Gene/Protein Disease Symptom Drug Enzyme Compound
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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)

The role of Cys-138 in the catalysis of the skeletal muscle 6-phosphofructo-2-kinase reaction was investigated by mutating this residue to serine, glutamine and alanine, expressing the mutants in E. coli with a T7 RNA polymerase-based expression system, and analyzing their kinetic properties. The Cys138Ala mutant had greatly diminished activity, while the Cys138Ser and Cys138Gln mutants had maximal velocities 2-3 fold higher than the wild-type enzyme. It was concluded that Cys-138 does not act as a base catalyst in the kinase reaction, but that it plays a significant structural role in the enzyme's active site.
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PMID:Lack of evidence for a role of Cys-138 as a base catalyst in the skeletal muscle 6-phosphofructo-2-kinase reaction. 836 5

Host cell RNA polymerase II (Pol II)-mediated transcription is inhibited by poliovirus infection. This inhibition is correlated to a specific decrease in the activity of a chromatographic fraction which contains the transcription factor TFIID. To investigate the mechanism by which poliovirus infection results in a decrease of TFIID activity, we have analyzed a component of TFIID, the TATA-binding protein (TBP). Using Western immunoblot analysis, we show that TBP is cleaved in poliovirus-infected cells at the same time postinfection as when Pol II transcription is inhibited. Further, we show that one of the cleaved forms of TBP can be reproduced in vitro by incubating TBP with cloned, purified poliovirus encoded protease 3C. Protease 3C is a poliovirus-encoded protease that specifically cleaves glutamine-glycine bonds in the viral polyprotein. The cleavage of TBP by protease 3C occurs directly. Finally, incubation of an uninfected cell-derived TBP-containing fraction (TFIID) with protease 3C results in significant inhibition of Pol II-mediated transcription in vitro. These results demonstrate that a cellular transcription factor can be directly cleaved both in vitro and in vivo by a viral protease and suggest a role of the poliovirus proteinase 3C in host cell Pol II-mediated transcription shutoff.
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PMID:Direct cleavage of human TATA-binding protein by poliovirus protease 3C in vivo and in vitro. 838 Aug 94

Host cell RNA polymerase II-mediated transcription is inhibited by poliovirus infection. We have shown previously that the human TATA-binding protein (TBP), a general transcription factor required for transcription of all RNA polymerase II genes, is directly cleaved both in vitro and in vivo by the virus-coded protease 3CPro. 3CPro specifically cleaves glutamine-glycine bonds in the viral polyprotein. Cellular transcription factor TBP contains three glutamine-glycine sites, at amino acids 12, 18, and 108. By using site-directed mutagenesis, we determined that the glutamine-glycine bond at amino acid 18, but not that at amino acid 12 or 108, is cleaved by the viral protease. Both the glutamine and the glycine appear to be important for the cleavage. Further mutations around the glutamine-glycine site at position 18 suggest that determinants other than the glutamine-glycine bond in TBP are also required for 3CPro-induced cleavage. An alanine at position P4 and a proline at position P2, proximal to the scissile glutamine-glycine pair, appear to be important for 3CPro-mediated cleavage of TBP. Our results suggest that the cleavage specificity of 3CPro for a cellular transcription factor is very similar to its mode of cleavage of viral polyproteins.
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PMID:Identification of the cleavage site and determinants required for poliovirus 3CPro-catalyzed cleavage of human TATA-binding transcription factor TBP. 838 2

Regulation of glutamine-synthetase (GS) activity in enteric bacteria involves a complex cascade of events. In response to nitrogen limitation, a transferase catalyses the uridylylation of the PII protein, which in turn stimulates deadenylylation of GS. Deadenylylated GS is the more active form of the enzyme. Here we characterize in detail the genes from Escherichia coli encoding uridylyl-transferase (glnD), the PII protein (glnB), and adenylyl-transferase (glnE). glnD is transcribed from its own promoter, glnE is contranscribed with another gene, orfXE, whereas glnB is partly contranscribed with a gene encoding a homologue of the transcription activator NtrC. All three gln regulatory genes were constitutively expressed at a low level, i.e. their expression was independent of the nitrogen status and the RNA polymerase sigma factor sigma 54. We conclude that the functioning of the GS adenylylation cascade is regulated by modulation of the activities of uridylyl-transferase and adenylyl-transferase, rather than by changes in the expression of their genes.
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PMID:The genes of the glutamine synthetase adenylylation cascade are not regulated by nitrogen in Escherichia coli. 841 94

The expression of RNA polymerase II transcripts can be regulated at the posttranscriptional level by RNA-binding proteins. Although extensively characterized in metazoans, relatively few RNA-binding proteins have been characterized in the yeast Saccharomyces cerevisiae. Three major proteins are cross-linked by UV light to poly(A)+ RNA in living S. cerevisiae cells. These are the 72-kDa poly(A)-binding protein and proteins of 60 and 50 kDa (S.A. Adam, T.Y. Nakagawa, M.S. Swanson, T. Woodruff, and G. Dreyfuss, Mol. Cell. Biol. 6:2932-2943, 1986). Here, we describe the 60-kDa protein, one of the major poly(A)+ RNA-binding proteins in S. cerevisiae. This protein, PUB1 [for poly(U)-binding protein 1], was purified by affinity chromatography on immobilized poly(rU), and specific monoclonal antibodies to it were produced. UV cross-linking demonstrated that PUB1 is bound to poly(A)+ RNA (mRNA or pre-mRNA) in living cells, and it was detected primarily in the cytoplasm by indirect immunofluorescence. The gene for PUB1 was cloned and sequenced, and the sequence was found to predict a 51-kDa protein with three ribonucleoprotein consensus RNA-binding domains and three glutamine- and asparagine-rich auxiliary domains. This overall structure is remarkably similar to the structures of the Drosophila melanogaster elav gene product, the human neuronal antigen HuD, and the cytolytic lymphocyte protein TIA-1. Each of these proteins has an important role in development and differentiation, potentially by affecting RNA processing. PUB1 was found to be nonessential in S. cerevisiae by gene replacement; however, further genetic analysis should reveal important features of this class of RNA-binding proteins.
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PMID:PUB1: a major yeast poly(A)+ RNA-binding protein. 841 13

The yeast HIS3 promoter region contains two functionally distinct TATA elements, TC and TR, that are responsible respectively for initiation from the +1 and +13 sites. Both TC and TR support basal HIS3 transcription and require the TATA binding protein TFIID, but only TR responds to transcriptional activation by GCN4 and GAL4. By selecting for yeast strains that increase transcription by a GCN4 derivative with a defective activation domain, we have isolated a temperature-sensitive mutation in CDC39, a previously defined gene implicated in cell-cycle control and the pheromone response. This cdc39-2 mutation causes increased basal transcription of many, but not all genes, as well as increased transcriptional activation by GCN4 and GAL4. Surprisingly, basal HIS3 transcription from the +1 initiation site is strongly increased, while initiation from the +13 site is barely affected. Thus, unlike acidic activator proteins that function through TR, CDC39 preferentially affects transcription mediated by TC. CDC39 is an essential gene that encodes a very large nuclear protein (2108 amino acids) containing two glutamine-rich regions. These observations suggest that CDC39 negatively regulates transcription either by affecting the general RNA polymerase II machinery or by altering chromatin structure.
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PMID:CDC39, an essential nuclear protein that negatively regulates transcription and differentially affects the constitutive and inducible HIS3 promoters. 842 77

Transcription of messenger RNA-encoding genes in vitro requires many protein factors. Transcription factor IID, possibly with the cooperation of TFIIA, binds to the TATA element of the promoter, forming a complex that can bind TFIIB (refs 6, 7) followed by RNA polymerase II (refs 6, 8) and other factors. One or more of these steps is thought to be facilitated by gene-specific transcriptional activation proteins; this seems to require TFIID-associated auxiliary factors and may involve direct contact between the activator and TFIID and/or TFIIB. If such contact is necessary in vivo, activation might conceivably be blocked by a TFIIB derivative containing the sequences necessary for this interaction, but lacking those necessary for binding to the rest of the transcriptional apparatus, an effect similar to that referred to as squelching or transcriptional interference. Here we show that the activity of the glutamine-rich fushi tarazu activation domain is indeed blocked by truncated TFIIB derivatives in Drosophila Schneider L2 cells, suggesting that it is mediated by interactions with TFIIB.
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PMID:Interaction between a transcriptional activator and transcription factor IIB in vivo. 846 96

A genomic clone of the small, round-structured virus Southampton virus (SV) was constructed from a set of overlapping PCR amplicons. Sequence analysis confirmed the absence of mutations and accurate ligation of the PCR products. The SV cDNA was cloned into a vector for in vitro production of RNA and subsequent translation by rabbit reticulocyte lysate. Two polypeptides corresponding to the N-terminal and C-terminal regions of the viral polyprotein were expressed in Escherichia coli and used to produce murine antisera for detection of translation products. Three major translation products of 113, 48, and 41 kDa were identified in a coupled transcription-translation system. The large 113-kDa protein reacted with antisera raised against the C-terminal region of the polyprotein and represents a precursor of the viral RNA polymerase. The 48-kDa protein detected in vitro reacted specifically with antisera raised against the polyprotein N terminus, showing that translation was initiated in SV at the three tandem in-frame AUG codons at the 5' end of the genome. A series of nested 3' deletions of the large open reading frame encoding the viral polyprotein was used to define the translation initiation site and genomic location of the viral protease. The results are consistent with a model in which translation of the viral genome is initiated at one of the three in-frame AUG codons starting at nucleotide position 5 and in which active viral protease is produced following translation of a region located between NheI (nucleotide 3052) and SphI (nucleotide 4056), resulting in rapid cleavage of a large precursor protein. Abolition of the viral 3C-like protease activity by site-directed mutagenesis of the putative active-site cysteine (Cys-1238) resulted in production of a large protein of approximately 200 kDa which reacted with both N-terminal and C-terminal antisera. Two potential polyprotein cleavage sites containing the preferred picornaviral QG recognition site were identified on either side of the putative 2C-like helicase region of the polyprotein. Proteolysis at these positions would give rise to products with relative molecular masses identical to those of the products detected in the rabbit reticulocyte system. Site-directed mutagenesis was used to introduce a single base change which resulted in the substitution of glutamine residues with proline residues at amino acids 399 and 762. These mutations completely abolished cleavage of the polyprotein at these positions and gave rise to alternative products with molecular masses which matched the predicted sizes for a single cleavage at either Q-399 or Q-762. These data indicate that the small, round-structured virus Southampton virus produces a 3C-like protease which has two primary cleavage sites at positions 399 and 762. Proteolytic cleavage at these positions releases the putative viral 2C-like helicase.
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PMID:Polyprotein processing in Southampton virus: identification of 3C-like protease cleavage sites by in vitro mutagenesis. 864 93

MalT is the transcriptional activator of the Escherichia coli maltose regulon. Several lines of evidence suggest that MalT might act by interacting with RNA polymerase. Here, we show that 'MalT, the DNA-binding domain of MalT, activates transcription. In order to identify amino acids of 'MalT playing a specific role in activation, and therefore possibly involved in the putative contact(s) with RNA polymerase, we developed a double screen to isolate mutations of the 'malT gene affecting activation by 'MalT without impairing its DNA-binding affinity. The effect of the mutations thus obtained on activation was assessed in vivo. This strategy essentially pointed to serine 834 and glutamine 876 of the MalT amino acid sequence as specifically involved in activation. Various 'MalT derivatives substituted at positions 834 or 876 were purified and tested in vitro for their DNA-binding affinity, as well as for their activation ability. Together, the results obtained clearly show that serine 834 and glutamine 876 are important for activation by 'MalT but not for DNA-binding. We argue that these amino acid residues are possibly solvent-exposed and propose that they act by contacting RNA polymerase.
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PMID:Two amino acid residues from the DNA-binding domain of MalT play a crucial role in transcriptional activation. 880 74

In this study, we isolated two cDNA molecules encoding putative glutamate receptor subunits, fGluR1 alpha and fGluR1 beta, from an Oreochromis sp. brain cDNA library by hybridizing with the glutamate receptor cDNA, fGluR2 beta, of the same fish. The deduced amino acid sequence of the fGluR1 alpha consists of 908 residues with an 18-residue signal peptide and displays a sequence identity of 74% to the amino acid sequence of rat GluR1 subunit. Northern blotting indicates that the expression level of fGluR1 alpha in telencephalon is higher than that in optic tectum and cerebellum in adult fish brain. Reverse-transcriptase polymerase chain reaction and genomic analyses reveal the presence of variants created by alternative splicing at the flip-flop module and the carboxyl terminus of fGluR1 alpha transcripts. The amino acid sequence of fGluR1 alpha is unique in that it contains a glutamine-rich sequence inserted at the loop 1 (L1) between transmembrane domains 1 and 2. A second incomplete cDNA clone, designated fGluR1 beta, coding for a polypeptide showing sequence identity to the rat GluR1 and fGluR1 alpha was isolated from the same library. Insertion of a serine- and glutamine-rich sequence at the L1 was also detected in the translated sequence of fGluR1 beta.
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PMID:Molecular analysis of cDNA molecules encoding glutamate receptor subunits, fGluR1 alpha and fGluR1 beta, of Oreochromis sp. 883 30


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