Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: 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 recognition of promoter region -10 nucleotide sequences in prokaryotes is believed to be mediated by a segment of alpha-helix in a region of RNA polymerase sigma factors called 2.4. Earlier genetic studies implicated Thr-100 in region 2.4 of the Bacillus subtilis sigma factor sigma H in the recognition of the G.C base pair at position -13 in the -10 region (GAAT) of a cognate promoter. In confirmation of this assignment, we now show that a change-of-specificity mutant of sigma H in which Thr-100 was replaced with isoleucine suppresses a G.C----A.T nucleotide substitution at position -13 but not other "promoter down mutations" (causing impaired promoter activity) at positions -13, -12, and -11. We also show that a loss-of-contact mutant created by the replacement of Thr-100 with alanine (having a short side chain) enables sigma H to tolerate three different promoter down mutations at position -13 but not down mutations at other positions. Finally, we suggest the identification of an additional amino acid involved in base-pair recognition by the demonstration that the replacement of Arg-96 with alanine specifically suppresses an A.T----G.C promoter down mutation at position -12. The identification of amino acids that are four residues apart that are involved in the recognition of adjacent base pairs may fix the orientation of region 2.4 (its NH2 terminus being proximal to the promoter transcription start site) and is consistent with a model in which the recognition of promoter region -10 nucleotide sequences is mediated by an alpha-helix in which residues involved in base-pair contact are separated by one turn and clustered on one face of the helix.
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PMID:Two amino acids in an RNA polymerase sigma factor involved in the recognition of adjacent base pairs in the -10 region of a cognate promoter. 212 53

A mutagenic oligonucleotide cassette was used to introduce single and tandem amino acid substitutions into the proteinase 3C coding region of an infectious poliovirus type 1 cDNA. The sites targeted for mutagenesis, residues 60, 61, and 66, are located within a putative helical loop structure which may be involved in substrate recognition by the enzyme. Fourteen viable 3C proteinase mutants were isolated. A Lys----Arg substitution at position 60 resulted in cold sensitivity for growth at 33 degrees. Replacement of Lys 60 with Ile, either singly or in combination with substitutions at position 61, resulted in viruses that produced three- to fivefold more 3D RNA polymerase than wild-type poliovirus. 3C-mediated processing of the remaining sites within the polyprotein was not noticeably affected. The overproduction of 3D is a consequence of more efficient processing of the carboxy-terminal Gln-Gly amino acid pair of 3C. Together with a previous report in which substitution of Val 54 with an Ala residue results in a poliovirus that produces decreased levels of 3D, these observations provide evidence that the putative loop region (residues 51-66) may be a functional domain involved in recognition of the carboxy-terminal Gln-Gly cleavage site of 3C.
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PMID:A genetic locus in mutant poliovirus genomes involved in overproduction of RNA polymerase and 3C proteinase. 215 85

Full-length cDNA copies of mRNAs coding for the matrix (M) proteins of vesicular stomatitis virus and its mutant tsO23(III) were cloned in pBSM13- (BlueScribe). The authenticity of these clones was demonstrated by restriction enzyme mapping, DNA sequencing, and in vitro transcription and translation to identify the two M proteins by Western immunoblotting with epitope-specific monoclonal antibodies. Site-directed mutants were constructed by primer extension of synthetic oligodeoxynucleotides with one or two nucleotide changes to alter the glycine at amino acid 21 of the wild-type (wt) M gene to glutamic acid, alanine, or proline. Similarly, a revertant was created in the M gene of mutant tsO23 by a Glu-21----Gly substitution. A series of wt- and mutant-M-gene chimeras was also constructed to create mutant and revertant clones with Leu----Phe and His----Tyr alterations at amino acids 111 and 227, respectively. We then moved the wt and tsO23 M genes and their site-specific mutants and chimeras cloned in pBSM13- into the eucaryotic expression vector pTF7 directed by the T7 bacteriophage RNA polymerase of the vaccinia virus recombinant vTF1-6,2. Western blot analysis of the M proteins transiently expressed in CV-1 cells by plasmids carrying M genes altered at amino acid 21 revealed that the critical antigenic determinant (epitope 1) is expressed only by the Gly-21 M protein and not by Glu-21, Ala-21, or Pro-21 M proteins. Of particular interest is an apparent conformational change, evidenced by slightly but significantly retarded electrophoretic migration, in plasmid-expressed M proteins with amino acids substituted for glycine at position 21. The glutamic acid at position 21 of tsO23 is not responsible for its temperature-sensitive phenotype, because a tsO23 revertant plasmid with glycine substituted at position 21 fails to rescue tsO23 virus in cells infected at the restrictive temperature; conversely, plasmids expressing wt M protein with substitutions of glutamic acid, alanine, or proline at position 21 are just as effective in marker rescue of tsO23 as is the Gly-21 wt M protein. Marker rescue experiments with wt- and mutant-M-gene chimeras support the hypothesis of K. Morita, R. Vanderoef, and J. Lenard (J. Virol. 61:256-263, 1987) that the temperature-sensitive phenotype of tsO23 is due to a phenylalanine substituted for leucine at amino acid 111, rather than the His-227----Tyr substitution or the Gly-21----Glu substitution, which independently accounts for the loss of epitope 1 in the mutant M protein of tsO23.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Site-specific mutations in vectors that express antigenic and temperature-sensitive phenotypes of the M gene of vesicular stomatitis virus. 245 88

We have determined the nucleotide sequences of three mutant rho genes encoding hyperfunctional rho proteins (rho S) together with their parent allele, rho-ts702. These mutant rho factors contain the following amino acid changes as deduced from their sequences: (1) the thermo-labile mutant, rho-ts702, has Thr304 substituting for Ala; (2) rho S-77 and rho S-81, which are selectively altered in the primary polynucleotide binding site, share an identical mutation, Leu3----Phe; (3) rho S-82, which is altered in both the primary and secondary polynucleotide binding sites, carries three amino acid substitutions together, Leu3----Phe, Asp156----Asn and Thr323----Ile. Dissection and functional characterization of each mutation in rho S-82 have revealed that Ile323 alone is responsible for alterations in both the secondary RNA interaction and the terminator selectivity observed with the original mutant, rho S-82. Taken together, these results not only confirm our proposal in the accompanying paper that the primary and secondary RNA binding sites differently contribute in determining the overall efficiency and site-specificity of termination, respectively, but also support the possibility that these binding sites exist as structurally distinct domains in rho protein. In contrast, Asn156 was shown to cause decreased termination efficiency, though it had no influence on RNA interactions. Thus, this amino acid residue appears to be associated with still another rate-determining step of termination, for instance, interactions between rho and RNA polymerase. On the basis of Chou-Fasman secondary structure predictions as well as amino acid sequence comparison with F1-ATPase, we discuss how the proposed domains are structurally and functionally related to the putative ATPase reactive center of rho protein.
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PMID:Mutant rho factors with increased transcription termination activities. II. Identification and functional dissection of amino acid changes. 247 57

A new DNA-binding unit, composed of four amino acid residues and common in gene regulatory proteins, is proposed. The occurrences of the sequences Ser-Pro-X-X (SPXX) and Thr-Pro-X-X (TPXX) in gene regulatory proteins are compared with those in general proteins. These sequences are found more frequently in gene regulatory proteins including homoeotic gene products, segmentation gene products, steroid hormone receptors and certain oncogene products, than they are in DNA-binding proteins that are not directly involved in gene regulation, such as the core histones, or in general proteins. It is therefore suggested that these sequences contribute to DNA-binding in a manner important for gene regulation. Amino acid residues characteristic of the types of proteins are found as the variable residues X: basic residues, Lys and Arg, in histones, H1 and sea urchin spermatogenous H2B; Tyr in RNA polymerase II; and Ser, Thr, Ala, Leu and Pro in other gene regulatory proteins S(T)PXX sequences are located on either side of other DNA-recognizing units such as Zn fingers, helix-turn-helices, and cores of histones. The structure of a S(T)PXX sequence is presumed to be a beta-turn I stabilized by two hydrogen bonds, and its potential mode of DNA-binding is discussed.
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PMID:SPXX, a frequent sequence motif in gene regulatory proteins. 250 May 31

Temperature-sensitive (ts) mutants of Sindbis virus belonging to complementation group F, ts6, ts110, and ts118, are defective in RNA synthesis at the nonpermissive temperature. cDNA clones of these group F mutants, as well as of ts+ revertants, have been constructed. To assign the ts phenotype to a specific region in the viral genome, restriction fragments from the mutant cDNA clones were used to replace the corresponding regions of the full-length clone Toto1101 of Sindbis virus. These hybrid plasmids were transcribed in vitro by SP6 RNA polymerase to produce infectious transcripts, and the virus recovered was tested for temperature sensitivity. After the ts lesion of each mutant was mapped to a specific region of 400 to 800 nucleotides by this approach, this region of the cDNA clones of both the ts mutant and ts+ revertants was sequenced in order to determine the precise nucleotide change and amino acid substitution responsible for each mutation. Rescued mutants, which have a uniform background except for one or two defined changes, were examined for viral RNA synthesis and complementation to show that the phenotypes observed were the result of the mutations mapped. ts6 and ts110 had a single base substitution in nsP4, resulting in replacement of Gly by Glu at position 153 or position 324, respectively. It is of interest that nsP4 contains the Gly-Asp-Asp motif characteristic of a number of viral replicases, and this, together with the fact that all RNA synthesis in ts6-infected cells and, to a lesser extent, in ts110-infected cells shut off when the cells were shifted from a permissive to a nonpermissive temperature, suggests that nsP4 is the virus polymerase. ts118 was a double mutant. It contained a single base substitution in nsP2, resulting in replacement of Val by Ala at position 425 that resulted in the formation of minute plaques, but not in a reduction in the plaque number at the nonpermissive condition. The second change, a substitution of Gln by Arg in ts118 at residue 93 in nsP4, had little apparent phenotype on its own, but in combination with the change in nsP2 led to a ts phenotype. Thus, in each case the mutation responsible for the temperature sensitivity of the three known complementation group F mutants lay in nsP4. In addition, the result with ts118 suggests that nsP2 and nsP4 may interact with each other in a complex.
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PMID:Mapping of RNA- temperature-sensitive mutants of Sindbis virus: complementation group F mutants have lesions in nsP4. 252 74

The Ada protein of Escherichia coli catalyzes transfer of methyl groups from methylated DNA to its own molecule, and the methylated form of Ada protein promotes transcription of its own gene, ada. Using an in vitro reconstituted system, we found that both the sigma factor and the methylated Ada protein are required for transcription of the ada gene. To elucidate molecular mechanisms involved in the regulation of the ada transcription, we investigated interactions of the non-methylated and methylated forms of Ada protein and the RNA polymerase holo enzyme (the core enzyme and sigma factor) with a DNA fragment carrying the ada promoter region. Footprinting analyses revealed that the methylated Ada protein binds to a region from positions -63 to -31, which includes the ada regulatory sequence AAAGCGCA. No firm binding was observed with the non-methylated Ada protein, although some DNase I-hypersensitive sites were produced in the promoter by both types of Ada protein. RNA polymerase did bind to the promoter once the methylated Ada protein had bound to the upstream sequence. To correlate these phenomena with the process in vivo, we used the DNAs derived from promoter-defective mutants. No binding of Ada protein nor of RNA polymerase occurred with a mutant DNA having a C to G substitution at position -47 within the ada regulatory sequence. In the case of a -35 box mutant with a T to A change at position -34, the methylated Ada protein did bind to the ada regulatory sequence, yet there was no RNA polymerase binding. Thus, the binding of the methylated Ada protein to the upstream region apparently facilitates binding of the RNA polymerase to the proper region of the promoter. The Ada protein possesses two known methyl acceptor sites, Cys69 and Cys321. The role of methylation of each cysteine residue was investigated using mutant forms of the Ada protein. The Ada protein with the cysteine residue at position 69 replaced by alanine was incapable of binding to the ada promoter even when the cysteine residue at position 321 of the protein was methylated. When the Ada protein with alanine at position 321 was methylated, it acquired the potential to bind to the ada promoter. These results are compatible with the notion that methylation of the cysteine residue at position 69 causes a conformational change of the Ada protein, thereby facilitating binding of the protein to the upstream regulatory sequence.
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PMID:Regulation of expression of the ada gene controlling the adaptive response. Interactions with the ada promoter of the Ada protein and RNA polymerase. 264 1

Four complementation groups of temperature-sensitive (ts) mutants of Sindbis virus that fail to make RNA at the nonpermissive temperature are known, and we have previously shown that group F mutants have defects in nsP4. Here we map representatives of groups A, B, and G. Restriction fragments from a full-length clone of Sindbis virus, Toto1101, were replaced with the corresponding fragments from the various mutants. These hybrid plasmids were transcribed in vitro by SP6 RNA polymerase to produce infectious RNA transcripts, and the virus recovered was tested for temperature sensitivity. After each lesion was mapped to a specific region, cDNA clones of both mutants and revertants were sequenced in order to determine the precise nucleotide change responsible for each mutation. Synthesis of viral RNA and complementation by rescued mutants were also examined in order to study the phenotype of each mutation in a uniform genetic background. The single mutant of group B, ts11, had a defect in nsP1 (Ala-348 to Thr). All of the group A and group G mutants examined had lesions in nsP2 (Ala-517 to Thr in ts17, Cys-304 to Tyr in ts21, and Gly-736 to Ser in ts24 for three group A mutants, and Phe-509 to Leu in ts18 and Asp-522 to Asn in ts7 for two group G mutants). In addition, ts7 had a change in nsP3 (Phe-312 to Ser) which also rendered the virus temperature sensitive and RNA-. Thus, changes in any of the four nonstructural proteins can lead to failure to synthesize RNA at a nonpermissive temperature, indicating that all four are involved in RNA synthesis. From the results presented here and from previous results, several of the activities of the nonstructural proteins can be deduced. It appears that nsP1 may be involved in the initiation of minus-strand RNA synthesis. nsP2 appears to be involved in the initiation of 26S RNA synthesis, and in addition it appears to be a protease that cleaves the nonstructural polyprotein precursors. It may also be involved in shutoff of minus-strand RNA synthesis. nsP4 appears to function as the viral polymerase or elongation factor. The functions of nsP3 are as yet unresolved.
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PMID:Mapping of RNA- temperature-sensitive mutants of Sindbis virus: assignment of complementation groups A, B, and G to nonstructural proteins. 272 21

The two variants of influenza A/Victoria/35/72 (H3N2) virus resistant simultaneously to remantadine, deitiforin, adapromine and amantadine were obtained while passaging the virus in presence of remantadine or deitiforin. Both variants differed from the parental strain in optimal pH for hemolysis, transcriptase activity and in amino acid sequence of M2 protein. Maximal hemolytic activity of the parental strain is registered at pH 5.2, for the variants cultured in the presence of remantadine or deitiforin at pH 5.5 and 5.8, respectively. In contrast to NH4OH, remantadine and deitiforin do not exert inhibition of virus-induced hemolysis. Transcriptase activity of resistant variants is about 50% higher as compared with parental strain (enzyme source--whole virus particles or RNP). The M2 protein of the remantadine variant has 2 amino acid substitutions: 31 (Ser----Asn) and 59 (Met----Leu); the deitiforin variant has 3 substitutions: 14 (Met----Leu), 30 (Ala----Val) and 59 (Met----Leu). The phenotypic resistance of the virus seems to be determined by the mutations in the hydrophobic protein region (30,31); the other substitutions (14,59) may modify conformational structure and functional activity of the viral proteins.
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PMID:[The change in functional activity and primary structure of the M2 protein in variants of the influenza virus resistant to remantadine and deitiforin: common and individual differences from the original strain]. 281

Four cAMP-independent receptor protein mutants (designated CRP* mutants) isolated previously are able to activate in vivo gene transcription in the absence of cAMP and their activity can be enhanced by cAMP or cGMP. One of the four mutant proteins, CRP*598 (Arg-142 to His, Ala-144 to Thr), has been characterized with regard to its conformational properties and ability to bind to and support abortive initiation from the lac promoter. In the absence of cGMP, CRP*598 shows a more open conformation than CRP, as indicated by its sensitivity to proteolytic attack and 5,5'-dithiobis(2-nitrobenzoic acid)-mediated subunit crosslinking. Binding of wild-type CRP to its site on the lac promoter and activation of abortive initiation by RNA polymerase on this promoter are effected by cAMP but not by cGMP. CRP*598 can activate lacP+-directed abortive initiation in the presence of cAMP and less efficiently in the presence of cGMP or in the absence of cyclic nucleotide. DNase I protection ("foot-printing") indicates that cAMP-CRP* binds to its site on the lac promoter whereas unliganded CRP* and cGMP-CRP* form a stable complex with the [32P]lacP+ fragment only in the presence of RNA polymerase, showing cooperative binding of two heterologous proteins. This cooperative binding provides strong evidence for a contact between CRP and RNA polymerase for activation of transcription. Although cGMP binds to CRP, it cannot replace cAMP in effecting the requisite conformational transition necessary for site-specific promoter binding. In contrast, the weakly active unliganded CRP*598 can be shifted to a functional state not only by cAMP but also by cGMP and RNA polymerase.
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PMID:Cooperative DNA binding of heterologous proteins: evidence for contact between the cyclic AMP receptor protein and RNA polymerase. 283 57


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