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Query: UNIPROT:P04637 (
p53
)
77,613
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The proliferative lifespan of normal mammalian cells is limited by intrinsic controls, which desensitize the cell-cycle machinery to extrinsic stimulation after a given number of cell divisions. One underlying clock driving this process of 'replicative senescence' is the progressive erosion of chromosome telomeres, which occurs with each round of DNA replication. This appears to trigger growth inhibition via activation of the tumour suppressor gene (TSG) product,
p53
, and the consequent up-regulation of the cell-cycle inhibitor p21WAF1. Other inhibitory pathways are also activated (possibly by additional clocks), including the TSG
p16INK4a
and the less well-defined complementation group genes. Loss of one pathway can be compensated, after a limited extension of lifespan, by further up-regulation of the others, so that to escape mortality a developing tumour must overcome multiple 'proliferative lifespan barriers' (PLBs) by successive genetic events, each conferring a new wave of clonal expansion. This provides one explanation for the existence of multiple genetic abnormalities in human cancers; furthermore, the diversity in the nature and timing of these PLBs between different cell types may explain the variation in the spectrum of abnormalities observed between the corresponding cancers. Even if all senescence pathways are inactivated, immortalization can only be achieved if erosion of telomeres is halted, before their end-protecting function is lost. This usually requires either activation of telomerase during tumour development, if the cell of origin is telomerase-negative, or up-regulation if the normal cell already has some activity, but not enough to prevent erosion. In either case, cancers often maintain near-critical telomere lengths; hence pharmacological inhibition of telomerase remains an attractive approach to the selective killing of tumour cells.
...
PMID:Cellular senescence and cancer. 1192 Jul 30
Inactivation of the tumour suppressors
p53
and
p16INK4a
or activating mutations in the ras oncogene are the most common genetic alterations found in human cancers. In this review, novel approaches designed to evaluate the effect of targeting intracellular molecules are described and it is shown how information derived from small synthetic peptides can stimulate novel approaches for cancer drugs. This review also gives an example of how molecular, biochemical, and cell biology studies of cancer-associated gene products can, via organic chemistry, be translated into active drugs ready for testing in clinical trials. New cancer treatments are directly springing out of studies related to tumour physiology, where the prime target is not the tumour cells but the tumour blood vessels; some of the different approaches that are being tested will be highlighted here. Finally, some of the difficulties and promises using cancer-associated genes in gene therapy are discussed.
...
PMID:New approaches to cancer therapies. 1034 14
The mammalian ARF-INK4a locus uniquely encodes two cell cycle inhibitors by using separate promoters and alternative reading frames.
p16INK4a
maintains the retinoblastoma protein in its growth suppressive state while ARF stabilizes
p53
. We report that human ARF protein predominantly localizes to the nucleolus via a sequence within the exon 2-encoded C-terminal domain and is induced to leave the nucleolus by MDM2. ARF forms nuclear bodies with MDM2 and
p53
and blocks
p53
and MDM2 nuclear export. Tumor-associated mutations in ARF exon 2 disrupt ARF's nucleolus localization and reduce ARF's ability to block
p53
nuclear export and to stabilize
p53
. Our results suggest an ARF-regulated MDM2-dependent
p53
stabilization and link the human tumor-associated mutations in ARF with a functional alteration.
...
PMID:Mutations in human ARF exon 2 disrupt its nucleolar localization and impair its ability to block nuclear export of MDM2 and p53. 1036 Jan 74
The
INK4A
locus on human chromosome 9p21 encodes two genes that have been implicated in replicative senescence and tumor suppression,
p16INK4A
and p14ARF. In contrast to
p16INK4A
, which is up-regulated to high levels, we were unable to detect p14ARF protein in senescent human keratinocytes. Also,
p53
, an established target of p14ARF, did not increase, suggesting that p14ARF is not instrumental in human keratinocyte senescence. In neoplastic keratinocyte cultures,
p16INK4A
inactivation was invariably associated with the immortal phenotype, and there was evidence for the inactivation of
p16INK4A
, independent of p14ARF, in 6 of 10 lines that lacked large homozygous deletions. In contrast, we failed to detect exon 1beta mutations or
p16INK4A
-independent deletions. These results emphasize the previously proposed role for
p16INK4A
in human keratinocyte senescence but do not rule out a supporting role for p14ARF inactivation.
...
PMID:Role of the alternative INK4A proteins in human keratinocyte senescence: evidence for the specific inactivation of p16INK4A upon immortalization. 1036 64
The cyclin-dependent kinase inhibitor 2a (Cdkn2a) locus encodes two distinct tumor suppressors,
p16INK4a
and p19ARF, whose functions interrelate in the regulation of cell proliferation as key components of the retinoblastoma and
p53
pathways, respectively. In many types of cancer, alterations of Cdkn2a abrogate the functions of both suppressors, implying that both are integral to the genesis of certain cancer types. While this has been observed in mouse lung adenocarcinogenesis, recent observations also suggested that naturally occurring variation at the Cdkn2a locus is probably operative in the development of these tumors. Firstly, two common haplotypes of mouse Cdkn2a have been identified, each of which encodes cosegregating variants of
p16INK4a
and p19ARF. The
p16INK4a
variants differ at amino acids 18 (histidine or proline) and 51 (valine or isoleucine), whereas the p19ARF variants differ only at amino acid 72 (histidine or arginine). Secondly, genetic resistance to lung tumor formation appears to segregate with one particular haplotype, which also is deleted preferentially in lung adenocarcinomas of Cdkn2a heterozygous mice. Here we attempt to explain these observations and to characterize further the roles of p16INK4 and p19ARF in mouse lung tumorigenesis by examining the function and expression of each of the variants of Cdkn2a. Functional analysis showed that the proline 18/isoleucine 51
p16INK4a
variant was diminished in cdk6 binding, cdk6 inhibition and NIH/3T3 fibroblast growth suppression compared with the histidine 18/valine 51 variant, whereas both of the p19ARF variants suppressed growth with similar potencies. Also, the different alleles for
p16INK4a
and p19ARF were transcribed equally in the normal lungs of Cdkn2a heterozygotes, as determined by comparative reverse transcription-polymerase chain reaction-single-stranded conformation polymorphism analysis. These results indicate that strain-specific variation in
p16INK4a
function is exploited in mouse lung tumorigenesis and strongly implicate a role for
p16INK4a
in lung cancer predisposition and development.
...
PMID:Cdkn2a encodes functional variation of p16INK4a but not p19ARF, which confers selection in mouse lung tumorigenesis. 1036 10
The
INK4A
and INK4B genes map to 9p21, with the
INK4A
gene encoding two products, p16 and p19ARF. Many neoplasms in which
INK4A
and INK4B genes are altered show deletions involving both genes. Mice carrying a targeted Ink4a deletion develop tumors at an early age. In the present study we examined the genetic alterations affecting the remaining Ink4a allele and the Ink4b gene in tumors arising in heterozygous Ink4a mice. We identified deletion of the remaining Ink4a allele in 7 of 18 (39%) tumors. We also observed deletion of the exon 1beta in 3 cases, one of them presenting this deletion as a unique alteration. In conclusion, the deletion of the remaining Ink4a allele was the alteration most frequently observed, representing the inactivation of two proteins capable of arresting the cell cycle through different pathways that involve the tumor suppressors pRB and
p53
.
...
PMID:Involvement of the Ink4a gene (p16 and p19arf) in murine tumorigenesis. 1037 89
The G1 cell cycle checkpoint regulates entry into S phase for normal cells. Components of the G1 checkpoint, including retinoblastoma (Rb) protein, cyclin D1 and
p16INK4a
, are commonly altered in human malignancies, abrogating cell cycle control. Using immunohistochemistry, we examined 79 invasive transitional cell carcinomas of the urinary bladder treated by cystectomy, for loss of Rb or
p16INK4a
protein and for cyclin D1 overexpression. As
p53
is also involved in cell cycle control, its expression was studied as well. Rb protein loss occurred in 23/79 cases (29%); it was inversely correlated with loss of
p16INK4a
, which occurred in 15/79 cases (19%). One biphenotypic case, with Rb+p16- and Rb-p16+ areas, was identified as well. Cyclin D1 was overexpressed in 21/79 carcinomas (27%), all of which retained Rb protein. Fifty of 79 tumours (63%) showed aberrant accumulation of
p53 protein
;
p53
staining did not correlate with Rb,
p16INK4a
, or cyclin D1 status. Overall, 70% of bladder carcinomas showed abnormalities in one or more of the intrinsic proteins of the G1 checkpoint (Rb,
p16INK4a
and cyclin D1). Only 15% of all bladder carcinomas (12/79) showed a normal phenotype for all four proteins. In a multivariate survival analysis, cyclin D1 overexpression was linked to less aggressive disease and relatively favourable outcome. In our series, Rb,
p16INK4a
and
p53
status did not reach statistical significance as prognostic factors. In conclusion, G1 restriction point defects can be identified in the majority of bladder carcinomas. Our findings support the hypothesis that cyclin D1 and
p16INK4a
can cooperate to dysregulate the cell cycle, but that loss of Rb protein abolishes the G1 checkpoint completely, removing any selective advantage for cells that alter additional cell cycle proteins.
...
PMID:G1 checkpoint protein and p53 abnormalities occur in most invasive transitional cell carcinomas of the urinary bladder. 1037 69
The
INK4A
and the INK4B genes map to chromosome 9p21, an area frequently deleted in bladder neoplasms. In addition to the p16 protein, the
INK4A
encodes for a second product, termed p19(ARF). We analyzed tissues from 121 patients with initial Ta and T1 tumors. Deletions of the
INK4A
gene were observed in 17 of 121 (14.1%) cases. Point mutations were identified in 2 of 64 (3.1%) tumors. The
INK4A
-exon 1beta and the INK4B gene were codeleted with
INK4A
in all of the homozygously deleted cases analyzed. The p16 promoter underwent de novo methylation in 7 of 47 (14.9%) evaluable cases. The p16-positive phenotype was observed in 18 of 56 (32%) evaluable cases. p16 negative phenotype correlated with deletion and methylation status. A statistically significant association between
INK4A
homozygous deletions and tumor size was observed (P = 0.003). Patients bearing tumors with
INK4A
homozygous deletions had a lower recurrence-free survival (P = 0.040) than those with wild type
INK4A
. In conclusion, deletions and methylation of the
INK4A
gene occur frequently in superficial bladder tumors. However, only those deletions that affect both the p16 and the p19(ARF), deregulating both the pRb and
p53
pathways, correlated with clinicopathological parameters of worse prognosis.
...
PMID:Deletions of the INK4A gene in superficial bladder tumors. Association with recurrence. 1039 43
Exposure to the carcinogen asbestos is considered to be a major factor contributing to the development of most malignant mesotheliomas (MMs). We highlight the role of asbestos in MM and summarize cytogenetic and molecular genetic findings in this malignancy. The accumulation of numerous clonal chromosomal deletions in most MMs suggests a multistep process of tumorigenesis, characterized by the loss and/or inactivation of multiple tumor suppressor genes (TSGs). Cytogenetic and loss of heterozygosity (LOH) analyses of MMs have demonstrated frequent deletions of specific sites within chromosome arms 1p, 3p, 6q, 9p, 13q, 15q, and 22q. Furthermore, TSGs within two of these regions, i.e.,
p16/CDKN2A
-p14ARF at 9p21 and NF2 at 22q12, are frequently altered in MMs. Homozygous deletion appears to be the major mechanism affecting
p16/CDKN2A
-p14ARF, whereas inactivating mutations coupled with allelic loss occur at the NF2 locus. Finally, recent studies have demonstrated the presence and expression of simian virus 40 (SV40) in many MMs. SV40 large T antigen has been shown to inactivate the TSG products Rb and
p53
, suggesting the possibility that asbestos and SV40 could act as cocarcinogens in MM. The frequent occurrence of homozygous deletions of
p16/CDKN2A
-p14ARF and the ability of SV40 Tag to bind TSG products suggest that perturbations of both Rb- and
p53
-dependent growth-regulatory pathways are critically involved in the pathogenesis of MM.
...
PMID:Asbestos, chromosomal deletions, and tumor suppressor gene alterations in human malignant mesothelioma. 1039 84
Using different molecular techniques, DNA has been detected in the plasma of cancer patients with various types of tumors. We undertook the present study to investigate the presence of plasma DNA, before mastectomy, in patients with breast cancer at diagnosis and to analyze the clinicopathological spectrum of this subgroup of patients with respect to patients without DNA with tumor characteristics. We studied 62 patients with breast cancer, who were selected sequentially after mastectomy and diagnosis of breast carcinomas. Genomic DNA extracted from tumor and normal tissues, normal blood cells, and plasma was used for molecular studies. Alterations in polymorphic markers selected because they had been found to show a high rate of alterations in breast cancer in previous studies (D17S855, D17S654, D16S421, TH2, D10S197, and D9S161), as well as mutations in the
p53
gene and aberrant methylation at the first exon of
p16INK4a
, were used to identify and characterize tumor and plasma DNA. Thirteen clinicopathological parameters were analyzed in each patient. We identified 56 cases (90%) with at least one molecular event in tumor DNA, and 41 cases (66%) with a similar alteration in plasma DNA. Comparison of the clinicopathological parameters between patients with and without plasma DNA revealed significant differences in the axillary involvement, rate of invasive ductal carcinoma, high proliferative index, and the parameter comprised of lymph node metastases, histological grade II, and peritumoral vessel involvement. A high proportion of breast cancer patients exhibited plasma DNA at diagnosis similar to tumor DNA, and its presence correlated significantly with pathological parameters associated with a poor prognosis.
...
PMID:Presence of tumor DNA in plasma of breast cancer patients: clinicopathological correlations. 1039 73
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