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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)
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
We identified a partially sequenced Saccharomyces cerevisiae gene which encodes a protein related to the S. cerevisiae RNA polymerase II subunit,
RPB7
. Several lines of evidence suggest that this related gene, YKL1, encodes the RNA polymerase III subunit C25. C25, like
RPB7
, is present in submolar ratios, easily dissociates from the enzyme, is essential for cell growth and viability, but is not required in certain transcription assays in vitro. YKL1 has ABF-1 and PAC upstream sequences often present in RNA polymerase subunit genes. The sodium dodecyl sulfate-polyacrylamide gel electrophoresis mobility of the YKL1 gene product is equivalent to that of the RNA polymerase III subunit C25. Finally, a C25 conditional mutant grown at the nonpermissive temperature synthesizes tRNA at reduced rates relative to 5.8S rRNA, a hallmark of all characterized
RNA polymerase III
mutants.
...
PMID:C25, an essential RNA polymerase III subunit related to the RNA polymerase II subunit RPB7. 806 49
The Saccharomyces cerevisiae RNA polymerase II subunit gene
RPB7
was isolated and sequenced.
RPB7
is a single copy gene whose sequence predicts a 19,000 Dalton protein of 171 amino acids.
RPB7
is known to dissociate from
RNA polymerase II
as an RPB4/
RPB7
subcomplex in vitro.
RPB7
also appears to interact with
RNA polymerase II
in a manner dependent upon RPB4, since
RNA polymerase II
purified from cells lacking RPB4 also lacks
RPB7
. Previous results have demonstrated that deletion of the RPB4 results in slow growth and cold- and temperature-sensitivity. In contrast, deletion of the
RPB7
gene revealed that it is essential for cell growth and viability. Loss of both the RPB4 and the
RPB7
genes causes lethality. These results suggest that
RPB7
contributes to the function of
RNA polymerase II
in the absence of RPB4 either in a manner independent of its association with the enzyme or by directly binding to the enzyme in a manner independent of its association with RPB4.
...
PMID:RPB7, one of two dissociable subunits of yeast RNA polymerase II, is essential for cell viability. 848 30
The human gene for the seventh largest subunit of
RNA polymerase II
complex,
hsRPB7
was cloned, sequenced and mapped. This complex is an integral part of the transcription-coupled DNA repair mechanism and has been shown to be involved in several human genetic diseases and implicated in many others. The
hsRPB7
gene consists of 8 exons and spans approximately 5.1 kb. Southern blots of genomic and cloned DNA suggest that
hsRPB7
is coded for by a single gene. Using human radiation hybrids and YACs, the gene was localized to 11q13.1, within 70 kb of marker D11S1765. The sequence of the 5' flanking region does not contain a TATA element, but does contain several Sp1 binding sites, an AP-1 site and a novel inverted polymorphic GATA tandem repeat. This novel GATA repeat can be used for linkage analysis. The
hsRPB7
gene seems to be highly conserved among eukaryotic species, showing general sequence conservation to yeast and Drosophila. Northern blot analysis reveals a high degree of tissue-specific expression. For example, adult retina, brain and kidney exhibit a relatively high level of expression. A moderate level of expression is observed in heart, lung, testis, cornea, retinal pigmented epithelium/choroid and placenta with a lower level of expression in the uterus, small intestine and skeletal muscle. A very low level of expression was observed in stomach and liver. Comparison between four fetal and adult tissues also demonstrate a surprising level of developmental specificity. Expression in fetal retina is considerably lower than fetal brain but similar to adult retina.
...
PMID:Human gene for the RNA polymerase II seventh subunit (hsRPB7): structure, expression and chromosomal localization. 925 63
An Arabidopsis cDNA (AtRPB15.9) that encoded a protein related to the RPB4 subunit in yeast
RNA polymerase II
was cloned. The predicted molecular mass of 15.9 kDa for the AtRPB15.9 protein was significantly smaller than 25 kDa for yeast RBP4. In SDS-PAGE, AtRPB15.9 migrated as the seventh or eighth largest subunit (i.e. apparent molecular mass of 14-15 kDa) in Arabidopsis
RNA polymerase II
, whereas RPB4 migrates as the fourth largest subunit (i.e. apparent molecular mass of 32 kDa) in yeast
RNA polymerase II
. Unlike yeast RPB4 and
RPB7
, which dissociate from
RNA polymerase II
under mildly denaturing conditions, plant subunits related to RPB4 and
RPB7
are more stably associated with the enzyme. Recombinant AtRPB15.9 formed stable complexes with AtRPB19.5 (i.e. a subunit related to yeast
RPB7
) in vitro as did recombinant yeast RPB4 and
RPB7
subunits. Stable heterodimers were also formed between AtRPB15. 9 and yeast
RPB7
and between yeast RPB4 and AtRPB19.5.
...
PMID:Two small subunits in Arabidopsis RNA polymerase II are related to yeast RPB4 and RPB7 and interact with one another. 948 92
Under conditions of environmental stress, prokaryotes and lower eukaryotes such as the yeast Saccharomyces cerevisiae selectively utilize particular subunits of
RNA polymerase II
(pol II) to alter transcription to patterns favoring survival. In S. cerevisiae, a complex of two such subunits, RPB4 and
RPB7
, preferentially associates with pol II during stationary phase; of these two subunits, RPB4 is specifically required for survival under nonoptimal growth conditions. Previously, we have shown that
RPB7
possesses an evolutionarily conserved human homolog,
hsRPB7
, which was capable of partially interacting with RPB4 and the yeast transcriptional apparatus. Using this as a probe in a two-hybrid screen, we have now established that hsRPB4 is also conserved in higher eukaryotes. In contrast to
hsRPB7
, hsRPB4 has diverged so that it no longer interacts with yeast
RPB7
, although it partially complements rpb4- phenotypes in yeast. However, hsRPB4 associates strongly and specifically with
hsRPB7
when expressed in yeast or in mammalian cells and copurifies with intact pol II. hsRPB4 expression in humans parallels that of
hsRPB7
, supporting the idea that the two proteins may possess associated functions. Structure-function studies of hsRPB4-
hsRPB7
are used to establish the interaction interface between the two proteins. This identification completes the set of human homologs for RNA pol II subunits defined in yeast and should provide the basis for subsequent structural and functional characterization of the pol II holoenzyme.
...
PMID:Analysis of the interaction of the novel RNA polymerase II (pol II) subunit hsRPB4 with its partner hsRPB7 and with pol II. 952 65
As a result of the t(11;22)(q24;q12) chromosomal translocation characterizing the Ewing family of tumors (ET), the amino terminal portion of EWS, an RNA binding protein of unknown function, is fused to the DNA-binding domain of the ets transcription factor Fli1. The hybrid EWS-Fli1 protein acts as a strong transcriptional activator and, in contrast to wildtype Fli1, is a potent transforming agent. Similar rearrangements involving EWS or the highly homologous TLS with various transcription factors have been found in several types of human tumors. Employing yeast two-hybrid cloning we isolated the seventh largest subunit of human
RNA polymerase II
(
hsRPB7
) as a protein that specifically interacts with the amino terminus of EWS. This association was confirmed by in vitro immunocoprecipitation. In nuclear extracts,
hsRPB7
was found to copurify with EWS-Fli1 but not with Fli1. Overexpression of recombinant
hsRPB7
specifically increased gene activation by EWS-chimeric transcription factors. Replacement of the EWS portion by
hsRPB7
in the oncogenic fusion protein restored the transactivating potential of the chimera. Our results suggest that the interaction of the amino terminus of EWS with
hsRPB7
contributes to the transactivation function of EWS-Fli1 and, since
hsRPB7
has characteristics of a regulatory subunit of
RNA polymerase II
, may influence promoter selectivity.
...
PMID:Oncogenic EWS-Fli1 interacts with hsRPB7, a subunit of human RNA polymerase II. 970 26
Rpb4 and Rpb7 are two yeast
RNA polymerase II
(Pol II) subunits whose mechanistic roles have recently started to be deciphered. Although previous data suggest that Rpb7 can stably interact with Pol II only as a heterodimer with Rpb4,
RPB7
is essential for viability, whereas RPB4 is essential only during some stress conditions. To resolve this discrepancy and to gain a better understanding of the mode of action of Rpb4, we took advantage of the inability of cells lacking RPB4 (rpb4Delta, containing Pol IIDelta4) to grow above 30 degrees C and screened for genes whose overexpression could suppress this defect. We thus discovered that overexpression of
RPB7
could suppress the inability of rpb4Delta cells to grow at 34 degrees C (a relatively mild temperature stress) but not at higher temperatures. Overexpression of
RPB7
could also partially suppress the cold sensitivity of rpb4Delta strains and fully suppress their inability to survive a long starvation period (stationary phase). Notably, however, overexpression of RPB4 could not override the requirement for
RPB7
. Consistent with the growth phenotype, overexpression of
RPB7
could suppress the transcriptional defect characteristic of rpb4Delta cells during the mild, but not during a more severe, heat shock. We also demonstrated, through two reciprocal coimmunoprecipitation experiments, a stable interaction of the overproduced Rpb7 with Pol IIDelta4. Nevertheless, fewer Rpb7 molecules interacted with Pol IIDelta4 than with wild-type Pol II. Thus, a major role of Rpb4 is to augment the interaction of Rpb7 with Pol II. We suggest that Pol IIDelta4 contains a small amount of Rpb7 that is sufficient to support transcription only under nonstress conditions. When
RPB7
is overexpressed, more Rpb7 assembles with Pol IIDelta4, enough to permit appropriate transcription also under some stress conditions.
...
PMID:Rpb7 can interact with RNA polymerase II and support transcription during some stresses independently of Rpb4. 1008 33
Rpb4p and Rpb7p are two subunits of the yeast
RNA polymerase II
, which form a subcomplex that can dissociate from the enzyme in vitro. Whereas
RPB7
is essential, RPB4 is dispensable for cellular viability. However, the rpb4 null mutant is heat-sensitive, and it has been suggested that Rpb4p is an essential component for cellular stress response. To examine this hypothesis, we used two-dimensional gel electrophoresis to analyze the protein expression pattern of the rpb4 null mutant in response to heat shock, oxidative stress, osmotic stress, and in the post-diauxic phase. We show that this mutant is not impaired in stress induced transcriptional activation: the absence of heat shock response of the mutant is due to a general defect in
RNA polymerase II
activity at high temperature. Under this condition, Rpb4p is necessary to maintain the polymerase activity in vivo. The heat growth defect of the rpb4 null mutant can be partially suppressed by overexpression of
RPB7
, suggesting that Rpb4p maintains or stabilizes Rpb7p in the
RNA polymerase
. We also demonstrate that rpb4 null mutant is an appropriate tool to analyze the involvement of transcriptional events in the survival and adaptation to heat shock or other stresses.
...
PMID:Rpb4p is necessary for RNA polymerase II activity at high temperature. 1042 37
Upon binding retinoic acid (RA), the retinoic acid receptors (RARs) are able to positively and negatively regulate transcription. It has been shown that the DNA-binding domain and carboxy terminus of RARs are necessary for the ligand-dependent ability of the receptor to repress AP-1 transcriptional activity. A fusion of these two regions, shown to constitutively inhibit AP-1 activity, was used in a yeast two-hybrid screen to identify a novel hRARalpha-interacting protein. This protein,
hsRPB7
, a subunit of
RNA polymerase II
, interacts with hRARalpha in the absence of RA and addition of RA disrupts the interaction. Truncation analysis indicates that
hsRPB7
specifically interacts with the hRARalpha DNA-binding domain. This interaction appears to compromise transcription, since overexpressed hRARalpha, in the absence of RA, is able to repress the activity of several
RNA polymerase II
-dependent activators, including AP-1 and the glucocorticoid receptor. This repression is relieved by transfected
hsRPB7
, strongly suggesting that ligand-free hRARalpha can block AP-1 activity by sequestering
hsRPB7
. The repression is dependent on the integrity of the hRARalpha DBD, since a mutation within the DBD blocks both the hRARalpha-
hsRPB7
interaction and ligand-free hRARalpha repression of AP-1. These results provide evidence that non-liganded hRARalpha can regulate transcription by directly interacting with
RNA polymerase II
, and thus suggest a novel pathway by which hRARalpha can cross-talk with AP-1 and perhaps other families of transcriptional activators.
...
PMID:Ligand-free RAR can interact with the RNA polymerase II subunit hsRPB7 and repress transcription. 1048 92
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