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)

Inactivation of the tumour suppressor gene lethal(2) giant larvae (D-lgl) of Drosophila leads to malignant transformation of the presumptive adult optic centers in the larval brain and tumours of the imaginal discs. These malignancies result from the disorganization of a cytoskeletal network in which the D-LGL protein participates. Here we describe the isolation of a cDNA encoding the human homologue to the D-lgl gene designated as hugl. The hugl cDNA detects a locus spanning at least 25 kilobases (kb) in human chromosome band 17p11.2-12, which is centromeric to the p53 gene and recognizes a 4.5 kb RNA transcript. The hugl gene is expressed in brain, kidney and muscle but is barely seen in heart and placenta. Sequence analysis of the hugl cDNA demonstrates a long open reading frame, which has the potential to encode a protein of 1057 amino acids with a predicted molecular weight of 115 kDaltons (kD). To further substantiate and identify the HUGL protein, we have prepared polyclonal rabbit antibodies against synthetic peptides corresponding to the amino and carboxyl termini of the conceptual translation product of the hugl gene. The affinity-purified anti-HUGL antibodies recognize a single protein with an apparent molecular weight of approximately 115 kD. Similar to the Drosophila protein, HUGL is part of a cytoskeletal network and, is associated with nonmuscle myosin II heavy chain and a kinase that specifically phosphorylates HUGL at serine residues.
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PMID:A human homologue of the Drosophila tumour suppressor gene l(2)gl maps to 17p11.2-12 and codes for a cytoskeletal protein that associates with nonmuscle myosin II heavy chain. 754 63

The analysis of loss of heterozygosity (LOH) in tumours can be a powerful tool for mapping the sites of tumour suppressor genes in the human genome. A panel of breast cancer patients was assembled as pairs of tumour and lymphocyte DNA samples and LOH studies carried out by Southern hybridisation with polymorphic loci mapping to the X chromosome with appropriate controls. Deletion mapping revealed a high frequency of small regionalised deletions, defining at least three independent regions, one of which is particularly well mapped to a 500 kb stretch of DNA in the distal portion of the pseudoautosomal region of Xp. A second region has been identified within the pseudoautosomal region close to the pseudoautosomal boundary, and there is a third discrete site of loss on distal Xq. Perturbations of sequences at these regions represent independent events in a number of patients. This study represents the first detailed analysis of LOH on the X chromosome in human breast tumours, the results of which indicate that at least three regions of this chromosome are involved in the disease.
Genes Chromosomes Cancer 1995 Aug
PMID:Loss of heterozygosity on the X chromosome in human breast cancer. 754 30

The loss of epithelial differentiation in carcinomas, which is accompanied by higher mobility and invasiveness of the tumour cells, is often a consequence of reduced intercellular adhesion. The primary cause of the "scattering" of cells in invasive carcinomas appears to be a disturbance of the integrity of intercellular junctions, often involving the cell adhesion molecule E-cadherin. Permanent and transient molecular mechanisms can lead to the impairment of junction integrity of epithelial cells and thus to the progression of carcinomas towards a more invasive state. These include downregulation of E-cadherin expression and interaction between the adherens junction protein beta-catenin and the tumour suppressor gene product APC.
Cancer Surv 1995
PMID:Adherens junction proteins in tumour progression. 755 58

Chromosome 18q is among the regions thought to harbour a tumour suppressor gene(s) that is frequently inactivated by LOH during the development of several cancer types, including those of the gastrointestinal tract. In addition, colorectal cancers with 18q LOH have been shown to have a more aggressive clinical behaviour than those without 18q LOH. A candidate tumour suppressor gene from 18q, called DCC, has been identified. The DCC gene is contained within the common region of LOH on 18q, its expression is markedly decreased or absent in the majority of colorectal cancers and cell lines and somatic mutations within the DCC gene have been identified in a subset of cases. Thus, DCC represents the strongest candidate tumour suppressor gene on 18q. At present, however, many questions remain regarding the mechanisms underlying the inactivation of DCC and its decreased expression in cancers. The predicted structural similarity of DCC to the NCAMs suggests that it may function through cell-cell and/or cell-extracellular matrix interactions; however, little is known regarding the specific cellular function(s) of DCC. Many reports have detailed the alterations in phenotype observed in cancer cells, including changes in cell morphology and tissue architecture, loss of differentiated phenotype, decreased cell adhesion and aggregation, increased motility and invasive behaviour. These altered properties are likely to account in part for the invasive and metastatic properties of cancer cells in the patient. It is hoped that further studies will identify the means by which DCC inactivation may contribute to the altered growth properties of advanced cancer cells.
Cancer Surv 1995
PMID:The deleted in colorectal cancer (DCC) gene: a candidate tumour suppressor gene encoding a cell surface protein with similarity to neural cell adhesion molecules. 755 61

Loss of function of one or both of the two tumour suppressor genes p53 and RB-1 has been recognised as an important step in the development of a variety of human neoplasias for some time. By virtue of the ability to manipulate the genome of murine embryonic stem cells in culture, it has become possible to generate strains of mice which bear inactivations of the murine counterparts of these genes. This article attempts to bring together some of the many results obtained from these murine strains which are shedding light both on the normal role played by both of these genes and the consequences of their dysfunction. Surprisingly neither gene product is revealed to have an indispensable role at the level of the single cell. Hence, even though the Rb-1 gene product clearly has an important role in cell cycle regulation animals constitutively deficient in this gene develop relatively normally for the first 10 days of embryogenesis. It is only at and beyond this stage of development that a requirement for Rb-1 becomes clear, in the regulation of certain cell populations through control of both proliferation and apoptosis. That loss of function of Rb-1 is associated with tumorigenesis is confirmed by the development of tumours of the pituitary gland within heterozygotes. The retinas of these animals, the target organ for tumorigenesis in human RB-1 heterozygotes, remain unaffected. The majority of mice homozygous for an inactivating p53 mutation survive to birth, but then rapidly succumb to tumorigenesis. Heterozygotes also develop tumours, but with a delayed time course and altered spectrum. Analysis of several tissue types from the mutant animals has shown p53 to be crucial for the normal induction of apoptosis following DNA damage, and it is thought that failure of this process is a key predisposing step towards tumorigenesis within the mutant animals. Finally, studies on these and other transgenic strains have revealed interactions between pathways governed by these two genes. For example, the fate of Rb-1 deficient cells has been shown, in some tissues at least, to be dependent upon the functional status of p53.
Cancer Metastasis Rev 1995 Jun
PMID:Murine models of neoplasia: functional analysis of the tumour suppressor genes Rb-1 and p53. 755 30

One of the most commonly detected abnormalities in human cancer is mutation of the p53 tumour suppressor gene. Intrinsic to the function of p53 is its ability to induce apoptotic cell death and to cause cell cycle arrest. Moreover, p53 plays an important role in controlling the cellular response to DNA damaging agents such as ionizing radiation and cancer chemotherapeutic drugs. Loss of p53 function causes increased resistance to radiation and chemotherapeutic agents, and there is increasing evidence that p53 mutational status is an important determinant of clinical outcome in cancer. This review will focus on recent data describing the biochemistry of p53 function, its role in mediating apoptosis and cell cycle arrest and in the control of tumour growth and death.
Cancer Metastasis Rev 1995 Jun
PMID:Apoptosis, cancer and the p53 tumour suppressor gene. 755 31

It is generally accepted that cancer is a genetic disease resulting from the accumulation of multiple genomic rearrangements. These rearrangements involve gross chromosomal abnormalities (e.g. translocations and deletions) as well as submicroscopic mutations affecting both oncogenes and tumour suppressor genes. Recent studies of several tumour specific translocations in sarcomas have shown that the translocations result in so-called fusion genes. In this review we will discuss the specificity and implications of different genetic alterations in both sporadic and hereditary human solid tumours, and provide examples of how these changes can be used as tumour specific markers of both diagnostic and prognostic significance.
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PMID:Cytogenetics and molecular genetics of human solid tumours. 756 7

We report a clinical case of a double primitive tumour (right kidney clear cell carcinoma and gastric carcinoma) in two brothers. There is no history of cancer in the parents. Both patients were previously affected by gastric ulcer. No report of association between the two neoplasms was found in literature. The age of the patients (61 and 70 years) and the singleness of the kidney tumour seem to exclude the case of a familial kidney cancer. The neoplastic transformation of the gastric ulcer is instead a quite frequent report with an incidence of about 1%. Alterations of oncogenes or tumour suppressor genes shared from both neoplasm are at present still unknown. Nevertheless molecular analysis of patients' neoplastic genome could point out typical chromosome translocations/deletions or gene mutations.
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PMID:[Appearance in 2 brothers of double primary neoplasms: right renal carcinoma and gastric adenocarcinoma]. 757 Feb 61

The human tumour suppressor protein p53 is critical for regulation of the cell cycle on genotoxic insult. When DNA is damaged by radiation, chemicals or viral infection, cells respond rapidly by arresting the cell cycle. A G1 arrest requires the activity of wild-type p53, as it is not observed in cells lacking functionally wild-type protein, and at least some component of S phase and G2/M arrests is also thought to be p53-dependent. p53 functions as a transcription factor which binds specific DNA sequences, and recently major downstream targets have been identified, including p21Cip1, an inhibitor of the cell cycle kinases that also blocks the replicative but not the repair function of DNA polymerase delta auxiliary factor, PCNA. Current interest focuses on developing novel cancer therapies based on our knowledge of the activity of p53 and p21Cip1 in the cell cycle.
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PMID:Tumour suppressors, kinases and clamps: how p53 regulates the cell cycle in response to DNA damage. 757 91

Numerous clinical, epidemiological and molecular findings link some types of Human Papillomaviruses (HPV) with cancer of the genital tract. They share a common pathway of transformation with a number of DNA tumour viruses, such as Adenovirus and SV40. Although all these viruses are termed 'DNA tumour viruses' and have similar in vitro transforming activities, Human Papillomavirus is the only one so far clearly involved in human cancer. Extensive studies on HPV E6 and E7 proteins have demonstrated their involvement in malignant transformation. E6 and E7 bind the products of tumour suppressor genes, p53 and Rb1, respectively, modifying or inactivating their normal functions. The Rb1 and p53 genes are deleted or mutated in several cancers and both proteins regulate the transcription of genes involved in cell cycle progression control. The E6/p53 and E7/Rb1 interactions result in a deregulation of the cell cycle with loss of control of crucial cellular events, such as DNA replication, DNA repair and apoptosis.
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PMID:Human papillomavirus E6 and E7: proteins which deregulate the cell cycle. 757 92


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