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 bacteriophage T7 RNA polymerase (T7gene1) was placed under the control of regulatory elements from the Escherichia coli lac operon to construct an inducible vaccinia virus expression system consisting entirely of prokaryotic transcriptional machinery. Regulated expression of T7 RNA polymerase was necessary to construct a stable recombinant vaccinia virus harboring a T7 promoter; otherwise, uncontrolled expression led to interference with endogenous virus replication. To this end, the gene encoding the repressor protein of the lac operon was fused to a viral early/late promoter so that it was expressed constitutively, and the lac operator was interposed between a viral major late promoter and T7gene1. Greater than 99% repression of T7 RNA polymerase, which was relieved approximately 80-fold in the presence of the inducer isopropyl-beta-D-thiogalactopyranoside (IPTG), was obtained. An expression cassette containing a T7 promoter-controlled beta-galactosidase reporter gene was recombined into a different region of the viral genome containing T7gene1. A stable, double recombinant virus was isolated and grown to a high titer. In the absence of inducer, beta-galactosidase expression was substantially repressed. Addition of increasing amounts of IPTG induced expression of beta-galactosidase to the point of suppression of viral replication. This hybrid vaccinia virus system (Vac/Op/T7) has potential applications for the efficient bioproduction of a wide variety of gene products.
...
PMID:Regulated expression of foreign genes in vaccinia virus under the control of bacteriophage T7 RNA polymerase and the Escherichia coli lac repressor. 156 May 32

We have investigated whether the RNA polymerase III-driven transcription of eukaryotic tRNA genes can be regulated by the prokaryotic tetracycline operator-repressor system. The bacterial tet operator (tetO) was inserted at two different positions (-7 and -46) upstream of a tRNA(Glu) (amber) suppressor gene. Both constructs are transcribed in Saccharomyces cerevisiae and yield functional tRNAs as scored by suppression of an amber nonsense mutation in the met8-1 allele. Controlled expression of Tet repressor was achieved by fusing the bacterial tetR gene to the yeast gal1 promoter. This leads to expression of Tet repressor in yeast on galactose--but not on glucose--containing media. Regulation of the su-tRNA gene with the tetO fragment inserted at position -7 has been demonstrated. Under conditions which allow tetR expression, cells exhibit a met- phenotype. This methionine auxotrophy can be conditionally reverted to prototrophy by adding tetracycline. However, a su-tRNA gene with the tetO fragment inserted at position -46 cannot be repressed. Our results demonstrate clearly that the bacterial repressor protein binds to its operator in the yeast genome. Formation of this complex in the vicinity of the pol III transcription initiation site reduces the level of su-tRNA at least 50-fold as concluded from quantitative primer extension analyses. This indicates for the first time that class III gene expression can be regulated by a DNA binding protein with its target site in the 5'-flanking region and that a prokaryotic repressor can confer regulation of a suitably engineered tRNA gene.
...
PMID:RNA polymerase III catalysed transcription can be regulated in Saccharomyces cerevisiae by the bacterial tetracycline repressor-operator system. 156 52

We have shown that a transcriptional repressor protein can regulate promoter activity via DNA bending by using the pLS1 plasmid promoter PII (which has intrinsic curvature upstream of its -35 box) and the plasmid-encoded repressor protein RepA (which strongly bends DNA). Substitution of the curved region for a straight DNA fragment containing the RepA target resulted in increased (or decreased) gene expression when RepA was supplied in trans: enhanced gene expression was evident when the target of RepA and the promoter were on the same face of the DNA helix; repression was found when they were on opposite faces of the DNA. In vitro activation of transcription from PII was observed when supercoiled DNA was used as template, but not with linear molecules. We propose that promoter activity can be regulated by the proper positioning (in or out of phase) of an induced DNA bend with the RNA polymerase recognition sites.
...
PMID:The RepA repressor can act as a transcriptional activator by inducing DNA bends. 202 40

According to our present understanding, lambda repressor bound to DNA stimulates transcription by touching RNA polymerase bound at an adjacent promoter. The part of repressor required for activation was identified in part by the isolation of mutants specifically impaired in transcriptional activation. The amino acids of repressor altered in these "positive control" mutants lie in an acidic patch on the surface of repressor that is closely apposed to RNA polymerase. In this study, we show that this "activating patch" of repressor is sufficient for transcriptional activation in another sequence context. We transfer this activating patch onto the surface of lambda Cro, a protein normally unable to activate transcription, and show that the modified Cro is a transcriptional activator. In addition, we provide evidence that the repressor protein of phage 434 also activates transcription using an activating patch similar to that of lambda repressor.
...
PMID:Turning lambda Cro into a transcriptional activator. 296 42

Operator sequence and repressor protein regulate the activity of the lac promoter over a greater than 1000-fold range. Combinations of the lac operator with other promoter sequences, however, differ vastly in the level of repression. The data presented show that the extent of repression is determined largely by the rates of complex formation of the competing systems operator-repressor and promoter-RNA polymerase and by the rate at which RNA polymerase clears the promoter. Moreover, up to 70-fold differences in the level of repression were found when the operator was placed in different positions within the promoter sequence. A kinetic model is proposed that explains the observed effects and that allows predictions on promoters controlled by negatively acting elements.
...
PMID:Promoters largely determine the efficiency of repressor action. 305 97

Two operators, spatially separated from each other and from the promoters, repress the gal operon when bound to Gal repressor. Conversion of either gal operator to a lac operator results in derepression, although both Gal and Lac repressors are present, suggesting that mere occupation of operator sites is not sufficient to cause repression. Conversion of both operators to lac operators restores normal repression in the presence of Lac repressor protein. We propose that normal repression requires interaction between operator-bound like repressor molecules; this generates a DNA loop, which is part of a higher order structure. RNA polymerase and cyclic AMP receptor protein are present in this complex but unable to initiate transcription because of the higher order structure. Such higher order DNA-multiprotein complexes could occur in a variety of genetic regulatory systems that are controlled from distal sites by regulatory proteins.
...
PMID:Interaction of spatially separated protein-DNA complexes for control of gene expression: operator conversions. 305 50

We have used transcriptional activity assays and DNase I footprinting techniques to examine in vitro the binding of Escherichia coli RNA polymerase and lambda repressor protein to the bacteriophage lambda rightward promoter-operator region. For the lambda PR promoter, the activity and physical binding results determined at several repressor concentrations correlated very well. Good agreement was also found for repression of PRM, which occurred at higher repressor concentrations; however, our results indicate that at low repressor concentrations, RNA polymerase can physically occupy PRM in a transcriptionally inactive form. These inactive complexes formed with a binding constant similar to that previously measured for "closed complexes" at PRM. A kinetic study of PR open complex formation on an OR2-template in the presence of lambda repressor showed that decreased initiation frequency from this promoter was due largely to a decrease in KB. The kinetically determined inhibition constant for repressor (Ki = 4 nM) was similar to the dissociation constant (Kd approximately 2 nM) determined from the footprinting studies.
...
PMID:Functional and physical characterization of transcription initiation complexes in the bacteriophage lambda OR region. 315 34

The synthesis of the inducible enzyme penicillinase of Bacillus licheniformis is negatively controlled by a repressor (D.A. Dubnau and M.R. Pollock, J. Gen. Microbiol. 41:7-21, 1965; D. J. Sherratt and J. F. Collins, J. Gen. Microbiol. 76:217-230,1973). The molecular organization of the genes coding for penicillinase (penP) and its repressor (penI) has recently been determined (T. Himeno, T. Imanaka, and S. Aiba, J. Bacteriol. 168:1128-1132, 1986). These two genes are transcribed divergently from within a 364-nucleotide region separating the coding sequences. We cloned and sequenced the repressor gene (penIc) from strain 749/C that constitutively produces penicillinase. The penIc and penI+ (wild-type) genes were expressed in Escherichia coli. Complementation analysis indicated that the repressor is the only trans-acting protein required to regulate the expression of the penI and penP genes. We purified the wild-type repressor protein, used it in gel retardation and DNase I protection experiments, and identified three operators positioned in the region between the penP and penI coding sequences. The spatial arrangement of the operators and the hierarchy in repressor binding seen in the protection experiments indicate that (i) the penI gene product represses the expression of the penP gene by physically blocking the RNA polymerase-binding site and (ii) the penI gene is autoregulated.
...
PMID:Regulation of the penicillinase genes of Bacillus licheniformis: interaction of the pen repressor with its operators. 326 Feb 34

In prokaryotic organisms, the control of gene expression is mediated by regulatory proteins that activate or repress transcription. However, the molecular mechanisms of positive and negative control are different. In terms of negative control, repressor proteins bind to sites located within the promoter region and as a consequence sterically interfere with functional binding by RNA polymerase. Here, I examine the properties of a regulatory sequence that specifies catabolite (glucose) repression in the yeast Saccharomyces cerevisiae. Specifically, a DNA segment containing this regulatory site was fused upstream of the intact his3 promoter region and structural gene at several locations. Normally, his3 expression in these derivatives occurs at a basal level which can be induced by conditions of amino-acid starvation. However, in glucose medium, the catabolite regulatory sequence overrides the normal his3 promoter elements and reduces transcription both in normal and starvation conditions. The implication from these results is that in contrast to catabolite repression in Escherichia coli, which is mediated by catabolite-activating protein (CAP), catabolite repression in yeast occurs by a negative control mechanism involving a putative repressor protein. The observation that this regulatory site exerts its repressing effects even when located upstream of an intact promoter region suggests that repression in yeast is not mediated by steric interference between regulatory proteins and the transcriptional apparatus.
...
PMID:Negative control at a distance mediates catabolite repression in yeast. 390 16

We have identified the Escherichia coli RNA polymerase-binding sites and the transcription initiation sites in the transposon Tn3. Results from nitrocellulose filter-binding assays indicate that there are two regions within Tn3 capable of forming stable binary complexes with RNA polymerase. The two regions are a 208-bp region containing the N-terminal coding sequence of the transposase (tnpA) and repressor (tnpR) genes, and a 332-bp region containing the N-terminal coding sequence for the beta-lactamase (bla) gene. DNase I footprint analysis of the 208-bp and 332-bp fragments further defined an extended region of protection, approx. 110 bp long, located between the transposase and repressor coding regions, and an 80-bp region of protection near the N-terminal coding sequence of the beta-lactamase gene. In vitro transcription studies with fragments containing these protected regions allowed us to determine the precise transcription initiation sites for the transposase, repressor, and beta-lactamase mRNAs. The transposase and repressor mRNAs are transcribed divergently and their transcription initiation sites are separated by 80 bp. The -35 homology regions for the transposase and repressor promoters are separated by 10 bp and the -10 homology region of the transposase promoter is coincident with the recombination site (res) for the site-specific recombinase activity (resolvase) of the repressor protein, which is required for resolution of Tn3 cointegrates. We discuss the significance of this complex divergently transcribed promoter region with respect to regulation of Tn3 transposition and we propose a model for coordinated regulation of the tnpA and tnpR genes. We also compare the Tn3 tnpA-tnpR intercistronic region with that of the closely related transposon gamma delta.
...
PMID:Escherichia coli RNA polymerase binding sites and transcription initiation sites in the transposon Tn3. 631 85

1 2 3 4 5 Next >>