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)

Cancer is now considered to be a multi-hit process which involves a number of aberrant genetic events culminating in malignant transformation. In squamous cell carcinoma (SCC) of the head and neck the action of both oncogenes and tumour-suppressor genes has been identified during the course of the disease. Cytogenetic analysis of these carcinomas has demonstrated chromosomal breakpoints, particularly in the regions of 1p22 and 11q13 together with frequent amplification of the proto-oncogenes in the 11q13 amplicon; int-2, hst-1 and bcl-1. Ras mutations have been infrequently identified in the Western World whereas ras over-expression has been a common finding and may be associated with the early development of head and neck cancer. C-myc over-expression appears to correlate with a poor prognosis for these patients. The tumour-suppressor gene p53 is also thought to be involved in the development of SCC in head and neck tumours and its aberrant expression is associated with a history of heavy smoking and heavy drinking. E-cadherin, a putative tumour-suppressor gene is down-regulated in poorly differentiated head and neck SCC and maybe important in nodal metastasis. A recent study has indicated that the Human Papilloma Virus (HPV 16 and 33) has a role in the aetiology of tonsillar carcinomas and HPV has been shown to produce transforming proteins which bind to and inactivate the p53 tumour suppressor gene. This evidence suggests that the possibility of a viral mechanism for the development of SCC in the head and neck should be considered. This paper proposes a series of genetic events to explain the development of SCC of the head and neck.
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PMID:Oncogenes and tumour-suppressor genes in squamous cell carcinoma of the head and neck. 133 Jan 49

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

p16INK4 gene, which encodes a specific inhibitor of cyclin-dependent kinase 4 (CDK4), has been recently reported as an important tumour suppressor gene. It is mapped to chromosome 9p21, which is frequently deleted or mutated in many tumour cell lines including malignant melanoma. Since the CDK4/cyclin D complex propels a cell to go through the G1 check point of the cell cycle, a critical phase of cell division, alteration of the p16INK4 gene could lead a cell to uncontrolled proliferation and malignant transformation. To clarify any role for p16INK4 and CDK4 proteins in the development of human malignant melanoma, we have examined, immunohistochemically, the expression of these two proteins in melanocytic neoplasms including 19 primary lesions of non-familial melanoma. Intense nuclear and/or cytoplasmic expression of the CDK4 protein was observed in 11 of 19 cases (58%) of melanoma. In contrast, virtually no nuclear or cytoplasmic staining for CDK4 protein was detected in 28 benign melanocytic naevi, including six Spitz naevi. Expression of p16INK4 protein was observed in three of 19 melanomas (16%) and in 17 of 28 benign naevi (61%). Inverse expression of CDK4 and p16INK4, at individual cell level, was detected in one case of melanoma. The present study suggests that CDK4 overexpression is characteristic for malignant melanoma, and probably reflects its autonomous accelerated cell proliferation. The expression rate of p16INK4 protein in malignant melanoma was lower than that in benign naevi, although the significance of p16INK4 deletion in melanoma development has not been definitely confirmed.
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PMID:Immunohistochemical detection of CDK4 and p16INK4 proteins in cutaneous malignant melanoma. 874 40

D-type cyclins are involved in regulation of cell traverse through G1 primarily by activating the cyclin-dependent kinase 4 (CDK4) and targeting it to the retinoblastoma tumour suppressor protein. There is a vast body of evidence that defective expression of D-type cyclins is associated with tumour development and/or progression. Immunocytochemical detection of D cyclins combined with multiparameter flow cytometry makes it possible to measure the expression of these proteins in individual cells in relation to their cell cycle position without the need for cell synchronization. This approach was used in the present study to compare the cell cycle phase specific expression of cyclins D3 and D1 in human normal proliferating lymphocytes and fibroblasts, respectively, with nine tumour cell lines of different lineage. During exponential, unperturbed growth, expression of cyclin D1 in fibroblasts from donors of different age, or cyclin D3 in lymphocytes, was limited to mid-G1 cells: Less than 7% of the cells entering S phase or progressing through S and G2 were cyclin D positive. In contrast, expression of either cyclin D1 or cyclin D3 in tumour cell lines of different lineage was not limited to G1 phase. Namely, over 80% of the cells in S and G2+M were cyclin D positive in eight of the nine cell lines studied. The data indicate that while expression of cyclin D1 or D3 in normal cells is discontinuous, occurring transiently in G1, these proteins are expressed in some tumour lines persistently throughout the cell cycle. This suggests that the partner kinase CDK4 is perpetually active throughout the cell cycle in these tumour lines.
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PMID:Unscheduled expression of cyclins D1 and D3 in human tumour cell lines. 878 88

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

Many human tumours show perturbations of a pathway that includes the D-cyclins, their associated cyclin-dependent kinases, and specific kinase inhibitors. The focal point of this pathway is the product of the retinoblastoma tumour suppressor gene, pRb, which imposes a block on G1 phase progression. Thus, the major role of the cyclin D-dependent kinases is to overcome this block by initiating the phosphorylation of pRb. Excessive activity of this pathway is likely to lead to excessive cell proliferation. Conversely, accumulation of the inhibitors is associated with the cessation of cell division.
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PMID:Regulation and function of the cyclin-dependent kinase inhibitor p16CDKN2. 920 87

We have previously shown that a 20 amino acid peptide derived from the third ankyrin-like repeat of the p16CDKN2/INK4a (p16) tumour suppressor protein (residues 84-103 of the human p16 protein) can bind to cdk4 and cdk6 and inhibit cdk4-cyclin D1 kinase activity in vitro as well as block cell cycle progression through G1. Substitution of two valine residues corresponding to amino acids 95 and 96 (V95A and V96A) of the p16 peptide reduces the binding to cdk4 and cdk6 and increases its IC0.5 for kinase inhibition approximately threefold when linked to the Antennapedia homeodomain carrier sequence. The same mutations increase the IC0.5 approximately fivefold in the p16 protein. Substitution of aspartic acid 92 by alanine instead increases the binding of the peptide to cdk4 and cdk6 and the kinase inhibitory activity. The p16 peptide blocks S-phase entry in non-synchronized human HaCaT cells by approximately 90% at a 24 microM concentration. The V95A and V96A double substitution minimizes the cell cycle inhibitory capacity of the peptide whereas the D92A substitution increases its capacity to block cell cycle progression. A deletion series of the p16 derived peptide shows that a 10 residue peptide still retains cdk4-cyclin D1 kinase and cell cycle inhibitory activity. The p16 peptide inhibited S-phase entry in five cell lines tested, varying between 47-75%, but had only a limited (11%) inhibitory effect in the pRb negative Saos-2 cells at a concentration of 24 microM. Like the full length p16 protein, the p16 peptide does not inhibit cyclin E dependent cdk2 kinase activity in vitro. These data suggest that acute inhibition of CDK-cyclin D activity by a peptide derived from the INK4 family will stop cells in late G1 in a pRb dependent fashion.
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PMID:Characterization of the cyclin-dependent kinase inhibitory domain of the INK4 family as a model for a synthetic tumour suppressor molecule. 948 4

The cyclin-dependent kinases 4 and 6 (Cdk4/6) that control the G1 phase of the cell cycle and their inhibitor, the p16INK4a tumour suppressor, have a central role in cell proliferation and in tumorigenesis. The structures of Cdk6 bound to p16INK4a and to the related p19INK4d reveal that the INK4 inhibitors bind next to the ATP-binding site of the catalytic cleft, opposite where the activating cyclin subunit binds. They prevent cyclin binding indirectly by causing structural changes that propagate to the cyclin-binding site. The INK4 inhibitors also distort the kinase catalytic cleft and interfere with ATP binding, which explains how they can inhibit the preassembled Cdk4/6-cyclin D complexes as well. Tumour-derived mutations in INK4a and Cdk4 map to interface contacts, solidifying the role of CDK binding and inhibition in the tumour suppressor activity of p16INK4a.
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PMID:Structural basis for inhibition of the cyclin-dependent kinase Cdk6 by the tumour suppressor p16INK4a. 975 Oct 50

CDKN2A (p16INK4A/MTS1) and CDKN2B (p15INK4B/MTS2) have recently been shown to be potent inhibitors of the cyclin D/cyclin-dependent kinase-4 complex. Both genes are candidates for the putative tumour suppressor genes located at chromosome 9p21 and are frequently inactivated in many human cancers through homozygous deletion. More recently, another reported pathway of inactivation involves loss of transcription associated with de novo methylation of the 5' CpG island of p16/MTS1 and p15/MTS2 in human cancers. We examined a total of 34 tumours from 30 hepatocellular carcinoma (HCC) patients for deletion, mutation and DNA methylation of these two genes by polymerase chain reaction (PCR) amplification, sequence analysis and Southern blot. Homozygous deletions of P16/MTS1 exon 1 were only identified in 1 of 30 cases (3%). Homozygous deletions of p15 exon 1 or exon 2 were found in 7 of 30 cases (13%). Automated sequencing analysis of p16 exon 1 and 2 and p15 exon 1 and 2 failed to demonstrate mutations in either p16 or p15 in any of these specimens. No aberrant 5' CpG island hypermethylation of p16 or p15 was found in any of the primary tumours by Southern blot. These data suggest that the p16/MTS1 gene has a limited role in HCC. However, deletions of the p15/MTS2 gene are found in 13% HCC and might be involved in a subset of HCC.
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PMID:Infrequent mutations and no methylation of CDKN2A (P16/MTS1) and CDKN2B (p15/MTS2) in hepatocellular carcinoma in Taiwan. 989 70

The tumour suppressor p16 is a member of the INK4 family of inhibi tors of the cyclin D-dependent kinases, CDK4 and CDK6, that are involved in the key growth control pathway of the eukaryotic cell cycle. The 156 amino acid residue protein is composed of four ankyrin repeats (a helix-turn-helix motif) that stack linearly as two four-helix bundles resulting in a non-globular, elongated molecule. The thermodynamic and kinetic properties of the folding of p16 are unusual. The protein has a very low free energy of unfolding, Delta GH-2O/D-N, of 3.1 kcal mol-1 at 25 degreesC. The rate-determining transition state of folding/unfolding is very compact (89% as compact as the native state). The other unusual feature is the very rapid rate of unfolding in the absence of denaturant of 0.8 s-1 at 25 degreesC. Thus, p16 has both thermodynamic and kinetic instability. These features may be essential for the regulatory function of the INK4 proteins and of other ankyrin-repeat-containing proteins that mediate a wide range of protein-protein interactions. The mechanisms of inactivation of p16 by eight cancer-associated mutations were dissected using a systematic method designed to probe the integrity of the secondary structure and the global fold. The structure and folding of p16 appear to be highly vulnerable to single point mutations, probably as a result of the protein's low stability. This vulnerability provides one explanation for the striking frequency of p16 mutations in tumours and in immortalised cell lines.
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PMID:Stability and folding of the tumour suppressor protein p16. 991 18


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