A gene from Escherichia coli affecting the sigma subunit of RNA polymerase.

Harris, Jeffrey D.; Martinez, Iris I.; Calendar, Richard

doi:10.1073/pnas.74.5.1836

Cited by 42 publications

(12 citation statements)

References 29 publications

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“…Similarly, P-galactosidase from K. aerogenes differs greatly in primary sequence from that of E. coli (9), and the K. aerogenes P-galactosidase is far more thermolabile under standard assay conditions than the E. coli enzyme (4). Even the sigma subunits of RNA polymerase from E. coli K-12, E. coli C, and S. typhimurium migrate differently on sodium dodecyl sulfate-polyacrylamide gels (19,21).…”

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confidence: 99%

Klebsiella aerogenes catabolite gene activator protein and the gene encoding it (crp)

Osuna

Bender

1991

J Bacteriol

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The catabolite gene activator protein from Klebsiella aerogenes (CAPK) and the corresponding protein from Escherichia coli (CAPE) were shown to be nearly identical. Both CAPK and CAPE activated transcription from the CAP-dependent promoters derived from E. coli and K. aerogenes. The crp gene from K. aerogenes (encoding CAP) is tightly linked to rpsL. The nucleotide sequence of crp predicts an amino acid sequence for CAPK that differs in only one position from that of CAPE.

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Section: ----------T--g--t ----T----t--t--c---c-g -----------------C mentioning

confidence: 99%

Klebsiella aerogenes catabolite gene activator protein and the gene encoding it (crp)

Osuna

Bender

1991

J Bacteriol

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“…One way to regulate global gene expression is to modulate the interaction of different a factors with core RNA polymerase in response to physiological and environmental changes (19,26,37). a70, the major a factor in E. coli, is encoded by rpoD (12,18,31) and is essential for cell growth (17,25,35). The rpoD285 mutation and the genetically identical rpoD800 mutation confer a temperature-sensitive (Ts) growth phenotype (17,20,25,30,35) because this mutant sigma factor is unstable and rapidly degraded at high temperature (12, 13).…”

mentioning

confidence: 99%

“…a70, the major a factor in E. coli, is encoded by rpoD (12,18,31) and is essential for cell growth (17,25,35). The rpoD285 mutation and the genetically identical rpoD800 mutation confer a temperature-sensitive (Ts) growth phenotype (17,20,25,30,35) because this mutant sigma factor is unstable and rapidly degraded at high temperature (12,13).…”

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confidence: 99%

A mutant sigma 32 with a small deletion in conserved region 3 of sigma has reduced affinity for core RNA polymerase

1992

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.70, encoded by rpoD, is the major v factor in Escherichia coli. rpoD285 (rpoD800) is a small deletion mutation in rpoD that confers a temperature-sensitive growth phenotype because the mutant (o70 is rapidly degraded at high temperature. Extragenic mutations which reduce the rate of degradation of RpoD285 &70 permit growth at high temperature. One class of such suppressors is located in rpoH, the gene encoding &2, an alternative cr factor required for transcription of the heat shock genes. One of these, rpoH113, is incompatible with rpoD+. We determined the mechanism of incompatibility. Although RpoH113 &32 continues to be made when wild-type &70 is present, cells show reduced ability to express heat shock genes and to transcribe from heat shock promoters. Glycerol gradient fractionation of &2 into the holoenzyme and free sigma suggests that RpoH113 &2 has a lower binding affinity for core RNA polymerase than does wild-type 2 . The presence of wild-type a70 exacerbates this defect. We suggest that the reduced ability of RpoH113 &2 to compete with wild-type a70 for core RNA polymerase explains the incompatibility between rpoH113 and rpoD+. The rpoH113 cells would have reduced amounts of -2 holoenzyme and thus be unable to express sufficient amounts of the essential heat shock proteins to maintain viability.Transcription in Escherichia coli is carried out by RNA polymerase, which exists in two forms: core RNA polymerase (a%2, 13, 1'; or E), which carries out elongation and termination, and holoenzyme (a2, 3, 1', C; or Ea), which carries out specific initiation at promoter regions of the DNA (2). E. coli contains multiple sigma factors, and the specificity of promoter binding is determined by the particular a subunit associated with the holoenzyme (for reviews, see references 19 and 37). One way to regulate global gene expression is to modulate the interaction of different a factors with core RNA polymerase in response to physiological and environmental changes (19,26,37). a70, the major a factor in E. coli, is encoded by rpoD (12,18,31) and is essential for cell growth (17,25,35). The rpoD285 mutation and the genetically identical rpoD800 mutation confer a temperature-sensitive (Ts) growth phenotype (17,20,25,30,35) because this mutant sigma factor is unstable and rapidly degraded at high temperature (12, 13). Structural changes in the mutant sigma factor resulting from the 42-bp in-frame deletion in the rpoD285 (rpoD800) allele presumably lead to its instability in vivo (13,20) and in vitro (27). One class of extragenic suppressors of rpoD285 is located in rpoH (htpR), the gene which encodes a32 (14,32,33,45 likely that such a study could provide some insight into how various sigma factors interact in the cell to modulate transcription. Our results indicate that the mutant a32 is present in cells expressing wild-type a70 but is unable to promote transcription from heat shock promoters, probably because it is ineffective in competing with wild-type &7 for binding to core RNA polymerase. This would lead to diminis...

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“…This mapping method depends upon the direct quantitation of RRF after separation of total cell proteins by two-dimensional gel electrophoresis (29). Although the method itself has been used by several investigators, the quantitation has been performed solely by immunological means (12,28). In mapping the tRNA genes, Ikemura and Ozeki (19) used two-dimensional gel electrophoresis for separation and subsequent quantitation of each tRNA species.…”

Section: Discussionmentioning

confidence: 99%

Localization of the ribosome-releasing factor gene in the Escherichia coli chromosome

et al. 1989

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The ribosome-releasing factor (RRF) gene was localized at a position between 2 and 6 min on the Escherichia coli chromosome by measuring the gene-dosage-dependent production of RRF in various E. coli F' merozygotes. This position was confirmed and refined by using a nucleotide probe corresponding to a 16-amino-acid sequence in RRF. It was found that the RRF gene was contained in pLC 6-32 of the Clark-Carbon Gene Bank. Restriction enzyme mapping of E. coli genomic DNA with the above probe led us to conclude that the RRF gene is situated in the 4-min region, somewhere downstream (clockwise) of the elongation factor Ts gene, tsf. A pLC 6-32-derived DNA fragment which carries the RRF gene was found to contain a partial sequence of tsf. The exact location of the translational initiation site of the RRF gene was determined to be 1.1 kilobases downstream from the translational termination site of tsf. The RRF gene is designated frr.

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A gene from Escherichia coli affecting the sigma subunit of RNA polymerase.

Cited by 42 publications

References 29 publications

Klebsiella aerogenes catabolite gene activator protein and the gene encoding it (crp)

Klebsiella aerogenes catabolite gene activator protein and the gene encoding it (crp)

A mutant sigma 32 with a small deletion in conserved region 3 of sigma has reduced affinity for core RNA polymerase

Localization of the ribosome-releasing factor gene in the Escherichia coli chromosome

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