Posttranscriptional Activation of the Transcriptional Activator Rob by Dipyridyl in Escherichia coli

ABSTRACT The transcriptional activator Rob consists of an N-terminal domain (NTD) of 120 amino acids responsible for DNA binding and promoter activation and a C-terminal domain (CTD) of 169 amino acids of unknown function. Although several thousand molecules of Rob are normally present per Escherichia coli cell, they activate promoters of the rob regulon poorly. We report here that in cells treated with either 2,2"- or 4,4"-dipyridyl (the latter is not a metal chelator), Rob-mediated transcription of various rob regulon promoters was increased substantially. A small, growth-phase-dependent effect of dipyridyl on the rob promoter was observed. However, dipyridyl enhanced Rob's activity even when rob was regulated by a heterologous (lac) promoter showing that the action of dipyridyl is mainly posttranscriptional. Mutants lacking from 30 to 166 of the C-terminal amino acids of Rob had basal levels of activity similar to that of wild-type cells, but dipyridyl treatment did not enhance this activity. Thus, the CTD is not an inhibitor of Rob but is required for activation of Rob by dipyridyl. In contrast to its relatively low activity in vivo, Rob binding to cognate DNA and activation of transcription in vitro is similar to that of MarA, which has a homologous NTD but no CTD. In vitro nuclear magnetic resonance studies demonstrated that 2,2"-dipyridyl binds to Rob but not to the CTD-truncated Rob or to MarA, suggesting that the effect of dipyridyl on Rob is direct. Thus, it appears that Rob can be converted from a low activity state to a high-activity state by a CTD-mediated mechanism in vivo or by purification in vitro.

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The C-Terminal Flexible Domain of the Heme Chaperone CcmE Is Important but Not Essential for Its Function

Journal of Bacteriology ◽

10.1128/jb.185.13.3821-3827.2003 ◽

2003 ◽

Vol 185 (13) ◽

pp. 3821-3827 ◽

Cited By ~ 8

Author(s):

Elisabeth Enggist ◽

Linda Thöny-Meyer

Keyword(s):

Escherichia Coli ◽

Amino Acids ◽

Heme Binding ◽

Membrane Anchor ◽

Terminal Domain ◽

Conserved Domain ◽

C Terminus ◽

Helical Turn ◽

Low Activity

ABSTRACT CcmE is a heme chaperone active in the cytochrome c maturation pathway of Escherichia coli. It first binds heme covalently to strictly conserved histidine H130 and subsequently delivers it to apo-cytochrome c. The recently solved structure of soluble CcmE revealed a compact core consisting of a β-barrel and a flexible C-terminal domain with a short α-helical turn. In order to elucidate the function of this poorly conserved domain, CcmE was truncated stepwise from the C terminus. Removal of all 29 amino acids up to crucial histidine 130 did not abolish heme binding completely. For detectable transfer of heme to type c cytochromes, only one additional residue, D131, was required, and for efficient cytochrome c maturation, the seven-residue sequence 131DENYTPP137 was required. When soluble forms of CcmE were expressed in the periplasm, the C-terminal domain had to be slightly longer to allow detection of holo-CcmE. Soluble full-length CcmE had low activity in cytochrome c maturation, indicating the importance of the N-terminal membrane anchor for the in vivo function of CcmE.

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CovR Activation of the Dipeptide Permease Promoter (PdppA) in Group A Streptococcus

Journal of Bacteriology ◽

10.1128/jb.01036-06 ◽

2006 ◽

Vol 189 (4) ◽

pp. 1407-1416 ◽

Cited By ~ 15

Author(s):

Asiya A. Gusa ◽

Barbara J. Froehlich ◽

Devak Desai ◽

Virginia Stringer ◽

June R. Scott

Keyword(s):

Group A Streptococcus ◽

Response Regulator ◽

Activation Of Transcription ◽

Genes Encoding ◽

Group A ◽

Transcription In Vitro ◽

Dna Template ◽

Regulated Promoters

ABSTRACT CovR, the two-component response regulator of Streptococcus pyogenes (group A streptococcus [GAS]) directly or indirectly represses about 15% of the genome, including genes encoding many virulence factors and itself. Transcriptome analyses also showed that some genes are activated by CovR. We asked whether the regulation by CovR of one of these genes, dppA, the first gene in an operon encoding a dipeptide permease, is direct or indirect. Direct regulation by CovR was suggested by the presence of five CovR consensus binding sequences (CBs) near the putative promoter. In this study, we identified the 5′ end of the dppA transcript synthesized in vivo and showed that the start of dppA transcription in vitro is the same. We found that CovR binds specifically to the dppA promoter region (PdppA) in vitro with an affinity similar to that at which it binds to other CovR-regulated promoters. Disruption of any of the five CBs by a substitution of GG for TT inhibited CovR binding to that site in vitro, and binding at two of the CBs appeared cooperative. In vivo, CovR activation of transcription was not affected by individual mutations of any of the four CBs that we could study. This suggests that the binding sites are redundant in vivo. In vitro, CovR did not activate transcription from PdppA in experiments using purified GAS RNA polymerase and either linear or supercoiled DNA template. Therefore, we propose that in vivo, CovR may interfere with the binding of a repressor of PdppA.

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Molecular characterization of the TonB2 protein from the fish pathogen Vibrio anguillarum

Biochemical Journal ◽

10.1042/bj20081462 ◽

2009 ◽

Vol 418 (1) ◽

pp. 49-59 ◽

Cited By ~ 14

Author(s):

Claudia S. López ◽

R. Sean Peacock ◽

Jorge H. Crosa ◽

Hans J. Vogel

Keyword(s):

Amino Acids ◽

Solution Structure ◽

Bacterial Species ◽

Vibrio Anguillarum ◽

Fish Pathogen ◽

E Coli ◽

Terminal Domain ◽

C Terminus

In the fish pathogen Vibrio anguillarum the TonB2 protein is essential for the uptake of the indigenous siderophore anguibactin. Here we describe deletion mutants and alanine replacements affecting the final six amino acids of TonB2. Deletions of more than two amino acids of the TonB2 C-terminus abolished ferric-anguibactin transport, whereas replacement of the last three residues resulted in a protein with wild-type transport properties. We have solved the high-resolution solution structure of the TonB2 C-terminal domain by NMR spectroscopy. The core of this domain (residues 121–206) has an αββαβ structure, whereas residues 76–120 are flexible and extended. This overall folding topology is similar to the Escherichia coli TonB C-terminal domain, albeit with two differences: the β4 strand found at the C-terminus of TonB is absent in TonB2, and loop 3 is extended by 9 Å (0.9 nm) in TonB2. By examining several mutants, we determined that a complete loop 3 is not essential for TonB2 activity. Our results indicate that the β4 strand of E. coli TonB is not required for activity of the TonB system across Gram-negative bacterial species. We have also determined, through NMR chemical-shift-perturbation experiments, that the E. coli TonB binds in vitro to the TonB box from the TonB2-dependent outer membrane transporter FatA; moreover, it can substitute in vivo for TonB2 during ferric-anguibactin transport in V. anguillarum. Unexpectedly, TonB2 did not bind in vitro to the FatA TonB-box region, suggesting that additional factors may be required to promote this interaction. Overall our results indicate that TonB2 is a representative of a different class of TonB proteins.

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Inducible degradation of I kappa B alpha in vitro and in vivo requires the acidic C-terminal domain of the protein.

Molecular and Cellular Biology ◽

10.1128/mcb.15.5.2413 ◽

1995 ◽

Vol 15 (5) ◽

pp. 2413-2419 ◽

Cited By ~ 66

Author(s):

M S Rodriguez ◽

I Michalopoulos ◽

F Arenzana-Seisdedos ◽

R T Hay

Keyword(s):

Amino Acids ◽

Proteolytic Activity ◽

Cell Activation ◽

Nf Kappa B ◽

Free System ◽

In Vitro System ◽

I Kappa B Alpha ◽

Terminal Domain

After exposure of cells to tumor necrosis factor (TNF), I kappa B alpha is rapidly degraded by a proteolytic activity that is required for nuclear localization and activation of transcription factor NF-kappa B. To investigate this problem, we have developed a cell-free system to study the degradation of I kappa B alpha initiated in vivo. In this in vitro system, characteristics of endogenous I kappa B alpha degradation were comparable to those observed in vivo. Recombinant I kappa B alpha, when added to lysates from cells exposed to TNF, was specifically degraded by a cellular proteolytic activity; however, it was stable in extracts from unstimulated cells. Inhibition characteristics of the proteolytic activity responsible for I kappa B alpha degradation suggest the involvement of a serine protease. Analysis of mutated forms of I kappa B alpha in the in vitro system demonstrated that an I kappa B alpha species which was unable to interact with NF-kappa B was still efficiently degraded. In contrast, deletion of the C-terminal 61 amino acids from I kappa B alpha rendered the protein resistant to proteolytic degradation. Expression of I kappa B alpha mutated forms in COS-7 cells confirmed the importance of the C-terminal domain for the degradation of the protein in vivo following cell activation. Thus, it is likely that the acidic, negatively charged region represented by the C-terminal 61 amino acids of the protein contains residues critical for TNF-inducible degradation of I kappa B alpha.

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Convergent In Vivo and In Vitro Selection of Ceftazidime Resistance Mutations at Position 167 of CTX-M-3 β-Lactamase in Hypermutable Escherichia coli Strains

Antimicrobial Agents and Chemotherapy ◽

10.1128/aac.01060-07 ◽

2008 ◽

Vol 52 (4) ◽

pp. 1297-1301 ◽

Cited By ~ 12

Author(s):

Marina N. Stepanova ◽

Maxim Pimkin ◽

Anatoly A. Nikulin ◽

Varvara K. Kozyreva ◽

Elena D. Agapova ◽

...

Keyword(s):

Escherichia Coli ◽

Molecular Typing ◽

In Vitro Selection ◽

Resistance Mutations ◽

Natural Evolution ◽

E Coli ◽

Low Activity ◽

Selection Of

ABSTRACT We report on a novel CTX-M extended-spectrum β-lactamase (ESBL), designated CTX-M-42, with enhanced activity toward ceftazidime. CTX-M-42 was identified in a hypermutable Escherichia coli nosocomial isolate (isolate Irk2320) and is a Pro167Thr amino acid substitution variant of CTX-M-3. By molecular typing of ESBL-producing E. coli strains previously isolated in the same hospital ward, we were able to identify a putative progenitor (strain Irk1224) of Irk2320, which had a mutator phenotype and harbored the CTX-M-3 β-lactamase. To reproduce the natural evolution of CTX-M-3, we selected for ceftazidime resistance mutations in bla CTX-M-3 gene in vitro both in clinical isolate Irk1224 and in laboratory-derived hypermutable (mutD5) strain GM2995. These experiments yielded CTX-M-3Pro167Ser and CTX-M-3Asn136Lys mutants which conferred higher levels of resistance to ceftazidime than to cefotaxime. CTX-M-3Asn136Lys had a level of low activity toward ampicillin, which may explain its absence from clinical isolates. We conclude that the selection of CTX-M-42 could have occurred in vivo following treatment with ceftazidime and was likely facilitated by the hypermutable background.

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Acetolactate Synthase from Bacillus subtilis Serves as a 2-Ketoisovalerate Decarboxylase for Isobutanol Biosynthesis in Escherichia coli

Applied and Environmental Microbiology ◽

10.1128/aem.01160-09 ◽

2009 ◽

Vol 75 (19) ◽

pp. 6306-6311 ◽

Cited By ~ 65

Author(s):

Shota Atsumi ◽

Zhen Li ◽

James C. Liao

Keyword(s):

Escherichia Coli ◽

Amino Acids ◽

Bacillus Subtilis ◽

Lactococcus Lactis ◽

Acetolactate Synthase ◽

Side Chains ◽

Decarboxylase Activity ◽

Small Side

ABSTRACTA pathway toward isobutanol production previously constructed inEscherichia coliinvolves 2-ketoacid decarboxylase (Kdc) fromLactococcus lactisthat decarboxylates 2-ketoisovalerate (KIV) to isobutyraldehyde. Here, we showed that a strain lacking Kdc is still capable of producing isobutanol. We found that acetolactate synthase fromBacillus subtilis(AlsS), which originally catalyzes the condensation of two molecules of pyruvate to form 2-acetolactate, is able to catalyze the decarboxylation of KIV like Kdc both in vivo and in vitro. Mutational studies revealed that the replacement of Q487 with amino acids with small side chains (Ala, Ser, and Gly) diminished only the decarboxylase activity but maintained the synthase activity.

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The Escherichia coli Ada Protein Can Interact with Two Distinct Determinants in the ς70 Subunit of RNA Polymerase According to Promoter Architecture: Identification of the Target of Ada Activation at the alkAPromoter

Journal of Bacteriology ◽

10.1128/jb.181.5.1524-1529.1999 ◽

1999 ◽

Vol 181 (5) ◽

pp. 1524-1529 ◽

Cited By ~ 34

Author(s):

Paolo Landini ◽

Stephen J. W. Busby

Keyword(s):

Escherichia Coli ◽

Amino Acids ◽

Rna Polymerase ◽

Promoter Architecture ◽

Charged Amino Acids ◽

Identify Amino Acid ◽

Ada Protein ◽

Positively Charged

ABSTRACT The methylated form of the Ada protein (meAda) activates transcription from the Escherichia coli ada,aidB, and alkA promoters with different mechanisms. In this study we identify amino acid substitutions in region 4 of the RNA polymerase subunit ς70 that affect Ada-activated transcription at alkA. Substitution to alanine of residues K593, K597, and R603 in ς70 region 4 results in decreased Ada-dependent binding of RNA polymerase to thealkA promoter in vitro and impairs alkAtranscription both in vivo and in vitro, suggesting that these residues define a determinant for meAda-ς70interaction. In a previous study (P. Landini, J. A. Bown, M. R. Volkert, and S. J. W. Busby, J. Biol. Chem. 273:13307–13312, 1998), we showed that a set of negatively charged amino acids in ς70 region 4 is involved inmeAda-ς70 interaction at the adaand aidB promoters. However, the alanine substitutions of positively charged residues K593, K597, and R603 do not affectmeAda-dependent transcription at ada andaidB. Unlike the ς70 amino acids involved in the interaction with meAda at the ada andaidB promoters, K593, K597, and R603 are not conserved in ςS, an alternative ς subunit of RNA polymerase mainly expressed during the stationary phase of growth. WhilemeAda is able to promote transcription by the ςS form of RNA polymerase (EςS) atada and aidB, it fails to do so atalkA. We propose that meAda can activate transcription at different promoters by contacting distinct determinants in ς70 region 4 in a manner dependent on the location of the Ada binding site.

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Autonomous Role of 3′-Terminal CCCA in Directing Transcription of RNAs by Qβ Replicase

Journal of Virology ◽

10.1128/jvi.75.23.11373-11383.2001 ◽

2001 ◽

Vol 75 (23) ◽

pp. 11373-11383 ◽

Cited By ~ 10

Author(s):

David M. Tretheway ◽

Shigeo Yoshinari ◽

Theo W. Dreher

Keyword(s):

Escherichia Coli ◽

Secondary Structure ◽

Similar Sequence ◽

Transcriptional Initiation ◽

Template Sequence ◽

Transcription In Vitro ◽

Internal Initiation

ABSTRACT We have studied transcription in vitro by Qβ replicase to deduce the minimal features needed for efficient end-to-end copying of an RNA template. Our studies have used templates ca. 30 nucleotides long that are expected to be free of secondary structure, permitting unambiguous analysis of the role of template sequence in directing transcription. A 3′-terminal CCCA (3′-CCCA) directs transcriptional initiation to opposite the underlined C; the amount of transcription is comparable between RNAs possessing upstream (CCA) n tracts, A-rich sequences, or a highly folded domain and is also comparable in single-round transcription assays to transcription of two amplifiable RNAs. Predominant initiation occurs within the 3′-CCCA initiation box when a wide variety of sequences is present immediately upstream, but CCA or a closely similar sequence in that position results in significant internal initiation. Removal of the 3′-A from the 3′-CCCA results in 5- to 10-fold-lower transcription, emphasizing the importance of the nontemplated addition of 3′-A by Qβ replicase during termination. In considering whether 3′-CCCA could provide sufficient specificity for viral transcription, and consequently amplification, in vivo, we note that tRNAHis is the only stable Escherichia coliRNA with 3′-CCCA. In vitro-generated transcripts corresponding to tRNAHis served as poor templates for Qβ replicase; this was shown to be due to the inaccessibility of the partially base-paired CCCA. These studies demonstrate that 3′-CCCA plays a major role in the control of transcription by Qβ replicase and that the abundant RNAs present in the host cell should not be efficient templates.

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An Atypical KdpD Homologue from the Cyanobacterium Anabaena sp. Strain L-31: Cloning, In Vivo Expression, and Interaction with Escherichia coli KdpD-CTD

Journal of Bacteriology ◽

10.1128/jb.187.14.4921-4927.2005 ◽

2005 ◽

Vol 187 (14) ◽

pp. 4921-4927 ◽

Cited By ~ 5

Author(s):

Anand Ballal ◽

Marc Bramkamp ◽

Hema Rajaram ◽

Petra Zimmann ◽

Shree Kumar Apte ◽

...

Keyword(s):

Escherichia Coli ◽

Response Regulator ◽

Nitrilotriacetic Acid ◽

Soluble Form ◽

Filamentous Cyanobacterium ◽

E Coli ◽

Transmembrane Segments ◽

Terminal Domain

ABSTRACT The kdpFABC operon of Escherichia coli, coding for the high-affinity K+ transport system KdpFABC, is transcriptionally regulated by the products of the adjacently located kdpDE genes. The KdpD protein is a membrane-bound sensor kinase consisting of a large N-terminal domain and a C-terminal transmitter domain interconnected by four transmembrane segments (the transmembrane segments together with the C-terminal transmitter domain of KdpD are referred to as CTD), while KdpE is a cytosolic response regulator. We have cloned and sequenced the kdp operon from a nitrogen-fixing, filamentous cyanobacterium, Anabaena sp. strain L-31 (GenBank accession. number AF213466 ). The kdpABC genes are similar in size to those of E. coli, but the kdpD gene is short (coding only for 365 amino acids), showing homology only to the N-terminal domain of E. coli KdpD. A kdpE-like gene is absent in the vicinity of this operon. Anabaena KdpD with six C-terminal histidines was overproduced in E. coli and purified by Ni2+-nitrilotriacetic acid affinity chromatography. With antisera raised against the purified Anabaena KdpD, the protein was detected in Anabaena sp. strain L-31 membranes. The membrane-associated or soluble form of the Anabaena KdpD(6His) could be photoaffinity labeled with the ATP analog 8-azido-ATP, indicating the presence of an ATP binding site. The coproduction of Anabaena KdpD with E. coli KdpD-CTD decreased E. coli kdpFABC expression in response to K+ limitation in vivo relative to the wild-type KdpD-CTD protein. In vitro experiments revealed that the kinase activity of the E. coli KdpD-CTD was unaffected, but its phosphatase activity increased in the presence of Anabaena KdpD(6His). To our knowledge this is the first report where a heterologous N-terminal domain (Anabaena KdpD) is shown to affect in trans KdpD-CTD (E. coli) activity, which is just opposite to that observed for the KdpD-N-terminal domain of E. coli.

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