Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: UNIPROT:P43146 (tumour suppressor)
 5,935 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The human tumour suppressor protein p53 is critical for regulation of the cell cycle on genotoxic insult. When DNA is damaged by radiation, chemicals or viral infection, cells respond rapidly by arresting the cell cycle. A G1 arrest requires the activity of wild-type p53, as it is not observed in cells lacking functionally wild-type protein, and at least some component of S phase and G2/M arrests is also thought to be p53-dependent. p53 functions as a transcription factor which binds specific DNA sequences, and recently major downstream targets have been identified, including p21Cip1, an inhibitor of the cell cycle kinases that also blocks the replicative but not the repair function of DNA polymerase delta auxiliary factor, PCNA. Current interest focuses on developing novel cancer therapies based on our knowledge of the activity of p53 and p21Cip1 in the cell cycle.
 ...
PMID:Tumour suppressors, kinases and clamps: how p53 regulates the cell cycle in response to DNA damage. 757 91

Infection with specific viruses has a role in the pathogenesis of some cancers in human beings. However, the incidence of such cancers is much lower than the frequency of virus infection, suggesting either that infection alone does not result in cancer and that cellular events in addition to the presence of the virus must occur, or that cancer occurs only if viral proteins are expressed in an appropriate cell type or in an immunocompromised host. Molecular analysis of viruses found in association with cancer has revealed that they function, at least in part, by encoding proteins which can associate with and subvert the function of host cell-encoded tumour suppressor proteins which regulate pathways of growth arrest and apoptosis. Better understanding of the mechanisms underlying this association will have diagnostic, prognostic, and therapeutic implications in the near future.
 ...
PMID:Viral infection and cancer. 747 39

In this study we investigated 56 renal cell carcinomas immunohistochemically for the expression of proliferating cell nuclear antigen (PCNA) and tumour suppressor protein p53. We also analyzed for the presence of human papilloma virus (HPV) DNA subtypes 6, 11, 16, 18, 31 and 33 by in situ hybridization. In carcinomas which showed more than 10% of PCNA positive nuclei there were significantly more cases with invasion (P = 0.032) or metastatic disease (P = 0.047). Nine out of 22 grade III-IV tumours (40.9%) but only six out of 30 grade I-II tumours (20%) showed more than 10% of PCNA positive cells (P = 0.097). Patients with 10% or more PCNA positive cells in kidney tumours had more advanced disease at the time of diagnosis than those showing less PCNA positive cells (P = 0.05). Six p53 positive cases were found among 56 tumours (11%), but only one case had more than 10% positive cell nuclei. The presence of HPV DNA was found in 29 out of 56 cases (52%). Multiple subtypes were found in 19 cases (34%). The most commonly occurring subtypes were 18 and 33. There was no association between PCNA, p53 and the presence of HPV DNA subtypes. Because of the association of PCNA with invasion and metastatic disease, it would be worth while to study PCNA further as a possible marker for aggressiveness of renal carcinomas. Both this study and those concentrated on mutational analysis suggest that p53 is generally not important for the development of renal cell carcinoma. On the other hand, the presence of HPV DNA in these tumours implicates HPV viral infection in the aetiology of renal cancer.
 ...
PMID:Proliferating cell nuclear antigen but not p53 or human papillomavirus DNA correlates with advanced clinical stage in renal cell carcinoma. 783 39

To examine the significance of mutation of the p53 tumour suppressor gene in the development of human hepatocellular carcinoma in a high-prevalence area for hepatitis B viral infection but a low-exposure area for aflatoxin B1, the spectrum of p53 gene mutations was examined in 21 tumour samples from Hong Kong Chinese patients, all of whom were HBsAg positive. DNA sequencing covering exons 5 to 9 of the p53 gene and Hae III restriction enzyme digestion for preliminary assessment of mutation at codon 249 were performed. Immunohistochemical staining with anti-p53 monoclonal antibodies was done on both tumour and nontumour liver tissues. Six tumours (28.6%) showed a p53 mutation and all were point mutations. Of the six point mutations, two (9.5%) were at codon 249 and both were G to T transversions (AGG-->ATG and AGG-->AGT transversions). The remaining point mutations were transversions scattered at codon 172 (exon 5), 214 (exon 6), 273 (exon 8) and 330 (exon 9). Mutated p53 protein was detected in five of these six cases with demonstrable point mutations by DNA sequencing, in contrast to none detected in all of the 15 cases without demonstrable point mutations. The presence of p53 mutations, including those at codon 249, did not show a significant association with tumour size, sex, age, tumour invasiveness in terms of liver invasion, microsatellites and venous permeation, cirrhosis and encapsulation, but tumours with low cellular differentiation tended to have a higher incidence (71%) of point mutations than those with high cellular differentiation (8%). In conclusion, both the overall p53 mutation rate and that a codon 249 in HCC in Hong Kong Chinese are lower than those reported in tumours from China and sub-Saharan Africa. The low mutation rate at codon 249 is compatible with a low aflatoxin exposure. A special type of p53 mutation has not been found to be associated with hepatitis B viral infection. Mutations of p53 gene tends to occur in tumours with low cellular differentiation, suggesting a late occurrence in the event of tumour progression.
 ...
PMID:p53 gene mutation spectrum in hepatocellular carcinomas in Hong Kong Chinese. 810 45

The E6 proteins originating from the tumour-associated Human Papillomavirus (HPV) types 16 and 18 have been shown to bind to and target the tumour suppressor protein, p53, for ubiquitin-mediated degradation. However, in cell lines derived from cervical neoplasias, the predominant early region transcripts are spliced and encode truncated forms of E6, termed E6*. We report here that HPV-18 E6* protein will interact both with the full-length E6 proteins from HPV-16 and HPV-18 and also with E6-AP, and subsequently blocks the association of full length E6 protein with p53. We also show that, as a result of this block, E6* can inhibit E6-mediated degradation of p53 both in vitro and in vivo. The biological consequences of this are increased transcriptional activity on p53-responsive promoters and an inhibition of cell growth in cells transfected with E6*. This is the first report of a potential biological function for this polypeptide and may represent a means by which HPV is able to modulate the activity of the full-length E6 protein with respect to p53 during viral infection.
 ...
PMID:Alternatively spliced HPV-18 E6* protein inhibits E6 mediated degradation of p53 and suppresses transformed cell growth. 923 60

The p53 tumour suppressor protein is a potent transcription factor that plays a major role in the defence against tumour development. p53 exists in a latent form that can be activated by a range of stresses including DNA damage, hypoxia, cytokines, metabolic changes, viral infection, and activated oncogenes. Activation of p53 can lead to cellular growth arrest prior to entry into either S phase or mitosis or can trigger cell death through apoptosis. The modification of p53 by multisite phosphorylation provides a potential link between stress signalling and the regulation of p53 activity, and there is now striking evidence that agents that activate p53 can lead to selective changes in its phosphorylation status. Topologically, the phosphorylation sites in p53 fall into two discrete functional domains. Four phosphorylation events take place within the N-terminal 83 amino acids containing the transactivation domain and a region involved in transcription-independent growth suppression. At least three of these modifications occur in response to agents that cause cellular stress such as DNA damage. At the C-terminus, there are three phosphorylation events, each of which can independently regulate the specific DNA-binding function of p53, suggesting convergent control by different signalling pathways. The multiplicity of these covalent modifications and their responsiveness to a wide range of signals suggest that p53 activity is tightly and coordinately controlled in response to stresses and changes in the cellular environment.
 ...
PMID:Multisite phosphorylation and the integration of stress signals at p53. 960 38

The p53 tumour suppressor protein is a potent transcription factor. p53 is latent in cells and can be activated in response to signals arising from a range of stresses including DNA damage, hypoxia, nucleotide depletion, viral infection and cytokines. Activation of p53 leads either to cellular growth arrest at the G1/S or G2/M transitions of the cell cycle or to programmed cell death (apoptosis). The mechanism of activation of p53 is poorly understood, as are the factors which govern the decision between growth arrest or apoptosis. However, accumulating evidence points to a role for multi-site phosphorylation of p53 in mediating these events. p53 is phosphorylated at different sites within its N-terminal domain by protein kinases which are responsive to UV radiation, cytokines, DNA damage and growth factors. At the C-terminus p53 is phosphorylated by protein kinases involved in growth stimulation, cell cycle control and apoptosis. While little is yet understood about the role of phosphorylation at the N-terminal sites, the C-terminal phosphorylation events are each involved in controlling the specific DNA binding function of p53, perhaps in a coordinate manner, and may also play a role in regulating other functions of p53 such as DNA strand annealing and transcriptional repression. Understanding the control of p53 by multisite phosphorylation may therefore provide essential information concerning the mechanisms of activation of p53, the biological consequences of this activation, and the role of p53 as an integrator of stress signals.
 ...
PMID:Post-translational modification of p53 and the integration of stress signals. 976 44

The p53 tumour suppressor protein has defined roles in G1/S and G2/M cell cycle checkpoints in response to a range of cellular stresses including DNA damage, dominant oncogene expression, hypoxia, metabolic changes and viral infection. In addition to these responses, p53 can also be activated when damage occurs to the mitotic spindle. Initially, spindle damage activates a p53-independent checkpoint which functions at the metaphase-anaphase transition and prevents cells from progressing through mitosis until the completion of spindle formation. Cells eventually escape from this block (a process termed 'mitotic slippage'), and an aberrant mitosis ensues in which sister chromatids fail to segregate properly. After a delay period, p53 responds to this mitotic failure by instituting a G1-like growth arrest, with an intact nucleus containing 4N DNA, but without the cells undergoing division. Cells lacking wild-type p53 are still able to arrest transiently at mitosis, and also fail to undergo division, underscoring that the delay in mitosis is p53-independent. However, these cells are not prevented from re-entering the cell cycle and can reduplicate their DNA unchecked, leading to polyploidy. Additionally, p53-null cells which experience spindle failure often show the appearance of micronuclei arising from poorly segregated chromosomes which have decondensed and been enclosed in a nuclear envelope. The ability of p53 to prevent their formation suggests an additional G2 involvement which prevents nuclear breakdown prior to mitosis. The molecular mechanism by which p53 is able to sense mitotic failure is still unknown, but may be linked to the ability of p53 to regulate duplication of the centrosome, the organelle which nucleates spindle formation.
 ...
PMID:The role of p53 in the response to mitotic spindle damage. 1085 57

The resistance of cancers to conventional therapies has inspired the search for novel strategies. One such approach, namely gene therapy, is based upon the introduction of genes such as those encoding suicide proteins, tumour suppressor proteins or cytokines into tumour cells by means of a genetic vector. The efficiency with which viruses transfer their genes from one host cell to another has led to the widespread use of viruses as genetic vectors. For safety reasons, such virus vectors are generally replication-defective but, unfortunately, this has limited the efficacy of treatment by restricting the number of cells to which the therapeutic gene is delivered. For this reason, the use of replication-competent viruses has been proposed, since virus replication would be expected to lead to amplification and spread of the therapeutic genes in vivo. The replication of many viruses results in lysis of the host cells. This inherent cytotoxicity, together with the efficiency with which viruses can spread from one cell to another, has inspired the notion that replication-competent viruses could be exploited for cancer treatment. Some viruses have been shown to replicate more efficiently in transformed cells but it is unlikely that such examples will exhibit a high enough degree of tumour selectivity, and hence safety, for the treatment of patients. Our increasing knowledge of the pathogenesis of virus disease and the ability to manipulate specific regions of viral genomes have allowed the construction of viruses that are attenuated in normal cells but retain their ability to lyse tumour cells. Such manipulations have included modifying the ability of viruses to bind to, or replicate in, particular cell types, while others have involved the construction of replication-competent viruses encoding suicide proteins or cytokines. Naturally occurring or genetically engineered oncolytic viruses based upon adenovirus, herpes simplex virus, Newcastle disease virus, poliovirus, vesicular stomatitis virus, weasles virus and reovirus have been described. The results of animal studies are encouraging and a number of viruses are now being evaluated in clinical trials.
 ...
PMID:Cytolytic viruses as potential anti-cancer agents. 1184 43

Association of infection with papillomavirus and dysplasia of the cervix uteri has been firmly established. There are only few cervical cancers where no HPV DNA is detectable. The mechanism of epithelial cell immortalization by interaction with tumour suppressor genes p53 and pRb by viral oncogenes E6 and E7 is elucidated. Progression of the HPV infected cell to a malignant phenotype involves further modification of host gene expression and/or mutations. The appearance of chromosomal aberrations can lead to mutational inactivation or loss of tumour suppressor genes (TSG), activation and amplification of oncogenes, with importance for the process of carcinogenesis. Oncogene amplification, with exception of few reports, seems not to be a major mechanism in cervical carcinogenesis. In contrast, cytogenetic and loss of heterozygosity (LOH) results from CIN and invasive cancer demonstrate alterations at specific chromosomal regions, pointing at localisation of TSG. Genetic alterations at chromosomes 3p, 6p, 1lq were frequently found early in tumour development Primary invasive carcinoma showed additional allelic losses at chromosome arms 6q, 17p and 18q. Useful biological diagnostic and prognostic markers for high-risk HPV infection and malignant progression may be p16NK4 p27Kip, and NET-I/C4.8. Putative senescence genes relevant for HPV-induced carcinogenesis are localized on chromosomes 2, 4 and 10. Genes for Telomerase suppression are presumably located on chromosomes 3, 4 and 6. Natural immune responses to HPV infection exist Therefore, immune therapy is an attractive possibility for prevention and therapy of HPV infection. To date, vaccine development has reached clinical evaluation. Prophylaxis aims at the induction of virus neutralizing antibodies to capsid proteins. Virus-like particle vaccines are currently tested in clinical trials. Due to the long lag period between infection and clinical manifestation trials will take a long time until conclusive results are obtained. Mandatory expression of viral and perhaps certain cellular genes in infected epithelial and tumour cells offers targets for therapeutic approaches. Since most dysplasia clears spontaneously the viral infection is immunogenic to some extent. However, in some individuals the immune response has to be stimulated by vaccination in order to be effective. Several strategies are being tested in clinical trials and others are in preclinical development The task will be to circumvent immunosuppressive features of the HPV infected cells.
 ...
PMID:HPV induced cervical carcinogenesis: molecular basis and vaccine development. 1279 44


1 2 3 Next >>