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Query: UNIPROT:P43146 (
tumour suppressor
)
5,935
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The p53
tumour suppressor
gene is intensively studied because mutations in this gene are the most common genetic alteration so far identified in human cancer. Considerable emphasis has thus been placed on characterizing the biological differences between mutant and wild-type p53 protein. This has led to the realization that in cultured cells, mutant p53 behaves like an oncogene, whereas wild-type p53 is a tumor suppressor gene. The p53 protein is also a target for the tumour virus oncogene products SV40 large T, adenovirus
E1B
, and human papillomavirus type 16 E6, which are all capable of forming complexes to the p53 protein. Although p53 represents an extremely important cellular regulatory molecule which is well conserved, there exists two allelic variants of wild-type human p53 that differ both in primary and confirmational structure. One variant contains an arginine at amino acid 72 (p53Arg), whereas the other form contains a proline at this residue (p53Pro). The possible implications for more than one allelic variant of wild-type human p53 in the general population is unknown. The present study was undertaken to compare some of the biological features of the different wild-type p53 variants. We present data demonstrating that there was a post-transcriptional selection against accumulation of both variants of wild-type human p53 in 3T3-A31 cells, arguing that both forms are proliferation inhibitory in these cells. Both variants of human p53 were stabilized by SV40 large T, but did not displace mouse p53 from SV40 large T. Neither allelic variant of human p53 was able to reduce significantly SV40-mediated anchorage-independent growth of 3T3-A31 cells.(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:Molecular analysis of different allelic variants of wild-type human p53. 129 28
The p53 gene is contained within 16-20 kb of cellular DNA located on the short arm of human chromosome 17 at position 17p13.1. This gene encodes a 393-amino-acid nuclear phosphoprotein involved in the regulation of cell proliferation. Current evidence suggests that loss of normal p53 function is associated with cell transformation in vitro and development of neoplasms in vivo. More than 50% of human malignancies of epithelial, mesenchymal, haematopoietic, lymphoid, and central nervous system origin analysed thus far, were shown to contain an altered p53 gene. The oncoproteins derived from several tumour viruses, including the SV40 large T antigen, the adenovirus
E1B
protein and papillomavirus E6 protein, as well as specific cellular gene products, e.g. murine double minute-2 (MDM2), were found to bind to the wild-type p53 protein and presumably lead to inactivation of this gene product. Therefore, the inactivation of p53
tumour suppressor
gene is currently regarded as an almost universal step in the development of human cancers. The current data on p53-associated tumourigenesis are briefly discussed in this minireview.
...
PMID:Tumourigenesis associated with the p53 tumour suppressor gene. 839 88
Colorectal cancer (CRC) is the second commonest cause of cancer death in the UK, with greater than 40% of these patients destined to die of the disease despite current medical management. Death is commonly due to liver metastases with sequelae including progressive liver dysfunction. Most patients with liver metastases present with tumours that are unresectable and incurable with existing therapies. The median survival for CRC patients after diagnosis with liver metastases is approximately 6 months or less. The human p53 gene is a
tumour suppressor
gene involved in the control of cell proliferation. Loss of wild-type p53 function is associated with the uncontrolled growth of many types of human cancers. The reintroduction and expression of wild-type p53 into p53 altered tumour cells has been shown to suppress tumour growth or induce apoptosis in both in vitro and in vivo models. In our experience greater than 50% of CRC tumours have p53 alterations. This study seeks to evaluate the safety, biological efficacy and the effectiveness of wtp53-CMV-Ad treatment which is a recombinant adenoviral vector containing the wild-type human p53 gene. It will be administered by infusion via the hepatic artery, for the regional gene therapy of malignant liver tumours. Study patients will have incurable metastatic (CRC) malignant tumours of the liver with evidence of p53 alteration in their liver tumours. In vitro studies have demonstrated p53-specific antiproliferative effects of wtp53-CMV-Ad on human liver tumour cells and in vivo studies have demonstrated p53-specific antiproliferative effects on human liver tumour cells. The vector Ad-p53 is a recombinant, replication-defective adenovirus based on adenovirus serotype 5. It contains a sequence encoding wild-type p53 whose expression is under the control of the human cytomegalovirus immediate early promoter-enhancer. This construct will be growth in 293 cells which contain the adenoviral E1A and
E1B
coding sequences which have been removed from the vector to render it replication defective. The study design is an open-label, non-randomised, single-dose, dose escalation Phase I/II clinical trial anticipated to involve a maximum of 19 patients. wtp53-CMV-Ad will be administered by infusion in a reservoir connected to the hepatic artery, for regional gene therapy (surgically implanted pump) in 3 escalating doses to successive cohorts of 3 patients each until the maximum tolerated dose is determined. Subsequently, 10 patients will be treated with this dose. Regional wtp53-CMV-Ad therapy will be administered as a single bolus infusion via hepatic artery catheter. The route of administration of wtp53-CMV-Ad via hepatic artery infusion is designed to maximise gene therapy exposure to the malignant tumours while minimising exposure to normal tissues outside the liver. The clinical protocol is designed to monitor treatment toxicity. Another objective is to evaluate the biological efficacy, including efficiency and stability of gene transfer by analysis of tumour tissues following therapy. As an important part of this objective the pharmacokinetics of wtp53-CMV-Ad will be studied. Clinical evidence of anti-tumour efficacy will also be collected. In addition, the safety and efficacy of different doses levels of wtp53-CMV-Ad will be studied.
...
PMID:A phase I/II study of hepatic artery infusion with wtp53-CMV-Ad in metastatic malignant liver tumours. 1046 36
The E1 region of adenovirus (Ad) type 5 is capable of transforming cells. According to current concepts, the Ad
E1B
55 kDa (
E1B
55K) protein enables transformed cells to grow by constantly binding and inactivating the p53
tumour suppressor
protein. To test this model, the transcriptional activity of p53 was determined in Ad E1-transformed cells. Surprisingly, it was found that a p53-responsive promoter is highly active in Ad E1-transformed cells and further activated only 3- to 4-fold (compared to 200-fold in p53(-/-) cells) by exogenously expressed p53 or p53mt24-28, a p53 mutant that is transcriptionally active but unable to bind the
E1B
55K. On the other hand, the transient overexpression of
E1B
55K led to a strong downregulation of a p53-responsive promoter relative to its baseline activity in Ad E1-transformed cells but not in p53(-/-) cells. COS-7 cells, transformed by simian virus 40 (SV40), also showed constitutive p53 activity, whereas HeLa cells, transformed with oncogenic human papillomavirus, did not. Upon stable transfection, Ad E1-transformed cells but not p53(-/-) cells gave rise to colonies that expressed exogenous p53 or p53mt24-28 but, nonetheless, grew at near-wild-type rates. It is proposed that
E1B
55K or the SV40 tumour antigen are saturated by the p53 protein, which accumulates in virus-transformed cells, leaving a proportion of active p53 molecules. The transformation of cells by the Ad E1 genes confers permissiveness for active p53, conceivably by inactivating the relevant products of p53 target genes that would otherwise prevent cell growth. Thus, Ad-transformed cells contain and tolerate active p53.
...
PMID:Adenovirus E1-transformed cells grow despite the continuous presence of transcriptionally active p53. 1212 69
Cells transformed by proteins of early regions 1A (E1A) and 1B (
E1B
) of oncogenic adenovirus serotype 12 (Ad12) grow to tumours in syngeneic, immunocompetent rodents. To gain insight into the mechanisms of oncogenic transformation, we point mutated the first splice donor in the Ad12-E1A gene, leading to the loss of the Ad12-E1A(9.5S) and Ad12-E1A(11S/10S) proteins and to a conservative amino acid (aa) exchange at position aa 30 (valine vs. leucine) in the Ad12-E1A(13S) and Ad12-E1A(12S ) proteins. BMK cells transformed by mutant Ad12-E1A (Ad12-E1Am) plus Ad12-
E1B
via retrovirus-mediated gene transfer showed features comparable to wild-type Ad12-E1A (Ad12-E1Awt) plus Ad12-
E1B
-transformed cells: they formed foci in soft agar and produced tumours in immunodeficient nude mice, although after a prolonged latency period. These results suggest that Ad12-E1A(9.5S) and Ad12-E1A(11S/10S) are dispensable for cellular transformation. However, in contrast to Ad12-E1Awt cells, Ad12-E1Am cells failed to grow to tumours in syngeneic, immunocompetent rodents, with the exception of one cell line, which produced tumours in about 50% of the immunocompetent animals. Interestingly, the concentration of the putative
tumour suppressor
and co-activator p300 was elevated in cell lines expressing high levels of Ad12-E1A and Ad12-
E1B
due to an increased half-life. These results indicate that p300 is stabilized in Ad12-E1-transformed BMK cells, probably by a mechanism linked to high expression of Ad12-E1A/
E1B
.
...
PMID:A point mutation in the first splice donor leads to reduced oncogenic properties of the adenovirus serotype 12 E1A gene. 1256 94
Only a small percentage of primary and secondary liver tumours is suitable for surgical resection. Gene therapy represents a novel strategy that seems to be effective both, in vitro and in vivo. The use of
tumour suppressor
gene p53 therapy, suicide gene therapy, immune gene therapy and therapy with replication-competent oncolytic adenoviruses in liver tumours already entered the first clinical trials. In patients with hepatocellular carcinoma, the first clinical trials in phase I and II showed good tolerance and low toxicity to gene therapy. However, the clinical benefit for the patients treated either with wild type p53 or
E1B
deleted adenoviruses were marginal.
...
PMID:[Gene therapy of liver tumors: results of the first clinical studies]. 1460 42
Tumour development is a disease of both somatic and genetic origin. It originates from a combination of oncogene and
tumour suppressor
alterations that force the cell into unprogrammed proliferation. It is reasonable to think that a genetic disease could be cured by gene therapy, and several strategies along this line are presently being employed. The use of retroviruses to carry 'suicide' genes has been the most successful approach to date for the treatment of neurological malignancies. The use of adenoviruses with deletions in the
E1B
region opens a new and elegant possibility for the destruction of tumours deficient in the p53 suppressor gene. Strategies based on the inhibition of angiogenesis are being developed, and those based on blockade of inducers of angiogenesis have given encouraging results in experimental animal models. However, gene therapy has not yet been able to permanently cure a human genetic disease, thereby creating a certain degree of caution among scientists and clinicians.
...
PMID:An overview of gene therapy approaches to neurological malignancies. 1802 May 69
The ability of adenovirus to induce cell transformation depends on the E1A and
E1B
-55K oncoproteins. While E1A functionally inactivates the retinoblastoma
tumour suppressor
,
E1B
-55K primarily interferes with the function of p53. In adenovirus transformed cells
E1B
-55K can directly affect p53-dependent transactivation. In virus-infected cells
E1B
-55K additionally cooperates with the viral E4orf6 protein to induce ubiquitin-dependent degradation of p53. Here we unravel a novel activity of
E1B
-55K by demonstrating that it drastically stimulates the post-translational modification of p53 by the ubiquitin-like SUMO modifier. Consistent with this finding the extent of p53 SUMOylation is highly elevated in adenovirus transformed cell lines.
E1B
-55K-mediated SUMOylation depends on the direct interaction of
E1B
-55K with p53 and additionally requires SUMO modification of
E1B
-55K. These data suggest that
E1B
-55K exploits both ubiquitin and ubiquitin-like systems to target host cell proteins and thus shed new light on the molecular mechanisms of
E1B
- 55K function. Moreover, the data expand the emerging concept of dual-specificity factors that act in both the SUMO and ubiquitin pathway and identify
E1B
-55K as the first viral protein that shares this dual activity.
...
PMID:The adenovirus E1B-55K oncoprotein induces SUMO modification of p53. 1846 21
The
E1B
-55K product from human adenovirus is a substrate of the small ubiquitin-related modifier (SUMO)-conjugation system. SUMOylation of
E1B
-55K is required to transform primary mammalian cells in cooperation with adenovirus E1A and to repress p53
tumour suppressor
functions. The biochemical consequences of SUMO1 conjugation of 55K have so far remained elusive. Here, we report that
E1B
-55K physically interacts with different isoforms of the
tumour suppressor
protein promyelocytic leukaemia (PML). We show that
E1B
-55K binds to PML isoforms IV and V in a SUMO1-dependent and -independent manner. Interaction with PML-IV promotes the localization of 55K to PML-containing subnuclear structures (PML-NBs). In virus-infected cells, this process is negatively regulated by other viral proteins, indicating that binding to PML is controlled through reversible SUMOylation in a timely coordinated manner. These results together with earlier work are consistent with the idea that SUMOylation regulates targeting of
E1B
-55K to PML-NBs, known to control transcriptional regulation, tumour suppression, DNA repair and apoptosis. Furthermore, they suggest that SUMO1-dependent modulation of p53-dependent growth suppression through
E1B
-55K PML-IV interaction has a key role in adenovirus-mediated cell transformation.
...
PMID:SUMO modification of E1B-55K oncoprotein regulates isoform-specific binding to the tumour suppressor protein PML. 2063 99
