Transcription activation at Escherichia coli promoters dependent on the cyclic AMP receptor protein: effects of binding sequences for the RNA polymerase alpha-subunit

The cAMP receptor protein from Gardnerella vaginalis is not regulated by ligands

Overgrowth of Gardnerella vaginalis causes an imbalance in vaginal microecology. The pathogenicity of G. vaginalis is directly regulated by the cAMP receptor protein (CRP). In this study, we resolve the crystal structure of CRPGv at a resolution of 2.22 Å and find some significant differences from homologous proteins. The first 23 amino acids of CRPGv are inserted into the ligand binding pocket, creating a strong steric barrier to ligand entry that has not been seen previously in its homologues. In the absence of ligands, the two α helices used by CRPGv to bind oligonucleotide chains are exposed and can specifically bind TGTGA-N6-TCACA sequences. cAMP and other ligands of CRP homologs are not cofactors of CRPGv. There is no coding gene of the adenylate cyclase, and cAMP could not be identified in G. vaginalis by liquid chromatography tandem mass spectrometry. We speculate that CRPGv may achieve fine regulation through a conformational transformation different from that of its homologous proteins, and this conformational transformation is no longer dependent on small molecules, but may be aided by accessory proteins. CRPGv is the first discovered CRP that is not ligand-regulated, and its active conformation provides a structural basis for drug screening.

Cyclic AMP Receptor Protein Acts as a Transcription Regulator in Response to Stresses in Deinococcus radiodurans

The cyclic AMP receptor protein family of transcription factors regulates various metabolic pathways in bacteria, and also play roles in response to environmental changes. Here, we identify four homologs of the CRP family in Deinococcus radiodurans, one of which tolerates extremely high levels of oxidative stress and DNA-damaging reagents. Transcriptional levels of CRP were increased under hydrogen peroxide (H₂O₂) treatment during the stationary growth phase, indicating that CRPs function in response to oxidative stress. By constructing all CRP single knockout mutants, we found that the dr0997 mutant showed the lowest tolerance toward H₂O₂, ultraviolet radiation, ionizing radiation, and mitomycin C, while the phenotypes of the dr2362, dr0834, and dr1646 mutants showed slight or no significant differences from those of the wild-type strain. Taking advantage of the conservation of the CRP-binding site in many bacteria, we found that transcription of 18 genes, including genes encoding chromosome-partitioning protein (dr0998), Lon proteases (dr0349 and dr1974), NADH-quinone oxidoreductase (dr1506), thiosulfate sulfurtransferase (dr2531), the DNA repair protein UvsE (dr1819), PprA (dra0346), and RecN (dr1447), are directly regulated by DR0997. Quantitative real-time polymerase chain reaction (qRT-PCR) analyses showed that certain genes involved in anti-oxidative responses, DNA repair, and various cellular pathways are transcriptionally attenuated in the dr0997 mutant. Interestingly, DR0997 also regulate the transcriptional levels of all CRP genes in this bacterium. These data suggest that DR0997 contributes to the extreme stress resistance of D. radiodurans via its regulatory role in multiple cellular pathways, such as anti-oxidation and DNA repair pathways.

The TodS-TodT two-component regulatory system recognizes a wide range of effectors and works with DNA-bending proteins

The TodS and TodT proteins form a previously unrecognized and highly specific two-component regulatory system in which the TodS sensor protein contains two input domains, each of which are coupled to a histidine kinase domain. This system regulates the expression of the genes involved in the degradation of toluene, benzene, and ethylbenzene through the toluene dioxygenase pathway. In contrast to the narrow substrate range of this catabolic pathway, the TodS effector profile is broad. TodS has basal autophosphorylation activity in vitro, which is enhanced by the presence of effectors. Toluene binds to TodS with high affinity (Kd = 684 +/- 13 nM) and 1:1 stoichiometry. The analysis of the truncated variants of TodS reveals that toluene binds to the N-terminal input domain (Kd = 2.3 +/- 0.1 microM) but not to the C-terminal half. TodS transphosphorylates TodT, which binds to two highly similar DNA binding sites at base pairs -107 and -85 of the promoter. Integration host factor (IHF) plays a crucial role in the activation process and binds between the upstream TodT boxes and the -10 hexamer region. In an IHF-deficient background, expression from the tod promoter drops 8-fold. In vitro transcription assays confirmed the role determined in vivo for TodS, TodT, and IHF. A functional model is presented in which IHF favors the contact between the TodT activator, bound further upstream, and the alpha-subunit of RNA polymerase bound to the downstream promoter element. Once these contacts are established, the tod operon is efficiently transcribed.

Characterisation of the Escherichia coli mfd promoter

The bacterial mfd gene encodes a transcription-repair coupling factor that mediates the preferential repair of DNA damage in the template strand of active transcriptional units. In this report, the transcription start site for the Escherichia coli mfd gene was determined in vivo and in vitro, and the DNA determinants for mfd transcription by deletion and site-directed mutagenesis were defined. A canonical sigma(70)-dependent promoter, mfd P1, was responsible for the majority of mfd transcription, and a core region consisting of residues -42 to +5 was sufficient for full activity in rich and minimal media.

Requirement for two copies of RNA polymerase alpha subunit C-terminal domain for synergistic transcription activation at complex bacterial promoters

Transcription activation by the Escherichia coli cyclic AMP receptor protein (CRP) at different promoters has been studied using RNA polymerase holoenzyme derivatives containing two full-length alpha subunits, or containing one full-length alpha subunit and one truncated alpha subunit lacking the alpha C-terminal domain (alpha CTD). At a promoter having a single DNA site for CRP, activation requires only one full-length alpha subunit. Likewise, at a promoter having a single DNA site for CRP and one adjacent UP-element subsite (high-affinity DNA site for alpha CTD), activation requires only one full-length alpha subunit. In contrast, at promoters having two DNA sites for CRP, or one DNA site for CRP and two UP-element subsites, activation requires two full-length alpha subunits. We conclude that a single copy of alpha CTD is sufficient to interact with one CRP molecule and one adjacent UP-element subsite, but two copies of alpha CTD are required to interact with two CRP molecules or with one CRP molecule and two UP-element subsites.

Structural basis of transcription activation: the CAP-alpha CTD-DNA complex

The Escherichia coli catabolite activator protein (CAP) activates transcription at P(lac), P(gal), and other promoters through interactions with the RNA polymerase alpha subunit carboxyl-terminal domain (alphaCTD). We determined the crystal structure of the CAP-alphaCTD-DNA complex at a resolution of 3.1 angstroms. CAP makes direct protein-protein interactions with alphaCTD, and alphaCTD makes direct protein-DNA interactions with the DNA segment adjacent to the DNA site for CAP. There are no large-scale conformational changes in CAP and alphaCTD, and the interface between CAP and alphaCTD is small. These findings are consistent with the proposal that activation involves a simple "recruitment" mechanism.

Repression of deoP2 in Escherichia coli by CytR: conversion of a transcription activator into a repressor

In the deoP2 promoter of Escherichia coli, a transcription activator, cAMP-CRP, binds at two sites, centered at -41.5 and -93.5 from the start site of transcription, while a repressor, CytR, binds to a space between the two cAMP-CRP complexes. The mechanisms for the cAMP-CRP-mediated transcription activation and CytR-mediated transcription repression were investigated in vitro using purified components. We classified the deoP2 promoter as a class II cAMP-CRP-dependent promoter, primarily by the action of cAMP-CRP at the downstream site. Interestingly, we also found that deoP2 carries an "UP-element" immediately upstream of the downstream cAMP-CRP site. The UP-element overlaps with the DNA site for CytR. However, it was observed that CytR functions with the RNA polymerase devoid of the C-terminal domain of the alpha-subunit as well as with intact RNA polymerase. The mechanism of repression by CytR proposed in this study is that the cAMP-CRP bound at -41.5 undergoes an allosteric change upon direct interaction with CytR such that it no longer maintains a productive interaction with the N-terminal domain of alpha, but instead acts as a repressor to interfere with RNA polymerase acting on deoP2.

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.

The Escherichia coli RNA polymerase alpha subunit linker: length requirements for transcription activation at CRP-dependent promoters

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. This domain is connected to the N-terminal domain by an unstructured linker, which is proposed to confer a high degree of mobility on alphaCTD. To investigate the role of this linker in transcription activation we tested the effect of altering the linker length on promoters dependent on the cyclic AMP receptor protein (CRP). Short deletions within the alpha linker decrease CRP-dependent transcription at a Class I promoter while increasing the activity of a Class II promoter. Linker extension impairs CRP-dependent transcription from both promoters, with short extensions exerting a more marked effect on the Class II promoter. Activation at both classes of promoter was shown to remain dependent upon activating region 1 of CRP. These results show that the response to CRP of RNA polymerase containing linker-modified alpha subunits is class specific. These observations have important implications for the architecture of transcription initiation complexes at CRP-dependent 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.

Interactions between the Escherichia coli cAMP receptor protein and the C-terminal domain of the alpha subunit of RNA polymerase at class I promoters

The Escherichia coli cAMP receptor protein (CRP) is a factor that activates transcription at over 100 target promoters. At Class I CRP-dependent promoters, CRP binds immediately upstream of RNA polymerase and activates transcription by making direct contacts with the C-terminal domain of the RNA polymerase alpha subunit (alphaCTD). Since alphaCTD is also known to interact with DNA sequence elements (known as UP elements), we have constructed a series of semi-synthetic Class I CRP-dependent promoters, carrying both a consensus DNA-binding site for CRP and a UP element at different positions. We previously showed that, at these promoters, the CRP-alphaCTD interaction and the CRP-UP element interaction contribute independently and additively to transcription initiation. In this study, we show that the two halves of the UP element can function independently, and that, in the presence of the UP element, the best location for the DNA site for CRP is position -69.5. This suggests that, at Class I CRP-dependent promoters where the DNA site for CRP is located at position -61.5, the two alphaCTDs of RNA polymerase are not optimally positioned. Two experiments to test this hypothesis are presented.

Escherichia coli promoters with UP elements of different strengths: modular structure of bacterial promoters

The alpha subunit of Escherichia coli RNA polymerase (RNAP) participates in promoter recognition through specific interactions with UP element DNA, a region upstream of the recognition hexamers for the sigma subunit (the -10 and -35 hexamers). UP elements have been described in only a small number of promoters, including the rRNA promoter rrnB P1, where the sequence has a very large (30- to 70-fold) effect on promoter activity. Here, we analyzed the effects of upstream sequences from several additional E. coli promoters (rrnD P1, rrnB P2, lambda pR, lac, merT, and RNA II). The relative effects of different upstream sequences were compared in the context of their own core promoters or as hybrids to the lac core promoter. Different upstream sequences had different effects, increasing transcription from 1.5- to approximately 90-fold, and several had the properties of UP elements: they increased transcription in vitro in the absence of accessory protein factors, and transcription stimulation required the C-terminal domain of the RNAP alpha subunit. The effects of the upstream sequences correlated generally with their degree of similarity to an UP element consensus sequence derived previously. Protection of upstream sequences by RNAP in footprinting experiments occurred in all cases and was thus not a reliable indicator of UP element strength. These data support a modular view of bacterial promoters in which activity reflects the composite effects of RNAP interactions with appropriately spaced recognition elements (-10, -35, and UP elements), each of which contributes to activity depending on its similarity to the consensus.

CAP, the -45 region, and RNA polymerase: three partners in transcription initiation at lacP1 in Escherichia coli

The lac operon of Escherichia coli is positively regulated by the catabolite activator protein (CAP) bound upstream of the -45 region (CAP binding is centered at -61.5; the -45 region extends from -50 to -38). Certain mutations within the -45 region generate sequences that resemble UP elements in base composition and mimic the stimulation by the rrnBP1 UP element, yielding up to 15-fold stimulation in vivo. These -45 region "UP mutants" are compromised in their CAP stimulation. CAP and UP elements do not act in a fully additive manner in vivo at the lac operon. Transcription assays with the wild-type lac promoter and an UP mutant of lac indicate that CAP and UP DNA also fail to act in a completely additive manner in vitro. RNA polymerase can stabilize CAP binding to promoter DNA with a -45 region UP element against a heparin challenge. This shows that CAP and the UP DNA do not compete for the alpha-CTD as a mechanism for their lack of additivity. CAP and UP elements both demonstrate decreased stimulation of transcription as RNA polymerase concentration is increased from 0.05 to 10 nM in in vitro transcription experiments. In addition CAP also stimulates transcription in a manner that does not decrease as RNA polymerase is varied over this concentration range. This invariable stimulation is by two- to threefold and occurs both in vivo and in vitro. It is not dependent upon the alpha-CTD of RNA polymerase and is maintained in the presence of the AR1 CAP mutant HL159. This two- to threefold invariable CAP stimulation appears to depend on the -45 region sequence as our -45 region mutants demonstrate different responses to HL159 CAP stimulation in vivo.

Transcription activation at Class II CRP-dependent promoters: identification of determinants in the C-terminal domain of the RNA polymerase alpha subunit

Many transcription factors, including the Escherichia coli cyclic AMP receptor protein (CRP), act by making direct contacts with RNA polymerase. At Class II CRP-dependent promoters, CRP activates transcription by making two such contacts: (i) an interaction with the RNA polymerase alpha subunit C-terminal domain (alphaCTD) that facilitates initial binding of RNA polymerase to promoter DNA; and (ii) an interaction with the RNA polymerase alpha subunit N-terminal domain that facilitates subsequent promoter opening. We have used random mutagenesis and alanine scanning to identify determinants within alphaCTD for transcription activation at a Class II CRP-dependent promoter. Our results indicate that Class II CRP-dependent transcription requires the side chains of residues 265, 271, 285-288 and 317. Residues 285-288 and 317 comprise a discrete 20x10 A surface on alphaCTD, and substitutions within this determinant reduce or eliminate cooperative interactions between alpha subunits and CRP, but do not affect DNA binding by alpha subunits. We propose that, in the ternary complex of RNA polymerase, CRP and a Class II CRP-dependent promoter, this determinant in alphaCTD interacts directly with CRP, and is distinct from and on the opposite face to the proposed determinant for alphaCTD-CRP interaction in Class I CRP-dependent transcription.

Spacing requirements for interactions between the C-terminal domain of the alpha subunit of Escherichia coli RNA polymerase and the cAMP receptor protein

During transcription initiation at bacterial promoters, the C-terminal domain of the RNA polymerase alpha subunit (alphaCTD) can interact with DNA-sequence elements (known as UP elements) and with activator proteins. We have constructed a series of semi-synthetic promoters carrying both an UP element and a consensus DNA-binding site for the Escherichia coli cAMP receptor protein (CRP; a factor that activates transcription by making direct contacts with alphaCTD). At these promoters, the UP element was located at a variety of distances upstream of the CRP-binding site, which was fixed at position -41.5 bp upstream of the transcript start. At some positions, the UP element caused enhanced promoter activity whereas, at other positions, it had very little effect. In no case was the CRP-dependence of the promoter relieved. DNase I and hydroxyl-radical footprinting were used to study ternary RNA polymerase-CRP-promoter complexes formed at two of the most active of these promoters, and co-operativity between the binding of CRP and purified alpha subunits was studied. The footprints show that alphaCTD binds to the UP element as it is displaced upstream but that this displacement does not prevent alphaCTD from being contacted by CRP. Models to account for this are discussed.

DNA binding and DNA bending by the MelR transcription activator protein from Escherichia coli

The Escherichia coli melR gene encodes MelR protein which is a member of the AraC/XylS family of bacterial transcription activators. The function of MelR was investigated by making a targeted deletion in the melR gene of the Escherichia coli chromosome. MelR is a transcription activator essential for melibiose- dependent expression of the melAB operon which is needed for bacterial growth with melibiose as a carbon source. To investigate the interactions of MelR at the melAB promoter, both full length MelR and a shortened derivative, MelR173, containing the C-terminal DNA-binding domain, were purified as fusions to glutathione- S -transferase. Circular permutation studies show that both full-length MelR and MelR173 induce an apparent bend upon binding to target sites at the melAB promoter. Bound full-length MelR, but not MelR173, can oligomerise to form larger complexes that are likely to be involved in transcription activation.

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.

Activation of the catBCA promoter: probing the interaction of CatR and RNA polymerase through in vitro transcription

The soil bacterium Pseudomonas putida is capable of degrading many aromatic compounds, including benzoate, through catechol as an intermediate. The catabolism of catechol is mediated by the catBCA operon, whose induction requires the pathway intermediate cis,cis-muconate as an inducer and the regulatory protein, CatR. CatR also regulates the plasmid-borne pheBA operon of P. putida PaW85, which is involved in phenol catabolism. We have used an in vitro transcription system to study the roles of CatR, cis,cis-muconate, Escherichia coli RNA polymerase, and promoter sequences in expression of the cat and phe operons. The assay confirmed the requirement of both CatR and cis,cis-muconate for transcript formation. We also examined the in vitro transcription of three site-directed mutants of the catBCA promoter; the results obtained compared favorably with previous in vivo data. The requirement of the alpha subunit of RNA polymerase for expression of the catBCA and the pheBA transcripts was also examined. The C-terminal region of the alpha subunit of RNA polymerase has been implicated in direct protein-protein contact with transcriptional regulatory proteins and/or direct contact with the DNA. We show that the carboxyl terminus of the alpha subunit is required for the expression of the catBCA and the pheBA operons because RNA polymerases with truncated alpha subunits were deficient in activation. Further experiments demonstrated the arginine at position 265 and the asparagine at position 268 of the alpha subunit as possible amino acids involved in activation. On the basis of these and previous results, we propose a model to explain the interaction of the different regulatory components leading to CatR-dependent activation of the catBCA operon.

The -45 region of the Escherichia coli lac promoter: CAP-dependent and CAP-independent transcription

The lactose (lac) operon promoter is positively regulated by the catabolite gene activator-cyclic AMP complex (CAP) that binds to the DNA located 61.5 bp upstream of the transcription start site. Between the CAP binding site and the core promoter sequence is a 13-bp sequence (from -38 to -50 [the -45 region]). The possible roles of the -45 region in determining the CAP-independent level of lac expression and in the CAP activation process were studied by isolating and characterizing random multisite mutations. Only a small percentage of mutants have dramatic effects on lac promoter activity. Among the mutations that did affect expression, a 26-fold range in lac promoter activity in vivo was observed in the CAP-independent activity. The highest level of CAP-independent lac expression (13-fold the level of the wild-type lac promoter) correlated with changes in the -40 to -45 sequence and required an intact RNA polymerase alpha subunit for in vitro expression, as expected for an upstream DNA recognition element. Mutant promoters varied in their ability to be stimulated by CAP in vivo, with levels ranging from 2-fold to the wild-type level of 22-fold. Only a change of twofold in responsiveness to CAP could be attributed to direct DNA sequence effects. The -40 to -45 sequence-dependent enhancement of promoter activity and CAP stimulation of promoter activity did not act additively. The mutant promoters also displayed other characteristics, such as the activation of nascent promoter-like activities overlapping lac P1 and, in one case, replicon-dependent changes in promoter activity.

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

The Escherichia coli cyclic AMP receptor protein (CRP) is a homodimeric transcription activator triggered by cyclic AMP. Escherichia coli contains more than 100 different promoters that can be activated by CRP: in most cases the CRP acts by making direct contact with RNA polymerase. Remarkably, there is considerable variation in the location of the DNA site for CRP from one CRP-dependent promoter to another. Genetic methods have been used to locate the activating regions of CRP that make contact with RNA polymerase at promoters of different architectures. At promoters where the DNA site for CRP is centred near to positions -61, -71 or -81 (i.e. 61, 71 or 81 base pairs upstream of the transcript start-point, respectively), a single surface-exposed loop (Activating Region 1) in the downstream subunit of the CRP dimer makes contact with RNA polymerase. The contact site in RNA polymerase is located in one of the C-terminal domains of two RNA polymerase alpha subunits. At promoters where the DNA site for CRP is centred near to position-41, both subunits of the CRP dimer make contact with RNA polymerase via three separate surface exposed regions (Activating Regions 1, 2 and 3). At these promoters, where bound CRP overlaps with RNA polymerase-binding elements, the C-terminal domains of the polymerase alpha subunits are displaced and bind upstream of CRP. Activation at a number of E. coli promoters is dependent on binding of two CRP dimers, with one dimer bound near to position-41 and the other dimer bound further upstream. In these cases, both bound CRP dimers contact RNA polymerase. The CRP dimer bound around position-41 contacts RNA polymerase via Activating Regions 1, 2 and 3, whereas the upstream bound CRP dimer contacts one of the displaced alpha C-terminal domains via Activating Region 1 in the downstream CRP subunit. Thus in these cases, codependence on two activators is due to simultaneous contacts between separate activators and RNA polymerase. This mechanism allows great flexibility, as any activator that can contact the C-terminal domain of the RNA polymerase alpha subunits can act cooperatively with CRP.