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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)
In a reconstituted system consisting of partially purified
RNA polymerase I
(pol I) and the initiation factors TIF-IA,
TIF
-IB, and
TIF
-IC, the nucleolar factor UBF (upstream binding factor) stimulates transcription from the rRNA-encoding DNA (rDNA) promoter at least 50-fold. This activation is not observed at high template concentrations or in the presence of highly purified pol I. Template commitment experiments suggest that UBF activates transcription by relieving inhibition exerted by a negative-acting factor(s) in the polymerase fraction that competes for
TIF
-IB binding to the rDNA promoter and prevents the formation of preinitiation complexes. Using purified histone H1 bound to DNA as a model for the repressed state of the rDNA promoter, we show that UBF counteracts H1-mediated repression of pol I transcription. The implications of these findings are discussed with respect to the protein-protein and protein-DNA interactions at the rDNA promoter and the possible involvement of UBF in control of ribosomal gene transcription.
...
PMID:Dual role of the nucleolar transcription factor UBF: trans-activator and antirepressor. 150 43
The components required for specific transcription of ribosomal RNA were isolated from logarithmically growing Acanthamoeba castellanii. The transcription initiation factor fraction,
TIF
, and
RNA polymerase I
were extracted from whole cells at 0.35 M KCl. The extract was fractionated with polyethylenimine, then chromatographed on phosphocellulose (P11) which resulted in the separation of
TIF
from
RNA polymerase I
. The fractions containing
TIF
were further chromatographed on DEAE cellulose (DE52), Heparin Affigel, and Matrex green agarose, followed by sedimentation through glycerol gradients.
TIF
was purified approximately 17,000-fold, and shown to have a native molecular weight of 289 kD, and to bind specifically to rRNA promoter sequences by DNase I footprinting. The addition of homogeneous
RNA polymerase I
to this complex permitted the initiation of specific transcription in vitro. The phosphocellulose fractions containing
RNA polymerase I
were chromatographed on DEAE cellulose, Heparin-Sepharose, DEAE-Sephadex, and sedimented through sucrose gradients. Polymerase I was purified to apparent homogeneity with a yield of 8.1% and a specific activity of 315. It contained one fewer subunit than previously reported. DNase I protection experiments demonstrated that in both partially purified and homogeneous fractions,
RNA polymerase I
was capable of stable binding to the
TIF
-rDNA complex, and correctly initiating transcription on rDNA templates.
...
PMID:Purification of components required for accurate transcription of ribosomal RNA from Acanthamoeba castellanii. 162 Jun 19
We have used purified transcription factors and
RNA polymerase I
(pol I) to analyze the individual steps involved in the formation of transcription initiation complexes at the mouse ribosomal gene promoter in vitro. Complete assembly of transcription complexes requires pol I and at least four auxiliary factors, termed TIF-IA,
TIF
-IB,
TIF
-IC, and UBF. Preincubation and template commitment, as well as order of addition protocols, were used to discriminate between various intermediate complexes generated during assembly of the initiation complex. As a first step,
TIF
-IB binds to the core promoter, a process that is facilitated by the upstream control element and the upstream binding factor (UBF). Binding of
TIF
-IB to the rDNA promoter results in the formation of a functional preinitiation complex (complex 1), which is stable for many rounds of transcription. UBF, which on its own does not stably associate with the rDNA promoter, triggers a 5-10-fold increase in the overall amount of this primary complex. Following binding of
TIF
-IB and UBF to the template DNA, pol I and
TIF
-IC successively bind, yielding complexes 2 and 3, respectively. Transcription-competent initiation complexes are built up by the final association of the growth-regulated factor TIF-IA. The various complexes can be distinguished by their different sensitivity to Sarkosyl. Only the complete complex consisting of all four factors and pol I shows resistance to intermediate concentrations of Sarkosyl (0.045%) and is competent to catalyze the formation of the first phosphodiester bond. The initiated complex is, on the other hand, resistant to high concentrations of Sarkosyl (0.3%). The hierarchical nature of the different complexes formed suggests a model for transcription initiation and predicts functions for the individual factors.
...
PMID:Transcription complex formation at the mouse rDNA promoter involves the stepwise association of four transcription factors and RNA polymerase I. 176 56
Faithful and efficient transcription initiation at the mouse ribosomal gene promoter requires besides
RNA polymerase I
(pol I) four polypeptide trans-acting factors, termed TIF-IA,
TIF
-IB,
TIF
-IC, and mUBF. We have partially purified these proteins from cultured Ehrlich ascites cells and show that in the presence of TIF-IA and
TIF
-IB, pol I directs very low amounts of specific transcripts. Neither
TIF
-IC nor mUBF on their own significantly stimulate the efficiency of template utilization. However, both factors together strongly activate transcription. Interestingly, factor
TIF
-IB - the murine homologue of human SL1 - fails to program a human extract to transcribe the murine template, but requires its homologous
RNA polymerase I
. This finding implicates that not only some rDNA transcription factors but also pol I exhibits species-specific differences. The growth-related factor TIF-IA, on the other hand, stimulates both mouse and human rDNA transcription. This regulatory factor whose amount or activity fluctuates according to the proliferation rate of the cells, is functionally inactivated by antibodies against cdc2 protein kinase. This result together with the observation that transcription is stimulated by ATP-gamma S, an ATP analogue which is a substrate for protein kinases but not for protein phosphatases, strongly suggests that post-translational protein modification is involved in rDNA transcription regulation.
...
PMID:Trans-acting factors involved in species-specificity and control of mouse ribosomal gene transcription. 192 92
The murine ribosomal gene promoter contains two cis-acting control elements which operate in concert to promote efficient and accurate transcription initiation by
RNA polymerase I
. The start site proximal core element which is indispensable for promoter recognition by
RNA polymerase I
(pol I) encompasses sequences from position -39 to -1. An upstream control element (UCE) which is located between nucleotides -142 and -112 stimulates the efficiency of transcription initiation both in vivo and in vitro. Here we report the isolation and functional characterization of a specific rDNA binding protein, the transcription initiation factor
TIF
-IB, which specifically interacts with the core region of the mouse ribosomal RNA gene promoter. Highly purified
TIF
-IB complements transcriptional activity in the presence of two other essential initiation factors TIF-IA and
TIF
-IC. We demonstrate that the binding efficiency of purified
TIF
-IB to the core promoter is strongly enhanced by the presence in cis of the UCE. This positive effect of upstream sequences on
TIF
-IB binding is observed throughout the purification procedure suggesting that the synergistic action of the two distant promoter elements is not mediated by a protein different from
TIF
-IB. Increasing the distance between both control elements still facilitates stable factor binding but eliminates transcriptional activation. The results demonstrate that
TIF
-IB binding to the rDNA promoter is an essential early step in the assembly of a functional transcription initiation complex. The subsequent interaction of
TIF
-IB with other auxiliary transcription initiation factors, however, requires the correct spacing between the UCE and the core promoter element.
...
PMID:Isolation and functional characterization of TIF-IB, a factor that confers promoter specificity to mouse RNA polymerase I. 232 84
Control of mouse ribosomal RNA synthesis in response to extracellular signals is mediated by TIF-IA, a regulatory factor whose amount or activity correlates with cell proliferation. Factor TIF-IA interacts with
RNA polymerase I
(pol I), thus converting it into a transcriptionally active holoenzyme, which is able to initiate specifically at the rDNA promoter in the presence of the other auxiliary transcription initiation factors, designated
TIF
-IB,
TIF
-IC and UBF. With regard to several criteria, the growth-dependent factor TIF-IA behaves like a bacterial sigma factor: (i) it associates physically with pol I, (ii) it is required for initiation of transcription, (iii) it is present in limiting amounts and (iv) under certain salt conditions, it is chromatographically separable from the polymerase. In addition, evidence is presented that dephosphorylation of pol I abolishes in vitro transcription initiation from the ribosomal gene promoter without significantly affecting the polymerizing activity of the enzyme at nonspecific templates. The involvement of both a regulatory factor and post-translational modification of the transcribing enzyme provides an efficient and versatile mechanism of rDNA transcription regulation which enables the cell to adapt ribosome synthesis rapidly to a variety of extracellular signals.
...
PMID:A growth-dependent transcription initiation factor (TIF-IA) interacting with RNA polymerase I regulates mouse ribosomal RNA synthesis. 239 Sep 74
Following infection of cells by herpes simplex virus, the cell nucleus is subverted for transcription and replication of the viral genome and assembly of progeny nucleocapsids. The transition from host to viral transcription involves viral proteins that influence the ability of the cellular
RNA polymerase II
to transcribe a series of viral genes. The regulation of
RNA polymerase II
activity by viral gene products seems to occur by several different mechanisms: (1) viral proteins complex with cellular proteins and alter their transcription-promoting activity (e.g., alpha
TIF
), (2) viral proteins bind to specific DNA sequences and alter transcription (e.g., ICP4), and (3) viral proteins affect the posttranslational modification of viral or cellular transcriptional regulatory proteins (e.g., possibly ICP27). Thus, HSV may utilize several different approaches to influence the ability of host-cell
RNA polymerase II
to transcribe viral genes. Although it is known that viral transcription uses the host-cell polymerase II, it is not known whether viral infection causes a change in the structural elements of the nucleus that promote transcription. In contrast, HSV encodes a new DNA polymerase and accessory proteins that complex with and reorganize cellular proteins to form new structures where viral DNA replication takes place. HSV may encode a large number of DNA replication proteins, including a new polymerase, because it replicates in resting cells where these cellular gene products would never be expressed. However, it imitates the host cell in that it localizes viral DNA replication proteins to discrete compartments of the nucleus where viral DNA synthesis takes place. Furthermore, there is evidence that at least one specific viral gene protein can play a role in organizing the assembly of the DNA replication structures. Further work in this system may determine whether assembly of these structures is essential for efficient viral DNA replication and if so, why assembly of these structures is necessary. Thus, the study of the localization and assembly of HSV DNA replication proteins provides a system to examine the mechanisms involved in morphogenesis of the cell nucleus. Therefore, several critical principles are apparent from these discussions of the metabolism of HSV transcription and DNA replication. First, there are many ways in which the activity of
RNA polymerase II
can be regulated, and HSV proteins exploit several of these in controlling the transcription of a single DNA molecule. Second, the interplay of these multiple regulatory pathways is likely to control the progress of the lytic cycle and may play a role in determining the lytic versus latent infection decision.(ABSTRACT TRUNCATED AT 400 WORDS)
...
PMID:The role of viral and cellular nuclear proteins in herpes simplex virus replication. 255 60
Mouse
RNA polymerase I
requires at least two chromatographically distinct transcription factors (designated TIF-IA and
TIF
-IB) to initiate transcription accurately and efficiently in vitro. In this paper we describe the partial purification of TIF-IA by a four-step fractionation procedure. The amount or activity of TIF-IA fluctuates in response to the physiological state of the cells. Extracts from quiescent cells are incapable of specific transcription and do not contain detectable levels of TIF-IA. Transcriptionally inactive extracts can be restored by the addition of TIF-IA preparations that have been highly purified from exponentially growing cells. During the fractionating procedure TIF-IA co-purifies with
RNA polymerase I
, suggesting that it is functionally associated with the transcribing enzyme. We suggest that only those enzyme molecules that are associated with TIF-IA are capable to interact with
TIF
-IB and to initiate transcription.
...
PMID:Growth-dependent regulation of rRNA synthesis is mediated by a transcription initiation factor (TIF-IA). 407 1
A faithful transcription system for ribosomal RNA genes has been developed by using components from the small free-living amoeba Acanthamoeba castellanii. The system utilizes protein-free recombinant DNA as a template and in addition requires a crude cell-free extract containing
RNA polymerase I
and a transcription initiation factor (
TIF
-I). The transcript is initiated at the same position as the in vivo precursor ribosomal RNA: templates truncated at various sites downstream of the transcription start site give rise to only the predicted runoff RNA transcripts, and the runoff transcript produced has a 5'-terminus identical with the 5'-terminus of the isolated ribosomal RNA precursor. Faithful initiation can be elicited by the DNA sequence extending from -55 to +19 in the template. Subclones containing this sequence yield only the predicted runoff RNAs regardless of the orientation of this fragment in the cloning vector DNA; thus, only the in vivo sense strand of the template is specifically transcribed in the in vitro system. The system is specific for the
RNA polymerase
responsible for the transcription of ribosomal RNA genes in vivo. Faithful transcription, like
RNA polymerase I
from Acanthamoeba, is insensitive to alpha-amanitin inhibition, and transcription is greatly stimulated by highly purified
RNA polymerase I
but not by RNA polymerases II or III. Conditions for optimal transcription were determined.
...
PMID:Faithful initiation of ribosomal RNA transcription from cloned DNA by purified RNA polymerase I. 609 40
We have utilized a cell-free transcription system from Acanthamoeba castellanii to test the functional activity of
RNA polymerase I
and transcription initiation factor I (TIF-I) during developmental down regulation of rRNA transcription. The results strongly suggest that rRNA transcription is regulated by modification, probably covalent, of
RNA polymerase I
: (1) The level of activity of
TIF
-I in extracts from transcriptionally active and inactive cells is constant. (2) The number of
RNA polymerase I
molecules in transcriptionally active and inactive cells is also constant. (3) In contrast, though the specific activity of polymerase I on damaged templates remains constant, both crude and purified polymerase I from inactive cells have lost the ability to participate in faithful initiation of rRNA transcription. (4) Polymerase I purified from transcriptionally active cells has the same subunit architecture as enzyme from inactive cells. However, the latter is heat denatured 5 times faster than the active polymerase.
...
PMID:In vitro evidence that eukaryotic ribosomal RNA transcription is regulated by modification of RNA polymerase I. 609 93
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