Protein-protein interactions during transcription activation: the case of the Escherichia coli cyclic AMP receptor protein

Regulation of Aerobic Succinate Transporter dctA of E. coli by cAMP-CRP, DcuS-DcuR, and EIIAGlc: Succinate as a Carbon Substrate and Signaling Molecule

INTRODUCTION

C4-dicarboxylates (C4-DC) have emerged as significant growth substrates and signaling molecules for various Enterobacteriaceae during their colonization of mammalian hosts. Particularly noteworthy is the essential role of fumarate respiration during colonization of pathogenic bacteria. To investigate the regulation of aerobic C4-DC metabolism, the study explored the transcriptional control of the main aerobic C4-DC transporter, dctA, under different carbohydrate conditions. In addition, mutants related to carbon catabolite repression (CCR) and C4-DC regulation (DcuS-DcuR) were examined to better understand the regulatory integration of aerobic C4-DC metabolism into CCR. For initial insight into posttranslational regulation, the interaction between the aerobic C4-DC transporter DctA and EIIAGlc from the glucose-specific phosphotransferase system was investigated.

METHODS

The expression of dctA was characterized in the presence of various carbohydrates and regulatory mutants affecting CCR. This was accomplished by fusing the dctA promoter (PdctA) to the lacZ reporter gene. Additionally, the interaction between DctA and EIIAGlc of the glucose-specific phosphotransferase system was examined in vivo using a bacterial two-hybrid system.

RESULTS

The dctA promoter region contains a class I cAMP-CRP-binding site at position -81.5 and a DcuR-binding site at position -105.5. DcuR, the response regulator of the C4-DC-activated DcuS-DcuR two-component system, and cAMP-CRP stimulate dctA expression. The expression of dctA is subject to the influence of various carbohydrates via cAMP-CRP, which differently modulate cAMP levels. Here we show that EIIAGlc of the glucose-specific phosphotransferase system strongly interacts with DctA, potentially resulting in the exclusion of C4-DCs when preferred carbon substrates, such as sugars, are present. In contrast to the classical inducer exclusion known for lactose permease LacY, inhibition of C4-DC uptake into the cytoplasm affects only its role as a substrate, but not as an inducer since DcuS detects C4-DCs in the periplasmic space ("substrate exclusion"). The work shows an interplay between cAMP-CRP and the DcuS-DcuR regulatory system for the regulation of dctA at both transcriptional and posttranslational levels.

CONCLUSION

The study highlights a hierarchical interplay between global (cAMP-CRP) and specific (DcuS-DcuR) regulation of dctA at the transcriptional and posttranslational levels. The integration of global and specific transcriptional regulation of dctA, along with the influence of EIIAGlc on DctA, fine-tunes C4-DC catabolism in response to the availability of other preferred carbon sources. It attributes DctA a central role in the control of aerobic C4-DC catabolism and suggests a new role to EIIAGlc on transporters (control of substrate uptake by substrate exclusion).

Autotrophic growth of Escherichia coli is achieved by a small number of genetic changes

Synthetic autotrophy is a promising avenue to sustainable bioproduction from CO2. Here, we use iterative laboratory evolution to generate several distinct autotrophic strains. Utilising this genetic diversity, we identify that just three mutations are sufficient for Escherichia coli to grow autotrophically, when introduced alongside non-native energy (formate dehydrogenase) and carbon-fixing (RuBisCO, phosphoribulokinase, carbonic anhydrase) modules. The mutated genes are involved in glycolysis (pgi), central-carbon regulation (crp), and RNA transcription (rpoB). The pgi mutation reduces the enzyme's activity, thereby stabilising the carbon-fixing cycle by capping a major branching flux. For the other two mutations, we observe down-regulation of several metabolic pathways and increased expression of native genes associated with the carbon-fixing module (rpiB) and the energy module (fdoGH), as well as an increased ratio of NADH/NAD+ - the cycle's electron-donor. This study demonstrates the malleability of metabolism and its capacity to switch trophic modes using only a small number of genetic changes and could facilitate transforming other heterotrophic organisms into autotrophs.

Hierarchy of transcription factor network in Escherichia coli K-12: H-NS-mediated silencing and Anti-silencing by global regulators

Transcriptional regulation for genome expression determines growth and adaptation of single-cell bacteria that are directly exposed to environment. The transcriptional apparatus in Escherichia coli K-12 is composed of RNA polymerase core enzyme and two groups of its regulatory proteins, seven species of promoter-recognition subunit sigma and about 300 species of transcription factors. The identification of regulatory targets for all these regulatory proteins is critical toward understanding the genome regulation as a whole. For this purpose, we performed a systematic search in vitro of the whole set of binding sites for each factor by gSELEX system. This review summarizes the accumulated knowledge of regulatory targets for more than 150 TFs from E. coli K-12. Overall TFs could be classified into four families: nucleoid-associated bifunctional TFs; global regulators; local regulators; and single-target regulators, in which the regulatory functions remain uncharacterized for the nucleoid-associated TFs. Here we overview the regulatory targets of two nucleoid-associated TFs, H-NS and its paralog StpA, both together playing the silencing role of a set of non-essential genes. Participation of LeuO and other global regulators have been indicated for the anti-silencing. Finally, we propose the hierarchy of TF network as a key framework of the bacterial genome regulation.

CRP-Like Transcriptional Regulator MrpC Curbs c-di-GMP and 3',3'-cGAMP Nucleotide Levels during Development in Myxococcus xanthus

Myxococcus xanthus has a nutrient-regulated biphasic life cycle forming predatory swarms in the presence of nutrients and spore-filled fruiting bodies in the absence of nutrients. The second messenger 3'-5', 3'-5 cyclic di-GMP (c-di-GMP) is essential during both stages of the life cycle; however, different enzymes involved in c-di-GMP synthesis and degradation as well as several c-di-GMP receptors are important during distinct life cycle stages. To address this stage specificity, we determined transcript levels using transcriptome sequencing (RNA-seq) and transcription start sites using Cappable sequencing (Cappable-seq) during growth and development genome wide. All 70 genes encoding c-di-GMP-associated proteins were expressed, with 28 upregulated and 10 downregulated during development. Specifically, the three genes encoding enzymatically active proteins with a stage-specific function were expressed stage specifically. By combining operon mapping with published chromatin immunoprecipitation sequencing (ChIP-seq) data for MrpC (M. Robinson, B. Son, D. Kroos, L. Kroos, BMC Genomics 15:1123, 2014, http://dx.doi.org/10.1186/1471-2164-15-1123), the cAMP receptor protein (CRP)-like master regulator of development, we identified nine developmentally regulated genes as regulated by MrpC. In particular, MrpC directly represses the expression of dmxB, which encodes the diguanylate cyclase DmxB that is essential for development and responsible for the c-di-GMP increase during development. Moreover, MrpC directly activates the transcription of pmxA, which encodes a bifunctional phosphodiesterase that degrades c-di-GMP and 3',3'-cGAMP in vitro and is essential for development. Thereby, MrpC regulates and curbs the cellular pools of c-di-GMP and 3',3'-cGAMP during development. We conclude that temporal regulation of the synthesis of proteins involved in c-di-GMP metabolism contributes to c-di-GMP signaling specificity. MrpC is important for this regulation, thereby being a key regulator of developmental cyclic di-nucleotide metabolism in M. xanthus. IMPORTANCE The second messenger c-di-GMP is important during both stages of the nutrient-regulated biphasic life cycle of Myxococcus xanthus with the formation of predatory swarms in the presence of nutrients and spore-filled fruiting bodies in the absence of nutrients. However, different enzymes involved in c-di-GMP synthesis and degradation are important during distinct life cycle stages. Here, we show that the three genes encoding enzymatically active proteins with a stage-specific function are expressed stage specifically. Moreover, we find that the master transcriptional regulator of development MrpC directly regulates the expression of dmxB, which encodes the diguanylate cyclase DmxB that is essential for development, and of pmxA, which encodes a bifunctional phosphodiesterase that degrades c-di-GMP and 3',3'-cGAMP in vitro and is essential for development. We conclude that temporal regulation of the synthesis of proteins involved in c-di-GMP metabolism contributes to c-di-GMP signaling specificity and that MrpC plays an important role in this regulation.

The Antiactivator of Type III Secretion, OspD1, Is Transcriptionally Regulated by VirB and H-NS from Remote Sequences in Shigella flexneri

Shigella species, the causal agents of bacillary dysentery, use a type III secretion system (T3SS) to inject two waves of virulence proteins, known as effectors, into the colonic epithelium to subvert host cell machinery. Prior to host cell contact and secretion of the first wave of T3SS effectors, OspD1, an effector and antiactivator protein, prevents premature production of the second wave of effectors. Despite this important role, regulation of the ospD1 gene is not well understood. While ospD1 belongs to the large regulon of VirB, a transcriptional antisilencing protein that counters silencing mediated by the histone-like nucleoid structuring protein H-NS, it remains unclear if VirB directly or indirectly regulates ospD1 Additionally, it is not known if ospD1 is regulated by H-NS. Here, we identify the primary ospD1 transcription start site (+1) and show that the ospD1 promoter is remotely regulated by both VirB and H-NS. Our findings demonstrate that VirB regulation of ospD1 requires at least one of the two newly identified VirB regulatory sites, centered at -978 and -1270 relative to the ospD1 +1. Intriguingly, one of these sites lies on a 193-bp sequence found in three conserved locations on the large virulence plasmids of Shigella The region required for H-NS-dependent silencing of ospD1 lies between -1120 and -820 relative to the ospD1 +1. Thus, our study provides further evidence that cis-acting regulatory sequences for transcriptional antisilencers and silencers, such as VirB and H-NS, can lie far upstream of the canonical bacterial promoter region (i.e., -250 to +1).IMPORTANCE Transcriptional silencing and antisilencing mechanisms regulate virulence gene expression in many important bacterial pathogens. In Shigella species, plasmid-borne virulence genes, such as those encoding the type III secretion system (T3SS), are silenced by the histone-like nucleoid structuring protein H-NS and antisilenced by VirB. Previous work at the plasmid-borne icsP locus revealed that VirB binds to a remotely located cis-acting regulatory site to relieve transcriptional silencing mediated by H-NS. Here, we characterize a second example of remote VirB antisilencing at ospD1, which encodes a T3SS antiactivator and effector. Our study highlights that remote transcriptional silencing and antisilencing occur more frequently in Shigella than previously thought, and it raises the possibility that long-range transcriptional regulation in bacteria is commonplace.

cAMP receptor protein (CRP) positively regulates the yihU-yshA operon in Salmonella enterica serovar Typhi

Salmonella enterica serovar Typhi (S. Typhi) is the aetiological agent of typhoid fever in humans. This bacterium is also able to persist in its host, causing a chronic disease by colonizing the spleen, liver and gallbladder, in the last of which the pathogen forms biofilms in order to survive the bile. Several genetic components, including the yihU-yshA genes, have been suggested to be involved in the survival of Salmonella in the gallbladder. In this work we describe how the yihU-yshA gene cluster forms a transcriptional unit regulated positively by the cAMP receptor global regulator CRP (cAMP receptor protein). The results obtained show that two CRP-binding sites on the regulatory region of the yihU-yshA operon are required to promote transcriptional activation. In this work we also demonstrate that the yihU-yshA transcriptional unit is carbon catabolite-repressed in Salmonella, indicating that it forms part of the CRP regulon in enteric bacteria.

Salmonella enterica response regulator SsrB relieves H-NS silencing by displacing H-NS bound in polymerization mode and directly activates transcription

The response regulator SsrB activates expression of genes encoded within and outside of a pathogenicity island (SPI-2), which is required for systemic infection of Salmonella. SsrB binds upstream of the sifA, sifB, and sseJ effector genes and directly regulates transcription. SsrB also relieves gene silencing by the nucleoid protein H-NS. Single molecule experiments with magnetic tweezers demonstrated that SsrB displaces H-NS from DNA only when it is bound in a polymerization (stiffening) mode and not when H-NS is bound to DNA in the bridging mode. Thus, in contrast to previous views, the polymerization binding mode of H-NS is the relevant form for counter-silencing by SsrB. Our results reveal that response regulators can directly activate transcription and also relieve H-NS silencing. This study adds to the repertoire of mechanisms by which NarL/FixJ subfamily members regulate transcription. Because SsrB-dependent promoters are diversely organized, additional mechanisms of transcriptional activation at other loci are likely.

The ribosomal protein L2 interacts with the RNA polymerase alpha subunit and acts as a transcription modulator in Escherichia coli

Identification of interacting proteins in stable complexes is essential to understand the mechanisms that regulate cellular processes at the molecular level. Transcription initiation in prokaryotes requires coordinated protein-protein and protein-DNA interactions that often involve one or more transcription factors in addition to RNA polymerase (RNAP) subunits. The RNAP alpha subunit (RNAPalpha) is a key regulatory element in gene transcription and functions through direct interaction with other proteins to control all stages of this process. A clear description of the RNAPalpha protein partners should greatly increase our understanding of transcription modulation. A functional proteomics approach was employed to investigate protein components that specifically interact with RNAPalpha. A tagged form of Escherichia coli RNAPalpha was used as bait to determine the molecular partners of this subunit in a whole-cell extract. Among other interacting proteins, 50S ribosomal protein L2 (RPL2) was clearly identified by mass spectrometry. The direct interaction between RNAPalpha and RPL2 was confirmed both in vivo and in vitro by performing coimmunoprecipitation and bacterial two-hybrid experiments. The functional role of this interaction was also investigated in the presence of a ribosomal promoter by using a beta-galactosidase gene reporter assay. The results clearly demonstrated that RPL2 was able to increase beta-galactosidase expression only in the presence of a specific ribosomal promoter, whereas it was inactive when it was assayed with an unrelated promoter. Interestingly, other ribosomal proteins (L1, L3, L20, and L27) did not have any effect on rRNA expression. The findings reported here strongly suggest that in addition to its role in ribosome assembly the highly conserved RPL2 protein plays a specific and direct role in regulation of transcription.

Cyclic AMP receptor protein-dependent activation of the Escherichia coli acsP2 promoter by a synergistic class III mechanism

The cyclic AMP receptor protein (CRP) activates transcription of the Escherichia coli acs gene, which encodes an acetate-scavenging enzyme required for fitness during periods of carbon starvation. Two promoters direct transcription of acs, the distal acsP1 and the proximal acsP2. In this study, we demonstrated that acsP2 can function as the major promoter and showed by in vitro studies that CRP facilitates transcription by "focusing" RNA polymerase to acsP2. We proposed that CRP activates transcription from acsP2 by a synergistic class III mechanism. Consistent with this proposal, we showed that CRP binds two sites, CRP I and CRP II. Induction of acs expression absolutely required CRP I, while optimal expression required both CRP I and CRP II. The locations of these DNA sites for CRP (centered at positions -69.5 and -122.5, respectively) suggest that CRP interacts with RNA polymerase through class I interactions. In support of this hypothesis, we demonstrated that acs transcription requires the surfaces of CRP and the C-terminal domain of the alpha subunit of RNA polymerase holoenzyme (alpha-CTD), which is known to participate in class I interactions: activating region 1 of CRP and the 287, 265, and 261 determinants of the alpha-CTD. Other surface-exposed residues in the alpha-CTD contributed to acs transcription, suggesting that the alpha-CTD may interact with at least one protein other than CRP.

The Escherichia coli cyclic AMP receptor protein forms a 2:2 complex with RNA polymerase holoenzyme, in vitro

Sedimentation equilibrium studies show that the Escherichia coli cyclic AMP receptor protein (CAP) and RNA polymerase holoenzyme associate to form a 2:2 complex in vitro. No complexes of lower stoichiometry (1:1, 2:1, 1:2) were detected over a wide range of CAP and RNA polymerase concentrations, suggesting that the interaction is highly cooperative. The absence of higher stoichiometry complexes, even in the limit of high [protein], suggests that the 2:2 species represents binding saturation for this system. The 2:2 pattern of complex formation is robust. A lower-limit estimate of the formation constant in our standard buffer (40 mm Tris (pH 7.9), 10 mm MgCl(2), 0.1 mm dithiothreitol, 5% glycerol, 100 mm KCl) is 2 x 10(20) m(-3). The qualitative pattern of association is unchanged over the temperature range 4 degrees C < or = T < or = 20 degrees C, by substitution of glutamate for chloride as the dominant anion, or on addition of 20 microm cAMP to the reaction mix. These results limit the possible mechanisms of CAP-polymerase association. In addition, they support the idea that CAP binding may influence the availability of the monomeric form of RNA polymerase that mediates transcription at many promoters.

Functional versatility in the CRP-FNR superfamily of transcription factors: FNR and FLP

The cAMP receptor protein (CRP; sometimes known as CAP, the catabolite gene activator protein) and the fumarate and nitrate reduction regulator (FNR) of Escherichia coli are founder members of an expanding superfamily of structurally related transcription factors. The archetypal CRP structural fold provides a very versatile mechanism for transducing environmental and metabolic signals to the transcription machinery. It allows different functional specificities at the sensory, DNA-recognition and RNA-polymerase-interaction levels to be 'mixed and matched' in order to create a diverse range of transcription factors tailored to respond to particular physiological conditions. This versatility is clearly illustrated by comparing the properties of the CRP, FNR and FLP (FNR-like protein) regulators. At the sensory level, the basic structural fold has been adapted in FNR and FLP by the acquisition in the N-terminal region of different combinations of cysteine or other residues; which bestow oxygen/redox sensing mechanisms that are poised according to the oxidative stress thresholds affecting the metabolism of specific bacteria. At the DNA-recognition level, discrimination between distinct but related DNA targets is mediated by amino acid sequence modifications in the conserved core contact between the DNA-recognition helix and target DNA. And, at the level of RNA-polymerase-interaction, different combinations of three discrete regions contacting the polymerase (the activating regions) are used for polymerase recruitment and promoting transcription.

A novel promoter architecture for microaerobic activation by the anaerobic transcription factor FNR

The yfiD gene of Escherichia coli has an unusual promoter architecture in which an FNR dimer located at -93.5 inhibits transcription activation mediated by another FNR dimer bound at the typical class II position (-40.5). In vitro transcription from the yfiD promoter indicated that FNR alone can downregulate yfiD expression. Analysis of yfiD::lac reporters showed that five turns of the DNA helix between FNR sites was optimal for downregulation. FNR heterodimers, in which one subunit carried a defective repression surface, revealed that the upstream subunit of the -40.5 dimer and the downstream subunit of the -93.5 dimer were most important for downregulating yfiD expression. Deletion of the C-terminal domain of the alpha-subunit of RNA polymerase (RNAP) did not affect FNR-mediated repression, suggesting that repression is mediated through FNR-FNR and not FNR-RNAP interactions. Maximum yfiD::lac expression was observed in cultures exposed to 10 microM oxygen. More or less oxygen reduced expression dramatically. This pattern of response was dependent on the combination of a high-affinity site at the activating class II position and a lower affinity site at the upstream position.

Characterization of the Lactococcus lactis transcription factor FlpA and demonstration of an in vitro switch

The commercially important bacterium Lactococcus lactis contains two FNR-like proteins (FlpA and FlpB) which have a high degree of identity to each other and to the FLP of Lactobacillus casei. FlpA was isolated from a GST-FlpA fusion protein produced in Escherichia coli. Like FLP, isolated FlpA is a homodimeric protein containing both Zn and Cu. However, the properties of FlpA were more like those of the E. coli oxygen-responsive transcription factor FNR than the FLP of L. casei. As prepared FlpA recognized an FNR site (TTGAT-N4-ATCAA) but not an FLP site (CCTGA-N4-TCAGG) in band-shift assays. In contrast to FLP, DNA binding by FlpA did not require the formation of an intramolecular disulphide bond. However, despite containing only two cysteine residues per monomer, FlpA was able to acquire an FNR-like, oxygen-labile [4Fe 4S] cluster. But, whereas the incorporation of a [4Fe 4S] cluster into FNR enhances interaction with target DNA, it abolished DNA binding by FlpA. An FlpA variant (FlpA') with an N-terminal region designed to be more FLP-like failed to incorporate an iron-sulphur cluster but could now form an intramolecular disulphide. This simple example of protein engineering, converting an oxygen-labile [4Fe 4S] containing FNR-like protein into a dithiol-disulphide FLP-like redox sensor demonstrates the versatility of the basic CRP structure. Attempts to demonstrate an FlpA-based aerobic-anaerobic switch in the heterologous host E. coli were unsuccessful. However, studies with a series of FNR-dependent lac reporter fusions in strains of E. coli expressing flpA or flpB revealed that both homologues were able to activate expression of FNR-dependent promoters in vivo but only when positioned 61 base pairs upstream of the transcription start.

Dissection of a surface-exposed portion of the cAMP-CRP complex that mediates transcription activation and repression

The Escherichia coli cAMP receptor protein (CRP) is essential for the activation and repression of transcription initiation at promoters in the CytR regulon. CRP performs these activities by making direct protein-protein interactions to the alpha-subunits of RNA polymerase and to the CytR regulator. Strikingly, it has been shown that amino acids of CRP that are critical for communication with the two partner proteins are located in close proximity on the surface of CRP. Here, we have dissected this surface in order to pinpoint the 'repression region' of CRP and to assess whether it overlaps with the characterized 'activating region'. Our results established that residues 12, 13, 17, 105, 108 and 110 are essential for the interaction with CytR and confirmed that 'activating region' 2 of CRP is made up of residues 19, 21 and 101. In the crystallographic structure of the CRP-DNA complex, the two sets of determinants are located immediately adjacent to each other forming a consecutive surface-exposed patch. The 'repression region' is chemically complementary to the characterized region on CytR that is essential for protein-protein communication to CRP. Moreover, the results provide insight into the mechanism by which CytR might prevent CRP-mediated transcription.

Identification of a surface of FNR overlapping activating region 1 that is required for repression of gene expression

A library of Escherichia coli fnr mutants has been screened to identify FNR (regulator of fumarate and nitrate reduction) variants that are defective repressors, but competent activators. All but one of seventeen variants had substitutions close to or within the face of FNR that contains activating region 1 (AR1). Activating region 1 is known to contact the alpha subunit of RNA polymerase to facilitate transcription activation. It is now evident that this face also has a role in FNR-mediated repression. Single amino acid substitutions at Lys54, Gly74, Ala95, Met147, Leu193, Arg197, or Leu239, and double substitutions at Ser13 and Ser145, Cys16 and Ile45, Tyr69 and Ser133, or Lys164 and Phe191, impaired FNR-mediated repression of ndh without greatly affecting activation from model Class I (FNR site at -71.5) and Class II (FNR site at -41.5) FNR-activated promoters. Although repression was impaired in a second group of FNR variants with substitutions at Leu34, Arg72 and Leu193, Phe92, or Ser178, transcription activation from the simple FNR-dependent promoters was severely reduced. However, expression from pyfiD (FNR sites at -40.5 and -93.5) and a derivative lacking the site at -93.5, pyfiD-/+, remained relatively high indicating that this second group have a context-dependent activation defect as well as a repression defect. The prediction that the substitutions affecting repression were likely to be in solvent exposed regions of FNR was supported by analysis of peptides produced by partial proteolysis of FNR. Thus, FNR-mediated repression at promoters with multiple FNR sites requires regions of FNR that are different from, but overlap, AR1.

Imposing specificity by localization: mechanism and evolvability

Cells detect extracellular signals by allostery and then give those signals meaning by 'regulated localization'. We suggest that this formulation applies to many biological processes and is particularly well illustrated by the mechanisms of gene regulation. Analysis of these mechanisms reveals that regulated localization requires simple molecular interactions that are readily used combinatorially. This system of regulation is highly 'evolvable', and its use accounts, at least in part, for the nature of the complexities observed in biological systems.

Downregulation of Escherichia coli yfiD expression by FNR occupying a site at -93.5 involves the AR1-containing face of FNR

The promoter of the FNR-activated yfiD gene of Escherichia coli has an unusual architecture because it contains two FNR sites, an arrangement usually associated with FNR-mediated repression. Investigation of yfiD promoter derivatives with altered FNR sites revealed that occupation of the far upstream FNR site (FNR II) downregulated expression, despite the presence of a FNR dimer activating expression from the promoter proximal site (FNR I). Transcript mapping by primer extension, and mutagenesis of potential -10 elements, indicated that yfiD expression is driven from a single FNR-dependent promoter with FNR sites at -40.5 (FNR I) and -93.5 (FNR II). However, yfiD mRNA is processed in stationary-phase cultures independently of rne, rpoS, ihfA and fis to yield transcripts lacking 12 and 21 bases from their respective 5' ends. Single amino acid substitutions (G74-->C, F92-->S, A95-->P, R184-->P, P188-->A or L193-->P) in the surface of FNR that contains activating region 1 (AR1 contacts the alpha-subunit of RNA polymerase to promote transcription activation) reduced the inhibitory effect of FNR at FNR II, indicating that this region of the protein may have a role in repression as well as activation. The FNR variant F92-->S was notable because, although it activated transcription of yfiD (two FNR sites), it was unable to activate transcription from model Class I and II promoters, which contain only a single FNR site.

The molecular basis for the differential regulation of the hlyE-encoded haemolysin of Escherichia coli by FNR and HlyX lies in the improved activating region 1 contact of HlyX

The regulator of fumarate and nitrate reduction (FNR) protein of Escherichia coli is an oxygen-responsive transcription regulator that acts mainly to activate the transcription of genes associated with anaerobic energy generation during periods of oxygen starvation. The hlyX gene of the swine pathogen Actinobacillus pleuropneumoniae encodes an FNR homologue, HlyX, which can complement the anaerobic respiratory deficiencies of an fnr mutant. However, FNR and HlyX have distinct but overlapping regulons because during anaerobic incubation, hlyX-expressing E. coli K-12 strains produce an otherwise latent haemolysin. The gene encoding the 'latent' haemolysin has been designated hlyE and analysis of the promoter region by DNase I footprinting reveals the presence of an FNR- (HlyX-) binding site. Anaerobic expression of an hlyE::lacZ reporter was 6.5-fold higher in hlyX compared to fnr-expressing cells. Both FNR and HlyX recruited RNA polymerase to the hlyE promoter but formed different ternary complexes. One major transcript (tsp1) initiating at 78.5 bp downstream of the FNR-binding site and four minor transcripts initiating at 73.5 (tsp2), 71.5 (tsp3), 63.5 (tsp4) and 62.5 (tsp5) bp from the FNR site were detected. From the position of the FNR box relative to the transcript starts, hlyE is expressed from a Class I FNR-regulated promoter. Substitution of selected FNR amino acids with the residues found in the equivalent positions in HlyX indicated that Activating Region 1 (AR1) of FNR forms a surface encompassing beta to beta 11 and that the AR1 contact at Class I promoters is different to that at Class II promoters, although the same surface is involved. The FNR variant, FNR-A225T, combined the properties of FNR (good activation from Class II promoters) and HlyX (good activation of Class I promoters) and conferred the haemolytic phenotype.

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.

Design of CytR regulated, cAMP-CRP dependent class II promoters in Escherichia coli: RNA polymerase-promoter interactions modulate the efficiency of CytR repression

In CytR regulated promoters in Escherichia coli, the cAMP-CRP complex acts as a transcriptional activator as well as a co-repressor for the CytR protein. Repression by CytR depends on the formation of nucleoprotein complexes in which CytR binds cooperatively to the DNA with one or two cAMP-CRP complexes. Here, we demonstrate that in order to establish CytR regulation in a cAMP-CRP dependent class II promoter with a single CRP site (CRP site centred around position -40.5) in which the CytR operator is located upstream of the CRP site, high affinity binding sites for both regulators are required. The efficiency of CytR regulation was observed to be modulated by RNA polymerase (RNAP)-promoter interactions. Specifically, in class II promoters with a single CRP site, the efficiency of CytR regulation was found to correlate inversely with cAMP-CRP independent promoter activity. These observations can be reconciled in a competition model for CytR regulation in which CytR and RNAP compete for cooperative binding with cAMP-CRP to the promoters in vivo. In this model, two mutually exclusive ternary complexes can be formed: a CytR/cAMP-CRP/promoter repression complex and an RNAP/cAMP-CRP/promoter activation complex. Thus, CytR regulation critically depends on formation of a repression complex that binds the promoter with sufficiently high affinity to exclude formation of the competing activation complex. We suggest that the transition from repression to activation involves a switch in the protein-protein interactions made by cAMP-CRP from CytR to RNAP. On the basis of the regulatory features of the promoters analysed here, we speculate about the advantages offered by the structural complexity of natural CytR/cAMP-CRP regulated promoters.

Molecular anatomy of a transcription activation patch: FIS-RNA polymerase interactions at the Escherichia coli rrnB P1 promoter

FIS, a site-specific DNA binding and bending protein, is a global regulator of gene expression in Escherichia coli. The ribosomal RNA promoter rrnB P1 is activated 3- to 7-fold in vivo by a FIS dimer that binds a DNA site immediately upstream of the DNA binding site for the C-terminal domain (CTD) of the alpha subunit of RNA polymerase (RNAP). In this report, we identify several FIS side chains important specifically for activation of transcription at rrnB P1. These side chains map to positions 68, 71 and 74, in and flanking a surface-exposed loop adjacent to the helix-turn-helix DNA binding motif of the protein. We also present evidence suggesting that FIS activates transcription at rrnB P1 by interacting with the RNAP alphaCTD. Our results suggest a model for FIS-mediated activation of transcription at rrnB P1 that involves interactions between FIS and the RNAP alphaCTD near the DNA surface. Although FIS and the transcription activator protein CAP have little structural similarity, they both bend DNA, use a similarly disposed activation loop and target the same region of the RNAP alphaCTD, suggesting that this is a common architecture at bacterial promoters.

An N-terminal mutation in the bacteriophage T4 motA gene yields a protein that binds DNA but is defective for activation of transcription

The bacteriophage T4 MotA protein is a transcriptional activator of T4-modified host RNA polymerase and is required for activation of the middle class of T4 promoters. MotA alone binds to the -30 region of T4 middle promoters, a region that contains the MotA box consensus sequence [(t/a)(t/a)TGCTT(t/c)A]. We report the isolation and characterization of a protein designated Mot21, in which the first 8 codons of the wild-type motA sequence have been replaced with 11 different codons. In gel retardation assays, Mot21 and MotA bind DNA containing the T4 middle promoter P(uvsX) similarly, and the proteins yield similar footprints on P(uvsX). However, Mot21 is severely defective in the activation of transcription. On native protein gels, a new protein species is seen after incubation of the sigma70 subunit of RNA polymerase and wild-type MotA protein, suggesting a direct protein-protein contact between MotA and sigma70. Mot21 fails to form this complex, suggesting that this interaction is necessary for transcriptional activation and that the Mot21 defect arises because Mot21 cannot form this contact like the wild-type activator.

Dual-function regulators: the cAMP receptor protein and the CytR regulator can act either to repress or to activate transcription depending on the context

Studies of gene regulation have revealed that several transcriptional regulators can switch between activator and repressor depending upon both the promoter and the cellular context. A relatively simple prokaryotic example is illustrated by the Escherichia coli CytR regulon. In this system, the cAMP receptor protein (CRP) assists the binding of RNA polymerase as well as a specific negative regulator, CytR. Thus, CRP functions either as an activator or as a corepressor. Here we show that, depending on promoter architecture, the CRP/CytR nucleoprotein complex has opposite effects on transcription. When acting from a site close to the DNA target for RNA polymerase, CytR interacts with CRP to repress transcription, whereas an interaction with CRP from appropriately positioned upstream binding sites can result in formation of a huge preinitiation complex and transcriptional activation. Based on recent results about CRP-mediated regulation of transcription initiation and the finding that CRP possesses discrete surface-exposed patches for protein-protein interaction with RNA polymerase and CytR, a molecular model for this dual regulation is discussed.