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:P43146 (tumour suppressor)
5,935 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The p53 tumour suppressor gene is intensively studied because mutations in this gene are the most common genetic alteration so far identified in human cancer. Considerable emphasis has thus been placed on characterizing the biological differences between mutant and wild-type p53 protein. This has led to the realization that in cultured cells, mutant p53 behaves like an oncogene, whereas wild-type p53 is a tumor suppressor gene. The p53 protein is also a target for the tumour virus oncogene products SV40 large T, adenovirus E1B, and human papillomavirus type 16 E6, which are all capable of forming complexes to the p53 protein. Although p53 represents an extremely important cellular regulatory molecule which is well conserved, there exists two allelic variants of wild-type human p53 that differ both in primary and confirmational structure. One variant contains an arginine at amino acid 72 (p53Arg), whereas the other form contains a proline at this residue (p53Pro). The possible implications for more than one allelic variant of wild-type human p53 in the general population is unknown. The present study was undertaken to compare some of the biological features of the different wild-type p53 variants. We present data demonstrating that there was a post-transcriptional selection against accumulation of both variants of wild-type human p53 in 3T3-A31 cells, arguing that both forms are proliferation inhibitory in these cells. Both variants of human p53 were stabilized by SV40 large T, but did not displace mouse p53 from SV40 large T. Neither allelic variant of human p53 was able to reduce significantly SV40-mediated anchorage-independent growth of 3T3-A31 cells.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Molecular analysis of different allelic variants of wild-type human p53. 129 28

Due to the accessibility of the intermediate steps in the progression of colorectal cancer and to the existence of heritable susceptibility to the disease, molecular genetic analysis of colorectal carcinogenesis seems likely to answer many of the questions concerning the fundamental nature of the common human epithelial cancers. Several genetic events appear to be required and, although there is no stringent adherence to any particular sequence of events, the accumulation of genetic defects does show some loose order. Each event must confer growth advantage in order to allow further clonal expansion. Such expansion then makes further events at other crucial loci more likely. Hence, the process proceeds until the tumour is capable of the destructive growth, infiltration and metastasis characteristic of malignancy. This review summarises recent important progress in our understanding of both constitutional and somatic molecular genetic events involved in the development of colorectal cancer. Germline changes responsible for syndromes, such as Familial Adenomatous Polyposis, which result in predisposition to large bowel neoplasia are discussed. The possibility that heritable mutations in tumour suppressor genes might confer susceptibility to apparently sporadic colorectal cancer is proposed.
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PMID:Colorectal cancer genetics. 132 46

In the last ten years considerable progress has been made in small-cell lung carcinoma (SCLC) biology, along with the technical progress made in molecular biology. This progress now allows us to propose a model for the genesis and the development of this type of tumor. Tobacco, the principal causal factor plays a dual role. In bringing about secretion of growth factors by the bronchial epithelia, usually involved in the normal development of lungs, and by functioning autocrinally and paracrinally, it facilitates the occurrence of mitotic mutations. Without directly contributing to cellular transformation, this autocrine functioning also gives a selective advantage to cells going through transformation or immortalization. The procarcinogenic or carcinogenic agents contained in tobacco smoke, whose level of production could be genetically determined, would also contribute to the accumulation of mutations affecting both suppressor genes and oncogenes. Two tumour suppressor genes have been identified: RB1 and P53. At least one other putative tumour suppressor gene has constantly been implied. It lies on the short arm of chromosome 3. There could also be the possibility of detecting subjects susceptible to developing an SCLC, a functional hemizygote still needing evaluation. The activated oncogenes principally belongs to the myc family. Their activation could correspond with the appearance of cellular clones having aggressive behavior independent of growth factors, chemoresistant and more metastatic. SCLC may be distinguished from other malignant lung tumors by a fairly characteristic pattern consisting of the loss of suppressor genes and the activation of oncogenes. The links between the neuroendocrine properties of this type of tumor and its characteristic description are being clarified and will contribute to a better understanding of the relationship between the different types of lung tumors. From this biologic knowledge follow several therapeutic applications under investigation (blocking autocrine loop through anti-GRP antibodies), as well as potential applications (concerning the products of suppressor genes) and possible applications such as prevention oriented towards detection of high-risk subjects.
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PMID:[Biology of small-cell bronchogenic carcinoma: recent advances]. 132 50

Colorectal tumours have proven to be an excellent system in which to identify and study the genetic alterations involved in the development of a common human neoplasm. A prevalent view is that colorectal tumours appear to arise as the result of multiple genetic alterations in the alleles of both oncogenes and tumour suppressor genes. The accumulation of genetic alterations appears to accompany the clinical and biological progression of the tumours and may determine the phenotype of the tumour cells. In addition to the many somatic alterations identified at various stages of colorectal tumour development, recent studies have led to the identification of the adenomatous polyposis coli (APC) gene, which, when mutated in the germline, predisposes to the development of colorectal tumours. On the basis of studies of inherited and somatic mutations in colorectal tumours, a genetic model for colorectal cancer development has been proposed. Although the model is undoubtedly incomplete, it nevertheless provides a useful framework for further studies of the multiple events that underlie human tumour initiation and progression. Numerous questions remain to be answered, including identification of the normal function of the genes implicated in tumorigenesis, how mutations in these genes arise and are selected for and what the relative contribution of the altered genes is to various stages of the neoplastic process. Nevertheless, an optimistic outlook is that fundamental insights into the pathogenesis of human cancer are within our reach.
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PMID:Genetic alterations underlying colorectal tumorigenesis. 163 44

Tumour viruses are thought to contribute to the development of one fifth of all human cancers, although the mechanisms involved are still obscure. Human papilloma virus (HPV) is a DNA virus associated with oral carcinomas. It has been shown that virus DNA has to become integrated into cellular DNA in order to transform normal to malignant cells. Cellular oncogenes and tumour suppressor genes are potential cancer genes. They are involved in the control of growth and differentiation of normal cells. It is known that structural or regulatory changes (activation) of these genes will lead to malignant transformation. Virus integration will sometimes take place in close relation to cellular oncogenes. Such incorporation may result in oncogene activation. Other cellular factors that may contribute to the development of oral squamous cell carcinoma are also discussed.
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PMID:[Can virus cause oral cancers?]. 165 Apr 50

Recent studies have identified a gene on chromosome 5q, designated MCC (mutated in colorectal cancers), as a candidate for the putative colorectal tumor suppressor gene that is located at 5q21. We examined loss of heterozygosity (LOH) at the MCC locus and its vicinity in sporadic colorectal carcinomas, using 12 RFLP (restriction fragment length polymorphism) markers. One clone, L5.71, had been used to identify the MCC gene; all 12 markers also had tight linkage to the gene responsible for adenomatous polyposis coli. All 40 cases studied were informative with at least one marker, and 22 of them (55%) showed LOH at one or more loci. LOH in the tumors was more frequent in the immediate vicinity of L5.71 than in distant parts of the chromosome, and a common region of deletion was detected between markers L5.62 and 15A6. In one case, alleles were retained at L5.71 and at loci proximal to L5.71, but alleles were lost at loci distal to L5.71. In another case, both alleles were retained at L5.71 but alleles were lost at loci proximal and distal to L5.71. These results support the conclusion that a tumor suppressor gene for colorectal carcinoma is located within or around locus L5.71.
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PMID:Frequent loss of heterozygosity at the MCC locus on chromosome 5q21-22 in sporadic colorectal carcinomas. 168 92

Suppressor gene loci involved in the development of hepatocellular carcinoma (HCC) have not been fully identified. The aim of this study was to look for consistent allele loss, or loss of heterozygosity (LOH), in HCC which might represent such gene loci. We have prepared DNA from tumour and non-tumour material from 16 patients with HCC (nine with and seven without liver cirrhosis). Tumour DNA was compared with non-tumour DNA by Southern analysis performed with a panel of 22 probes recognising restriction fragment length polymorphisms assigned to chromosomes 1, 4, 5, 7, 9, 11, 12, 13, 14, 16, 17, 18 and 20. Non-tumour DNA from five of the seven patients with HCC without cirrhosis was heterozygous with the probe Lambda MS8 (5q35-qter), and in all five there was LOH in tumour DNA. Probes for other regions of chromosome 5 have as yet shown no LOH in this group of patients. Cirrhotic HCC patients exhibited LOH on chromosomes 1q and 5p but not in the region 5q35-qter. Both groups of HCC showed LOH on chromosome 17p13. Screening with other probes has not shown any consistent LOH in either group as yet. A comparison of LOH on chromosome 5 in seven patients with colorectal metastasis in the liver showed a different pattern, which suggests that the proposed tumour suppressor gene locus for HCC without cirrhosis on chromosome 5 appears to be distinct from the familial adenomatous polyposis coli gene.
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PMID:Loss of constitutional heterozygosity on chromosome 5q in hepatocellular carcinoma without cirrhosis. 168 7

Tumour development is the consequence of a multistep process involving the activation of oncogenes and loss of tumour suppressor gene function. The study of molecular alterations which accompany carcinogenesis and distinguish the tumour from its normal cellular counterpart, may provide a basis for the in vivo development of drug resistance and facilitate the rational design of anticancer drugs which exploit these differences. In this review we shal discuss some of the effects of carcinogen exposure in relation to how this may influence the response of a tumour to chemotherapy.
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PMID:Carcinogenesis and the response of tumours to anticancer drugs. 176 46

Recent studies have suggested the existence of a tumor suppressor gene located at chromosome region 5q21. DNA probes from this region were used to study a panel of sporadic colorectal carcinomas. One of these probes, cosmid 5.71, detected a somatically rearranged restriction fragment in the DNA from a single tumor. Further analysis of the 5.71 cosmid revealed two regions that were highly conserved in rodent DNA. These sequences were used to identify a gene, MCC (mutated in colorectal cancer), which encodes an 829-amino acid protein with a short region of similarity to the G protein-coupled m3 muscarinic acetylcholine receptor. The rearrangement in the tumor disrupted the coding region of the MCC gene. Moreover, two colorectal tumors were found with somatically acquired point mutations in MCC that resulted in amino acid substitutions. MCC is thus a candidate for the putative colorectal tumor suppressor gene located at 5q21. Further studies will be required to determine whether the gene is mutated in other sporadic tumors or in the germ line of patients with an inherited predisposition to colonic tumorigenesis.
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PMID:Identification of a gene located at chromosome 5q21 that is mutated in colorectal cancers. 184 68

Six families of activated protooncogenes, ras, raf, fur, neu, jun and myc have so far been associated with human lung cancer. Human bronchial epithelial cells in vitro are being used to investigate the functional role of these specific oncogenes and growth regulatory genes in carcinogenesis and tumour progression. When transferred into normal human bronchial epithelial cells by the highly efficient protoplast fusion method, the v-Ha-ras oncogene initiates a cascade of events leading to decreased responsiveness of these cells to inducers of squamous differentiation, aneuploidy and, less frequently, 'immortality' and tumorigenicity with metastasis in athymic nude mice. Transfection of the SV40 T antigen gene results in nontumorigenic cell lines that have a nearly normal pathway of terminal squamous differentiation and can be transformed into malignant cells by transfected Ha-ras, N-ras or Ki-ras. The combination of transfected c-myc and c-raf-1 also transforms human bronchial epithelial cells into neoplastic cells that exhibit some phenotypic traits found in small-cell carcinomas. These and other results indicate that proto-oncogenes dysregulate the pathways of growth and differentiation of human bronchial epithelial cells and play an important role in human carcinogenesis. Analyses of allelic deletion and somatic cell hybrids are being used to identify the chromosomal localization of tumour suppressor genes. We have examined 54 non-small-cell bronchogenic carcinomas with 13 polymorphic markers. Loss of heterozygosity was more frequent than among 23 squamous-cell carcinomas than among 23 adenocarcinomas or eight large-cell carcinomas. Loss of heterozygosity for chromosome 17p was found in 89% of cases of squamous-cell carcinoma and 18% of adenocarcinomas. Analysis of chromosome 11 for allelic deletions revealed two commonly deleted regions (11p13 and 11p15.5). Somatic cell hybrids between normal human bronchial epithelial cells and Hut292DM, a lung carcinoma cell line, had a finite lifespan in vitro and were nontumorigenic in athymic nude mice. Tumour suppressive effects of individual or combinations of specific human chromosomes on Hut292DM are being examined by formation of microcell-cell hybrids. Chromosome 11 has tumour suppressor activity in these hybrids. Both of these studies suggest that tumour suppressor genes play a dominant role in lung carcinogenesis and provide in-vitro model systems for isolating these genes by subtraction library and insertional mutagenesis techniques.
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PMID:Role of oncogenes and tumour suppressor genes in human lung carcinogenesis. 185 68


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