UNIPROT:P04637 - FACTA Search

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

Recent advances in understanding the molecular etiology of colorectal carcinoma have made possible a discussion of molecular targets for therapy of the disease. The genes for two inherited predispositions, familial adenomatous polyposis and the Lynch syndrome, have been mapped to specific chromosomal locations. At least five of the genes that are altered in structure or expression to give rise to the tumorigenic phenotype have been isolated by molecular cloning: The K-ras and N-ras protooncogenes have been shown to be altered by point mutation, and expression of the c-myc protooncogene is deregulated. The p53 and DCC genes, both tumor suppressor genes or antioncogenes, are deleted or altered so as to be rendered nonfunctional. Although a single tumor may not suffer all these changes, available evidence indicates that most colorectal tumors contain at least one of these alterations. In addition, work in cell culture and animal systems indicates that tumor cells may be converted to nonmalignant cells by reversing the effects of just one of these changes.
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PMID:Are there molecular targets for therapy of colon cancer? 166 28

Inactivation of tumor suppressor genes is now believed to play an important role in various progression stages of human cancers. To clarify the possible involvement of tumor suppressor gene inactivation in the acquisition of metastatic potential in lung and colorectal carcinoma cells, we examined various genetic alterations in both primary tumors and metastases obtained from patients with lung and colorectal carcinomas. In lung carcinoma, loss of heterozygosity on chromosomes 3p, 13q, and 17p is a common genetic alteration, and both RB and p53 genes are inactivated as a result of chromosome 13q and 17p losses. In some cases, allelic loss on chromosome 11p and amplification of myc family oncogenes occur during tumor progression. In colorectal carcinoma, p53 and DCC alterations were detected in 100% of metastases, and sequential accumulation of allelic losses on chromosomes 13q, 14q, and 18q in the process of metastasis was observed. These results indicate that a subset of tumor suppressor genes is involved in metastasis of lung and colorectal carcinomas.
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PMID:Tumor suppressor genes involved in metastasis of lung and colorectal carcinomas. 184 53

The inherited cancer-inducing disease familial polyposis coli (FPC) provides an excellent model not only for studying tumor progression in colorectal cancer but also for elucidating molecular mechanisms in general oncogenesis. This paper reviewed recent remarkable progresses of molecular mechanisms in colorectal tumorigenesis. This is concerned with the various kinds of genetic alterations that accumulate in the development from normal mucosa to adenoma, and then to adenocarcinoma in comparison with FPC and sporadic cases. This review included also information on the localization of FPC major gene. These observations indicate that in cases of colorectal tumorigenesis several genetic alterations may be involved, including activation of K-ras gene, deregulated expression of c-myc gene or c-fos gene and inactivation of tumor suppressor genes such as p53 and DCC genes, as well as the loss of heterozygosity. The observation suggest that adenomas will have undergone several gene or chromosome mutations before reaching to the fully malignant state. Therefore, DNA diagnosis for colorectal tumors in the clinical level may contribute to more accurate prognosis and better results for further therapy.
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PMID:[Diagnosis of colorectal cancer from DNA level]. 184 82

This report reviewed recent remarkable progresses on the cytomolecular mechanisms in colorectal carcinogenesis. Colorectal carcinoma is a good model for the study of multi-step progression, because we can obtain adenomatous polyps which are considered as a precancerous form. Furthermore, a familial syndrome, which is characterized by numerous adenomas of the colon, is available for linkage analysis. Recently, the p53 and DCC genes have been identified as candidate tumor suppressor genes on chromosome 17p and 18q respectively. In this paper, we present the multiple genetic alterations in colorectal carcinoma, including activation of K-ras gene and inactivation of tumor suppressor gene such as p53 and DCC genes as well as loss of heterozygosity and approach to the gene responsible for adenomatous polyposis coli by reverse genetics.
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PMID:[Cytomolecular aspects of colorectal carcinoma]. 184 88

Two features of colorectal cancer have greatly aided the recent progress in understanding its genetics: firstly the majority of colorectal cancers arise from premalignant adenomatous polyps allowing the analysis of somatic genetic changes during tumorigenesis, and secondly there are several well defined inherited syndromes that predispose to colorectal cancer in an autosomal dominant manner. The familial polyposis gene has been mapped to chromosome 5q and loss of material on chromosome 5 shown in a large proportion of sporadic (non-familial) adenomas and carcinomas. Allele loss has also been found in a high proportion of colorectal cancers on chromosomes 17 and 18 and the respective genes involved identified as that coding for the oncoprotein p53 on 17p and the DCC ('deleted in colorectal carcinomas') gene on 18q. In addition activation of k-ras is found frequently in colorectal adenomas and carcinomas. The development of colorectal neoplasia is associated with the accumulation of genetic changes. Family studies of apparently sporadic colorectal cancer probands have shown an increased incidence of adenomas and carcinomas in first degree relatives. More recently pedigree studies have suggested that an inherited predisposition may be responsible for the majority of colorectal tumours.
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PMID:The genetics of colorectal cancer. 210 25

Remarkable advances in the understanding of specific inherited and acquired genetic events that are important in colonic carcinogenesis have occurred in the last several years. Studies of the population genetics of colon cancer have determined that the gene responsible for familial adenomatous polyposis (FAP), and Gardner's syndrome has been localized on the long arm of chromosome 5 and have more clearly defined the importance of genetic influences in 'sporadic' colon cancer. Studies of the molecular genetics of colon cancer have identified acquired alterations in oncogenes such as the K-ras gene and in putative tumor suppressor genes such as the FAP gene on chromosome 5, the p53 gene on chromosome 17, and the DCC gene on chromosome 18, which appear to mediate important steps in the adenoma-dysplasia-carcinoma sequence. Some of these research advances (FAP gene carriage) are already being used clinically to identify individuals at risk for colon cancer, and they offer great promise for the future of both prevention and therapeutic programs.
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PMID:Lessons from the genetics of colon cancer. 217 30

We present a restriction fragment length polymorphism (RFLP) analysis of 29 benign and 30 malignant prostatic tumors, using polymorphic DNA probes to the putative tumor suppressor genes DCC (Deleted in Colorectal Carcinoma; chromosome 18q21.3), nm23-H1 (17q21.3), APC (Adenomatous Polyposis Coli; 5q21) and p53 (17p13). Six of 23 evaluable cancers (26%) showed loss of heterozygosity (LOH) at DCC; 5 were advanced stage and one was clinically localized (p < 0.05). Mapping 18q deletions, another (advanced) cancer showed LOH at a locus distal to DCC (18q22), but no LOH at DCC. Three of 15 evaluable cancers (20%), all advanced, showed LOH at APC. Three of eight (38%) cancers, of which 2 were advanced, showed LOH at p53. One high grade/stage cancer of 21 (5%) showed LOH at nm23-H1 (and also at DCC). Combining data, allelic losses at either DCC, APC, or p53 genes were seen in 13% of localized cancers, but in 71% of advanced cancers (p < 0.002). Allelic loss involving nm23-H1 is rare in prostatic carcinoma. We suggest that loss of tumor suppressor genes DCC and/or an unidentified gene located distally on chromosome 18q, APC, or p53 may influence progression in prostatic carcinoma.
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PMID:Somatic allelic loss at the DCC, APC, nm23-H1 and p53 tumor suppressor gene loci in human prostatic carcinoma. 751 Mar 45

The complex but poorly understood human male germ cell tumors offer unusual opportunities for the genetic analysis of malignant transformation and embryonal differentiation in a pluripotential stem cell lineage. Histologically, these tumors are divided into two major subgroups, seminomas which are characterized by inability to express embryonal differentiation, and non-seminomas which are characterized by ability to express embryonal as well as extra-embryonal patterns of differentiation. To understand the role of genetic factors in the development of these tumors and the regulation of differentiation expressed by them, we carried out a detailed allelotype analysis by the loss of heterozygosity assay. This analysis revealed frequent deletions in known tumor suppressor genes (RB1, DCC, NME), a number of previously described sites of candidate tumor suppressor genes (3p, 9p, 9q, 10q, 11p, 11q and 17p), as well as several novel sites (2p, 3q, 5p, 12q, 18p and 20p). Our results also showed that well differentiated teratomas exhibit a significantly higher level of allelic loss compared to the less differentiated embryonal carcinomas. In addition, certain loci and genes exhibited frequent non-random deletion in teratomas (D3S32, D3S42, D5S12, D10S25, D11S12, RB1, TP53, NME1, NME2, D17S4, D18S6 and D20S6) and embryonal carcinomas (IFNB, D9S27). Among these loci, the NME genes were notable for a high degree of genetic loss (> 70%) in teratomas. These results suggested that nonrandom loss or inactivation of certain genes may be associated with tumor development and loss or inactivation of other genes may be associated with somatic differentiation.
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PMID:Allelic loss and somatic differentiation in human male germ cell tumors. 751 76

Esophageal cancer is an important problem in the United States. It results in more deaths (over 10,000 annually) than rectal cancer. Furthermore, the incidence of esophageal adenocarcinoma is increasing at a rate faster than that of nearly any other cancer and the reasons for the increase are not well understood. A variety of tumor-suppressor genes (including p53, APC, DCC and Rb) and proto-oncogenes (including prad1, EGFR, c-erb-2 and TGF alpha) may be involved in the development and progression of esophageal cancer. Clinical prognostic factors include stage, Karnofsky performance status, sex, age, anatomic location of the tumor, and degree of weight loss. A new staging system based on depth of wall penetration and lymph node involvement correlates well with prognosis for patients undergoing esophagectomy. Newer staging procedures including endoscopic ultrasound as well as the use of minimally invasive surgery, such as thoracoscopy and laparoscopy, may allow accurate staging without esophagectomy. Surgical resection provides excellent palliation; however, the chance for cure with esophagectomy alone is only 10% to 20%. Adjuvant treatment with pre- or postesophagectomy radiation may improve local-regional control but does not improve survival. Nor has preoperative chemotherapy been shown to improve survival; however, it remains an active area of investigation. Multimodality therapy, namely, chemotherapy and radiation (chemoradiation), given concurrently prior to surgical resection shows promise, with one study indicating a 5-year survival of 34%. A complete pathologic response to chemoradiation correlates with improved survival. Chemoradiation has been shown to be superior to radiation as primary management of esophageal cancer. There has been no successfully completed randomized trial of surgery versus definitive radiation or chemoradiation. However, chemoradiation represents a reasonable alternative to esophagectomy in the primary management of squamous cell carcinoma of the esophagus and chemoradiation also appears to be effective in the treatment of patients with adenocarcinoma of the esophagus, offering significant palliation and a chance for long-term survival as well. Randomized studies of preoperative chemoradiation versus surgery or versus chemoradiation alone are needed. The treatment of advanced esophageal cancer must be directed toward palliation of symptoms. Newer endoscopic techniques, including the use of expansile metal stents, laser ablation, intraluminal high-dose rate brachytherapy, BICAP tumor probe, or photodynamic therapy, offer selected patients short-term palliation.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Esophageal cancer. 753 69

In order to detect regions of DNA containing tumor suppressor genes involved in the development of gastric cancer, we performed an allelotype study on 78 gastric adenocarcinomas from a population composed largely of Texan Hispanics and Anglos, two ethnic groups that have a ratio of incidence rates of gastric cancer of approximately 2:1. In total, 42 microsatellite markers were employed, which detected at least one site per arm of each autosome in the human genome. These included several markers linked to known tumor suppressor genes (TP53, APC, DCC, RB1, and BRCA1). Sites showing quantitative allelic imbalance (AI) greater than 30% were located on 3p (36%), 11q (31%), 12q (38%), 13q (33%), 17p near TP53 (74%), and 17q near BRCAI (32%). Among the 22% of cases showing microsatellite instability (MI), a subset (4 of 17) showed instability at 59% or more of sites tested. No ethnic bias was detected in cases showing MI or in cases with AI at sites with rates of AI above 30%. Tumors of the intestinal subtype were significantly more likely than diffuse tumors to show AI at DI3S170 (P = 0.01). A deletion map of chromosome arm 3p was prepared for tumors with AI at D3S1478. These data indicate that a tumor suppressor gene on chromosome arm 3p is involved in the development of a subset of gastric cancers.
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PMID:Allelic imbalance in gastric cancer: an affected site on chromosome arm 3p. 754 34

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