Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:2.7.7.6 (RNA polymerase)
 34,946 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A role for human papilloma virus (HPV) infection in the pathogenesis of head and neck neoplasms has gained support in recent years. Expression of two early-region HPV genes, E6 and E7, is widely accepted as essential for viral-induced carcinomas of the genital tract. These oncoproteins interact with the products of the cellular tumor suppressor genes, p53 and retinoblastoma, and inactivate them. Examining E6/E7 transforming gene expression is an important step toward elucidating the pathogenesis of HPV in head and neck neoplasms. We introduce nasal inverted papilloma (IP) as a novel system for evaluating viral genomic expression and transforming gene regulation of tumorigenesis by virtue of its association to HPV infection and potential for malignant progression. We describe here a reverse transcriptase-polymerase chain reaction approach for the detection of HPV E6/E7-specific transcripts in RNA extracted from IR. A primer pair flanking previously mapped HPV 6 E6/E7 splice donor/acceptor sites was used to direct amplification of cDNA. Reverse transcriptase-polymerase chain reaction experiments generated products representing the 1.2 Kb E1E4 splice transcript and a smaller unclassified fragment in IP from two patients. These results provide evidence for HPV 6 E6/E7 expression in IP with the potential to encode transforming proteins.
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PMID:The HPV 6 E6/E7 transforming genes are expressed in inverted papilloma. 952 9

Adenovirus type 12 (Ad12) infection of human cells induces four chromosomal fragile sites corresponding to the U1 small nuclear RNA (snRNA) genes (the RNU1 locus), the U2 snRNA genes (RNU2), the U1 snRNA pseudogenes (PSU1), and the 5S rRNA genes (RN5S). Ad12-induced fragility of the RNU2 locus requires U2 snRNA transcriptional regulatory elements and viral early functions but not viral replication or integration, or chromosomal sequences flanking the RNU2 locus. We now show that Ad12 cannot induce the RNU1, RNU2, or PSU1 fragile sites in Saos-2 cells lacking the p53 and retinoblastoma (Rb) proteins but that viral induction of fragility is rescued in these cells when the expression of wild-type p53 or selected hot-spot mutants (i.e., V143A, R175H, R248W, and R273H) is restored by transient expression or stable retroviral transduction. We also observed weak constitutive fragility of the RNU1 and RNU2 loci in cells belonging to xeroderma pigmentosum complementation groups B and D (XPB and XPD) which are partially defective in the ERCC2 (XPD) and ERCC3 (XPB) helicase activities shared between the repairosome and the RNA polymerase H basal transcription factor TFIIH. We propose a model for Ad12-induced chromosome fragility in which interaction of p53 with the Ad12 E1B 55-kDa transforming protein (and possibly E4orf6) induces a p53 gain of function which ultimately perturbs the RNA polymerase II basal transcription apparatus. The p53 gain of function could interfere with chromatin condensation either by blocking mitotic shutdown of U1 and U2 snRNA transcription or by phenocopying global or local DNA damage. Specific fragilization of the RNU1, RNU2, and PSU1 loci could reflect the unusually high local concentration of strong transcription units or the specialized nature of the U1 and U2 snRNA transcription apparatus.
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PMID:Adenovirus type 12-induced fragility of the human RNU2 locus requires p53 function. 955 7

p53 is a major tumour suppressor that is inactivated in a large proportion of human cancers. We show that p53 serves as a general repressor of transcription by RNA polymerase (pol) III. It can inhibit the synthesis of a range of essential small cellular RNAs including tRNA, 5S rRNA and U6 snRNA, as well as viral products such as the adenovirus VAI RNA. Fibroblasts derived from p53 knock-out mice display a substantial increase in pol III transcriptional activity. Endogenous cellular p53 is shown to interact with the TATA-binding protein (TBP)-containing general factor TFIIIB, thereby compromising its function severely. However, assembly of TFIIIB into a pre-initiation complex confers substantial protection against the inhibitory effects of p53. Since TFIIIB is an essential determinant of the biosynthetic capacity of cells, its release from repression by p53 may contribute to a loss of growth control during the development of many tumours.
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PMID:p53 is a general repressor of RNA polymerase III transcription. 960 93

A human T-acute lymphoblastic leukemia (ALL) cell line (Loucy), derived from cells from a patient with resistant ALL with a t(16:20) and 5q- chromosomal aberrations was evaluated for p53 gene alterations and expression. Western blot analysis of p53 showed elevated levels of the protein. Reverse transcriptase-polymerase chain reaction (RT-PCR) analysis and direct sequencing identified a point mutation at codon 272 (GTG --> ATG) of the p53 gene. Possible molecular mechanisms underlying these alterations and their role in the establishment of this cell line and in leukemogenesis in general are discussed.
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PMID:P53 gene mutation in a T-acute lymphoblastic leukemia cell line (loucy) with t(16:20) and 5q- chromosomal aberrations. 964 74

Cells expressing the R273H mutant of p53, which lacks sequence specific DNA binding capacity, do not undergo cell cycle arrest in G1 following exposure to ionizing or UV radiation because of their inability to induce p21Waf1/Cip1, a cyclin-dependent kinase inhibitor and downstream mediator of p53-dependent DNA damage-induced growth arrest. Following UV-irradiation or treatment with an inhibitor of RNA pol II, we observed a rapid induction of the apoptotic process, as evidenced by DNA fragmentation and the proteolytic cleavage of poly(ADP-ribose) polymerase. Using mimosine, a p21Waf1/Cip1 inducer that bypasses the requirement for transcriptional transactivation by p53, we demonstrated that a G1 cell cycle arrest can prevent apoptosis following UV-irradiation or treatment with an RNA polymerase 11 inhibitor. Serum starvation, which also synchronized cells in G1 but did not induce p21Waf1/Cip1, did not protect cells from apoptosis. These results demonstrate that restoring a late G1 checkpoint by inducing p21Waf1/Cip1 expression can protect cells from DNA damage induced apoptosis. Our results suggest that p21Waf1/Cip1 can interrupt the apoptotic process at a point downstream from p53 accumulation but upstream from caspase-3 activation.
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PMID:p21-induced cycle arrest in G1 protects cells from apoptosis induced by UV-irradiation or RNA polymerase II blockage. 969 54

Tumor cells frequently lack the p53 tumor suppressor because p53 mediates apoptosis in these cells. We report here that c-Abl, and to a greater extent a c-Abl mutant defective for DNA-binding, can provoke programmed cell death in p53-deficient tumor cells. Tyrosine kinase mutant K290R is less cytotoxic. In contrast, a C-terminal deletion mutant that lacks the RNA polymerase 11 (PolII)/actin interaction domain, fails to mediate apoptosis unless expressed to very high levels. Cytotoxicity is overcome by coexpression of the apoptosis antagonist E1B 19K protein, and partially overcome by full-length retinoblastoma protein (Rb) or the C pocket fragment of Rb (SEA) that associates with c-Abl. c-Abl is also highly toxic to Saos-2 cells that are deficient for both Rb and p53, indicating that cell death is not the result of inhibition through c-Abl of the anti-apoptotic function of Rb. Finally, p53 and c-Abl combined induce apoptosis stronger than either protein alone. Unlike c-Abl-mediated cell death, apoptosis by p53 is antagonized efficiently only by full-length Rb with intact A/B pocket but not by SEA. Mutant p53 inhibits apoptosis by p53 but not c-Abl. Thus, c-Abl with intact kinase and PolII/ actin-binding domains can affect tumor cell survival independently of Rb and p53.
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PMID:c-Abl tyrosine kinase can mediate tumor cell apoptosis independently of the Rb and p53 tumor suppressors. 970 21

Poly(ADP-ribosyl) transferase (ADPRT) is a nuclear protein that modifies proteins by forming and attaching to them poly(ADP-ribose) chains. Poly(ADP-ribosyl)ation represents an event of major importance in perturbed cell nuclei and participates in the regulation of fundamental processes including DNA repair and transcription. Although ADPRT serves as a positive cofactor of transcription, initiation of its catalytic activity may cause repression of RNA polymerase II-dependent transcription. It is demonstrated here that ADPRT-dependent silencing of transcription involves ADP-ribosylation of the TATA-binding protein. This modification occurs only if poly(ADP-ribosyl)ation is initiated before TATA-binding protein has bound to DNA and thereby prevents formation of active transcription complexes. Specific DNA binding of other transcription factors including Yin Yang 1, p53, NFkappaB, Sp1, and CREB but not c-Jun or AP-2 is similarly affected. After assembly of transcription complexes initiation of poly(ADP-ribosyl)ation does not influence DNA binding of transcription factors. Accordingly, if bound to DNA, transcription factors are inaccessible to poly(ADP-ribosyl)ation. Thus, poly(ADP-ribosyl)ation prevents binding of transcription factors to DNA, whereas binding to DNA prevents their modification. Considering its ability to detect DNA strand breaks and stimulate DNA repair, it is proposed that ADPRT serves as a molecular switch between transcription and repair of DNA to avoid expression of damaged genes.
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PMID:Regulation of RNA polymerase II-dependent transcription by poly(ADP-ribosyl)ation of transcription factors. 982 23

The growth suppressor p53 is an important key element which controls cell cycle progression in response to cellular stress like DNA damage. Its ability to act as transcriptional activator or repressor links transcription and cell cycle control. Several target genes selectively transactivated by p53 are implicated in growth control, apoptosis and DNA repair. Here we report the interaction of p53 with another important dual player of cell cycle control and transcription, the protein kinase complex CDK7/cyclin H/Mat1 (CDK activating kinase, CAK kinase). This is implicated in the activating phosphorylation of CDK2/cyclin A kinase required to allow cells to proceed through the G1/S transition, and on the other hand, as a component of the basal transcription factor TFIIH found to be necessary for CTD phosphorylation of RNA polymerase II in order to allow elongation of transcription. Based on previous binding studies of p53 with other C-terminal interaction partners of p53 we demonstrate a direct physical interaction of p53 with cyclin H in vitro and in vivo. As a consequence of this interaction we tested the influence of p53 on the kinase activity of CAK kinase for CTD and CDK2 phosphorylation. The addition of wild type p53 to the kinase reactions resulted in a significant downregulation of CDK2 phosphorylation and CTD phosphorylation by the CDK activating kinase. On the other hand addition of a mutant p53His175 failed to downregulate CDK2 and CTD phosphorylation by the CDK activating kinase. In an attempt to support our findings in vivo we measured CAK kinase activity in p21-/- and p53-/- mice embryonal fibroblasts under conditions when p53 gets activated by irradiation. In the case of p21-/- cells this led to a significant reduction of CTD phosphorylation activity of the CDK activating kinase by irradiation of the cells. On the other hand in p53 cells no downregulation of CTD phosphorylation activity of CAK kinase was observed indicating that this kind of negative regulation of CAK kinase activity is exclusively due to a functional p53. These findings imply a direct involvement of p53 in triggering growth arrest by its interaction with the CDK activating kinase complex without the need of cyclin-dependent kinase inhibitors (CKIs) and potentially suggest a new mechanism for p53-dependent apoptosis.
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PMID:Regulation of CAK kinase activity by p53. 984 Sep 37

The mechanisms by which the p53 response is triggered following exposure to DNA-damaging agents have not yet been clearly elucidated. We and others have previously suggested that blockage of RNA polymerase II may be the trigger for induction of the p53 response following exposure to ultraviolet light. Here we report on the correlation between inhibition of mRNA synthesis and the induction of p53, p21WAF1 and apoptosis in diploid human fibroblasts treated with either UV light, cisplatin or the RNA synthesis inhibitors actinomycin D, DRB, H7 and alpha-amanitin. Exposure to ionizing radiation or the proteasome inhibitor LLnL, however, induced p53 and p21WAF1 without affecting mRNA synthesis. Importantly, induction of p53 by the RNA synthesis or proteasome inhibitors did not correlate with the induction of DNA strand breaks. Furthermore, cisplatin-induced accumulation of active p53 in repair-deficient XP-A cells occurred despite the lack of DNA strand break induction. Our results suggest that the induction of the p53 response by certain toxic agents is not triggered by DNA strand breaks but rather, may be linked to inhibition of mRNA synthesis either directly by the poisoning of RNA polymerase II or indirectly by the induction of elongation-blocking DNA lesions.
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PMID:Inhibition of RNA polymerase II as a trigger for the p53 response. 998 8

Induction of the tumor suppressor protein p53 restricts cellular proliferation. Since actively growing cells require the ongoing synthesis of ribosomal RNA to sustain cellular biosynthesis, we studied the effect of p53 on ribosomal gene transcription by RNA polymerase I (Pol I). We have measured rDNA transcriptional activity in different cell lines which either lack or overexpress p53 and demonstrate that wild-type but not mutant p53 inhibits cellular pre-rRNA synthesis. Conversely, pre-rRNA levels are elevated both in cells which express mutant p53 and in fibroblasts from p53 knock-out mice. Transient transfection assays with a set of rDNA deletion mutants demonstrate that intergenic spacer sequences are dispensable and the minimal rDNA promoter is sufficient for p53-mediated repression of Pol I transcription. However, in a cell-free transcription system, recombinant p53 does not inhibit rDNA transcription, indicating that p53 does not directly interfere with the basal Pol I transcriptional machinery. Thus, repression of Pol I transcription by p53 may be a consequence of p53-induced growth arrest.
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PMID:p53 represses ribosomal gene transcription. 1002 89


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