Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
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Target Concepts:
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Query: UNIPROT:P43146 (
tumour suppressor
)
5,935
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The CDKN2 gene, encoding the cyclin-dependent kinase inhibitor p16, is a
tumour suppressor
gene that maps to chromosome band 9p21-
p22
. The most common mechanism of inactivation of this gene in human cancers is through homozygous deletion; however, in a smaller proportion of tumours and tumour cell lines intragenic mutations occur. In this study we have compiled a database of over 120 published point mutations in the CDKN2 gene from a wide variety of tumour types. A further 50 deletions, insertions, and splice mutations in CDKN2 have also been compiled. Furthermore, we have standardised the numbering of all mutations according to the full-length 156 amino acid form of p16. From this study we are able to define several hot spots, some of which occur at conserved residues within the ankyrin domains of p16. While many of the hotspots are shared by a number of cancers, the relative importance of each position varies, possibly reflecting the role of different carcinogens in the development of certain tumours. As reported previously, the mutational spectrum of CDKN2 in melanomas differs from that of internal malignancies and supports the involvement of UV in melanoma tumorigenesis. Notably, 52% of all substitutions in melanoma-derived samples occurred at just six nucleotide positions. Nonsense mutations comprise a comparatively high proportion of mutations present in the CDKN2 gene, and possible explanations for this are discussed.
...
PMID:Compilation of somatic mutations of the CDKN2 gene in human cancers: non-random distribution of base substitutions. 883 70
BCL10 is a
tumour suppressor
gene originally cloned from a t(1;14)(
p22
;q32) breakpoint in a case of mucosa-associated lymphoid tissue (MALT) lymphoma. Translocations involving this gene, though uncommon, are sometimes encountered in MALT lymphomas. This gene is thought to play an important role in the development of malignant lymphomas. Fluorescence in situ hybridization (FISH) was therefore undertaken on 22 cases of malignant lymphoma of varying histology to establish the incidence of rearrangements involving the BCL10 gene. Initially, one case with a novel t(1;2)(
p22
;p12) translocation involving the BCL10 gene was identified, in a marginal zone lymphoma of the MALT type, and was reported elsewhere. Seven other cases were subsequently identified with abnormalities in the 1p region, including a translocation with a breakpoint in the 1p22 region in a case of lymphoblastic lymphoma. However, none of these involved the BCL10 gene. Mutation analysis of BCL10 was then performed on 57 cases of malignant lymphoma, including 17 MALT lymphomas, by single-strand conformational polymorphism (SSCP) analysis of tumour DNA. Tissue was obtained for mutation analysis for 12 of the 22 cases analysed by FISH. Selected cases with SSCP band shifts were further studied by direct sequencing. Polymorphisms were identified in eight cases, but no mutations of pathogenic significance were identified. Further RT-PCR and mutation analysis was performed on cDNAs from 12 cases (four MALT, seven diffuse large B-cell lymphoma, one Hodgkin's disease) in which DNA analysis had already been completed. This included the MALT lymphoma with the t(1;2)(
p22
;p12) rearrangement. Again, no mutations were identified in the coding sequence. This study confirms that rearrangements of the BCL10 gene are uncommon in lymphoma (1/22) and may be limited tothe MALT subtype of non-Hodgkin's lymphomas. It was also found that breakpoints or rearrangements in the 1p22 region do not necessarily involve the BCL10 gene. Moreover, the absence of mutations at both the DNA (0/60) and the mRNA (0/12) level indicates that this gene is not frequently inactivated by mutation, in those tumours in which it is not involved in translocations. Our findings suggest that the BCL10 gene is unlikely to have a frequent or key role in general lymphomagenesis.
...
PMID:BCL10 in malignant lymphomas--an evaluation using fluorescence in situ hybridization. 1174 43
The development of gastric mucosa-associated lymphoid tissue (MALT) lymphoma is dependent on Helicobacter pylori infection. Bacterial colonisation of the gastric mucosa triggers lymphoid infiltration and the formation of acquired MALT. The bacterial infection induces and sustains an actively proliferating B-cell population through direct (autoantigen) and indirect (intratumoral T cells specific for H. pylori) immunological stimulation. Moreover, the bacterial infection provokes a neutrophilic response, which causes the release of oxygen free radicals. These reactive species may promote the acquisition of genetic abnormalities and malignant transformation of reactive B cells. A transformed clone carrying the translocation t(1;18)(q21;q21) forms a MALT lymphoma, the growth of which is independent of H. pylori and will not respond to bacterial eradication. Malignant clones without t(11;18)(q21;q21), but with other genetic abnormalities, such as trisomy 3 or microsatellite instability, depend critically on immune stimulation mediated by H. pylori for their clonal expansion. In the early stages, the tumour can be successfully treated by eradication of the bacterium, whereas at later stages the tumour may escape its growth dependency through acquisition of additional genetic abnormalities such as t(1;14)(
p22
;q32) and t(1;2)(
p22
,p12) involving the BCL-10 gene. Finally, further genetic abnormalities, such as inactivation of the
tumour suppressor
genes, p53 and p16, can lead to high-grade transformation. Detection of these abnormalities may help with the clinical management of patients with gastric MALT lymphoma.
...
PMID:Gastric MALT lymphoma: from aetiology to treatment. 1190 29
The paediatric eye tumour retinoblastoma is initiated by inactivation of RB1, a
tumour suppressor
on chromosome 13q. In addition to RB1 loss, many retinoblastomas show other genetic alterations including gains on chromosomes 6p21-pter and 1q31-q32. Recently, the minimal region of gains on chromosome 6 was narrowed to band
p22
. We examined genomic gains and expression changes in primary retinoblastomas to identify potential target genes in 6p22. Quantitative multiplex PCR detected copy numbers > or = 3 in 25 (33%) tumours and no gains in 31 of 76 (40%) tumours. The remaining 20 (26%) samples showed gains only at some loci, most often including E2F3 and DEK in 6p22.3. Analysis of RNA from 21 primary retinoblastomas showed that expression levels of these and some other genes in 6p22 correspond to DNA gains. However, KIF 13A, a reported candidate oncogene on 6p, was expressed at low levels or absent. Clinical manifestation of tumours with gains at all 6p22 loci was distinct in that distribution of age at diagnosis was markedly shifted to older age compared to tumours with no or partial gains. In summary, our results suggest that DEK and E2F3 are potential targets of 6p gains in retinoblastoma.
...
PMID:Gains and overexpression identify DEK and E2F3 as targets of chromosome 6p gains in retinoblastoma. 1600 92
Loss of heterozygosity (LOH) studies have been used extensively to identify regions on chromosomes that may contain putative
tumour suppressor
genes. We have undertaken extensive allelotyping of 45 specimens of non-small cell lung cancer (NSCLC) using 92 polymorphic microsatellite markers on 39 chromosome arms. The most frequent allelic imbalances were found on chromosome arms 3p, 9p and 17p. Significant allelic imbalance was found on other chromosome arms including, 5q (21%), 8p (19%), 13q (24%) and 17q (18%). The LOH data on 3p was subdivided into the four chromosomal regions considered to contain putative
tumour suppressor
genes 3p25-p24 (10%), 3p21 (10%), 3p14 (25%) and 3p13-p12 (22%). The frequency of loss in the different regions on 9p were: 9pter-p23 (31%), 9p23-
p22
(45%) and 9p21-cent (30%). LOH on 17p was separated into three regions: 17pter-p13 (9%), 17p13 (33%) and 17p13-cent (22%). No correlation was found between LOH on any of the chromosomal arms and any of the clinicopathological parameters such as pathology, level of differentiation, TNM staging or alcohol intake. Only one significant association was found between LOH and tumour types. A significant difference was found between LOH on 17q in adenocarcinomas and squamous cell carcinomas (p=0.037). The fractional allele loss (FAL) values for this group of 45 NSCLC gave a median value of 0.9 (range 0-0.45). No correlation was found between FAL and nodes at pathology (p>0.05) and between FAL and tumour grade (p>0.05). No correlation was found between p53 or ras mutations in these NSCLC specimens and their FAL values. Accumulated genetic damage, as provided by this allelotype analysis, provides a useful molecular parameter by which to assess NSCLC and may, in time, assist in the determination of the clinical behaviour and clinical outcome of these tumours.
...
PMID:Allelotype of non-small cell lung cancer. 2154 47
Narrowing the search for the critical
hTERT
repressor sequence(s) has identified three regions on chromosome 3p (3p12-p21.1, 3p21.2 and 3p21.3-
p22
). However, the precise location and identity of the sequence(s) responsible for
hTERT
transcriptional repression remains elusive. In order to identify critical
hTERT
repressor sequences located within human chromosome 3p12-
p22
, we investigated
hTERT
transcriptional activity within 21NT microcell hybrid clones containing chromosome 3 fragments. Mapping of chromosome 3 structure in a single
hTERT-
repressed 21NT-#3fragment hybrid clone, revealed a 490kb region of deletion localised to 3p21.3 and encompassing the histone H3, lysine 36 (H3K36) trimethyltransferase enzyme SETD2; a putative
tumour suppressor
gene in breast cancer. Three additional genes, BAP1, PARP-3 and PBRM1, were also selected for further investigation based on their location within the 3p21.1-p21.3 region, together with their documented role in the epigenetic regulation of target gene expression or
hTERT
regulation. All four genes (SETD2, BAP1, PARP-3 and PBRM1) were found to be expressed at low levels in 21NT. Gene copy number variation (CNV) analysis of SETD2, BAP1, PARP-3 and PBRM1 within a panel of nine breast cancer cell lines demonstrated single copy number loss of all candidate genes within five (56%) cell lines (including 21NT cells). Stable, forced overexpression of BAP1, but not PARP2, SETD2 or PBRM1, within 21NT cells was associated with a significant reduction in
hTERT
expression levels relative to wild-type controls. We propose that at least two sequences exist on human chromosome 3p, that function to regulate
hTERT
transcription within human breast cancer cells.
...
PMID:Functional role of
SETD2, BAP1, PARP-3
and
PBRM1
candidate genes on the regulation of
hTERT
gene expression. 2897 12
