Functional map of the alpha subunit of Escherichia coli RNA polymerase: two modes of transcription activation by positive factors

A Copper-Responsive Two-Component System Governs Lipoprotein Remodeling in Listeria monocytogenes

Bacterial lipoproteins are membrane-associated proteins with a characteristic acylated N-terminal cysteine residue anchoring C-terminal globular domains to the membrane surface. While all lipoproteins are modified with acyl chains, the number, length, and position can vary depending on host. The acylation pattern also alters ligand recognition by the Toll-like receptor 2 (TLR2) protein family, a signaling system that is central to bacterial surveillance and innate immunity. In select Listeria monocytogenes isolates carrying certain plasmids, copper exposure converts the lipoprotein chemotype into a weak TLR2 ligand through expression of the enzyme lipoprotein intramolecular acyltransferase (Lit). In this study, we identify the response regulator (CopR) from a heavy metal-sensing two-component system as the transcription factor that integrates external copper levels with lipoprotein structural modifications. We show that phosphorylated CopR controls the expression of three distinct transcripts within the plasmid cassette encoding Lit2, prolipoprotein diacylglyceryl transferase (Lgt2), putative copper resistance determinants, and itself (the CopRS two-component system). CopR recognizes a direct repeat half-site consensus motif (TCTACACA) separated by 3 bp that overlaps the -35 promoter element. Target gene expression and lipoprotein conversion were not observed in the absence of the response regulator, indicating that CopR phosphorylation is the dominant mechanism of regulation. IMPORTANCE Copper is a frontline antimicrobial used to limit bacterial growth in multiple settings. Here, we demonstrate how the response regulator CopR from a plasmid-borne two-component system in the opportunistic pathogen L. monocytogenes directly induces lipoprotein remodeling in tandem with copper resistance genes due to extracellular copper stress. Activation of CopR by phosphorylation converts the lipoprotein chemotype from a high- to low-immunostimulatory TLR2 ligand. The two-component system-mediated coregulation of copper resistance determinants, in tandem with lipoprotein biosynthesis demonstrated here in L. monocytogenes, may be a common feature of transmissible copper resistance cassettes found in other Firmicutes.

Redox Brake Regulator RedB and FnrL Function as Yin-Yang Regulators of Anaerobic-Aerobic Metabolism in Rhodobacter capsulatus

We recently described a new member of the CRP (cyclic AMP receptor protein)/FNR (fumarate and nitrate reductase regulatory protein) family called RedB, an acronym for redox brake, that functions to limit the production of ATP and NADH. This study shows that the RedB regulon significantly overlaps the FnrL regulon, with 199 genes being either directly or indirectly regulated by both of these global regulatory proteins. Among these 199 coregulated genes, 192 are divergently regulated, indicating that RedB functions as an antagonist of FnrL. Chromatin immunoprecipitation sequencing (ChIP-seq) analysis indicates that RedB and Fnr directly coregulate only 4 out of 199 genes. The primary mechanism for the divergent regulation of target genes thus involves indirect regulation by both RedB and FnrL (156 cases). Additional regulation involves direct binding by RedB and indirect regulation by FnrL (36 cases) or direct binding by FnrL and indirect regulation by RedB (3 cases). Analysis of physiological pathways under direct and indirect control by these global regulators demonstrates that RedB functions primarily to limit energy production, while FnrL functions to enhance energy production. This regulation includes glycolysis, gluconeogenesis, photosynthesis, hydrogen oxidation, electron transport, carbon fixation, lipid biosynthesis, and protein synthesis. Finally, we show that 75% of genomes from diverse species that code for RedB proteins also harbor genes coding for FNR homologs. This cooccurrence indicates that RedB likely has an important role in buffering FNR-mediated energy production in a broad range of species. IMPORTANCE The CRP/FNR family of regulatory proteins constitutes a large collection of related transcription factors, several of which globally regulate cellular energy production. A well-characterized example is FNR (called FnrL in Rhodobacter capsulatus), which is responsible for regulating the expression of numerous genes that promote maximal energy production and growth under anaerobic conditions. In a companion article (N. Ke, J. E. Kumka, M. Fang, B. Weaver, et al., Microbiol Spectr 10:e02353-22, 2022, https://doi.org/10.1128/Spectrum02353-22), we identified a new subgroup of the CRP/FNR family and demonstrated that a member of this new subgroup, called RedB, has a role in limiting cellular energy production. In this study, we show that numerous genes encompassing the RedB regulon significantly overlap genes that are members of the FnrL regulon. Furthermore, 97% of the genes that are members of both the RedB and FnrL regulons are divergently regulated by these two transcription factors. RedB thus functions as a buffer limiting the amount of energy production that is promoted by FnrL.

EnvZ/OmpR Two-Component Signaling: An Archetype System That Can Function Noncanonically

Two-component regulatory systems represent the major paradigm for signal transduction in prokaryotes. The simplest systems are composed of a sensor kinase and a response regulator. The sensor is often a membrane protein that senses a change in environmental conditions and is autophosphorylated by ATP on a histidine residue. The phosphoryl group is transferred onto an aspartate of the response regulator, which activates the regulator and alters its output, usually resulting in a change in gene expression. In this review, we present a historical view of the archetype EnvZ/OmpR two-component signaling system, and then we provide a new view of signaling based on our recent experiments. EnvZ responds to cytoplasmic signals that arise from changes in the extracellular milieu, and OmpR acts canonically (requiring phosphorylation) to regulate the porin genes and noncanonically (without phosphorylation) to activate the acid stress response. Herein, we describe how insights gleaned from stimulus recognition and response in EnvZ are relevant to nearly all sensor kinases and response regulators.

The master quorum-sensing regulators LuxR/HapR directly interact with the alpha subunit of RNA polymerase to drive transcription activation in Vibrio harveyi and Vibrio cholerae

In Vibrio species, quorum sensing controls gene expression for numerous group behaviors, including bioluminescence production, biofilm formation, virulence factor secretion systems, and competence. The LuxR/HapR master quorum-sensing regulators activate expression of hundreds of genes in response to changes in population densities. The mechanism of transcription activation by these TetR-type transcription factors is unknown, though LuxR DNA binding sites that lie in close proximity to the -35 region of the promoter are required for activation at some promoters. Here, we show that Vibrio harveyi LuxR directly interacts with RNA polymerase to activate transcription of the luxCDABE bioluminescence genes. LuxR interacts with RNA polymerase in vitro and in vivo and specifically interacts with both the N- and C-terminal domains of the RNA polymerase α-subunit. Amino acid substitutions in the RNAP interaction domain on LuxR decrease interactions between LuxR and the α-subunit and result in defects in transcription activation of quorum-sensing genes in vivo. The RNAP-LuxR interaction domain is conserved in Vibrio cholerae HapR and is required for activation of the HapR-regulated gene hapA. Our findings support a model in which LuxR/HapR bind proximally to RNA polymerase to drive transcription initiation at a subset of quorum-sensing genes in Vibrio species.

Structure and dynamics of polymyxin-resistance-associated response regulator PmrA in complex with promoter DNA

PmrA, an OmpR/PhoB family response regulator, manages genes for antibiotic resistance. Phosphorylation of OmpR/PhoB response regulator induces the formation of a symmetric dimer in the N-terminal receiver domain (REC), promoting two C-terminal DNA-binding domains (DBDs) to recognize promoter DNA to elicit adaptive responses. Recently, determination of the KdpE-DNA complex structure revealed an REC-DBD interface in the upstream protomer that may be necessary for transcription activation. Here, we report the 3.2-Å-resolution crystal structure of the PmrA-DNA complex, which reveals a similar yet different REC-DBD interface. However, NMR studies show that in the DNA-bound state, two domains tumble separately and an REC-DBD interaction is transiently populated in solution. Reporter gene analyses of PmrA variants with altered interface residues suggest that the interface is not crucial for supporting gene expression. We propose that REC-DBD interdomain dynamics and the DBD-DBD interface help PmrA interact with RNA polymerase holoenzyme to activate downstream gene transcription.

Expanded roles of two-component response regulator OmpR in Escherichia coli: genomic SELEX search for novel regulation targets

The two-component system (TCS) is a sophisticated bacterial signal transduction system for regulation of genome transcription in response to environmental conditions. The EnvZ-OmpR system is one of the well-characterized TCS of Escherichia coli, responding to changes in environmental osmolality. Regulation has largely focused on the differential expression of two porins, OmpF and OmpC, which transport small molecules across the outer membrane. Recently, it has become apparent that OmpR serves a more global regulatory role and regulates additional targets. To identify the entire set of regulatory targets of OmpR, we performed the genomic SELEX screening of OmpR-binding sites along the E. coli genome. As a result, more than 30 novel genes have been identified to be under the direct control of OmpR. One abundant group includes the genes encoding a variety of membrane-associated transporters that mediate uptake or efflux of small molecules, while another group encodes a set of transcription regulators, raising a concept that OmpR is poised to control a diverse set of responses by altering downstream transcriptional regulators.

MG428 is a novel positive regulator of recombination that triggers mgpB and mgpC gene variation in Mycoplasma genitalium

The human pathogen Mycoplasma genitalium employs homologous recombination to generate antigenic diversity in the immunodominant MgpB and MgpC proteins. Only recently, some of the molecular factors involved in this process have been characterized, but nothing is known about its regulation. Here, we show that M. genitalium expresses N-terminally truncated RecA isoforms via alternative translation initiation, but only the full-length protein is essential for gene variation. We also demonstrate that overexpression of MG428 positively regulates the expression of recombination genes, including recA, ruvA, ruvB and ORF2, a gene of unknown function co-transcribed with ruvAB. The co-ordinated induction of these genes correlated with an increase of mgpBC gene variation. In contrast, cells lacking MG428 were unable to generate variants despite expressing normal levels of RecA. Similarly, deletion analyses of the recA upstream region defined sequences required for gene variation without abolishing RecA expression. The requirement of these sequences is consistent with the presence of promoter elements associated with MG428-dependent recA induction. Sequences upstream of recA also influence the relative abundance of RecA isoforms, possibly through translational regulation. Overall, these results suggest that MG428 is a positive regulator of recombination and that precise control of recA expression is required to initiate mgpBC variation.

The hierarchic network of metal-response transcription factors in Escherichia coli

Enterobacteria such as Escherichia coli are able to survive under various environments within host animals by changes of the expression pattern of its genome. The selective expression of genes in its genome takes place by controlling the promoter recognition properties of RNA polymerase by protein-protein interplays with transcription factors. In this review, I describe the regulatory network formed by the metal-sensing transcription factors in E. coli. Comprehensive analyses identify the set of regulation targets for a total of 13 metal-response transcription factors, indicating that nine species of transcription factors are local regulators while four species of transcription factors are global regulators. The signal transduction pathways for these metal-response regulons show not only the complex cross-talks but also the hierarchic multi-regulatory network. This regulatory network seems to play a role for E. coli survival to colonize in a large intestine within host animals.

Interactions of the CpxA sensor kinase and cognate CpxR response regulator from Yersinia pseudotuberculosis

BACKGROUND

The CpxA sensor kinase-CpxR response regulator two-component regulatory system is a sentinel of bacterial envelope integrity. Integrating diverse signals, it can alter the expression of a wide array of components that serve to shield the envelope from damage and to promote bacterial survival. In bacterial pathogens such as Yersinia pseudotuberculosis, this also extends to pathogenesis. CpxR is thought to dimerize upon phosphorylation by the sensor kinase CpxA. This phosphorylation enables CpxR binding to specific DNA sequences where it acts on gene transcription. As Cpx pathway activation is dependent on protein-protein interactions, we performed an interaction analysis of CpxR and CpxA from Y. pseudotuberculosis.

RESULTS

CpxR full-length and truncated versions that either contained or lacked a putative internal linker were all assessed for their ability to homodimerize and interact with CpxA. Using an adenylate cyclase-based bacterial two hybrid approach, full-length CpxR readily engaged with CpxA. The CpxR N-terminus could also homodimerize with itself and with a full-length CpxR. A second homodimerization assay based upon the λcI repressor also demonstrated that the CpxR C-terminus could homodimerize. While the linker was not specifically required, it enhanced CpxR homodimerization. Mutagenesis of cpxR identified the aspartate at residue 51, putative N-terminal coiled-coil and C-terminal winged-helix-turn-helix domains as mediators of CpxR homodimerization. Scrutiny of CpxA full-length and truncated versions revealed that dimerization involved the N-terminus and an internal dimerization and histidine phosphotransfer domain.

CONCLUSIONS

This interaction analysis mapped regions of CpxR and CpxA that were responsible for interactions with self or with each other. When combined with other physiological and biochemical tests both hybrid-based assays can be useful in dissecting molecular contacts that may underpin Cpx pathway activation and repression.

Activating transcription in bacteria

Bacteria use a variety of mechanisms to direct RNA polymerase to specific promoters in order to activate transcription in response to growth signals or environmental cues. Activation can be due to factors that interact at specific promoters, thereby increasing transcription directed by these promoters. We examine the range of architectures found at activator-dependent promoters and outline the mechanisms by which input from different factors is integrated. Alternatively, activation can be due to factors that interact with RNA polymerase and change its preferences for target promoters. We summarize the different mechanistic options for activation that are focused directly on RNA polymerase.

Regulatory effects of cAMP receptor protein (CRP) on porin genes and its own gene in Yersinia pestis

Background

The cAMP receptor protein (CRP) is a global bacterial regulator that controls many target genes. The CRP-cAMP complex regulates the ompR-envZ operon in E. coli directly, involving both positive and negative regulations of multiple target promoters; further, it controls the production of porins indirectly through its direct action on ompR-envZ. Auto-regulation of CRP has also been established in E. coli. However, the regulation of porin genes and its own gene by CRP remains unclear in Y. pestis.

Results

Y. pestis employs a distinct mechanism indicating that CRP has no regulatory effect on the ompR-envZ operon; however, it stimulates ompC and ompF directly, while repressing ompX. No transcriptional regulatory association between CRP and its own gene can be detected in Y. pestis, which is also in contrast to the fact that CRP acts as both repressor and activator for its own gene in E. coli. It is likely that Y. pestis OmpR and CRP respectively sense different signals (medium osmolarity, and cellular cAMP levels) to regulate porin genes independently.

Conclusion

Although the CRP of Y. pestis shows a very high homology to that of E. coli, and the consensus DNA sequence recognized by CRP is shared by the two bacteria, the Y. pestis CRP can recognize the promoters of ompC, F, and X directly rather than that of its own gene, which is different from the relevant regulatory circuit of E. coli. Data presented here indicate a remarkable remodeling of the CRP-mediated regulation of porin genes and of its own one between these two bacteria.

The Structural Basis of Signal Transduction for the Response Regulator PrrA from Mycobacterium tuberculosis

The structure of the two-domain response regulator PrrA from Mycobacterium tuberculosis shows a compact structure in the crystal with a well defined interdomain interface. The interface, which does not include the interdomain linker, makes the recognition helix and the trans-activation loop of the effector domain inaccessible for interaction with DNA. Part of the interface involves hydrogen-bonding interactions of a tyrosine residue in the receiver domain that is believed to be involved in signal transduction, which, if disrupted, would destabilize the interdomain interface, allowing a more extended conformation of the molecule, which would in turn allow access to the recognition helix. In solution, there is evidence for an equilibrium between compact and extended forms of the protein that is far toward the compact form when the protein is inactivated but moves toward a more extended form when activated by the cognate sensor kinase PrrB.

Showing your ID: intrinsic disorder as an ID for recognition, regulation and cell signaling

Regulation, recognition and cell signaling involve the coordinated actions of many players. To achieve this coordination, each participant must have a valid identification (ID) that is easily recognized by the others. For proteins, these IDs are often within intrinsically disordered (also ID) regions. The functions of a set of well-characterized ID regions from a diversity of proteins are presented herein to support this view. These examples include both more recently described signaling proteins, such as p53, alpha-synuclein, HMGA, the Rieske protein, estrogen receptor alpha, chaperones, GCN4, Arf, Hdm2, FlgM, measles virus nucleoprotein, RNase E, glycogen synthase kinase 3beta, p21(Waf1/Cip1/Sdi1), caldesmon, calmodulin, BRCA1 and several other intriguing proteins, as well as historical prototypes for signaling, regulation, control and molecular recognition, such as the lac repressor, the voltage gated potassium channel, RNA polymerase and the S15 peptide associating with the RNA polymerase S-protein. The frequent occurrence and the common use of ID regions in important protein functions raise the possibility that the relationship between amino acid sequence, disordered ensemble and function might be the dominant paradigm for the molecular recognition that serves as the basis for signaling and regulation by protein molecules.

The response regulator SsrB activates transcription and binds to a region overlapping OmpR binding sites at Salmonella pathogenicity island 2

OmpR activates expression of the two-component regulatory system located on Salmonella pathogenicity island 2 (SPI-2) that controls the expression of a type III secretion system, as well as many other genes required for systemic infection in mice. Measurements of SsrA and SsrB protein levels under different growth conditions indicate that expression of these two components is uncoupled, i.e. SsrB is produced in the absence of ssrA and vice versa. This result was suggested from our previous studies, in which two promoters at ssrA/B were identified. The isolated C-terminus of SsrB binds to DNA and protects regions upstream of ssrA, ssrB and srfH from DNase I digestion. Furthermore, the C-terminus of SsrB alone is capable of activating transcription in the absence of the N-terminus. Results from beta-galactosidase assays indicate that the N-terminal phosphorylation domain inhibits the C-terminal effector domain. A previous study from our laboratory reported that ssrA-lacZ and ssrB-lacZ transcriptional fusions were substantially reduced in an ssrB null strain. Results from DNase I protection assays provide direct evidence that SsrB binds at ssrA and ssrB, although the binding sites lie within the transcribed regions. Additional regulators clearly affect gene expression at this important locus, and here we provide evidence that SlyA, a transcription factor that contributes to Salmonella virulence, also affects ssrA/B gene expression.

The Response Regulator OmpR Oligomerizes via β-Sheets to Form Head-to-head Dimers

In Escherichia coli, the EnvZ/OmpR two-component regulatory system regulates expression of the porin genes ompF and ompC in response to changes in osmolarity. It has recently become apparent that OmpR functions as a global regulator, by regulating the expression of many genes in addition to the porin genes. OmpR consists of two domains; phosphorylation of the N-terminal receiver domain increases DNA binding affinity of the C-terminal domain and vice versa. Many response regulators including PhoB and FixJ dimerize upon phosphorylation. Here, we demonstrate that OmpR dimerization is stimulated by phosphorylation or by DNA binding. The dimerization interface revealed here was unanticipated and had previously not been predicted. Using the accepted head-to-tail tandem-binding model as a guide, we set out to examine the intermolecular interactions between OmpR dimers bound to DNA by protein-protein cross-linking methods. Surprisingly, amino acid positions that we expected to form cross-linked dimers did not. Conversely, positions predicted not to form dimers did. Because of these results, we designed a series of 23 cysteine-substituted OmpR mutants that were used to investigate dimer interfaces formed via the beta-sheet region. This four-stranded beta-sheet is a unique feature of the OmpR group of winged helix-turn-helix proteins. Many of the cysteine-substituted mutants are dominant to wild-type OmpR, are phosphorylated by acetyl phosphate as well as the cognate kinase EnvZ, and the cross-linked proteins are capable of binding to DNA. Our results are consistent with a model in which OmpR binds to DNA in a head-to-head orientation, in contrast to the previously proposed asymmetric head-to-tail model. They also raise the possibility that OmpR may be capable of adopting more than one orientation as it binds to a vast array of genes to activate or repress transcription.

Escherichia coli can tolerate insertions of up to 16 amino acids in the RNA polymerase alpha subunit inter-domain linker

The C-terminal domain of the Escherichia coli RNA polymerase alpha subunit (alphaCTD) plays a key role in transcription initiation at many activator-dependent promoters and at UP element-dependent promoters. This domain is connected to the alpha N-terminal domain (alphaNTD) by an unstructured linker. To investigate the requirements of the alpha inter-domain linker to support growth of E. coli, we utilised a recently described technique for the substitution of the chromosomal rpoA gene, encoding alpha, by mutant rpoA alleles. We found that it was possible to replace wild-type rpoA by mutant alleles encoding alpha subunits containing inter-domain linkers that were longer by as many as 16 amino acids. However, using this method, it was not possible to transfer to the chromosome rpoA alleles encoding alpha subunits that contained an insertion of 32 amino acids or short deletions within the inter-domain linker. The effect of lengthening the alpha linker on activator-dependent and UP element-dependent transcription in the "haploid" rpoA system was shown to be qualitatively the same as observed previously in the diploid system. The ability of E. coli to tolerate insertions within the alpha inter-domain linker suggests that lengthening the alpha linker does not severely impair transcription of essential genes.

The Escherichia coli tppB (ydgR) gene represents a new class of OmpR-regulated genes

The EnvZ/OmpR two-component regulatory system plays a critical role in the Escherichia coli stress response. In this study, we examined the expression of a new OmpR-regulated gene, ydgR. Our results indicate that ydgR is equivalent to the Salmonella enterica serovar Typhimurium tppB gene and represents a new class of OmpR-regulated genes.

Spx-dependent global transcriptional control is induced by thiol-specific oxidative stress in Bacillus subtilis

The Spx protein of Bacillus subtilis represses activator-stimulated transcription by interacting with the C-terminal domain of RNA polymerase (RNAP) alpha subunit. Its concentration increases in cells lacking the ATP-dependent protease, ClpXP, resulting in severe effects on growth and developmental processes. Microarray analysis was undertaken to identify genes that are induced or repressed when Spx interacts with RNAP. The induced genes included those encoding products known to function in maintaining thiol homeostasis. Two genes, thioredoxin (trxA) and thioredoxin reductase (trxB), are transcriptionally induced under conditions of thiol-specific oxidative (disulfide) stress by a mechanism involving Spx-RNAP interaction. Disulfide stress also results in an increase in Spx-dependent transcriptional repression. The increase in Spx activity in cells encountering disulfide stress is due in part to a posttranscriptional mechanism of spx control resulting in an increase in Spx concentration. An spx null mutant and a strain bearing an allele of rpoA that prevents Spx-RNAP interaction show hypersensitivity to disulfide stress. From these results, it is proposed that Spx is an activator that mobilizes the operations necessary to reverse the effects of oxidative damage, but it also serves as a negative regulator that causes the postponement of developmental programs and energy-consuming growth-related functions while the cell copes with the period of stress.

Interdomain linkers of homologous response regulators determine their mechanism of action

OmpR and PhoB are response regulators that contain an N-terminal phosphorylation domain and a C-terminal DNA binding effector domain connected by a flexible interdomain linker. Phosphorylation of the N terminus results in an increase in affinity for specific DNA and the subsequent regulation of gene expression. Despite their sequence and structural similarity, OmpR and PhoB employ different mechanisms to regulate their effector domains. Phosphorylation of OmpR in the N terminus stimulates the DNA binding affinity of the C terminus, whereas phosphorylation of the PhoB N terminus relieves inhibition of the C terminus, enabling it to bind to DNA. Chimeras between OmpR and PhoB containing either interdomain linker were constructed to explore the basis of the differences in their activation mechanisms. Our results indicate that effector domain regulation by either N terminus requires its cognate interdomain linker. In addition, our findings suggest that the isolated C terminus of OmpR is not sufficient for a productive interaction with RNA polymerase.

Novel mode of transcription regulation of divergently overlapping promoters by PhoP, the regulator of two-component system sensing external magnesium availability

PhoP is a response regulator of the PhoQ-PhoP two-component system controlling a set of the Mg(II)-response genes in Escherichia coli. Here we demonstrate the mode of transcription regulation by phosphorylated PhoP of divergently transcribed mgtA and treR genes, each encoding a putative Mg(II) transporter and a repressor for the trehalose utilization operon respectively. Under Mg(II)-limiting conditions in vivo, two promoters, the upstream constitutive P2 and the downstream inducible P1, were detected for the mgtA gene. Gel-shift analysis in vitro using purified PhoP indicates its binding to a single DNA target, centred between -43 and -24 of the mgtAP1 promoter. This region includes the PhoP box, which consists of a direct repeat of the heptanucleotide sequence (T)G(T)TT(AA). Site-directed mutagenesis studies indicate the critical roles for T (position 3), T (position 4) and A (position 6) for PhoP-dependent transcription from mgtAP1. DNase I footprinting assays reveal weak binding of PhoP to this PhoP box, but the binding becomes stronger in the simultaneous presence of RNA polymerase. Likewise the RNA polymerase binding to the P1 promoter becomes stronger in the presence of PhoP. For the PhoP-assisted formation of open complex at the mgtAP1 promoter, however, the carboxy-terminal domain of alpha subunit (alpha CTD) is not needed. For transcription in vivo of the treR gene, four promoters were identified. The most upstream promoter treRP4 divergently overlaps with the mgtAP1 promoter, sharing the same sequence as the respective -10 signal in the opposite direction. In vitro transcription using mutant promoters support this prediction. In the presence of PhoP, transcription from the promoter treRP3 was repressed with concomitant activation of mgtAP1 transcription. The PhoP box is located between -46 and -30 with respect to treRP3, and the alpha CTD is needed for this repression.

Identification and comparative analysis of the chloroplast alpha-subunit gene of DNA-dependent RNA polymerase from seven Euglena species

When the sequence of the Euglena gracilis chloroplast genome was reported in 1993 the alpha-subunit gene (rpoA) of RNA polymerase appeared to be missing, based on a comparison of all putative reading frames to the then known rpoA loci. Since there has been a large increase in known rpoA sequences, the question of a Euglena chloroplast rpoA gene was re-examined. A previously described unknown reading frame of 161 codons was found to be part of an rpoA gene split by a single group III intron. This rpoA gene, which is highly variable from species to species, was then isolated and characterized in five other euglenoid species, Euglena anabaena, Euglena granulata, Euglena myxocylindracea, Euglena stellata and Euglena viridis, and in the Astasia longa plastid genome. All seven Euglena rpoA genes have either one or three group III introns. The rpoA gene products in Euglena spp. appear to be the most variable in this gene family when compared to the rpoA gene in other species of bacteria, algae and plants. Additionally, Euglena rpoA proteins lack a C-terminal domain required for interaction with some regulatory proteins, a feature shared only with some chlorophyte green algae. The E.gracilis rpoA gene is the distal cistron of a multigene cluster that includes genes for carbohydrate biosynthesis, photosynthetic electron transport, an antenna complex and ribosomal proteins. This study provides new insights into the transcription system of euglenoid plastids, the organization of the plastid genome, group III intron evolution and euglenoid phylogeny.

Residues 137 and 153 of XylS influence contacts with the C-terminal domain of the RNA polymerase alpha subunit

XylS and XylS1 are transcriptional regulators that stimulate transcription from the Pm promoter for the meta-cleavage pathway operon for alkylbenzoate degradation. These regulators that differ in five amino acids interact with alpha-CTD domain of RNA polymerase. These interactions take place preferentially through residues 291 in XylS and 289 in XylS1. Substitution at position 137 and 153 in XylS influence the interactions with alpha-CTD because single and double mutants in these positions turned preferential interactions to residue 289.

Novel mode of transcription regulation by SdiA, an Escherichia coli homologue of the quorum-sensing regulator

SdiA, an Escherichia coli homologue of the quorum-sensing regulator, controls the expression of the ftsQAZ operon for cell division. Transcription of ftsQ is under the control of two promoters, upstream ftsQP2 and downstream ftsQP1, which are separated by 125 bp. SdiA activates transcription from ftsQP2 in vivo. Here, we demonstrate that SdiA facilitates the RNA polymerase binding to ftsQP2 and thereby stimulates transcription from P2. Gel shift and DNase I footprinting assays indicated that SdiA binds to the ftsQP2 promoter region between -51 and -25 with respect to the P2 promoter. Activation of ftsQP2 transcription by SdiA was observed with a mutant RNA polymerase containing a C-terminal domain (CTD)-deleted alpha-subunit (alpha 235) but not with RNA polymerase containing sigma(S) or a CTD-deleted sigma(D) (sigma(D)529). In good agreement with the transcription assay, no protection of P2 was observed with the RNA polymerase holoenzymes, E sigma(S) and E sigma(D)529. These observations together indicate that: (i) SdiA supports the RNA polymerase binding to ftsQP2; and (ii) this recruitment of RNA polymerase by SdiA depends on the presence of intact sigmaCTD. This is in contrast to the well-known mechanism of RNA polymerase recruitment by protein-protein contact between class I factors and alpha CTD. In addition to the P2 activation, SdiA inhibited RNA polymerase binding to the ftsQP1 promoter and thereby repressed transcription from P1. Gel shift assays indicate weak binding of SdiA to the P1 promoter region downstream from -13 (or +112 with respect to P2). Neither alpha CTD nor sigma CTD are required for this inhibition. Thus, the transcription repression of P1 by SdiA may result from its competition with the RNA polymerase in binding to this promoter.

Reconstitution of acetosyringone-mediated Agrobacterium tumefaciens virulence gene expression in the heterologous host Escherichia coli

The ability to utilize Escherichia coli as a heterologous system in which to study the regulation of Agrobacterium tumefaciens virulence genes and the mechanism of transfer DNA (T-DNA) transfer would provide an important tool to our understanding and manipulation of these processes. We have previously reported that the rpoA gene encoding the alpha subunit of RNA polymerase is required for the expression of lacZ gene under the control of virB promoter (virBp::lacZ) in E. coli containing a constitutively active virG gene [virG(Con)]. Here we show that an RpoA hybrid containing the N-terminal 247 residues from E. coli and the C-terminal 89 residues from A. tumefaciens was able to significantly express virBp::lacZ in E. coli in a VirG(Con)-dependent manner. Utilization of lac promoter-driven virA and virG in combination with the A. tumefaciens rpoA construct resulted in significant inducer-mediated expression of the virBp::lacZ fusion, and the level of virBp::lacZ expression was positively correlated to the copy number of the rpoA construct. This expression was dependent on VirA, VirG, temperature, and, to a lesser extent, pH, which is similar to what is observed in A. tumefaciens. Furthermore, the effect of sugars on vir gene expression was observed only in the presence of the chvE gene, suggesting that the glucose-binding protein of E. coli, a homologue of ChvE, does not interact with the VirA molecule. We also evaluated other phenolic compounds in induction assays and observed significant expression with syringealdehyde, a low level of expression with acetovanillone, and no expression with hydroxyacetophenone, similar to what occurs in A. tumefaciens strain A348 from which the virA clone was derived. These data support the notion that VirA directly senses the phenolic inducer. However, the overall level of expression of the vir genes in E. coli is less than what is observed in A. tumefaciens, suggesting that additional gene(s) from A. tumefaciens may be required for the full expression of virulence genes in E. coli.

Mutational analysis of regulatory cis-acting elements for the transcriptional activation of the dmsCBA operon in Rhodobacter sphaeroides f. sp. denitrificans

Four direct repeats of a 10-nt sequence, called dms boxes, are located upstream of the dmsCBA operon encoding dimethyl sulfoxide (DMSO) reductase in Rhodobacter sphaeroides f. sp. denitrificans IL106. Two dms boxes 1 and 2 have been shown to be binding sites of DmsR protein, a response regulator of a two-component system involved in the anaerobic induction by DMSO of DMSO reductase synthesis. In this study, functions of four dms boxes in the transcriptional regulation of the dmsCBA operon were investigated. The transcription start site of the dmsCBA genes was identified at the distance of 23 nt downstream of the closest dms box 4. Expression of the dmsC-lacZ gene fusion which included the dmsCBA promoter region containing the dms boxes was examined and its anaerobic induction by DMSO and DmsR-dependency were demonstrated in the phototroph. The examination with nucleotide substitutions in the four respective dms boxes showed that the set of four dms boxes is required for the dmsCBA operon activation. Moreover, the importance of the nucleotide sequence of TTCAC in dms box 4 and of A at the center in dms box 1 was significantly shown. These facts suggest that the pentad nucleotides TTCAC and TTAAC in the dms boxes serve as cis-acting elements in the transcriptional activation of the dmsCBA operon.

Interactions of the XylS regulators with the C-terminal domain of the RNA polymerase alpha subunit influence the expression level from the cognate Pm promoter

The Pseudomonas putida meta-cleavage operon encodes the enzymes for the catabolism of alkylbenzoates. Activation of meta-operon transcription is mediated by the XylS protein which, upon activation by effectors, binds two sites between -70 and -35 with respect to the main transcription initiation point at the Pm promoter. Two naturally occurring regulators, XylS and XylS1, that differ by only five amino acids, have been analyzed with regard to potential interactions of these positive regulators with the C-terminal domain of the alpha subunit of RNA polymerase (alpha-CTD). For these studies we expressed a derivative of alpha deprived of the entire C-terminal domain (alpha-Delta235) and found that expression from Pm with XylS or XylS1 was significantly decreased. To discern whether alpha-CTD activation depended on interactions with DNA and/or XylS proteins we tested a large collection of alanine substitutions within alpha-CTD. Most substitutions that had an effect on XylS and XylS1-dependent transcription were located in or adjacent to helix 1 and 4, which are known to be involved in alpha-CTD interactions with DNA. Two alanine substitutions in helix 3 (residues 287 and 291) identified a putative region of alpha-CTD/XylS regulator interactions.

Interaction of the C-terminal domain of the E. coli RNA polymerase alpha subunit with the UP element: recognizing the backbone structure in the minor groove surface

The C-terminal domain of the alpha-subunit of Escherichia coli RNA polymerase (alphaCTD) is responsible for transcriptional activation through interaction with both activator proteins and UP element DNA. Previously, we determined the solution structure of alphaCTD. Here, we investigated the interaction between alphaCTD and UP element DNA by NMR. DNA titration curves and intermolecular NOE measurements indicate that alphaCTD can bind to multiple sites on the UP element DNA. Unlike many transcription factors, alphaCTD does not have a strict base sequence requirement for binding. There is a good correlation between the strength of the interaction and the extent of intrinsic bending of the DNA oligomer estimated from the gel retardation assay. We propose that alphaCTD recognizes the backbone structure of DNA oligomers responsible for the intrinsic bending. Moreover, NMR studies and drug competition experiments indicated that alphaCTD interacts with the UP element on the minor groove side of the DNA. The C-terminal end of helix-1, the N-terminal end of helix-4, and the loop between helices 3 and 4 are used for the interaction. Based on these observations, we propose a model for the UP element-alphaCTD complex.

The trans-activation domain of the sporulation response regulator Spo0A revealed by X-ray crystallography

Sporulation in Bacillus involves the induction of scores of genes in a temporally and spatially co-ordinated programme of cell development. Its initiation is under the control of an expanded two-component signal transduction system termed a phosphorelay. The master control element in the decision to sporulate is the response regulator, Spo0A, which comprises a receiver or phosphoacceptor domain and an effector or transcription activation domain. The receiver domain of Spo0A shares sequence similarity with numerous response regulators, and its structure has been determined in phosphorylated and unphosphorylated forms. However, the effector domain (C-Spo0A) has no detectable sequence similarity to any other protein, and this lack of structural information is an obstacle to understanding how DNA binding and transcription activation are controlled by phosphorylation in Spo0A. Here, we report the crystal structure of C-Spo0A from Bacillus stearothermophilus revealing a single alpha-helical domain comprising six alpha-helices in an unprecedented fold. The structure contains a helix-turn-helix as part of a three alpha-helical bundle reminiscent of the catabolite gene activator protein (CAP), suggesting a mechanism for DNA binding. The residues implicated in forming the sigmaA-activating region clearly cluster in a flexible segment of the polypeptide on the opposite side of the structure from that predicted to interact with DNA. The structural results are discussed in the context of the rich array of existing mutational data.

The structure and the characteristic DNA binding property of the C-terminal domain of the RNA polymerase alpha subunit from Thermus thermophilus

The C-terminal domain of the alpha subunit of the RNA polymerase (alphaCTD) from Escherichia coli (Ec) regulates transcription by interacting with many kinds of proteins and promoter upstream (UP) elements consisting of AT-rich sequences. However, it is unclear how this system is common in all eubacteria. We investigate the structure and properties of alphaCTD from an extremely thermophilic eubacterium, Thermus thermophilus (Tt). The solution structure of Tt alphaCTD (85 amino acids) was determined by NMR, and the interaction between Tt alphaCTD and DNA with different sequences was investigated by means of chemical shift perturbation experiments. The tertiary structure of Tt alphaCTD is almost identical with that of Ec alphaCTD despite 32% sequence homology. However, Tt alphaCTD interacts with the upstream region sequence of the promoter in the Tt 16 S ribosomal protein operon rather than the Ec UP element DNA. The upstream region sequence of Tt is composed of 25 base pairs with 40% AT, unlike the Ec UP element with 80% AT. The DNA binding site in Tt alphaCTD is located on the surface composed of helix 4 and the loop preceding helix 4. The electric charges on this surface are not remarkably localized like those of Ec alphaCTD.

Negative regulation of the bolA1p of Escherichia coli K-12 by the transcription factor OmpR for osmolarity response genes

To test whether OmpR is involved in regulation of the bolA1p, we investigated possible effects of ompR mutation on transcription from bolA1p. In vivo, bolA1p was found to be repressed by OmpR. Furthermore in vitro, the phospho-OmpR was found to bind to the OmpR binding region of bolA1p and repress the transcription by Esigma(S) or Esigma(D). These results suggest that the phosphorylated form of OmpR is a negative regulator for the transcription of the bolA1p promoter.

Structural comparison of the PhoB and OmpR DNA-binding/transactivation domains and the arrangement of PhoB molecules on the phosphate box

PhoB is a transcriptional activator that binds to the phosphate box in the promoters of the phosphate genes of Escherichia coli. PhoB contains two functional domains, an N-terminal phosphorylation domain and a C-terminal DNA-binding/transactivation domain. Here, the three-dimensional structure of the DNA-binding/transactivation domain has been determined by NMR. It consists of an N-terminal four-stranded beta-sheet, a central three helical bundle and a C-terminal beta-hairpin. The second and third helices form a helix-turn-helix (HTH) variant containing a longer turn than the corresponding turn of the classical HTH motif. The overall architecture is very close to that of the OmpR DNA-binding/transactivation domain, however, the conformation of the long turn region of PhoB, a putative interaction site for the RNA polymerase sigma subunit, is entirely different from that of the corresponding turn of OmpR, which interacts with the alpha subunit. In addition, the third helix of PhoB is three amino acid residues longer than the corresponding helix of OmpR. The binding site of PhoB is a TGTCA sequence and the phospahte box contains the two binding sites. NMR studies of the complexes of the PhoB DNA-binding/transactivation domain bound to several different DNA molecules have revealed that two PhoB molecules bind in a tandem array on the phosphate box. In each complex of PhoB the third helix of the DNA-binding/transactivation domain is likely to recognize the TGTCA sequence from the major groove of DNA and the C-terminal beta-hairpin contacts on the minor groove of the 3' site out of the TGTCA sequence in a non-specific manner. The long turn region facing outward is likely to interact with the sigma subunit.

Transcription activation mediated by the carboxyl-terminal domain of the RNA polymerase alpha-subunit. Multipoint monitoring using a fluorescent probe

Conformational changes within the carboxyl-terminal domain of the Escherichia coli RNA polymerase alpha-subunit (alpha-CTD) upon interaction with the DNA UP element or the transcription factor cAMP receptor protein (CRP) were studied by monitoring the spectral parameters of a fluorescent dye, fluorescein mercuric acetate, conjugated to various positions of alpha-CTD. When fluorescein mercuric acetate was conjugated to Cys located on helix I and the loop between helices III and IV, the spectral changes typical for DNA interaction were observed for the RNA polymerase-promoter binary complex with UP element-dependent rrnBP1 and the ternary complex with the CRP-dependent uxuAB promoter in the presence of cAMP/CRP. Likewise, the chemical nuclease iron-(p-bromoacetamidobenzyl)-EDTA conjugated to Cys-269 or Cys-272 introduced CRP-dependent cleavage of the uxuAB promoter, as in the case of rrnBP1 (Murakami, K., Owens, J. T., Belyaeva, T. A., Meares, C. F., Busby, S. J. W., and Ishihama, A. (1997) Proc. Natl. Acad. Sci. U. S. A. 94, 11274-11278), indicating that CRP rearranges the topology of the DNA contact surface in alpha-CTD. Conformational changes in alpha-CTD were also observed upon formation of a binary complex with the uxuAB (in the absence of CRP) and factor-independent T7D promoters. The spectral changes suggested that helix IV of alpha-CTD approaches the negatively charged phosphate moiety of DNA. In agreement with this prediction, iron-(p-bromoacetamidobenzyl)-EDTA conjugated to Cys-309 induced extensive DNA cleavage upstream from the uxuAB promoter -35 element. We propose that helix IV of alpha-CTD is involved in direct interaction with some promoters.

Transcription activation by catabolite activator protein (CAP)

Transcription activation by Escherichia coli catabolite activator protein (CAP) at each of two classes of simple CAP-dependent promoters is understood in structural and mechanistic detail. At class I CAP-dependent promoters, CAP activates transcription from a DNA site located upstream of the DNA site for RNA polymerase holoenzyme (RNAP); at these promoters, transcription activation involves protein-protein interactions between CAP and the RNAP alpha subunit C-terminal domain that facilitate binding of RNAP to promoter DNA to form the RNAP-promoter closed complex. At class II CAP-dependent promoters, CAP activates transcription from a DNA site that overlaps the DNA site for RNAP; at these promoters, transcription activation involves both: (i) protein-protein interactions between CAP and RNAP alpha subunit C-terminal domain that facilitate binding of RNAP to promoter DNA to form the RNAP-promoter closed complex; and (ii) protein-protein interactions between CAP and RNAP alpha subunit N-terminal domain that facilitates isomerization of the RNAP-promoter closed complex to the RNAP-promoter open complex. Straightforward combination of the mechanisms for transcription activation at class I and class II CAP-dependent promoters permits synergistic transcription activation by multiple molecules of CAP, or by CAP and other activators. Interference with determinants of CAP or RNAP involved in transcription activation at class I and class II CAP-dependent promoters permits "anti-activation" by negative regulators. Basic features of transcription activation at class I and class II CAP-dependent promoters appear to be generalizable to other activators.

A second operator is involved in Pseudomonas aeruginosa elastase (lasB) activation

Pseudomonas aeruginosa LasB elastase gene (lasB) transcription is controlled by the two-component quorum-sensing system of LasR, and the autoinducer, 3OC(12)-HSL (N-3-[oxododecanoyl]homoserine lactone). LasR and 3OC(12)-HSL-mediated lasB activation requires a functional operator sequence (OP1) in the lasB promoter region. Optimal activation of lasB, however, requires a second sequence of 70% identity to OP1, named OP2, located 43 bp upstream of OP1. In this study, we used sequence substitutions and insertion mutations in lasBp-lacZ fusion plasmids to explore the role of OP2 in lasB activation. Our results demonstrate that (i) OP1 and OP2 synergistically mediate lasB activation; (ii) OP2, like OP1, responds to LasR and 3OC(12)-HSL; and (iii) the putative autoinducer-binding domain of LasR is not required for synergistic activation from OP1 and OP2.

GalR-mediated repression and activation of hybrid lacUV5 promoter: differential contacts with RNA polymerase

The GalR repressor regulates expression of genes of the gal regulon in Escherichia coli. We studied the regulatory effect of GalR in vitro on a heterologous promoter, lacUV5, by placing the GalR-binding site, OE, at different locations upstream of this promoter. Despite the fact that the lacUV5 promoter is transcribed efficiently by RNA polymerase (RNP) alone, GalR modulated transcription from many of the PlacUV5 variants. Depending on the location of OE and the neighboring DNA sequence, GalR repressed, activated or had no effect on the promoter. Both repression and activation involved formation of GalR-RNP-DNA ternary complexes and required an intact c-domain of the alpha subunit of the holoenzyme. These results support the differential contact model of a regulator action, in which a regulator differentially binds to, and lowers the energy of, intermediates of transcription initiation either to hinder or to facilitate a step of initiation. The nature of the contacts depends upon the context, i.e. the geometry of the ternary complex. The observed repression and activation effect of GalR on a heterologous promoter also underscores the point that a regulator is not a dedicated protein for repression or for activation.

Spo0A mutants of Bacillus subtilis with sigma factor-specific defects in transcription activation

The transcription factor Spo0A of Bacillus subtilis has the unique ability to activate transcription from promoters that require different forms of RNA polymerase holoenzyme. One class of Spo0A-activated promoter, which includes spoIIEp, is recognized by RNA polymerase associated with the primary sigma factor, sigma A (sigmaA); the second, which includes spoIIAp, is recognized by RNA polymerase associated with an early-sporulation sigma factor, sigma H (sigmaH). Evidence suggests that Spo0A probably interacts directly with RNA polymerase to activate transcription from these promoters. To identify residues of Spo0A that may be involved in transcriptional activation, we used PCR mutagenesis of the entire spo0A gene and designed a screen using two distinguishable reporter fusions, spoIIE-gus and spoIIA-lacZ. Here we report the identification and characterization of five mutants of Spo0A that are specifically defective in activation of sigmaA-dependent promoters while maintaining activation of sigmaH-dependent promoters. These five mutants identify a 14-amino-acid segment of Spo0A, from residue 227 to residue 240, that is required for transcriptional activation of sigmaA-dependent promoters. This region may define a surface or domain of Spo0A that makes direct contacts with sigmaA-associated holoenzyme.

Positioning of two alpha subunit carboxy-terminal domains of RNA polymerase at promoters by two transcription factors

Interactions between the cAMP receptor protein (CRP) and the carboxy-terminal regulatory domain (CTD) of Escherichia coli RNA polymerase alpha subunit were analyzed at promoters carrying tandem DNA sites for CRP binding using a chemical nuclease covalently attached to alpha. Each CRP dimer was found to direct the positioning of one of the two alpha subunit CTDs. Thus, the function of RNA polymerase may be subject to regulation through protein-protein interactions between the two alpha subunits and two different species of transcription factors.

DNA bending by the TrpI protein of Pseudomonas aeruginosa

TrpI protein, the activator of transcription of the trpBA operon of fluorescent pseudomonads, bends the DNA when it forms either of two well-characterized complexes with the trpBA regulatory region. In complex 1, with TrpI bound only to its strong binding site (site I), the calculated bending angle is 65 to 67 degrees and the center of bending is in the middle of site I. In complex 2, which is required for activation of the trpBA promoter, with TrpI bound both to site I and to the weaker site II, the bending angle is increased to 89 to 90 degrees and the center of bending is at the site I-site II boundary. Indoleglycerol phosphate (InGP), which strongly stimulates formation of complex 2 and is required for activation, does not affect the bending angle of either complex. However, a mutation (-10C/11C) shown previously to affect activation has a small but detectable effect on bending, reducing the calculated bending angle to 83 to 86 degrees. These results suggest a way that DNA bending and InGP may be important for activation.

Promoters and transcripts associated with the aroP gene of Escherichia coli

Analysis of in vitro transcriptional events initiating within the region immediately upstream of the aroP coding region has revealed the presence of three promoters, P1, P2, and P3. Both P1 and P2 give rise to mRNA encoding the AroP protein, whereas P3 initiates transcription in the opposite direction. Both P1 and P3 contain UP elements which contribute to promoter strength. Regulation of expression from these three promoters has been examined in vitro by using supercoiled DNA templates and in vivo by using lacZ transcriptional fusions and specific promoter mutants. Expression from P2 is partially repressed by TyrR alone both in vitro and in vivo. Addition of the aromatic amino acid tyrosine, phenylalanine, or tryptophan further increases this repression. P1 is not repressed by TyrR alone but is repressed in vivo in the presence of phenylalanine, tyrosine, or tryptophan. This also occurs in vitro but requires Ca2+ ions in the reaction mixture for its demonstration. Under these conditions, transcription from P3 is enhanced by TyrR protein with phenylalanine, tyrosine, or tryptophan. However, we were unable to demonstrate P3 expression in vivo. Under repressing conditions, there is no production of truncated RNA molecules (from P1), which would be expected if repression involved a roadblock mechanism.

Structural relationships in the OmpR family of winged-helix transcription factors

OmpR, a protein that regulates expression of outer membrane porin proteins in enteric bacteria, belongs to a large family of transcription factors. These transcription factors bind DNA and interact productively with RNA polymerase to activate transcription. The two functions, DNA-binding and transcriptional activation, have been localized within the 100 amino acid DNA-binding domain that characterizes members of the OmpR family. Both DNA binding and transcriptional activation by OmpR related proteins have remained poorly understood for lack of structural information or lack of sequence homology with transcription factors of known three-dimensional structure. The recently determined crystal structures of the Escherichia coli OmpR DNA-binding domain (OmpRc) have defined a new subfamily of "winged-helix-turn-helix" DNA-binding proteins. Structural elements of OmpRc can be assigned functional roles by analogy to other winged-helix DNA-binding proteins. A structure based sequence analysis of the OmpR family of transcription factors indicates specific roles for all conserved amino acid residues. Mutagenesis studies performed on several members of this family, OmpR, PhoB, ToxR and VirG, can now be interpreted with respect to the structure.

FNR-dependent repression of ndh gene expression requires two upstream FNR-binding sites

The ndh gene of Escherichia coli encodes a non-proton-translocating NADH dehydrogenase (NdhII) that is anaerobically repressed by the global transcription regulator, FNR. FNR binds at two sites (centred at -50.5 and -94.5) in the ndh promoter but the mechanism of FNR-mediated repression appears not to be due to promoter occlusion. This mechanism has been investigated using an aerobically active derivative of FNR, FNR* (FNR-D154A), with ndh promoters containing altered FNR-binding sites. FNR* repressed ndh gene expression both aerobically and anaerobically in vivo. Gel retardation analysis and DNase I footprinting with purified FNR* protein confirmed that FNR interacts at two sites in the ndh promoter, and that FNR and RNA polymerase (RNAP) can bind simultaneously. Studies with three altered ndh promoters, each containing an impaired or improved FNR-site, indicated that both FNR-sites are needed for efficient repression in vivo. The alpha-subunit of RNAP interacted with two regions (centred at -105 and -46), each overlapping one of the FNR-sites in the ndh promoter. Footprints of the FNR*-RNAP-ndh ternary complex indicated that FNR*-binding at -50.5 prevents the alpha-subunit of RNAP from docking with the DNA just upstream of the -35 element. Binding of a second FNR* molecule at the -105 site likewise prevents binding of the alpha-subunit at its alternative site, thus providing a plausible mechanism for FNR-mediated repression based on displacement of the alpha-subunit of RNAP.

Flexible linker in the RNA polymerase alpha subunit facilitates the independent motion of the C-terminal activator contact domain

The dynamic properties of the C-terminal one-third of the alpha subunit of RNA polymerase were investigated. The intact alpha subunit exhibited almost the same NMR spectral pattern as the isolated C-terminal fragment, indicating that the C-terminal domain retains the same conformation as the isolated fragment, and that its motion is independent of that of the associated N-terminal domain. Analysis of the NMR dynamics data for the intact alpha subunit indicated that at least 13 residues between the N and C-terminal domains show distinctly higher motional flexibility than the structured parts. This flexible linker may endow the C-terminal domain with locational freedom in different kinds of initiation complex. The dynamics data also revealed that the residues in the contact site for DNA and transcription factors exhibited higher mobility than other secondary structural elements.

The two alpha subunits of Escherichia coli RNA polymerase are asymmetrically arranged and contact different halves of the DNA upstream element

RNA polymerase core enzyme of Escherichia coli is composed of two alpha subunits and one each of the beta and beta' subunits. The C-terminal domain of the RNA polymerase alpha subunit plays a key role in molecular communications with class I transcription factors and upstream (UP) elements of promoter DNA, using the same protein surface. To identify possible differences in the functional roles of the two alpha subunits, we have developed a reconstitution method for hybrid RNA polymerases containing two distinct alpha subunit derivatives in a defined orientation ("oriented alpha-heterodimer"). The binding sites of two alpha C-terminal domains on the UP element DNA were determined by hydroxyl radical-based DNA cleavage mediated by (p-bromoacetamidobenzyl)-EDTA x Fe, which was bound at Cys-269 on the UP recognition surface of one or both alpha subunits. The results clearly indicated that the two alpha subunits bind in tandem to two helix turns of the rrnBP1 UP element, and that the beta'-associated alpha subunit is bound to the promoter-distal region.

Escherichia coli positive regulator OmpR has a large loop structure at the putative RNA polymerase interaction site

The C-terminal DNA-binding domain of OmpR, a positive regulator involved in osmoregulation expression of the ompF and ompC genes in Escherichia coli, has a helix-turn-helix variant motif. The 'turn' region, consisting of 11 residues, forms an RNA polymerase contact site.

Transcription activation by the bacteriophage Mu Mor protein requires the C-terminal regions of both alpha and sigma70 subunits of Escherichia coli RNA polymerase

Middle transcription of bacteriophage Mu requires Escherichia coli RNA polymerase and a Mu-encoded protein, Mor. Consistent with these requirements, the middle promoter, Pm, has a -10 hexamer but lacks a recognizable -35 hexamer. Interactions between Mor and RNA polymerase were studied using in vitro transcription, DNase I footprinting, and the yeast interaction trap system. We observed reduced promoter activity in vitro using reconstituted RNA polymerases with C-terminal deletions in alpha or sigma70. As predicted if alpha were binding to Pm, we detected a polymerase-dependent footprint in the -60 region. Reconstituted RNA polymerases containing Ala substitutions in the alpha C-terminal domain were used to assay Mor-dependent transcription from Pm in vitro. The D258A substitution and alpha deletion gave large reductions in activation, whereas the L262A, R265A, and N268A substitutions caused smaller reductions. The interaction trap assay revealed weak interactions between Mor and both alpha and sigma70; consistent with a key role of alpha-D258, the D258A substitution abolished interaction, whereas the R265A substitution did not. We propose that: (i) alpha-D258 is a Mor "contact site"; and (ii) residues Leu-262, Arg-265, and Asn-268 indirectly affect Mor-polymerase interaction by stabilizing the ternary complex via alpha-DNA contact.

Transcription activation at class II CAP-dependent promoters: two interactions between CAP and RNA polymerase

At Class II catabolite activator protein (CAP)-dependent promoters, CAP activates transcription from a DNA site overlapping the DNA site for RNA polymerase. We show that transcription activation at Class II CAP-dependent promoters requires not only the previously characterized interaction between an activating region of CAP and the RNA polymerase alpha subunit C-terminal domain, but also an interaction between a second, promoter-class-specific activating region of CAP and the RNA polymerase alpha subunit N-terminal domain. We further show that the two interactions affect different steps in transcription initiation. Transcription activation at Class II CAP-dependent promoters provides a paradigm for understanding how an activator can make multiple interactions with the transcription machinery, each interaction being responsible for a specific mechanistic consequence.