EC:2.7.7.6 - FACTA Search

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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)

PSM2, PSM1, and PSM15 are small plasmids derived from R100 by spontaneous deletions at either end of the insertion sequence IS1. These plasmids were used to identify regions neighboring IS1 as well as the IS1 DNA itself, by cleavage with EcoR1, HindIII, Hae III, Hpa II, Hha I, Hinf, and AIu I. The nucleotide sequencing results demonstrate that IS1 contains 768 bases. About 30 bases at the ends of IS1 were found to be repeated in an inverted order. The deletions occurring at the ends of IS1 were found to be due to illegitimate recombination. The hypothesis that RNA polymerase could play an important role in such recombination phenomena is discussed based on the nucleotide sequences surrounding the recombinational hot spots.
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PMID:Nucleotide sequence of an insertion element, IS1. 27 24

We report here that the ends of IS1 are bound and protected in vitro by the heterodimeric protein integration host factor (IHF). Under identical conditions, RNA polymerase binds to one of these ends (IRL) and protects a region that includes the sequences protected by IHF. Other potential sites within IS1, identified by their homology to the apparent consensus sequence, are not protected. Footprinting analysis of deletion derivatives of the ends demonstrates a correspondence between the ability of the end sequence to bind IHF and its ability to function as an end in transposition. Nonetheless, some transposition occurs in IHF- cells, indicating that IHF is not an essential component of the transposition apparatus. IHF also binds and protects four closely spaced regions within the major hot-spot for insertion of IS1 in the plasmid pBR322. This striking correlation of hot-spot and IHF-binding sites suggests a possible role for IHF in IS1 insertion specificity.
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PMID:Escherichia coli integration host factor binds specifically to the ends of the insertion sequence IS1 and to its major insertion hot-spot in pBR322. 282 Dec 73

Escherichia coli K-12 strain 285c contains a short deletion mutation in rpoD, the gene encoding the sigma 70 subunit of RNA polymerase. The sigma 70 protein encoded by this allele (rpoD285) unstable, and this instability leads to temperature-sensitive growth. Pseudorevertants of 285c that can grow at high temperature contain mutations in the rpoH gene (encoding the heat shock sigma factor sigma 32), and their mutant sigma 70 proteins have increased stability. We characterized the alterations in three of these rpoH alleles. rpoH111 was a point mutation resulting in a single amino acid substitution. rpoH107 and rpoH113, which are known to be incompatible with rpoD+, altered the restriction map of rpoH. rpoH113 was deleted for 72 base pairs of the rpoH gene yet retained some sigma 32 activity. rpoH107 had two IS1 elements that flanked an unknown DNA segment of more than 6.4 kilobases inserted in the rpoH promoter region. The insertion decreased the amount of rpoH mRNA to less than 0.5% of the wild-type level at 30 degrees C. However, the mRNA from several heat shock promoters was decreased only twofold, suggesting that the strain has a significant amount of sigma 32.
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PMID:Deletion and insertion mutations in the rpoH gene of Escherichia coli that produce functional sigma 32. 284 Dec 88

Escherichia coli RNA polymerase was found to bind specifically to restriction fragments containing either end of IS1. DNase I footprint analyses indicate that RNA polymerase protects approximately 70 base-pairs at each end of IS1, including the left or right terminal inverted repeat sequences in IS1 (termed insL or insR, respectively) as well as some non-IS1 sequence directly adjacent to each end of IS1. Analysis of transcripts from the left terminal region of IS1 shows that the insL sequence contains a promoter (named insPL), and that RNA synthesis initiates apparently at one in a stretch of five adenylate residues within insL and continues toward the interior region of IS1. Interestingly, most of the resulting transcripts contain polyuridylate residues (more than 5 U residues) at their 5'-ends. Analysis of transcripts from the right terminal region of IS1 indicates that the insR sequence also contains a promoter (named insPR). RNA synthesis initiates specifically at an adenylate residue within insR and continues toward the interior region of IS1, i.e. in the opposite direction to RNA synthesis initiating at insPL, which is present at the other end of IS1. We propose that insPL is used to make the messenger RNA for the IS1-encoded genes insA and insB, while insPR might be used to synthesize an anti-mRNA and thereby negatively regulate insPL.
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PMID:Both inverted repeat sequences located at the ends of IS1 provide promoter functions. 608 43

We find that the uvrC gene is preceded by three promoters (P1, P2 and P3), identified by heparin-resistant RNA polymerase-DNA complex formation, P2 and P3 promoters are located proximal to the 5' end of the uvrC gene, while the P1 promoter is separated from the uvrC structural gene by an interposed DNA region of more than 1 kb. We have reported that P2 and P3 are not sufficient to promote uvrC complementation. However, plasmids containing the direct fusion of the P1 promoter to the uvrC gene complements the uvrC defect. Insertion of IS1 downstream from the P1 promoter leads to efficient synthesis of the uvrC protein as measured in maxicells. Fusion of the lac promoter to the uvrC structural gene can substitute for in vivo regulatory functions. We conclude that uvrC protein synthesis is controlled in a complex manner and that a distal promoter, P1, is required.
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PMID:Distal regulatory functions for the uvrC gene of E. coli. 608 82

Transcription is known to be coupled to translation in many or all bacterial operons which code for proteins. In these operons, nonsense codons which prevent normal translation often result in premature termination of transcription (polarity). However, efficient transcription of ribosomal ribonucleic acid operons (rrn operons) occurs, although rrn transcripts are not translated. It therefore seemed possible that insertion sequences and transposable elements which are polar in protein-coding operons might not be polar in rrn operons. Previously, it has been shown (E. A. Morgan, Cell 21:257-265, 1980) that Tn10 is incompletely polar in the rrnX operon. Here we show that the transposon Tn9 and the insertion sequence IS1 also incompletely polar in rrnX. In normal cells expression of sequences distal to the insertions can be detected by genetic methods. In ultraviolet-irradiated cells expression of distal sequences is about 80% of that observed in uninterrupted rrnX operons. These observations provide evidence that ribonucleic acid polymerase molecules beginning at rrnX promoters can read through Tn9 and IS1 and that, at least in ultraviolet-irradiated cells, read-through is very efficient.
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PMID:Tn9 and IS1 inserts in a ribosomal ribonucleic acid operon of Escherichia coli are incompletely polar. 617 59

The Escherichia coli lac and ara promoters and rrnC ribosomal RNA promoter-leader region were fused to lacZYA. Transcription termination signals were introduced into the lac genes of these fusions by Tn9 and IS1 insertions. Measurement of lac enzymes from upstream and downstream of the insertions showed that termination signals resulting from these insertions are very efficient when transcription begins at lac or ara promoters but are very inefficient when transcription begins at the rrnC promoter-leader region. The rrnC promoter-leader region must, therefore, modify RNA polymerase to enable it to read through transcription termination signals.
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PMID:Antitermination of transcription from an Escherichia coli ribosomal RNA promoter. 620 58

Interactions between Escherichia coli RNA polymerase holoenzyme and three small plasmid DNAs (pSM1, pSM2, and pSM15) derived from the drug resistant factor R12 have been studied. These plasmids carry the copy number and incompatibility determinants, the origin of DNA replication and the rep gene(s) necessary for plasmid replication. They also contain the insertion element IS1 and the putative finO cistron. Thirteen DNA segments within the largest of the three plasmids (pSM2) were able to form either a binary and/or ternary complex with RNA polymerase. A unique strong binding site was mapped within the left end of IS1. Five binding sites were found within the rep-cop-inc region. Four of these are weak binding sites whereas the fifth does not form a stable binary complex and was detected by ternary complex formation. A strong binding site was located in the putative finO region whereas the remaining six binding sites are located in regions with unidentified genetic functions.
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PMID:Mapping of RNA polymerase binding sites in R12 derived plasmids carrying the replication-incompatibility region and the insertion element IS1. 629 71

Five mutations that result in reduced expression of the araBAD operon were cloned onto the plasmid pBR322. The position of each mutation was determined by DNA sequence analysis. Three of the mutations were located in the RNA polymerase binding site of the araBAD promoter. The first, ara-1016, was a one-base-pair deletion at position -35; the second, ara-1036, was a transversion at position -13; the third, ara-1027, was a nine-base-pair deletion from +5 to +13. S1 nuclease mapping showed that mutations ara-1016 and ara-1036 greatly reduced transcription and that mutation ara-1027 had little, if any, effect on transcription. Two other mutations resulted from the transposition of the insertion element, IS1, downstream from the transcriptional start site of the operon. Molecular mechanisms for all of the mutations are discussed.
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PMID:Five mutations in the promoter region of the araBAD operon of Escherichia coli B/r. 631 19

The bacterial repetitive sequence IS1, is a translocatable DNA segment. The internal region of IS1 acts as a cis-element to stimulate RNA synthesis from the upstream promoter. The product of the bacterial artA gene works with this cis-element to stimulate transcription. Eukaryotic genes for small RNAs and short interspersed repetitive elements (SINEs) have internal promoters, transcribed by RNA polymerase III (RNAP III). RNAP III requires the multisubunit protein factor TFIIIC in transcription initiation. TFIIIC contains the B-block binding subunit which recognizes the internal promoter. Here, I report that the eukaryotic RNAP III promoter-like sequence was found in the cis-element of bacterial IS1. Mutations in the cis-element which affect transcription were present in the RNAP III promoter-like sequence. The RNAP III promoter sequence of Alu, which is a human SINE, was cloned into Escherichia coli, and was shown to stimulate bacterial transcription like the cis-element of IS1. Furthermore, the primary structures of ArtA protein and B-block binding subunits were compared. The amino acid sequence of ArtA appeared to be similar to the N- and C-terminal regions conserved in many B-block binding subunits. Prokaryotes and eukaryotes have been thought to have inherent transcription machineries. The results shown here, however, suggest a new aspect of the evolution of the RNAP III transcription machinery.
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PMID:Possible presence and role of the promoter sequence for eukaryotic RNA polymerase III in bacteria. 1715 57

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