EC:2.7.7.6 - FACTA Search

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)

The gene encoding yeast U6 snRNA that is transcribed by RNA polymerase III (Pol III) contains both a TATA box upstream of the transcription start site and a downstream binding site for the factor TFIIIC. This juxtaposition of elements typical of both Pol II- and Pol III-transcribed genes raises the question of how polymerase specificity is determined. The upstream U6 promoter containing the TATA box and transcription start site was shown previously to be transcribed by Pol III in vitro. We therefore tested whether the upstream promoter of yeast U6 encodes Pol III specificity. One model is that polymerase specificity is conferred by the homologous Pol II and Pol III transcription factors TFIIB and BRF1. However, we found no specificity in the binding of BRF1 or TFIIB to TATA-containing promoters of genes specifically transcribed by Pol III or Pol II. Yeast strains deficient for Pol II or Pol III transcription were employed to examine U6 polymerase specificity in vivo. We find that the U6 upstream promoter is Pol II-specific in vivo and is converted to Pol III specificity by TFIIIC. Thus, preferential recruitment of TFIIIB by TFIIIC probably excludes the Pol II general factors and promotes Pol III transcription, thereby determining polymerase specificity.
...
PMID:TFIIIC determines RNA polymerase III specificity at the TATA-containing yeast U6 promoter. 770 60

The TATA-box-binding protein TBP exists in the cell complexed with different sets of TBP-associated factors (TAFs). In general, each of these TBP-TAF complexes is dedicated to transcription by a single RNA polymerase. Thus, SL1, TFIID and TFIIIB are required for transcription by polymerases I, II and III, respectively. Here we characterize a fourth TBP-TAF complex called SNAPc. Unlike the other TBP-TAF complexes, SNAPc is implicated in transcription by two types of polymerases; it is required for transcription of both the RNA polymerase II and III small-nuclear RNA genes and binds specifically to the proximal sequence element PSE, a non-TATA-box basal promoter element common to these two types of genes. In addition to TBP, SNAPc is composed of at least three TAFs, SNAP43, SNAP45 and SNAP50. The predicted amino-acid sequence of SNAP43 reveals that it corresponds to a new protein.
...
PMID:A TBP-TAF complex required for transcription of human snRNA genes by RNA polymerase II and III. 771 7

We find striking similarities in promoter structure and requirements for template commitment on 5S RNA and tRNA genes from silkworms. The promoters are nearly the same size (approximately 160 bp) and include flanking as well as internal sequences. To analyze the factor requirements for 5S RNA transcription complex assembly in a completely homologous system, we have isolated a silkworm fraction that is highly enriched for the 5S RNA-specific transcription factor, TFIIIA. Using this fraction, together with the other silkworm fractions, TFIIIB, TFIIIC, TFIIID and RNA polymerase III, we demonstrate that the requirements for 5S RNA transcription complex assembly are very similar to those previously established for a tRNA(C)(Ala) gene. Specifically, no individual factor fraction is sufficient for commitment of silkworm 5S RNA genes to transcription complex assembly. Rather, combinations of at least three factor fractions are required. Our observation that more than one subset of factors is competent for commitment suggests that silkworm 5S RNA genes further resemble tRNA(C)(Ala) genes in their ability to use multiple pathways for transcription complex formation.
...
PMID:Silkworm TFIIIA requires additional class III factors for commitment to transcription complex assembly on a 5S RNA gene. 773 3

Transcription of large rRNA precursor and 5S RNA were examined during encystment of Acanthamoeba castellanii. Both transcription units are down regulated almost coordinately during this process, though 5S RNA transcription is not as completely shut down as rRNA transcription. The protein components necessary for transcription of 5S RNA and tRNA were determined, and fractions containing transcription factors comparable to TFIIIA, TFIIIB, and TFIIIC, as well as RNA polymerase III and a 3'-end processing activity, were identified. Regulation of 5S RNA transcription could be recapitulated in vitro, and the activities of the required components were compared. In contrast to regulation of precursor rRNA, there is no apparent change during encystment in the activity of the polymerase dedicated to 5S RNA expression. Similarly, the transcriptional and promoter-binding activities of TFIIIC are not altered in parallel with 5S RNA regulation. TFIIIB transcriptional activity is unaltered in encysting cells. In contrast, both the transcriptional and DNA-binding activities of TFIIIA are strongly reduced in nuclear extracts from transcriptionally inactive cells. These results were analyzed in terms of mechanisms for coordinate regulation of rRNA and 5S RNA expression.
...
PMID:Coordinate regulation of ribosomal component synthesis in Acanthamoeba castellanii: 5S RNA transcription is down regulated during encystment by alteration of TFIIIA activity. 776 Aug 28

The yeast RNA polymerase III system is probably the best-characterized eukaryotic transcription system. Nearly all of the components have been identified and the genes for them cloned. Many of the interactions within initiation complexes are coming to light. Considering the many parallels between Pol III transcription and the other polymerase systems, findings in the Pol III system can act as predictions for Pol II and Pol I transcription. Despite the many advances made in the study of transcription by RNA polymerase III, many important questions remain to be answered. It is unclear what are the functions of individual TFIIIC, TFIIIB and polymerase subunits. Why are so many proteins required? Another extremely important mystery is the mechanism by which the factors assemble. What is the molecular mechanism for TFIIIC recruiting TFIIIB, and how does TFIIIB recruit polymerase? These and many other problems will eventually be solved as researchers apply the biochemical and genetic techniques available in the yeast system.
...
PMID:RNA polymerase III transcription in the yeast Saccharomyces cerevisiae. 776 92

Following protein synthesis inhibition in cycloheximide growth-arrested yeast cells, the rates of tRNA and 5 S RNA synthesis decrease with apparent half-times of about 20 and 10 min, respectively. This effect is mimicked by extracts of treated cells, and the impairment of tRNA gene transcription activity that is observed in vitro parallels the in vivo inactivation of RNA polymerase III transcription. As revealed by experiments in which partially purified class III transcription factors were singly added to extracts of treated cells, only the activity of the multiprotein transcription factor TFIIIB is severely impaired after 3 h of cycloheximide treatment. Similar assays carried out in an in vitro transcription system in which TFIIIB activity was reconstituted by a combination of the TATA box-binding protein (TBP), the 70-kDa component TFIIIB70, plus a partially purified fraction known as B" have shown that the latter two components are both necessary and sufficient to restore control levels of transcription. Their activity, but not TBP activity, is considerably reduced in extracts of treated cells. TFIIIB70 and a component of fraction B" thus appear to be the selective targets of the down-regulation of polymerase III transcription that is brought about by cycloheximide. A substantial depletion of the TFIIIB70 polypeptide was detected by Western immunoblot analysis of extracts derived from cycloheximide growth-arrested cells, indicating that the inactivation of this TFIIIB component results primarily from its enhanced destabilization under conditions of protein synthesis inhibition.
...
PMID:Selective inactivation of two components of the multiprotein transcription factor TFIIIB in cycloheximide growth-arrested yeast cells. 776 51

Transcription of yeast class III genes requires the sequential assembly of the general transcription factors TFIIIC and TFIIIB, and of RNA polymerase III, into an initiation complex composed of at least 25 polypeptides. The 70-kDa subunit of TFIIIB (TFIIIB70) is central in this network of interactions as it contacts both TATA-binding protein and a subunit of polymerase III. We show here that the TATA-binding protein interacts with the carboxyl-terminal part of TFIIIB70. TFIIIB70 also contacts TFIIIC (factor tau) via its tau 131 subunit. The protein domains of tau 131 and TFIIIB70 involved in this interaction, either positively or negatively, were mapped using the two-hybrid system. We provide evidence that intramolecular interactions mask functional domains in both polypeptides.
...
PMID:Complex interactions between yeast TFIIIB and TFIIIC. 779 24

The C31 subunit belongs to a complex of three subunits (C31, C34 and C82) specific to RNA polymerase (pol) III that have no counterparts in other RNA polymerases. This complex is thought to play a role in transcription initiation since it interacts with the general initiation factor TFIIIB via subunit C34. We have obtained a conditional mutation of pol III by partially deleting the acidic C-terminus of the C31 subunit. A Saccharomyces cerevisiae strain carrying this truncated C31 subunit is impaired in in vivo transcription of tRNAs and failed to grow at 37 degrees C. This conditional growth phenotype was suppressed by overexpression of the gene coding for the largest subunit of pol III (C160), suggesting an interaction between C160 and C31. The mutant pol III enzyme transcribed non-specific templates at wild-type rates in vitro, but was impaired in its capacity to transcribe tRNA genes in the presence of general initiation factors. Transcription initiation, but not termination or recycling of the enzyme, was affected in the mutant, suggesting that it could be altered on interaction with initiation factors or on the formation of the open complex. Interestingly, the C-terminal deletion was also suppressed by a high gene dosage of the DED1 gene encoding a putative helicase.
...
PMID:A mutation in the C31 subunit of Saccharomyces cerevisiae RNA polymerase III affects transcription initiation. 783 45

The Saccharomyces cerevisiae U6 RNA gene (SNR6), which is transcribed by RNA polymerase III, has an unusual combination of promoter elements: an upstream TATA box, an intragenic A block, and a downstream B block. In tRNA genes, the A and B blocks are binding sites for the transcription initiation factor TFIIIC, which positions TFIIIB a fixed distance upstream of the A block. However, in vitro transcription of SNR6 with purified components requires neither TFIIIC nor the A and B blocks, presumably because TFIIIB recognizes the upstream sequences directly. Here we demonstrate that TFIIIB placement on SNR6 in vivo is directed primarily by the TFIIIC-binding elements rather than by upstream sequences. We show that the A block is a stronger start site determinant than the upstream sequences when the two are uncoupled by an insertion mutation. Furthermore, while TFIIIC-independent in vitro transcription of SNR6 is highly sensitive to TATA box point mutations, in vivo initiation on SNR6 is only marginally sensitive to such mutations unless the A block is mutated. Intriguingly, a deletion downstream of the U6 RNA coding region that reduces A-to-B block spacing also increases in vivo dependence on the TATA box. Moreover, this deletion results in the appearance of micrococcal nuclease-hypersensitive sites in the TFIIIB chromatin footprint, indicating that TFIIIB binding is disrupted by a mutation 150 bp distant. This and additional chromatin footprinting data suggest that SNR6 is assembled into a nucleoprotein complex that facilitates the TFIIIC-dependent binding of TFIIIB.
...
PMID:TFIIIB placement on a yeast U6 RNA gene in vivo is directed primarily by TFIIIC rather than by sequence-specific DNA contacts. 786 39

The yeast retroviruslike element Ty3 inserts at the transcription initiation sites of genes transcribed by RNA polymerase III (Pol III). An in vitro integration assay was developed with the use of Ty3 viruslike particles and a modified SUP2 tyrosine transfer RNA (tRNA(Tyr)) gene target. Integration was position-specific and required Ty3 integrase, Pol III transcription factor (TF) IIIB-, TFIIIC-, and Pol III-containing fractions showed that TFIIIB and TFIIIC, together, were sufficient for position-specific Ty3 integration, but not for transcription. This report demonstrates that in vitro integration of a retroelement can be targeted by cellular proteins.
...
PMID:Requirement of RNA polymerase III transcription factors for in vitro position-specific integration of a retroviruslike element. 787 62

<< Previous 1 2 3 4 5 6 7 8 9 10 Next >>