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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)

Gene 1 of bacteriophage T7 early region--the RNA polymerase gene--is very actively translated during the infectious cycle of this phage. A 29 base pair fragment of its ribosome binding site containing the initiation triplet, the Shine-Dalgarno sequence (S-D), 10 nucleotides (nt) upstream and 6 nt downstream of these central elements was cloned into a vector to control the expression of the mouse dihydrofolate reductase gene (dhfr). Although all essential parts of this translation initiation region (TIR) should be present, this fragment showed only very low activity. Computer analysis revealed a potentially inhibitory hairpin binding the S-D sequence into its stem base paired to vector-derived upstream sequences. Mutational alterations demonstrated that this hairpin was not responsible for the low activity. However, addition of 21 nt of the T7 gene 1 upstream sequence to the 29 base pair fragment were capable of increasing the translational efficiency by one order of magnitude. Computer analysis of this sequence, including nucleotide shuffling, revealed that it contains a highly unstructured region lacking mRNA secondary structures but with a hairpin at its 5' end, here formed solely by T7 sequences. There was not much difference in activity whether the mRNA included or lacked vector-derived sequences upstream of the hairpin. Such highly unstructured mRNA regions were found in all very efficiently expressed T7 genes without any obvious sequence homologies. The delta G values of these regions were higher, i.e. potential secondary structural elements were fewer, than in TIR of genes from E. coli. This is likely due to the fact that T7 as a lytic phage is relying for successful infection on much stronger signals which a cell cannot afford because of the indispensable balanced equilibria of its interdependent biochemical processes. When the 5' ends of efficient T7 gene mRNA are formed by the action of RNase III they generally start with an unstructured region. Efficiently expressed T7 genes within a polycistronic mRNA, however, always contain a hairpin preceding the structure free sequence. We suggest that the formation of this 5' hairpin is releasing enough energy to keep the unstructured regions free of secondary RNA structures for sufficient time to give ribosomes and factors a good chance for binding to the TIR. In addition, sequences further downstream of the start codon give rise to an additional increase in efficiency of the TIR by almost two orders of magnitude.
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PMID:An unstructured mRNA region and a 5' hairpin represent important elements of the E. coli translation initiation signal determined by using the bacteriophage T7 gene 1 translation start site. 828 18

Cloned RNase III gene in a T7 RNA polymerase promoter system was expressed in Escherichia coli cells lacking endogenous RNase III, and the over-expressed recombinant RNase III was purified to homogeneity using ion exchange, exclusion and affinity column chromatography. The overexpressed RNase III was found to separate with the membrane fraction after sonication, which was solubilized, fractionated with (NH)2SO4 and the active fractions used for further purification. The properties of the purified recombinant RNase III were studied using the synthetic RNA substrate, 3[H]poly[A].poly[U], and the natural substrates, 7S and p10Sa RNAs, and compared with the partially purified RNase III from wild-type E. coli cells. The recombinant RNase III showed maximal activity at 37 degrees C and at a pH range of 6.9 to 7.4, which was similar to the RNase III purified from the wild-type cells. Recombinant RNase III efficiently hydrolyzed 3[H].poly[A].poly[U] in the presence of Mg2+. However, the recombinant RNase III cleaved natural RNA substrates efficiently and accurately in the presence of Mn2+. A concentration of Mn2+ ranging from 150 to 300 microM was found to be optimal; concentrations higher than 0.5 mM were inhibitory. Other divalent cations did not support RNase III activity. Monovalent cations, Na+, K+ and NH4+ at 20 mM were equally effective in stimulating RNase III activity although they were not absolutely required for the activity. The thermal stability of the recombinant RNase III was examined at two temperatures, 37 degrees and 50 degrees C. Incubation of RNase III at 37 degrees C for 30 min did not affect activity, but it lost almost 50% of its activity when incubated at 50 degrees C for 30 min. Thus, the recombinant RNase III prefers Mn2+ for the cleavage of natural substrates and exhibits several properties similar to the wild-type RNase III.
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PMID:Expression, purification and properties of recombinant E. coli ribonuclease III. 879 39

Yeast U2 snRNA is transcribed by RNA polymerase II to generate a single non-polyadenylated transcript. A temperature-sensitive yeast strain carrying a disruption in RNT1, the gene encoding a homolog of RNase III, produces 3'-extended U2 that is polyadenylated. The U2 3'-flanking region contains a putative stem-loop that is recognized and cleaved at two sites by recombinant GST-Rnt1 protein in vitro. Removal of sequences comprising the stem-loop structure blocks cleavage in vitro and mimics the effects of Rnt1 depletion in vivo. Strains carrying a U2 gene lacking the Rnt1 cleavage site produce only polyadenylated U2 snRNA, and yet are not impaired in growth or splicing. The results suggest that eukaryotic RNase III may be a general factor in snRNA processing, and demonstrate that polyadenylation is not incompatible with snRNA function in yeast.
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PMID:Depletion of yeast RNase III blocks correct U2 3' end formation and results in polyadenylated but functional U2 snRNA. 964 43

Early in infection of Bacillus subtilis by bacteriophage SPO1, the synthesis of most host-specific macromolecules is replaced by the corresponding phage-specific biosyntheses. It is believed that this subversion of the host biosynthetic machinery is accomplished primarily by a cluster of early genes in the SPO1 terminal redundancy. Here we analyze the nucleotide sequence of this 11.5-kb "host-takeover module," which appears to be designed for particularly efficient expression. Promoters, ribosome-binding sites, and codon usage statistics all show characteristics known to be associated with efficient function in B. subtilis. The promoters and ribosome-binding sites have additional conserved features which are not characteristic of their host counterparts and which may be important for competition with host genes for the cellular biosynthetic machinery. The module includes 24 genes, tightly packed into 12 operons driven by the previously identified early promoters PE1 to PE12. The genes are smaller than average, with half of them having fewer than 100 codons. Most of their inferred products show little similarity to known proteins, although zinc finger, trans-membrane, and RNA polymerase-binding domains were identified. Transcription-termination and RNase III cleavage sites were found at appropriate locations.
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PMID:Genes and regulatory sites of the "host-takeover module" in the terminal redundancy of Bacillus subtilis bacteriophage SPO1. 965 51

The level of the vitamin B12 transport protein BtuB in the outer membrane of Escherichia coli is strongly reduced by growth in the presence of cobalamins. Previous analyses of regulatory mutants and of btuB-lacZ fusions indicated that the primary site of btuB gene regulation was at the translational level, and this required sequences throughout the 240-nucleotide (nt) leader region. Cobalamin-dependent regulation of transcriptional fusions was of a lesser magnitude but required, in addition to the leader, sequences within the first 100 nt of the coding sequence, termed the translated regulatory region (TRR). To analyze the process of transcription-level regulation of btuB in E. coli, the levels and metabolism of btuB RNA were analyzed by S1 nuclease protection assays, and mutations that alter the coupling of translational and transcriptional control were analyzed. Expression of transcriptional fusions was found to correlate with changes in the level of intact btuB RNA and was related to changes in the metabolic stability of the normally long-lived RNA. Mutational analysis showed that the btuB start codon and a hairpin structure that can sequester the Shine-Dalgarno sequence are necessary for cobalamin-dependent regulation and that translation of the TRR is necessary for extended RNA stability and for expression of the transcriptional fusion. The absence of regulation at the stage of transcription initiation was confirmed by the findings that several truncated btuB RNA fragments were expressed in a constitutive manner and that the normal regulatory response occurred even when the btuB promoter and upstream sequences were replaced by the heterologous bla and lac promoters. Transcription driven by phage T7 RNA polymerase was not regulated by cobalamins, although some regulation at the translational level was retained. Cobalamin-dependent changes in RNA structure were suggested from the RNase III-dependent production of a transcript fragment that is made only in the presence of cobalamin and is independent of the regulatory outcome. These results indicate that the primary control of btuB expression by cobalamin occurs at the level of translation initiation, which directly affects the level and stability of btuB RNA in a process that requires the presence of the intact translated regulatory region.
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PMID:Coupled changes in translation and transcription during cobalamin-dependent regulation of btuB expression in Escherichia coli. 985 20

Like its homologs in higher eukaryotes, the U2 snRNA in Schizosaccharomyces pombe is transcribed by RNA polymerase II and is not polyadenylated. Instead, an RNA stem-loop structure located downstream of the U2 snRNA coding sequence and transcribed as part of a 3' extended precursor serves as a signal for 3'-end formation. We have identified three mutants that have temperature-sensitive defects in U2 snRNA 3'-end formation. In these mutants, the synthesis of the major snRNAs is also affected and unprocessed rRNA precursors accumulate at the restrictive temperature. Two of these mutants contain the same G-to-A transition within the pac1 gene, whereas the third contains a lesion outside the pac1 locus, indicating that at least two genes are involved. The pac1+ gene is codominant with the mutant allele and can rescue the temperature-sensitive phenotype and the defects in snRNA and rRNA synthesis, if overexpressed. In vitro, Pac1p, an RNase III homolog, can cleave a synthetic U2 precursor within the signal for 3'-end formation, generating a product that is a few nucleotides longer than mature U2 snRNA. In addition, U2 precursors are cleaved and trimmed to the mature size in extracts made from wild-type S. pombe cells. However, extracts made from pac1 mutant cells are unable to do so unless they are supplemented with purified recombinant Pac1p. Thus, the 3' end of S. pombe U2 snRNA is generated by a processing reaction that requires Pac1p and an additional component, and can be dissociated from transcription in vitro.
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PMID:Pac1p, an RNase III homolog, is required for formation of the 3' end of U2 snRNA in Schizosaccharomyces pombe. 1044 82

We have mapped transcription termination sites for RNA polymerase I in the yeast Saccharomyces cerevisiae. S1 nuclease mapping shows that the primary terminator is the Reb1p terminator located at +93 downstream of the 3' end of 25S rRNA. Reverse transcription coupled with quantitative PCR shows that approximately 90% of all transcripts terminate at this site. Transcripts which read through the +93 site quantitatively terminate at a fail-safe terminator located further downstream at +250. Inactivation of Rnt1p (an RNase III involved in processing the 3' end of 25S rRNA) greatly stabilizes transcripts extending to both sites and increases readthrough at the +93 site. In vivo assay of mutants of the Reb1p terminator shows that this site operates in vivo by the same mechanism as has previously been delineated through in vitro studies.
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PMID:Saccharomyces cerevisiae RNA polymerase I terminates transcription at the Reb1 terminator in vivo. 1052 25

A recently described new signal for transcription termination in vitro by T7 RNA polymerase has now been tested in vivo. This signal, identified during transcription of the cloned human preproparathyroid hormone (PTH) gene, is also found in the phage T7 genome, at the concatemer junction (CJ). We introduced the 17-bp concatemer junction sequence at the ends of a test gene and control gene (both derived from T7 gene 9) in a T7 vector previously used to study effects of rare codons on expression. The CJ elements replaced the original vector's RNase III processing sites, and a new T7 promoter was also introduced to drive the downstream (control) gene. We assayed for test and control gene mRNA and protein by direct labeling with [32P]phosphate and [35S]methionine. The altered vector with CJ sequences (pCT1.1) expressed the upstream test gene, but showed poor expression of the downstream control gene. No discrete T7 mRNA bands could be discerned by direct labeling with 32P. A precursor vector with only the control gene in single copy expressed the protein much better, suggesting that the inhibition of control gene expression in pCT1.1 was a result of the upstream CJ element at the 3' end of the test gene. RT-PCR experiments were consistent with readthrough and possibly pausing at CJ. An RNA folding program predicts a highly stable secondary structure between the upstream CJ element and the control gene's translation start signals. These data support an interpretation that the CJ element is ineffective as a T7 transcription terminator in vivo in this vector, and that structure of the readthrough transcript blocks ribosome access to the downstream translation start. The readthrough transcripts are also likely to be less stable than properly terminated or processed T7 mRNA, because levels of test protein expression in pCT1.1 were reduced compared to original vector, and basal expression was negligible, while the original codon test vector shows substantial basal expression.
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PMID:The T7 concatemer junction sequence interferes with expression from a downstream T7 promoter in vivo. 1063 16

The repertoire of 4,431 open reading frames (ORFs), eight rRNA operons and 98 tRNA genes of Chromobacterium violaceum must be expressed in a regulated manner for successful adaptation to a wide variety of environmental conditions. To accomplish this feat, the organism relies on protein machineries involved in transcription, RNA processing and translation. Analysis of the C. violaceum genome showed that transcription initiation, elongation and termination are performed by the five well-known RNA polymerase subunits, five categories of sigma 70 factors, one sigma 54 factor, as well as six auxiliary elongation and termination factors. RNA processing is performed by a variety of endonucleases and exonucleases, such as ribonuclease H, ribonuclease E, ribonuclease P, and ribonuclease III, in addition to poly(A) polymerase and specific methyltransferases and pseudouridine synthases. ORFs for all ribosomal proteins, except S22, were found. Only 19 aminoacyl-tRNA synthetases were found, in addition to three aminoacyl-tRNA synthetase-related proteins. Asparaginyl-tRNA (Asn) is probably obtained by enzymatic modification of a mischarged aminoacyl-tRNA. The translation factors IF-1, IF-2, IF-3, EF-Ts, EF-Tu, EF-G, RF-1, RF-2 and RF-3 are all present in the C. violaceum genome, although the absence of selB suggests that C. violaceum does not synthesize selenoproteins. The components of trans-translation, tmRNA and associated proteins, are present in the C. violaceum genome. Finally, a large number of ORFs related to regulation of gene expression were also found, which was expected, considering the apparent adaptability of this bacterium.
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PMID:Gene expression in Chromobacterium violaceum. 1510 Sep 88

Sen1p in Saccharomyces cerevisiae is a Type I DNA/RNA helicase. Mutations in the helicase domain perturb accumulation of diverse RNA classes, and Sen1p has been implicated in 3' end formation of non-coding RNAs. Using a combination of global and candidate-specific two hybrid screens, eight proteins were identified that interact with Sen1p. Interactions with three of the proteins were analyzed further: Rpo21p(Rpb1p), a subunit of RNA polymerase II, Rad2p, a deoxyribonuclease required in DNA repair, and Rnt1p (RNase III), an endoribonuclease required for RNA maturation. For all three interactions, the two-hybrid results were confirmed by co-immunoprecipitation experiments. Genetic tests designed to assess the biological significance of the interactions indicate that Sen1p plays functionally significant roles in transcription and transcription-coupled DNA repair. To investigate the potential role of Sen1p in RNA processing and to assess the functional significance of the Sen1p/Rnt1p interaction, we examined U5 snRNA biogenesis. We provide evidence that Sen1p functions in concert with Rnt1p and the exosome at a late step in 3' end formation of one of the two mature forms of U5 snRNA but not the other. The protein-protein and protein-RNA interactions reported here suggest that the DNA/RNA helicase activity of Sen1p is utilized for several different purposes in multiple gene expression pathways.
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PMID:Multiple protein/protein and protein/RNA interactions suggest roles for yeast DNA/RNA helicase Sen1p in transcription, transcription-coupled DNA repair and RNA processing. 1512 1


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