Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: UNIPROT:P43146 (tumour suppressor)
 5,935 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Some of the cellular changes underlying the presentation of cancer in a patient can already be understood in terms of mutations affecting specific gene functions. So far, only a few of the mutated genes responsible for carcinogenesis have been identified and these are chiefly involved in deregulation of cell growth rather than with the processes of invasion and metastasis. Proto-oncogenes are important cellular genes which can acquire gain in function mutations as random events in somatic cells. In their mutated, activated forms they are called cellular oncogenes or c-oncs. This distinguishes them from homologous DNA sequences captured by viruses from host cells in the course of retroviral evolution that cause cancers in animal hosts (viral oncogenes or v-oncs). In recent years, loss of function mutations have been identified in regulatory genes that normally serve to constrain cell growth. These are called tumour suppressor genes. Loss of function mutations may be transmitted in the germline, as in hereditary retinoblastoma, or arise de novo in somatic cells. The normal molecular mechanisms disrupted by mutations in tumour suppressor genes include processes regulating progression through the cell cycle.
Eur J Cancer 1992
PMID:What are cancer genes, and how do they upset cell behaviour? 156 75

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.
Cancer Surv 1992
PMID:Genetic alterations underlying colorectal tumorigenesis. 163 44

The development of Friend virus induced murine erythroleukaemia is associated with specific genetic events. One of these events is loss of wild type p53 expression, which can occur by internal deletion or proviral insertion in the p53 gene and by single point mutations in the coding sequence. In all cases, the corresponding wild type allele is absent. The high frequency of observed p53 mutations strongly suggests that inactivation of p53 may be an obligatory step in the development of Friend disease. Further evidence that abrogation of normal p53 expression contributes to the development of malignant clones was provided by in vitro reconstitution experiments in Friend cell lines: whereas exogenous mutant p53 was stably expressed in p53 negative FCLs, long term wild type p53 expression was not detected. Friend erythroleukaemia arises as a late consequence of infection of susceptible mice with Friend virus. In addition to p53 gene mutations, proviral insertions occur frequently adjacent to one of two cellular genes, Spi-1/PU.1 or Fli-1. Aberrant expression of these genes may therefore be involved in virus induced erythroleukaemia. Interaction of SFFV env gp55 with the EPO-R also appears to be important in providing a mitogenic signal to infected cells. The order in which these events occur and whether the order is relevant to the progression of the disease are not known. Investigation of the stepwise appearance of these events could provide information on the possible interactions of the gene products involved. Abrogation of normal p53 expression is not restricted to Friend erythroleukaemia: the observation of p53 mutations and allele loss in human breast, lung, colon and hepatocellular carcinomas and in leukaemia suggests that mutation of p53 may be the most common genetic abnormality detected in human cancer (reviewed in this issue). Studies of p53 expression in FCLs provided an early indication that p53 was a tumour suppressor gene. Further studies of the mechanisms by which wild type and mutant p53 affect the growth of p53 negative FCLs may reveal important biochemical properties of p53 in relation to cell cycle control and differentiation of erythroid cells.
Cancer Surv 1992
PMID:Friend virus induced murine erythroleukaemia: the p53 locus. 163 45

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

Retinoblastoma, the most common intraocular malignancy of children, has served as an important paradigm for understanding the events involved in neoplastic transformation. Much of the contemporary molecular description of human cancers stems directly from experimental approaches first developed to study this childhood tumour. This analytical methodology has demonstrated a major role for heritable predisposition in tumourigenesis, provided evidence for tissue pleiotropy of cancer genes, and revealed a more precise estimation of the number, activity, and location of other tumour suppressor loci.
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PMID:Molecular genetics in the pathology and diagnosis of retinoblastoma. 166 90

We have examined a series of 13 benign and 27 malignant human gliomas for evidence of molecular abnormalities of proto-oncogene and putative tumour suppressor gene loci. The results indicated that specific molecular lesions were associated with increasing grades of malignancy. Thus, loss of genetic material on chromosome 17 was present with approximately equal frequency in both benign and malignant gliomas, whereas loss of loci on chromosome 10 was seen only in malignant gliomas. Only the most malignant tumours, known as glioblastoma multiforme, had more than one molecular abnormality in the same tumour. These findings may contribute to our understanding of glial tumour development, as well as improve the accuracy of tumour diagnosis.
Br J Cancer 1991 May
PMID:Multiple sequential molecular abnormalities in the evolution of human gliomas. 167 78

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.
Jpn J Cancer Res 1991 Sep
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.
Br J Cancer 1991 Dec
PMID:Loss of constitutional heterozygosity on chromosome 5q in hepatocellular carcinoma without cirrhosis. 168 7

Point mutations in the p53 gene are the most frequently identified genetic change in human cancer. They convert murine p53 from a tumour suppressor gene into a dominant transforming oncogene able to immortalize primary cells and bring about full transformation in combination with an activated ras gene. In both the human and murine systems the mutations lie in regions of p53 conserved from man to Xenopus. We have developed a monoclonal antibody to p53 designated PAb240 which does not immunoprecipitate wild type p53. A series of different p53 mutants all react more strongly with PAb240 than with PAb246. The PAb240 reactive form of p53 cannot bind to SV40 large T antigen but does bind to HSP70. In contrast, the PAb246 form binds to T antigen but not to HSP70. PAb240 recognizes all forms of p53 when they are denatured. It reacts with all mammalian p53 and chicken p53 in immunoblots. We propose that immunoprecipitation of p53 by PAb240 is diagnostic of mutation in both murine and human systems and suggest that the different point mutations which convert p53 from a recessive to a dominant oncogene exert a common conformational effect on the protein. This conformational change abolishes T antigen binding and promotes self-oligomerization. These results are consistent with a dominant negative model where mutant p53 protein binds to and neutralizes the activity of p53 in the wild type conformation.
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PMID:Activating mutations in p53 produce a common conformational effect. A monoclonal antibody specific for the mutant form. 169 10

As yet, few molecular markers are available that are likely to be useful in predicting the metastatic potential of prostate cancer cancer cells. The need for such "progression markers" is indicated by the expectation that more localized cancers (ie stage A-2, B-1,2) will be clinically diagnosed in the near future, owing to improvements in diagnostic techniques (eg transrectal ultrasound) and the screening of population groups at risk (males over 50 years old). Few model systems are available for such studies. Animal models are unsuitable for the isolation of monoclonal antibodies that detect epitopes associated with the progression of prostate cancer. Since few cell lines are available, an approach using primary cancer tissue should be undertaken. For the differential hybridization approach described here, the choice of species presents no difficulty, since many DNA sequences are conserved between species. However, no model system fully represents the human situation. Hence, differential hybridization studies using primary prostate cancer tissue need to be considered. Moreover, the group of genes/proteins with potential relevance for cancer progression (eg oncogenes, tumour suppressor genes, genes encoding cell adhesion molecules or growth factors) has not been studied extensively in prostate cancer. Because of the intrinsic heterogeneity of prostate tumours, the use of pathologically defined tissue sections is imperative for a reliable study. This could be achieved either by in situ techniques (whereby tissue morphology is conserved) or by step sectioning. The difficulties associated with the small amount of material obtained from such sections can be overcome by the use of techniques based on the polymerase chain reaction. Taking these considerations into account, a systematic screening of prostate cancer with probes representing the above mentioned genes should be undertaken.
Cancer Surv 1991
PMID:Molecular methods for predicting the metastatic potential of prostate cancer. 172 88


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