EC:2.7.11.1 - FACTA Search

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Query: EC:2.7.11.1 (protein kinase)
81,284 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Using polytene chromosomes of salivary gland cells of Chironomus tentans, phosphorylation state-sensitive antibodies and the transcription and protein kinase inhibitor 5,6-dichloro-1-beta-D-ribofuranosylbenzimidazole (DRB), we have visualized the chromosomal distribution of RNA polymerase II (pol II) with hypophosphorylated (pol IIA) and hyperphosphorylated (pol II0) carboxyl-terminal repeat domain (CTD). DRB blocks labeling of the CTD with 32Pi within minutes of its addition, and nuclear pol II0 is gradually converted to IIA; this conversion parallels the reduction in transcription of protein-coding genes. DRB also alters the chromosomal distribution of II0: there is a time-dependent clearance from chromosomes of phosphoCTD (PCTD) after addition of DRB, which coincides in time with the completion and release of preinitiated transcripts. Furthermore, the staining of smaller transcription units is abolished before that of larger ones. The staining pattern of chromosomes with anti-CTD antibodies is not detectably influenced by the DRB treatment, indicating that hypophosphorylated pol IIA is unaffected by the transcription inhibitor. Microinjection of synthetic heptapeptide repeats, anti-CTD and anti-PCTD antibodies into salivary gland nuclei hampered the transcription of BR2 genes, indicating the requirement for CTD and PCTD in transcription in living cells. The results demonstrate that in vivo the protein kinase effector DRB shows parallel effects on an early step in gene transcription and the process of pol II hyperphosphorylation. Our observations are consistent with the proposal that the initiation of productive RNA synthesis is CTD-phosphorylation dependent and also with the idea that the gradual dephosphorylation of transcribing pol II0 is coupled to the completion of nascent pol II gene transcripts.
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PMID:Phosphorylation dependence of the initiation of productive transcription of Balbiani ring 2 genes in living cells. 860 37

Human immunodeficiency virus types 1 and 2 encode closely related proteins, Tat-1 and Tat-2, that stimulate viral transcription. Previously, we showed that the activation domains of these proteins specifically interact in vitro with a cellular protein kinase named TAK. In vitro, TAK phosphorylates the Tat-2 but not the Tat-1 protein, a 42-kDa polypeptide of unknown identity, and the carboxyl-terminal domain (CTD) of RNA polymerase II (RNAP II). We now show that the 42-kDa substrate of TAK cochromatographs with TAK activity, suggesting that this 42-kDa polypeptide is a subunit of TAK. We also show that the Tat proteins specifically associate with TAK in vivo, since wild-type Tat-1 and Tat-2 proteins expressed in mammalian cells, but not mutant Tat proteins containing a nonfunctional activation domain, can be coimmunoprecipitated with TAK. We also mapped the in vivo phosphorylation sites of Tat-2 to the carboxyl terminus of the protein, but analysis of proteins with mutations at these sites suggests that phosphorylation is not essential for Tat-2 transactivation function. We further investigated whether the CTD of RNAP II is required for Tat function in vivo. Using plasmid constructs that express an alpha-amanitin-resistant RNAP II subunit with a truncated or full-length CTD, we found that an intact CTD is required for Tat function. These observations strengthen the proposal that the mechanism of action of Tat involves the recruitment or activation of TAK, resulting in activated transcription through phosphorylation of the CTD.
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PMID:The human immunodeficiency virus Tat proteins specifically associate with TAK in vivo and require the carboxyl-terminal domain of RNA polymerase II for function. 867 84

Transcription factor IIH (TFIIH) is a multisubunit complex required for transcription and for DNA nucleotide excision repair. TFIIH possesses three enzymatic activities: (i) an ATP-dependent DNA helicase, (ii) a DNA-dependent ATPase, and (iii) a kinase with specificity for the carboxyl-terminal domain of RNA polymerase II. The kinase activity was recently identified as the cdk (cyclin-dependent kinase) activating kinase, CAK, composed of cdk7, cyclin H, and MAT-1. Here we report the isolation and characterization of three distinct CAK-containing complexes from HeLa nuclear extracts: CAK, a novel CAK-ERCC2 complex, and TFIIH. CAK-ERCC2 can efficiently associate with core-TFIIH to reconstitute holo-TFIIH transcription activity. We present evidence proposing a critical role for ERCC2 in mediating the association of CAK with core TFIIH subunits.
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PMID:Human cyclin-dependent kinase-activating kinase exists in three distinct complexes. 869 42

The transcription factor TFIIH continues to be a subject of interest. In addition to its function as a repair and transcription factor, TFIIH includes a cyclin-dependent kinase and a cyclin, which raises the possibility that nucleotide excision repair (NER), RNA polymerase II transcription and cell cycle control are connected. Progress in mechanistic studies of NER include the identification of dual incision activities operating on either side of base damage and the isolation of a repairosome supercomplex in yeast. Additionally, NER has been demonstrated in reconstituted human and yeast systems, both of which include TFIIH.
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PMID:DNA repair and transcription. 872 69

The Kin28 protein kinase interacts physically and genetically with cyclin Ccl1. Kin28 has been reported recently to be involved in the in vivo phosphorylation of the largest subunit of RNA polymerase II (Rpb1) in Saccharomyces cerevisiae. Now, we show that in a strain harboring a conditional ccl1-ts mutation, the C-terminal domain (CTD) of the Rpb1 subunit is under-phosphorylated at restrictive temperature. The transcription of a set of genes, chosen at random, is severely affected in a kin28-ts mutant shifted at restrictive temperature. Here, we report that the same set of genes requires a functional CCL1 gene product to be transcribed. These findings, added to previously published data, establishes that Kin28p is a cyclin-dependent kinase (CDK) with Ccl1p as a companion, both of them being necessary for general transcription and CTD phosphorylation.
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PMID:Ccl1, a cyclin associated with protein kinase Kin28, controls the phosphorylation of RNA polymerase II largest subunit and mRNA transcription. 876 64

The untranslatable, RNA polymerase II-dependent gene (dutA) of Dictyostelium discoideum is induced early in development. However, unlike other early genes, dutA induction was not affected by cAMP pulses and occurred normally in various cAMP-related mutant cells, the results indicating that this induction depended solely on factors other than cAMP. In the knockout strain of the catalytic subunit of protein kinase A, dutA expression was severely blocked and not recovered by cAMP pulses. This demonstrates that even the cAMP-independent gene, dutA, requires protein kinase A for its expression.
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PMID:Expression of Dictyostelium early gene, dutA, is independent of cAMP pulses but dependent on protein kinase A. 876 72

TFIIH is by far the most complex of the basal RNA polymerase II transcription factors. It is a protein kinase, a bi-directional DNA helicase and is essential for both transcription and nucleotide excision repair (NER). Furthermore, the factor can activate cyclin-dependent kinases and so might play a role in cell-cycle regulation. The recent elucidation of the subunit composition of TFIIH has shown an extraordinary conservation of its structure from yeast to human.
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PMID:The multiple roles of transcription/repair factor TFIIH. 887 Apr 99

Previously, we showed that the viral transactivator proteins E1A and VP16 specifically interact with a cellular CTD kinase activity in vitro. We now report that E1A and VP16 complexes contain human CDK8, a newly identified member of the cyclin-dependent kinase family that has been shown to be a component of the RNA polymerase II (RNAP II) holoenzyme complex. The presence of CDK8 in the E1A- and VP16-containing complexes is specific for a functional activation domain of these viral transactivators, strongly suggesting that this association is relevant for the transactivation function of E1A and VP16. We show that CDK8 is associated with CTD kinase activity and that CDK8 co-fractionates with E1A- and VP16-associated CTD kinase activity over several chromatography columns. Therefore, CDK8 is likely responsible for the E1A- and VP16-associated CTD kinase activity. Gel filtration chromatography indicates that the E1A- and VP16-associated CTD kinase activity has a molecular size of approximately 1.5 MDa and contains cyclin C and the human homolog of SRB7 in addition to CDK8. This implies that E1A and VP16 associate with the RNAP II holoenyzme. We also looked at the transcriptional activity of CDK8 and found that CDK8 can function as a transcriptional activator when fused to the DNA binding domain of GAL4. Surprisingly, the ability of GAL4-CDK8 to activate transcription in this assay was not dependent on the kinase activity of CDK8, since a kinase-deficient mutant of CDK8 stimulated transcription nearly as well as wild-type GAL4-CDK8. This suggests that CDK8 may play a role in transcription that is distinct from its ability to function as a CTD kinase.
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PMID:Viral transactivators E1A and VP16 interact with a large complex that is associated with CTD kinase activity and contains CDK8. 887 57

Nuclear transcription is repressed when eukaryotic cells enter mitosis. Using Xenopus egg extracts shifted to the mitotic state with recombinant cyclin B1 protein, we have been able to reproduce mitotic repression of transcription in vitro. Active RNA polymerase III transcription is observed in interphase extracts in the absence of added cyclin, but is strongly repressed by the induction of cdc2/cyclin B (maturation/mitosis promoting factor, MPF) kinase activity in the mitotic extract. Studies with protein kinase inhibitors show that protein phosphorylation is required for repression. Add-back experiments indicate that repression of class III gene transcription is due to inactivation of the transcription factor TFIIIB. TFIIIB is composed of the TATA-box binding protein (TBP) and TBP-associated factors of 75 and 92 kDa. In the present study, we show that TBP and a polypeptide of 92 kDa are substrates of the mitotic kinase in highly purified TF- IIIB fractions. We also show that a phosphatase present in the Xenopus egg extract can reactivate transcription after repression by the mitotic kinases. This result suggests a mechanism for reactivation of transcription after exit from mitosis into the G1 phase of the cell cycle. As for pol III genes, purified cdc2/cyclin B kinase is sufficient to inhibit transcription by RNA polymerase II in a reconstituted transcription system containing the basal transcription factors and polymerase.
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PMID:Repression of RNA polymerase II and III transcription during M phase of the cell cycle. 898 11

The expression of herpes simplex virus 1 gamma (late) genes requires functional alpha proteins (gamma1 genes) and the onset of viral DNA synthesis (gamma2 genes). We report that late in infection after the onset of viral DNA synthesis, cell nuclei exhibit defined structures which contain two viral regulatory proteins (infected cell proteins 4 and 22) required for gamma gene expression, RNA polymerase II, a host nucleolar protein (EAP or L22) known to be associated with ribosomes and to bind small RNAs, including the Epstein-Barr virus small nuclear RNAs, and newly synthesized progeny DNA. The formation of these complexes required the onset of viral DNA synthesis. The association of infected cell protein 22, a highly posttranslationally processed protein, with these structures did not occur in cells infected with a viral mutant deleted in the genes U(L)13 and U(S)3, each of which specifies a protein kinase known to phosphorylate the protein.
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PMID:Association of herpes simplex virus regulatory protein ICP22 with transcriptional complexes containing EAP, ICP4, RNA polymerase II, and viral DNA requires posttranslational modification by the U(L)13 proteinkinase. 899 34

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