been linked to chromosome 5q21 has been identified. The APC gene has been found to be altered by point mutations in the germ line of both adenomatous polyposis coli and Gardner's syndrome patients and somatically in tumors from sporadic colorectal cancer patients. During the hunt for the APC gene, the closely linked MCC (mutated in colorectal cancer) gene was identified and found to be altered somatically in tumors from sporadic cancer patients. These data suggest that more than one gene on chromosome 5q21 may contribute to colorectal carcinogenesis and that mutations at the APC gene can cause both adenomatous polyposis coli and Gardner's syndrome. The identification of these genes should aid in the counseling of patients with genetic predispositions to colorectal cancer. Progress has also been made in identifying specific genetic changes that occur in other gastrointestinal cancers. A mutational "hotspot" in the p53 gene in human hepatocellular carcinomas has been identified that could reflect exposure to a specific carcinogen, one candidate being aflatoxin B1.
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PMID:Cell and molecular biology of gastrointestinal tract cancer. 132 39

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

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.
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PMID:Loss of heterozygosity involves multiple tumor suppressor genes in human esophageal cancers. 142 99

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.
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PMID:Suppressor gene alterations in the colorectal adenoma-carcinoma sequence. 146 93

The ability to efficiently detect DNA polymorphisms is essential for the completion of a high-resolution polymorphic linkage map of the human genome. Currently the most informative polymorphisms are the multiallelic dinucleotide repeat polymorphisms. However, many gene sequences lack an associated dinucleotide repeat sequence. We used GC-clamped denaturing gradient gel electrophoresis to screen for DNA polymorphisms in the following six gene sequences: MCC, p53, prealbumin (transthyretin), rhodopsin, S-antigen, and TGF-alpha. A single-base sequence polymorphism was identified in each of these gene sequences. Some of these polymorphisms were multiallelic and highly informative. Our results demonstrate the value of denaturing gradient gel electrophoresis for both identifying and analyzing human DNA polymorphisms. The ability to detect highly informative polymorphisms within gene sequences will greatly contribute to a gene-based polymorphic linkage map.
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PMID:Detection of multiallele polymorphisms within gene sequences by GC-clamped denaturing gradient gel electrophoresis. 153 94

Colorectal cancer affect the 15% of general population in developed countries. Cancer is a multistep process in which multiple genetic alterations must usually occur in several years. The premalignant step consists of one or multiple aberrant crypts due to hyperproliferation of cells and its shift from the deep third of the crypt to its surface. It has been suggested that abnormality in the APC gene is responsible for this. Furthermore, there exists DNA hypometilation, activation of the gene K-ras and ornithine decarboxylase activity. There is also a loss of MCC gene, that seems to interact with the APC gene. Entire alterations described make possible the Class I adenoma formation. This adenoma, needs the loss of the DCC gene (late stage in the carcinogenesis process), to become a Class II adenoma. The following alteration is deleted and mutation of the p53 gene. There is also an activation of the c-myc oncogene. These two genes are important mechanisms for the conversion of a benign adenoma to a malignant one, adenoma with in situ carcinoma or Class III adenoma. This type of adenoma becomes carcinoma and metastatic stage, throughout inactivation of several tumor suppressor genes. Besides the hereditary APC alteration and other acquired genetic changes as described above there are other associated genetics, antigenics, and enzymes that have an important role in the adenoma-carcinoma sequence. Several carcinogenic factors have been described which also contribute in the adenoma and carcinoma formation: ulcerative colitis, acromegaly, familial history of colonic neoplasia, certain professions, smoking and drinking, consumption of red or processed meat, etc.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:[Etiology of colorectal cancer]. 755 83

The correlation between the mutation spectra of tumor suppressor genes Rb, p53, APC and MCC in human esophageal cancer (EC) and in human and monkey esophageal epithelium treated with N-Methyl-N-Benzyl nitrosamine (NMBzA) was studied using PCR amplification and direct sequencing methods. The results showed that in 40.9% (9/22) of the specimen examined, the mutation spectrum of p53 in primary EC was similar to that in the esophageal epithelium of human fetus (in vitro) and monkey (in vivo) treated with NMBzA. The same mutational spectra of tumor suppressor genes Rb, APC, MCC in esophageal epithelium cells of human and monkey treated with NMBzA were also found in some human primary EC. The correlation observed in the mutation spectra of multiple tumor suppressor genes between human primary EC and the esophageal epithelia of human and monkey origin treated with NMBzA wouldsuggest that NMBzA may be the esophageal etiological agent for human esophageal cancer in China.
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PMID:[Correlation studies on the alterations of multiple tumor suppressor genes in human esophageal cancer and in human and monkey esophageal epithelial cells treated with N-methyl-N-benzyl nitrosamine]. 758 88

Results of epidemiological studies have shown that nitrosamine-induced carcinogensis is involved in esophageal cancer in China. In order to demonstrate the mechanism at molecular level, Multiple tumor suppressor genes Rb, p53, APC and MCC in human fetus esophageal epithelium treated with NMBzA (in vitro) for 24 hours or three weeks and esophageal carcinoma induced by NMBzA were analyzed with PCR amplification and direct sequencing. In PCR amplification analysis. Rb, p53, APC and MCC deletions in esophageal carcinoma of human fetus induced by NMBzA were found, but no deletions of these genes was demonstrated in NMBzA-treated human fetal esophageal epithelium. PCR direct sequencing analysis revealed mutation of p53, Rb and MCC genes in human fetal esophageal epithelium treated with NMBzA for three weeks. The results first confirmed (in vitro) that nitrosamine can cause mutations and deletions of multiple tumor suppressor genes in human esophageal epithelium. The mutations of tumor suppressor genes in nitrosamine-induced esophageal carcinoma may occur in the early stage, while deletions in late stage of carcinogenesis.
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PMID:[Multiple tumor suppressor genes in esophageal carcinoma induced in human fetus esophageal epithelium by NMBzA]. 765 18

Little is known of the molecular changes that occur in germ cell tumors (GCT) of the testis. We studied three GCT cell lines and 44 tumors for loss of heterozygosity (LOH) of the tumor suppressor genes APC, MCC, DCC, RB, TP53, and WT-1. We observed that LOH occurred in 55% (21 of 38) of informative cases at DCC, in 28% (10 of 36) of informative cases at APC, in 23% (6 of 26) at MCC, in 30% (13 of 43) at RB, and in 27% (6 of 22) at WT-1. The LOH level in these tumors using anonymous primers mapping to the short and long arms of chromosome 19, which is cytogenetically normal in GCT, revealed LOH of 11 and 5%, respectively. We also observed a LOH of 22% in the TP53 gene, despite the fact that mutations in TP53 do not occur in testis cancer. Since a high frequency of LOH at DCC (18q21.3) occurs equally at all histological subsets in GCT, we conclude that the loss of the function of this gene is an early event in testicular GCTs. However, the observed LOH levels at APC/MCC (5q21), RB (13q14), and WT-1 (11p13) could represent a functional loss of the corresponding tumor suppressor gene in some GCTs or reflect the loss of sequences in the same general chromosome region but involving a different tumor suppressor locus. Therefore, detailed mapping of these chromosomes is required to define the precise locations of maximal LOH in testis cancer.
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PMID:Loss of heterozygosity of tumor suppressor genes in testis cancer. 779 15


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