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)

Several thyroid hormone analogs have been tested for thyromimetic activity on rat brain and liver subcellular organelles. The compounds were administered immediately after thyroidectomy to 90 g male S-D rats for 10 days, by daily s.c. injection. In cerebral cortex and liver we measured the activities of mitochondrial succinate cytochrome c reductase and alpha-GPD, and nuclear RNA polymerase I. Brain mitochondrial enzymes were unchanged in thyroidectomized (Tx) and in Tx-treated rats, whereas the activities of these enzymes in liver mitochondria were partially restored by the treatments. RNA polymerase I activity in brain and liver dropped significantly 10 days after thyroidectomy and daily injection of thyroid hormones or analogs maintained the nuclear activity at a normal level. Correlation between the structure of thyroid hormone analogs and their subcellular effects is in good agreement with previous binding and in vivo studies. Enzyme activities stimulated by T3 were lowered by replacing the T3 side-chain by an acetic acid group or by substituting the bridged oxygen atom by atom by CO. In contrast, the activity was enhanced by substituting iodine with a 3' isopropyl group. Although less active than iodine, the 3,5-dimethyl substituents may be introduced without a complete loss of nuclear activity.
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PMID:Comparative effects of thyroid hormone analogs on the activities of brain and liver mitochondria and nuclei in thyroidectomized rats. 648 4

In spite of the generally well-coordinated synthesis of RNA polymerase core enzyme subunits (alpha, beta and beta') in Escherichia coli, a situation was found during the growth transition from exponential to stationary phase in which this coordination was broken (the order of differential repression being alpha leads to beta' leads to beta; Kawakami et al. (1979). The present study indicates that, during a certain period of the growth transition, twice as much beta subunit is synthesized as beta' subunit and the overproduced beta subunit accumulates as the assembly intermediate alpha 2 beta complex, which is rapidly and preferentially degraded. Two independent factors, i.e., carbon source down-shift and oxygen depletion, were examined separately for their influence on the coordinated regulation of the synthesis of RNA polymerase subunits. The depletion of glucose added as a sole carbon source was accompanied by repression of the synthesis of all core enzyme subunits, while under the same conditions the differential rate of sigma subunit synthesis increased. In contrast, the sudden ending of the oxygen supply resulted in specific repression of the synthesis of only beta and beta' subunits but not of sigma and alpha subunits. The latter result may be explained by the autogenous repression of the rpoBC genes by a temporal increase in the amount of unused cytoplasmic RNA polymerase.
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PMID:Biosynthesis of RNA polymerase in Escherichia coli. XII. Noncoordinate synthesis of core enzyme subunits after suppression of cell growth. 704 23

Model compounds for the Zn sites of the beta' and the beta subunits in RNA polymerase [1] were synthesized. Single crystal structures and X-ray absorbtion spectroscopy measurements for these two model complexes are reported. In Zn(C6H12OS2)2(ClO4)2, the Zn is coordinated by four sulfur and two oxygen atoms. The average Zn-S bond length is 2.514 A and the Zn-O bond length is 2.089 A, which are similar to these bond distances reported for the Zn site in the beta' subunit of RNA polymerase. In Zn(C3H6NS2)2(C3H4N2), the Zn atom is coordinated by four sulfur atoms and one nitrogen atom of an imidazole group. The average of the Zn-S bond length is 2.469 A and the Zn-N bond length is 2.009 A, which are also similar to the Zn-S and Zn-N bonds in the beta subunits of RNA polymerase.
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PMID:Synthesis and structures of Zn(C6H12OS2)2(ClO4)2 and Zn(C3H6NS2)2(C3H4N2)--model compounds for the Zn sites in RNA polymerase. 750 87

When the single-stranded RNA genome of HIV-1 is copied into double-stranded DNA, the viral enzyme reverse transcriptase (RT) catalyzes the addition of approximately 20,000 nucleotides; however, the precise mechanism of nucleotide addition is unknown. In this study, we attempt to integrate the genetic data and biochemical mechanism of DNA polymerization with the structure of HIV-1 RT complexed with a dsDNA template-primer. The first step of polymerization involves the physical association of a polymerase with its nucleic acid substrate. A comparison of the structures of HIV-1 RT in the presence and absence of DNA indicates that the tip of the p66 thumb moves approximately 30 A upon DNA binding. This conformational change permits numerous interactions between residues of alpha-helices H and I in the thumb subdomain and the DNA. Measurements of DNA binding affinity for nucleic acids with double-stranded DNAs that have an increasing number of bases in the template overhang and molecular modeling suggest that portions of beta 3 and beta 4 within the fingers subdomain bind single-stranded regions of the template. Measurements of nucleotide incorporation efficiency (kcat/Km) show that the binding and incorporation of the next complementary nucleotide are not dependent on the length of the template overhang. Molecular modeling of an incoming nucleotide triphosphate (dTTP), based in part on the position of mercury atoms in a RT/DNA/Hg-UTP/Fab structure, suggests that portions of secondary structural elements alpha C-beta 6, alpha E, beta 11b, and beta 9-beta 10 determine the topology of the dNTP-binding site. These results also suggest that nucleotide incorporation is accompanied by a protein conformational change that positions the dNTP for nucleophilic attack. Nucleophilic attack by the oxygen atom of the 3'-OH group of the primer strand could be metal-mediated, and Asp185 may be directly involved in stabilizing the transition state. The translocation step may be characterized by rotational as well as translational motions of HIV-1 RT relative to the DNA double helix. Some of the energy required for translocation could be provided by dNTP hydrolysis and could be coupled with conformational changes within the nucleic acid. A structural comparison of HIV-1 RT, Klenow fragment, and T7 RNA polymerase identified regions within T7 RNA polymerase which are not present in the other two polymerases that might help this polymerase to remain bound with nucleic acids and contribute to the ability of the T7 RNA polymerase to polymerize processively.
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PMID:Insights into DNA polymerization mechanisms from structure and function analysis of HIV-1 reverse transcriptase. 753 90

Sophisticated biochemical networks allow organisms such as bacteria and insects to switch from very rapid growth and development in ideal environments to dormancy during severely unfavorable conditions. These switches may be accompanied by abrupt changes in oxidation/reduction involving reactive oxygen species (ROS). ROS have the potential of damaging nucleic acids, proteins, and membranes. In Escherichia coli, certain genetically regulated circuits (regulons) turn on synthesis of anti-oxidant enzymes to protect against distinct ROS excesses (superoxide, hydrogen peroxide, organic or lipid peroxides, etc.). As examples, the soxRS regulon controls synthesis of Mn-superoxide dismutase, oxyR controls catalase HPI, rpoS positively regulates HPII, and fur regulates several oxidative reactions that involve iron uptake. Our studies have focused on the regulatory role of rpoS, known to be a sigma factor (sigma 38) that combines with RNA polymerase and is a regulator of those gene products needed to protect cells during dormancy. Since insect cells, during both active growth and dormancy, endure severe environments, analogous protective gene products may be induced. Examples are presented of insect anti-oxidant metabolism, including those involved in the aging process. In addition, we searched several DNA and protein sequence data banks to compare resemblances between anti-oxidant gene products of bacteria and insects.
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PMID:Genetic mechanisms involved in cellular recovery from oxidative stress. 760 42

In Klebsiella pneumoniae, transcription of all nif (nitrogen fixation) operons except the regulatory nifLA operon itself is regulated by the proteins NifA and NifL. NifA, an enhancer-binding protein, activates transcription by RNA polymerase containing the alternative sigma factor sigma 54. The central catalytic domain of NifA is sufficient for transcriptional activation, which can occur from solution. In vivo, NifL antagonizes the action of NifA in the presence of molecular oxygen or combined nitrogen. Inhibition has also been shown in vitro, but it was not responsive to environmental signals. Assuming a two-domain structure of NifL, we localized inhibition by NifL to its carboxy (C)-terminal domain, which is more soluble than the intact protein. The first line of evidence for this is that internal deletions of NifL containing an intact C-terminal domain were able to inhibit transcriptional activation by NifA in a coupled transcription-translation system. The second line of evidence is that the isolated C-terminal domain of NifL (assayed as a fusion to the soluble maltose-binding protein [MBP]) was sufficient to inhibit transcriptional activation by the central domain of NifA in a purified transcription system. The final line of evidence is that an MBP fusion to the C-terminal domain of NifL inhibited transcriptional activation by NifA in vivo. On the basis of these data, we postulate that the inhibitory function of NifL lies in its C-terminal domain and hence infer that this domain is responsible for interaction with NifA. Gel filtration experiments with MBP-NifL fusion derivatives lacking portions of the N- or C-terminal domain of the protein revealed that the C-terminal domain is the most soluble part of NifL. Up to 50% of two MBP-NifL truncations containing only the C-terminal domain appeared to be in a defined dimeric state.
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PMID:The C-terminal domain of NifL is sufficient to inhibit NifA activity. 766 87

The enhancer-binding protein NIFA is required for transcriptional activation of nif promoters by the alternative holoenzyme form of RNA polymerase, which contains the sigma factor sigma 54 (sigma N). NIFA hydrolyzes nucleoside triphosphates to catalyze the isomerization of closed promoter complexes to transcriptionally competent open complexes. The activity of NIFA is antagonized by the regulatory protein NIFL in response to oxygen and fixed nitrogen in vivo. We have investigated the requirement for nucleotides in the formation and stability of open promoter complexes by NIFA and inhibition of its activity by NIFL at the Klebsiella pneumoniae nifH promoter. Open complexes formed by sigma 54-containing RNA polymerase are considerably more stable to heparin challenge in the presence of GTP than in the presence of ATP. This differential stability is most probably a consequence of GTP being the initiating nucleotide at this promoter. Adenosine nucleosides are specifically required for Azotobacter vinelandii NIFL to inhibit open complex formation by native NIFA, and the nucleoside triphosphatase activity of NIFA is strongly inhibited by NIFL under these conditions. We propose a model in which NIFL modulates the activity of NIFA via an adenosine nucleotide switch.
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PMID:Transcriptional activation of the nitrogenase promoter in vitro: adenosine nucleotides are required for inhibition of NIFA activity by NIFL. 786 90

The Bradyrhizobium japonicum NifA protein, the central regulator for nitrogen fixation gene expression, is encoded in the fixRnifA operon. This operon is activated during free-living anaerobic growth and in the symbiotic root nodule bacteroid state. In addition, it is expressed in aerobic conditions, albeit at a low level. Here, we report that this pattern of expression is due to the presence of two overlapping promoters: fixRp1, which is of the -24/-12 class recognized by the RNA polymerase sigma 54, and fixRp2, which shares homology with the -35 and -10 regions found in other putative B. japonicum housekeeping promoters. Primer extension analyses showed that fixRp1 directed the synthesis of a transcript, P1, that starts 12 nucleotides downstream of the -12 region. In addition to sigma 54, P1 was dependent on NifA and low oxygen tension. Transcripts originating from fixRp2 started at two sites: one coincided with P1, while the most abundant, P2 initiated just two nucleotides further downstream of P1. Expression from fixRp2 was dependent on the upstream -68 promoter region, a region known to bind a putative activator protein, but it was independent of sigma 54 and NifA. This promoter was expressed in aerobic and anaerobic conditions but was not expressed in 30-day-old bacteroids. Mutations in the conserved 12 region for the sigma 54 promoter did not show any transcript, because these mutations also disrupted the overlapping -10 region of the fixRp2 promoter. Conversely, mutations at the -24 region only affected the sigma 54-dependent P1 transcript, having no effect on the expression of P2. In the absence of omega(54), anaerobic expression from the fixRp(2) promoter was enhanced threefold, suggesting that in the wild-type strain, the two RNA polymerase holoenzymes must compete for binding to the same promoter region.
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PMID:Overlapping promoters for two different RNA polymerase holoenzymes control Bradyrhizobium japonicum nifA expression. 789 98

The mucoid phenotype is common among strains of Pseudomonas aeruginosa that cause chronic pulmonary infections in patients with cystic fibrosis and is due to overproduction of an exopolysaccharide called alginate. However, the mucoid phenotype is unstable in vitro, especially when the cells are incubated under low oxygen tension. Spontaneous conversion to the nonmucoid form is typically due to mutations (previously called algS) that are closely linked to the alginate regulatory gene algT, located at 68 min on the chromosome. Our sequence analysis of algT showed that its 22-kDa gene product shares homology with several alternate sigma factors in bacteria, suggesting that AlgT (also known as AlgU) interacts directly with RNA polymerase core to activate the promoters of alginate genes. AlgT showed striking sequence similarity (79%) to sigma E of Escherichia coli, an alternate sigma factor involved in high-temperature gene expression. Our analysis of the molecular basis for spontaneous conversion from mucoid to nonmucoid, in the cystic fibrosis isolate FRD, revealed that nonmucoid conversion was often due to one of two distinct missense mutations in algT that occurred at codons 18 and 29. RNase protection assays showed that spontaneous nonmucoid strains with the algT18 and algT29 alleles have a four- to fivefold reduction in the accumulation of algT transcripts compared with the wild-type mucoid strain. Likewise, a plasmid-borne algT-cat transcriptional fusion was about 3-fold less active in the algT18 and algT29 backgrounds compared with the mucoid wild-type strain, and it was 20-fold less active in an algT::Tn501 background. These data indicate that algT is autoregulated. The spontaneous algT missense alleles also caused about fivefold-reduced expression of the adjacent negative regulator, algN (also known as mucB). Transcripts of algN were essentially absent in the algT::Tn501 strain. Thus, algT regulates the algTN cluster, and the two genes may be cotranscribed. A primer extension analysis showed that algT transcription starts 54 bp upstream of the start of translation. Although the algT promoter showed little similarity to promoters recognized by the vegetative sigma factor, it was similar to the algR promoter. This finding suggests that AlgT may function as a sigma factor to activate its own promoter and those of other alginate genes. The primer extension analysis also showed that algT transcripts were readily detectable in the typical nonmucoid strain PAO1, which was in contrast to a weak signal seen in the algT18 mutant of FRD. A plasmid-borne algT gene in PAO1 resulted in both the mucoid phenotype and high levels of algT transcripts, further supporting the hypothesis that AlgT controls its own gene expression and expression of genes of the alginate regulon.
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PMID:Mucoid-to-nonmucoid conversion in alginate-producing Pseudomonas aeruginosa often results from spontaneous mutations in algT, encoding a putative alternate sigma factor, and shows evidence for autoregulation. 796 21

This review presents a comparison between the complex genetic regulatory networks that control nitrogen fixation in three representative rhizobial species, Rhizobium meliloti, Bradyrhizobium japonicum, and Azorhizobium caulinodans. Transcription of nitrogen fixation genes (nif and fix genes) in these bacteria is induced primarily by low-oxygen conditions. Low-oxygen sensing and transmission of this signal to the level of nif and fix gene expression involve at least five regulatory proteins, FixL, FixJ, FixK, NifA, and RpoN (sigma 54). The characteristic features of these proteins and their functions within species-specific regulatory pathways are described. Oxygen interferes with the activities of two transcriptional activators, FixJ and NifA. FixJ activity is modulated via phosphorylation-dephosphorylation by the cognate sensor hemoprotein FixL. In addition to the oxygen responsiveness of the NifA protein, synthesis of NifA is oxygen regulated at the level of transcription. This type of control includes FixLJ in R. meliloti and FixLJ-FixK in A. caulinodans or is brought about by autoregulation in B. japonicum. NifA, in concert with sigma 54 RNA polymerase, activates transcription from -24/-12-type promoters associated with nif and fix genes and additional genes that are not directly involved in nitrogen fixation. The FixK proteins constitute a subgroup of the Crp-Fnr family of bacterial regulators. Although the involvement of FixLJ and FixK in nifA regulation is remarkably different in the three rhizobial species discussed here, they constitute a regulatory cascade that uniformly controls the expression of genes (fixNOQP) encoding a distinct cytochrome oxidase complex probably required for bacterial respiration under low-oxygen conditions. In B. japonicum, the FixLJ-FixK cascade also controls genes for nitrate respiration and for one of two sigma 54 proteins.
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PMID:Genetic regulation of nitrogen fixation in rhizobia. 796 19

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