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Query: EC:2.7.7.6 (
RNA polymerase
)
34,946
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The largest subunit of mammalian
RNA polymerase II
contains at its C terminus an unusual domain consisting of multiple tandem repeats of the seven-amino acid consensus sequence Tyr-Ser-Pro-Thr-Ser-Pro-Ser. This domain is unphosphorylated in
RNA polymerase
IIA and extensively phosphorylated in
RNA polymerase
IIO. To investigate the role of the C-terminal domain and the functional significance of its phosphorylation, changes in the level of phosphorylation were followed as a function of the position of
RNA polymerase II
in the transcription cycle. Complexes were formed with 32P-labeled
RNA polymerase
IIA and separated from the free polymerase by gel filtration. The phosphorylation state of the
RNA polymerase II largest subunit
was determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Results indicate that
RNA polymerase
IIA interacts with the template-committed complex to form a stable preinitiation complex.
RNA polymerase
IIA associated with such complexes is converted to
RNA polymerase
IIO in the presence of ATP prior to the formation of the first phosphodiester bond. Furthermore, the observation that purified preinitiation complexes can catalyze the conversion of
RNA polymerase
IIA to IIO indicates that the protein kinase(s) responsible for phosphorylation of the C-terminal domain is a component of such complexes. The concentration of ATP required for the phosphorylation of
RNA polymerase II
associated with the preinitiation complex is two to three orders of magnitude lower than that required for the conversion of
RNA polymerase
IIA to IIO free in solution. These results support the idea that phosphorylation of the C-terminal domain of RNA polymerase subunit IIa occurs subsequent to the association of enzyme with the promoter and prior to the initiation of transcription.
...
PMID:Phosphorylation of RNA polymerase IIA occurs subsequent to interaction with the promoter and before the initiation of transcription. 237 91
Purified eukaryotic nuclear
RNA polymerase II
consists of three subspecies that differ in the apparent molecular masses of their largest subunit, designated IIo, IIa, and IIb for polymerase species IIO, IIA, and IIB, respectively. Subunits IIo, IIa, and IIb are the products of a single gene. We present here the amino acid composition of calf thymus subunits IIa and IIb and the C-terminal amino acid sequence of subunit IIa (IIo) inferred from the nucleotide sequence of part of the mouse gene encoding this RNA polymerase subunit. The calculated amino acid composition of the peptide unique to subunit IIa indicates that subunit IIa contains a domain rich in serine, proline, threonine, and tyrosine. The sequence at the 3' end of the mouse
RNA polymerase II largest subunit
gene reveals that the C-terminal domain consists of 52 repeats of a seven amino acid block with the consensus sequence Tyr-Ser-Pro-Thr-Ser-Pro-Ser. This sequence is also unusual in that it contains a high percentage of potential phosphorylation sites.
...
PMID:A unique structure at the carboxyl terminus of the largest subunit of eukaryotic RNA polymerase II. 299 85
The carboxyl-terminal domain (CTD) of the mouse
RNA polymerase II largest subunit
consists of 52 repeats of a seven-amino-acid block with the consensus sequence Tyr-Ser-Pro-Thr-Ser-Pro-Ser. A genetic approach was used to determine whether the CTD plays an essential role in
RNA polymerase
function. Deletion, insertion, and substitution mutations were created in the repetitive region of an alpha-amanitin-resistant largest-subunit gene. The effects of these mutations on
RNA polymerase II
activity were assayed by measuring the ability of mutant genes to confer alpha-amanitin resistance after transfection of susceptible rodent cells. Mutations that resulted in CTDs containing between 36 and 78 repeats had no effect on the transfer of alpha-amanitin resistance, whereas mutations with 25 or fewer repeats were inactive in this assay. Mutations that contained 29, 31, or 32 repeats had an intermediate effect; the number of alpha-amanitin-resistant colonies was lower and the colonies obtained were smaller, indicating that the mutant
RNA polymerase II
was defective. In addition, not all of the heptameric repeats were functionally equivalent in that repeats that diverged in up to three amino acids from the consensus sequence could not substitute for the conserved heptamer repeats. We concluded that the CTD is essential for
RNA polymerase II
activity, since substantial mutations in this region result in loss of function.
...
PMID:Genetic analysis of the repetitive carboxyl-terminal domain of the largest subunit of mouse RNA polymerase II. 327 73
RNA polymerase II
is inhibited by the mushroom toxin alpha-amanitin. A mouse BALB/c 3T3 cell line was selected for resistance to alpha-amanitin and characterized in detail. This cell line, designated A21, was heterozygous, possessing both amanitin-sensitive and -resistant forms of
RNA polymerase II
; the mutant form was 500 times more resistant to alpha-amanitin than the sensitive form. By using the wild-type mouse
RNA polymerase II largest subunit
(RPII215) gene (J.A. Ahearn, M.S. Bartolomei, M. L. West, and J. L. Corden, submitted for publication) as the probe, RPII215 genes were isolated from an A21 genomic DNA library. The mutant allele was identified by its ability to transfer amanitin resistance in a transfection assay. Genomic reconstructions between mutant and wild-type alleles localized the mutation to a 450-base-pair fragment that included parts of exons 14 and 15. This fragment was sequenced and compared with the wild-type sequence; a single AT-to-GC transition was detected at nucleotide 6819, corresponding to an asparagine-to-aspartate substitution at amino acid 793 of the predicted protein sequence. Knowledge of the position of the A21 mutation should facilitate the study of the mechanism of alpha-amanitin resistance. Furthermore, the A21 gene will be useful for studying the phenotype of site-directed mutations in the RPII215 gene.
...
PMID:Localization of an alpha-amanitin resistance mutation in the gene encoding the largest subunit of mouse RNA polymerase II. 382 24
To understand the in vivo function of the unique and conserved carboxy-terminal repeat domain (CTD) of
RNA polymerase II largest subunit
(RpII215), we have studied
RNA polymerase II
biosynthesis, activity and genetic function in Drosophila RpII215 mutants that possessed all (C4), half (W81) or none (IIt) of the CTD repeats. We have discovered that steady-state mRNA levels from transgenes encoding a fully truncated, CTD-less subunit (IIt) are essentially equal to wild-type levels, whereas the levels of the CTD-less subunit itself and the amount of polymerase harboring it (Pol IIT) are significantly lower than wild type. In contrast, for the half-CTD mutant (W81), steady-state mRNA levels are somewhat lower than for wild type or IIt, while W81 subunit and polymerase amounts are much less than wild type. Finally, we have tested genetically the ability of CTD mutants to complement (rescue) partially functional RpII215 alleles and have found that IIt fails to complement whereas W81 complements partially to completely. These results suggest that removal of the entire CTD renders polymerase completely defective in vivo, whereas eliminating half of the CTD results in a polymerase with significant in vivo activity.
...
PMID:Functional studies of the carboxy-terminal repeat domain of Drosophila RNA polymerase II in vivo. 749 40
Using a screen to identify human genes that promote pseudohyphal conversion in Saccharomyces cerevisiae, we obtained a cDNA encoding hsRPB7, a human homologue of the seventh largest subunit of yeast
RNA polymerase II
(RPB7). Overexpression of yeast RPB7 in a comparable strain background caused more pronounced cell elongation than overexpression of hsRPB7. hsRPB7 sequence and function are strongly conserved with its yeast counterpart because its expression can rescue deletion of the essential RPB7 gene at moderate temperatures. Further, immuno-precipitation of
RNA polymerase II
from yeast cells containing hsRPB7 revealed that the hsRPB7 assembles the complete set of 11 other yeast subunits. However, at temperature extremes and during maintenance at stationary phase, hsRPB7-containing yeast cells lose viability rapidly, stress-sensitive phenotypes reminiscent of those associated with deletion of the RPB4 subunit with which RPB7 normally complexes. Two-hybrid analysis revealed that although hsRPB7 and RPB4 interact, the association is of lower affinity than the RPB4-RPB7 interaction, providing a probable mechanism for the failure of hsRPB7 to fully function in yeast cells at high and low temperatures. Finally, surprisingly, hsRPB7 RNA in human cells is expressed in a tissue-specific pattern that differs from that of the
RNA polymerase II largest subunit
, implying a potential regulatory role for hsRPB7. Taken together, these results suggest that some RPB7 functions may be analogous to those possessed by the stress-specific prokaryotic sigma factor rpoS.
...
PMID:Human RNA polymerase II subunit hsRPB7 functions in yeast and influences stress survival and cell morphology. 757 93
Mutations conferring streptolydigin resistance onto Escherichia coli
RNA polymerase
have been found exclusively in the beta subunit (Heisler, L. M., Suzuki, H., Landick, R., and Gross, C. A. (1993) J. Biol. Chem. 268, 25369-25375). We report here the isolation of a streptolydigin-resistant mutation in the E. coli rpoC gene, encoding the beta' subunit. The mutation is the Phe793-->Ser substitution, which occurred in an evolutionarily conserved segment of the beta' subunit. The homologous segment in the eukaryotic
RNA polymerase II largest subunit
harbors mutations conferring alpha-amanitin resistance. Both streptolydigin and alpha-amanitin are inhibitors of transcription elongation. Thus, the two antibiotics may inhibit transcription in their respective systems by a similar mechanism, despite their very different chemical nature.
...
PMID:Streptolydigin-resistant mutants in an evolutionarily conserved region of the beta' subunit of Escherichia coli RNA polymerase. 759 84
Hyperphosphorylation of the C-terminal heptapeptide repeat domain (CTD) of the
RNA polymerase II largest subunit
has been suggested to play a key role in regulating transcription initiation and elongation. To facilitate investigating functional consequences of CTD phosphorylation we developed new templates, the double G-less cassettes, which make it possible to assay simultaneously the level of initiation and the efficiency of elongation. Using these templates, we examined the effects of yeast CTD kinase I or CTD kinase inhibitors on transcription and CTD phosphorylation in HeLa nuclear extracts. Our results showed that polymerase II elongation efficiency and CTD phosphorylation are greatly reduced by CTD kinase inhibitors, whereas both are greatly increased by CTD kinase I; in contrast, transcription initiation is much less affected. These results demonstrate that CTD kinase I modulates the elongation efficiency of
RNA polymerase II
and are consistent with the idea that one function of CTD phosphorylation is to promote effective production of long transcripts by stimulating the elongation efficiency of
RNA polymerase II
.
...
PMID:Modulation of RNA polymerase II elongation efficiency by C-terminal heptapeptide repeat domain kinase I. 911 Sep 87
In mammalian embryos, zygotic gene transcription initiates after a limited number of cell divisions through a two-step process termed the zygotic gene activation (ZGA). Here we report that
RNA polymerase II
undergoes major changes in mouse and rabbit preimplantation embryos during the ZGA. In transcriptionally inactive unfertilized oocytes, the
RNA polymerase II largest subunit
is predominantly hyperphosphorylated on its carboxy-terminal domain (CTD). The CTD is markedly dephosphorylated several hours after fertilization, before the onset of a period characterized by a weak transcriptional activity. The largest subunit of
RNA polymerase II
then lacks immunological and drug-sensitivity characteristics related to its phosphorylation by the TFIIH-associated kinase and gradually translocates into the nuclei independently of DNA replication and mitosis. A phosphorylation pattern of the largest subunit, close to that observed in somatic cells, is established in both mouse and rabbit embryos at the stage when transcription becomes a requirement for further development (respectively at the 2- and 8/16-cell stage). As these events occurred in the presence of actinomycin D, the nuclear translocation of
RNA polymerase II
and the phosphorylation of the CTD might be major determinants of ZGA.
...
PMID:Nuclear translocation and carboxyl-terminal domain phosphorylation of RNA polymerase II delineate the two phases of zygotic gene activation in mammalian embryos. 932 4
The monoclonal antibody MPM-2 recognizes a subset of M phase phosphoproteins in a phosphorylation-dependent manner. It is believed that phosphorylation at MPM-2 antigenic sites could regulate mitotic events since most of the MPM-2 antigens identified to date have M phase functions. In addition, many of these proteins are substrates of the mitotic regulator Pin1, a peptidyl-prolyl isomerase which is present throughout the cell cycle and which is thought to alter its mitotic targets by changing their conformation. In interphase cells, most MPM-2 reactivity is confined to nuclear speckles. We report here that a hyperphosphorylated form of the
RNA polymerase II largest subunit
is the major MPM-2 interphase antigen. These findings were made possible by the availability of another monoclonal antibody, CC-3, that was previously used to identify a 255 kDa nuclear matrix protein associated with spliceosomal components as a hyperphosphorylated form of the
RNA polymerase II largest subunit
. MPM-2 recognizes a phosphoepitope of the large subunit that becomes hyperphosphorylated upon heat shock in contrast to the phosphoepitope defined by CC-3, whose reactivity is diminished by the heat treatment. Therefore, these two antibodies may discriminate between distinct functional forms of
RNA polymerase II
. We also show that
RNA polymerase II
large subunit interacts with Pin1 in HeLa cells. Pin1 may thus regulate transcriptional and post-transcriptional events by catalyzing phosphorylation-dependent conformational changes of the large RNA polymerase II subunit.
...
PMID:A hyperphosphorylated form of RNA polymerase II is the major interphase antigen of the phosphoprotein antibody MPM-2 and interacts with the peptidyl-prolyl isomerase Pin1. 1039 5
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