UNIPROT:P43146 - FACTA Search

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

Recent investigations revealed that the 9p arm and 17q arm of human chromosomes harbour tumour suppressor genes (TSGs) with an important role in multistage carcinogenesis. At the 9p arm is located the p16 (MTS1) TSG and probably others with an effect on various human tumours such as acute lymphoblastic leukaemia, bladder cancer, gliomas, malignant mesotheliomas, melanomas and non-small cell lung carcinomas. In addition, the 17q arm harbours BRCA1 TSG which is responsible for approximately 80% of the familial breast/ovarian cancer cases. In order to investigate the implication of these performed a loss of heterozygosity (LOH) analysis with 10 polymorphic microsatellite markers (three at the 17q arm surrounding the BRCA1 region and seven at the 9p arm). Fourteen of the 17 (82%) tumours exhibited deletions at 9p. The highest incidence of LOH (6/13, 46%) was found for the marker D9S157 at 9p22. One sample exhibited deletion of all the informative markers tested indicating deletion of the complete 9p arm. No homozygous deletions were found. LOH at the 17q arm near the BRCA1 locus was found in 6 (35%) among 17 specimens. The results of this study indicate that allelic deletions at 9p are frequent in the development of laryngeal tumours. The highest incidence of LOH was found for the marker D9S157 which is near, but distinct from the location of p16 (MTS1) tumour suppressor gene, indicating the presence of multiple tumour suppressor genes within this chromosomal region. In addition, BRCA1 TSG is implicated in the development of laryngeal tumours.
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PMID:Loss of heterozygosity at 9p and 17q in human laryngeal tumors. 758 72

Cell division is controlled by a series of positive and negative regulators which act at sequential points throughout the cell cycle. Disturbance of these checks could contribute to cancer by allowing excessive cell proliferation. The point in G1 at which cells irrevocably commit to DNA synthesis is controlled by protein complexes consisting of cyclin-dependent kinases (CDK4 or CDK6) and cyclins (D1, D2 or D3). These complexes are inhibited by low molecular weight proteins, such as p16INK4 (refs 1,2), p15INK4B (ref. 3) and p18 (ref. 4). Deletion or mutation of these CDK-inhibitors could lead to unchecked cell growth, suggesting that members of the p16INK4 family may be tumour suppressor genes. The recent detection of p16INK4 (MTS1) mutations in familial melanoma kindreds, many human tumour cell lines, and primary tumours is consistent with this idea. Previously, we described eight germline p16INK4 substitutions in 18 familial melanoma kindreds. Genetic analyses suggested that five mutations predisposed carriers to melanoma, whereas two missense mutations had no phenotypic effect. We now describe biochemical analyses of the missense germline mutations and a single somatic mutation detected in these families. Only the melanoma-predisposing mutants were impaired in their ability to inhibit the catalytic activity of the cyclin D1/CDK4 and cyclin D1/CDK6 complexes in vitro. Our data provide a biochemical rationale for the hypothesis that carriers of certain p16INK4 mutations are at increased risk of developing melanoma.
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PMID:Mutations associated with familial melanoma impair p16INK4 function. 764 80

The p16Ink4/MTS1/CDKN2 is a cell-cycle regulatory inhibitor of cyclin-dependent kinase 4 (cdk4), and a candidate tumour suppressor whose gene on chromosome band 9p21 is frequently deleted or mutated in diverse types of cancer. Cdk4 in association with its D-type cyclin partners, together with p16Ink4, and the product of the retinoblastoma tumour-suppressor gene (pRB), appear to constitute a G1-phase-controlling pathway which can become de-regulated through oncogenic aberrations of any of the components. In an attempt to elucidate the underlying molecular mechanisms, we have now surveyed expression of p16Ink4, at the protein and the mRNA levels, in 21 human cell types expressing normal pRB, as compared with another series of 21 cell lines whose pRB is mutant and/or inactivated through sequestration by DNA tumour virus onco-proteins. In contrast to aberrant lack of p16 expression in the majority of RB-positive cell types, expression of apparently normal (as shown by electrophoretic mobility and/or the ability to form protein-protein complexes with cdk4 in vivo) p16 was uniformly preserved in the cancer cell lines whose RB function was compromised. These data indicate that p16 operates upstream of pRB along the same pathway in G1. The results are discussed in view of the nature of a selective growth advantage potentially gained by cells through de-regulation of this key cell-cycle control mechanism.
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PMID:Aberrations of p16Ink4 and retinoblastoma tumour-suppressor genes occur in distinct sub-sets of human cancer cell lines. 770 23

Venous malformations are a common form of vascular anomaly that cause pain and disfigurement and can be life threatening if they involve critical organs. They occur sporadically or in a familial form, where multiple lesions are usually present. We have identified a large kindred showing autosomal dominant inheritance of venous malformations. Using this family we confirm linkage of a familial form of venous malformations to chromosome 9p. We suggest that blue rubber bleb naevus syndrome can be considered a particular manifestation of this form of familial venous malformations. The candidate region for this gene encompasses the interferon gene cluster and the MTS1 (p16) tumour suppressor gene.
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PMID:A gene for familial venous malformations maps to chromosome 9p in a second large kindred. 778 68

D-type cyclins, in association with the cyclin-dependent kinases Cdk4 or Cdk6, regulate events in the G1 phase of the cell cycle and may contribute to the phosphorylation of the retinoblastoma gene product (Rb). However, in cells in which the function of Rb has been compromised, either by naturally arising mutations or through binding to proteins encoded by DNA tumour viruses, Cdk4 and Cdk6 are not associated with D cyclins. Instead, both kinases form binary complexes with a stable 16 kDa protein (p16) encoded by the putative tumour suppressor gene INK4/MTS1 on human chromosome 9p21. Here we show an inverse correlation between Rb status and the expression of p16. Since Rb-negative cells express high levels of p16, we suggest that in these cells p16 competes with D cyclins for binding to Cdk4 and Cdk6 and prevents formation of active complexes. In line with these predictions, DNA tumour virus oncoproteins do not disrupt cyclin D1-Cdk4 complexes in cells lacking p16.
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PMID:Lack of cyclin D-Cdk complexes in Rb-negative cells correlates with high levels of p16INK4/MTS1 tumour suppressor gene product. 785 39

The MTS1/CDK4I gene encodes a 16 kDa cyclin kinase inhibitor and maps to chromosome 9p21. Previous studies have suggested the presence of a major tumour suppressor gene at this locus which may be inactivated in head and neck squamous cell carcinoma (HNSCC). To determine the status of this gene in human primary and metastatic HNSCC, we examined the locus and its transcript for abnormalities by polymerase chain reaction (PCR). Out of 14 cell lines studied, four had lost only exon 1, one had lost only exon 2, three had lost both exons 1 and 2, and none of the remaining six lines expressed a normal p16 mRNA. These latter six cell lines expressed p16 transcripts that had suffered deletions ranging in size from 2-16 base pairs. In each case, deletions led to a change of reading frame. Furthermore, in two cases abnormalities in the MTS1/CDK4I gene were identical in cells derived from metastatic tumours as compared to cells derived independently from the corresponding primary tumour. The identical nature of mutations observed in primary tumours and metastases derived from the same patient provides strong evidence that inactivation of p16 function was an in vivo event.
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PMID:MTS1/CDK4I is altered in cell lines derived from primary and metastatic oral squamous cell carcinoma. 800 Dec 21

Homozygous deletions of the cyclin-dependent kinase 4 (CDK4) inhibitor gene CDKN2 (p16, MTS1) have been demonstrated to occur frequently in human cancer cell lines of different origin. However, in most primary tumours the frequencies of CDKN2 deletions are not well defined. We studied primary samples of 100 patients with lymphoid leukaemias [B-lineage acute lymphoblastic leukaemia (ALL), n = 23; T-ALL, n = 7; B-cell chronic lymphocytic (B-CLL) or prolymphocytic (B-PLL) leukaemia, n = 50; T-CLL/T-PLL, n = 20] using fluorescence in situ hybridization (FISH) with eight overlapping cosmid clones covering the region on chromosome band 9p21 containing CDKN2. We did not observe any CDKN2 deletions in the 70 patients with chronic lymphoid leukaemias of B- or T-cell origin. Of the 23 patients with B-lineage ALL, one (4%) exhibited a CDKN2 deletion: in this patient, two clones were detected, one exhibiting a hemizygous and the other a homozygous deletion. On chromosome banding analysis, four patients with B-lineage ALL had a 9p aberration, whereas all CDKN2 copies were retained. In contrast, six of the seven (86%) patients with T-ALL exhibited CDKN2 deletions (homozygous, n = 4; hemizygous, n = 2). We conclude that hemizygous or homozygous deletions of the CDKN2 gene occur at high frequency in T-ALL and at low frequency in B-lineage ALL, supporting the role of this gene as a tumour suppressor, especially in T-ALL. However, from our data there is no evidence that CDKN2 is involved in the pathogenesis of chronic lymphoid leukaemias of B- or T-cell origin.
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PMID:CDKN2 gene deletion is not found in chronic lymphoid leukaemias of B- and T-cell origin but is frequent in acute lymphoblastic leukaemia. 854 31

Recent reports have indicated a high frequency of deletions of MTS1 (CDKN2, p16ink4, CDKI4) in acute lymphoblastic leukaemias (ALLs). This gene is located at chromosome 9p21 and encodes an inhibitor of cyclin D-dependent kinases. In contrast with the observations in some other malignancies, no inactivation of MTS1 by intragenic mutation was demonstrated in leukaemias. A contribution of MTS1 alterations to leukaemogenesis therefore remains questionable. In order to test for the implication of MTS1 as a tumour suppressor gene in paediatric ALLs we have explored the 9p21 chromosomal region of 46 children with this disease. The copy number of the MTS1 gene in blasts from the patients was determined using a quantitative PCR assay enabling us to precisely detect mono- and bi-allelic deletions. Rearrangements of the gene were sought by Southern blot analysis. The extent of the deletions was studied using microsatellite markers spanning the 9p21 chromosomal region. Point mutations were sought in exon 1 and exon 2 of the MTS1 gene in patients with a mono-allelic deletion in addition, exon 2 of MTS1, which contains two-thirds of the coding region, was sequenced in all patients who had no deletion of the gene. Altogether, our data are consistent with the view that MTS1 is the target of 9p21 deletions. Either one or two alleles of the gene were deleted in 36% of non-selected children with B-lineage ALL and both alleles were deleted in all seven patients we studied with T-lineage ALL. The absence of any point mutation implies that the major mechanism of inactivation of MTS1 in ALLs is deletional.
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PMID:Deletion mapping indicates that MTS1 is the target of frequent deletions at chromosome 9p21 in paediatric acute lymphoblastic leukaemias. 860 8

Acute leukaemias are characterized by nonrandom chromosomal aberrations which are often strictly related to the inactivation of tumour suppressor genes (TSGs). Alterations at the short arm of chromosome 9 have been reported in a remarkable percentage of acute lymphoblastic leukaemias (ALL) and have been suggested to cause the loss of activity of the putative TSG, p16INK4A (MTS1/CDKN2) gene. In order to evaluate the correlation between this gene inactivation and visible cytogenetic abnormalities, we have investigated p16INK4A homozygous gene deletions in 10 paediatric acute leukaemias of different cell lineages which demonstrated karyotype aberrations involving chromosome 9. Moreover, the dimension of the genetic alteration was evaluated by studying the loss of heterozygosity of two highly polymorphic markers of chromosome 9p, namely alpha-interferon (IFNA) and D9S104, and the deletion of 5'-methylthioadenosine phosphorylase (MTAPase) gene. Finally, the deletion of a gene belonging to p16INK4A family, the p18 gene, was analysed in these acute leukaemias. Our results demonstrated that: (1) the biallelic loss of p16INK4A gene is strictly related to a specific immunophenotype, namely ALL of T-cell lineage; (ii) no significant correlation exists between alterations at chromosome 9p level and the homozygous deletions of p16INK4A gene; and (iii) p18 gene was not deleted in the examined cases. These findings suggest a possible correlation between the T-lymphocyte phenotype and the expression of p16INK4A gene. Moreover, the absence of MTAPase activity seems to be a valuable marker of p16INK4A gene inactivation, thus indicating that the deleted chromosomal area on 9p21 very frequently involves the MTAPase gene.
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PMID:P16INK4A gene homozygous deletions in human acute leukaemias with alterations of chromosome 9. 865 84

p16INK4a (MTS1) is an important negative regulator of mammalian cell proliferation, acting via inhibition of CDK4/cyclin D-dependent phosphorylation of pRb to prevent progression through the G1 phase of the cell cycle. Loss of p16 activity by either gene deletion, mutation or transcriptional inactivation has now been found in a wide range of human cancers of both epithelial and mesenchymal origin, at a frequency rivalling that of p53 mutation. As a first step towards investigating its possible role as a tumour suppressor gene in thyroid tumorigenesis, we have carried out a Southern blot analysis of the p16 gene locus in a series of cell lines derived from differentiated human thyroid cancers. Homozygous deletion of the entire p16 coding sequence was observed in two of three follicular and two of four papillary cancer cell lines, but not in normal tissue or normal cells immortalised by SV40 T antigen. Given the co-existence of p16 abnormalities in primary tumours and cell lines observed in other tumour types, this high frequency of deletion suggests that p16 is a key tumour suppressor gene in the genesis of differentiated thyroid cancer.
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PMID:High frequency deletion of the tumour suppressor gene P16INK4a (MTS1) in human thyroid cancer cell lines. 882 72

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