Identification of the subunit of cAMP receptor protein (CRP) that functionally interacts with CytR in CRP-CytR-mediated transcriptional repression

At promoters of the Escherichia coli CytR regulon, the cAMP receptor protein (CRP) interacts with the repressor CytR to form transcriptionally inactive CRP-CytR-promoter or (CRP)(2)-CytR-promoter complexes. Here, using "oriented heterodimer" analysis, we show that only one subunit of the CRP dimer, the subunit proximal to CytR, functionally interacts with CytR in CRP-CytR-promoter and (CRP)(2)-CytR-promoter complexes. Our results provide information about the architecture of CRP-CytR-promoter and (CRP)(2)-CytR-promoter complexes and rule out the proposal that masking of activating region 2 of CRP is responsible for the transcriptional inactivity of the complexes.

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.

Protein-ligand interaction: grafting of the uridine-specific determinants from the CytR regulator of Salmonella typhimurium to Escherichia coli CytR

Members of the LacI family of transcriptional repressors respond to the presence of small effector molecules. The binding of the ligands affect the proteins ability to repress transcription by stabilizing a conformation that, in most cases, is unfavorable for high-affinity DNA binding. The CytR anti-activator diverges from the other family members by relying on the cooperative DNA binding with the global regulator CRP. The inducers of CytR do not affect CytR-DNA binding per se, but alleviate repression by interrupting protein-protein interactions between the two regulators. Here, we have studied of the CytR-inducer interaction by exploring a discrepancy in the inducer response observed for the homologous CytR regulators of Escherichia coli and Salmonella typhimurium. CytR of S. typhimurium (CytRSt) appears to respond to the presence of both uridine and cytidine nucleosides, whereas E. coli CytR (CytREc) responds to cytidine only. We have used a combination of genetic and structural modeling studies to provide detailed information regarding the nature of this discrepancy. By analysis of hybrid CytR proteins followed by site-directed mutagenesis, we have successfully transferred the specificity determinants for uridine from CytRSt to CytREc, revealing that serine substitutions of only two residues (G131 and A152) in CytREc is required to make CytREc sensitive to uridine. In addition, by employing a genetic screen for induction of defective mutants, we have identified four amino acid residues in CytRSt that appear to be important for the response to uridine. The implications of these findings for the understanding of the ligand binding and induction of CytR are discussed in the context of the structural knowledge of CytR and homologous protein-ligand complexes.

Transcription of rpoH, encoding the Escherichia coli heat-shock regulator sigma32, is negatively controlled by the cAMP-CRP/CytR nucleoprotein complex

In Escherichia coli, the rpoH gene encoding the essential heat-shock regulator sigma32, is expressed in a complex manner. Transcription occurs from four promoters (P1, P3, P4 and P5) and is modulated by several factors including (i) two sigma factors (sigma70 and sigmaE); (ii) the global regulator CRP; and (iii) the DnaA protein. Here, a further dissection of the rpoH regulatory region has revealed that an additional transcription control exists that appears to link rpoH expression to nucleoside metabolism. The cAMP-CRP complex and the CytR anti-activator bind co-operatively to the promoter region forming a repression complex that overlaps the sigmaE-dependent P3 promoter and the sigma70-dependent P4 and P5 promoters. During steady-state growth conditions with glycerol as the carbon and energy source, transcription from P3, P4 and P5 is reduced approximately threefold by CytR, whereas transcription from the upstream promoter, P1, appears to be unaffected. Furthermore, in strains that slightly overproduce CytR, transcription from P3, P4 and P5 is reduced even further (approximately 10-fold), and repression can be fully neutralized by the addition of the inducer cytidine to the growth medium. In the induced state, P4 is the strongest promoter and, together with P3 and P5, it is responsible for most rpoH transcription (65-70%). At present, CytR has been shown to 'fine tune' transcription of two genes (rpoH and ppiA) that are connected with protein-folding activities. These findings suggest that additional assistance in protein folding is required under conditions in which CytR is induced (i.e. in the presence of nucleosides).

DNA-binding characteristics of the Escherichia coli CytR regulator: a relaxed spacing requirement between operator half-sites is provided by a flexible, unstructured interdomain linker

The Escherichia coli CytR regulator belongs to the LacI family of sequence-specific DNA-binding proteins and prevents CRP-mediated transcription in the CytR regulon. Unlike the other members of this protein family, CytR binds with only modest affinity to its operators and transcription repression thus relies on the formation of nucleoprotein complexes with the cAMP-CRP complex. Moreover, CytR exhibits a rotational and translational flexibility in operator binding that is unprecedented in the LacI family. In this report we examined the effect of changing the spacing between CytR half-operators on CytR regulation in vivo and on CytR binding in vitro. Maximum repression was seen with the short spacing variants: repression peaks when the half-operators lie on the same face of the DNA helix. Repression was retained for most spacing variants with centre separations of half-operators < or = 3 helical turns. Our data confirm and extend the view that CytR is a highly flexible DNA binder that can adapt many different conformations for co-operative binding with CRP. Furthermore, limited proteolysis of radiolabelled CytR protein showed that the interdomain linker connecting the DNA binding domains and the core part of CytR does not become structured upon DNA binding. We conclude that CytR does not use hinge alpha-helices for minor groove recognition. Rather, CytR possesses a highly flexible interdomain linker that allows it to form complexes with CRP at promoters with quite different architecture.

Protein-protein communication: structural model of the repression complex formed by CytR and the global regulator CRP

The cAMP receptor protein (CRP) and the LacI-related CytR antiactivator bind cooperatively to adjacent DNA sites at or near promoters, an interaction that involves direct protein contacts. Here, we identify a collection of amino acid substitutions in CytR that reestablish protein-protein communication to mutant CRP proteins specifically defective in cooperative binding with wild-type CytR. To assess the location and spatial arrangement of these substitutions, we built a three-dimensional model of CytR based on the recent X-ray structure of the highly homologous PurR repressor bound to DNA. This approach enables us to specify the patch on CytR's surface that contacts CRP. Furthermore, our results permit the construction of a three-dimensional structure of the higher order nucleoprotein complex formed by CytR and CRP.

Protein-induced fit: the CRP activator protein changes sequence-specific DNA recognition by the CytR repressor, a highly flexible LacI member

The CytR repressor and the cAMP receptor protein (CRP) bind cooperatively to several promoters in Escherichia coli to repress transcription initiation. The synergistic binding is mediated by protein-protein interactions between the two regulators. Here, in vitro selection experiments have been used to examine the DNA-binding characteristics of CytR, by itself and when co-binding with cAMP-CRP. We show that the optimal CytR-binding site consists of two octamer repeats, in direct or inverted orientation, and separated by 2 bp. However, when co-binding with cAMP-CRP, CytR instead recognizes inverted repeats separated by 10-13 bp, or direct repeats separated by 1 bp. The configurations of the latter set of operators correlate well with the configurations of natural CytR targets. Thus, cAMP-CRP induces conformational changes in CytR so that the repressor fits the natural targets. Most strikingly, CytR can adopt widely different conformations that are equally favored energetically for complex formation with cAMP-CRP. We propose that this structural adaptability is essential for CytR repression of promoters with diverse architectures. We discuss these novel concepts in the context of the CRP/CytR regulatory system, as well as the structural and functional implications for multiprotein-DNA complex formation in general.

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.

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.

CytR/cAMP-CRP nucleoprotein formation in E. coli: the CytR repressor binds its operator as a stable dimer in a ternary complex with cAMP-CRP

The CytR repressor protein relies on protein-protein interactions to the cAMP-CRP complex to bind its operators with sufficiently high affinity to repress transcription. Here, the quaternary structure of CytR and the mechanism underlying the cooperative binding of CytR and cAMP-CRP have been analyzed. Using a modified Ferguson analysis in which protein-DNA complexes are separated in a non-denaturing gel system, we show that CytR binds its operators as a dimer alone as well as in a ternary complex with cAMP-CRP. Analyses of DNA binding of CytR at low protein concentrations indicate that CytR is a dimer in solution at physiological concentrations. Moreover, the CytR inducer cytidine was found not to have any effect on the oligomerization of free CytR or DNA bound CytR. Thus, these data rule out the possibility that the cooperative DNA binding of CytR and cAMP-CRP involves induced dimerization of CytR, and they suggest that cytidine interrupts the cooperative binding of CytR and cAMP-CRP solely by perturbing the protein-protein interactions between the two proteins.

A flexible partnership: the CytR anti-activator and the cAMP-CRP activator protein, comrades in transcription control

A vital point in gene regulation is control at the level of transcription initiation. Recent research has established that this regulation can involve sophisticated networks of interacting proteins that modulate the activity of the transcription machinery by DNA looping, direct protein-protein interactions or changing DNA topology in the promoter region. This Micro-Review focuses on our investigations of a relatively simple prokaryotic gene regulatory system, the Escherichia coli CytR regulon, which exhibits a number of these features. This work has opened the door to the molecular understanding of how a prokaryotic repressor can be correctly positioned at specific DNA sequences with the help of a global activator, and how the repressor subsequently inhibits factor-dependent transcription initiation.

Organization and transcriptional regulation of the Escherichia coli K-12 D-serine tolerance locus

We have reinvestigated the genetic organization and the transcription regulation of the dsd operon of Escherichia coli. By combining genetic and biochemical studies, it is demonstrated that the regulatory region of the operon and the gene encoding the specific regulator of D-serine tolerance (dsdC) had been misplaced in previous work on the dsd system. Also, the previous erroneous DNA sequence of the dsdC gene has been corrected. It turned out that an additional gene (dsdX) is present immediately upstream of dsdA (encoding D-serine deaminase) and that dsdC is located adjacent to dsdX. The dsdXA genes are cotranscribed from a common promoter region present in the dsdX-dsdC intercistronic region. The DsdC activator belongs to the LysR-type of transcriptional regulators and is absolutely required for dsdA expression. Additionally, the activity of the dsdXA promoter depends on the cyclic AMP receptor protein, and the two activators act in concert to synergistically activate transcription.

Gene-regulatory modules in Escherichia coli: nucleoprotein complexes formed by cAMP-CRP and CytR at the nupG promoter

Repression by CytR depends on the formation of nucleoprotein complexes in which the CytR repressor and the cAMP-CRP activator complex bind co-operatively to the DNA. Transcription initiation from CytR-regulated promoters requires cAMP-CRP; therefore, the cAMP-CRP complex functions both as an activator and as a co-repressor in these promoters. Another interesting aspect of the CytR regulon is that each promoter appears to have individual features. Therefore, structural and functional rules governing the formation of repression and activation complexes in one promoter may not be valid for other promoters of the CytR regulon. Here we show that the Escherichia coli nupG gene contains one CytR- and four CRP-binding sites in the control region. Notably, the architecture of the CytR binding site is different from previously described targets. In addition, the CytR repressor triggers a DNA repositioning of a cAMP-CRP complex in the -35 region upon binding to its operator. Thus, formation of the repression and activation complexes at the nupG promoter involves different subsets of CRP-binding sites. These findings show that the bacterium uses positive and negative regulatory modules to differentially control the expression of CytR- and cAMP-CRP-regulated genes.

The gene encoding the periplasmic cyclophilin homologue, PPIase A, in Escherichia coli, is expressed from four promoters, three of which are activated by the cAMP-CRP complex and negatively regulated by the CytR repressor

The rot gene in Escherichia coli encodes PPIase A, a periplasmic peptidyl-prolyl cis-trans isomerase with homology to the cyclophilin family of proteins. Here it is demonstrated that rot is expressed in a complex manner from four overlapping promoters and that the rot regulatory region is unusually compact, containing a close array of sites for DNA-binding proteins. The three most upstream rot promoters are activated by the global gene regulatory cAMP-CRP complex and negatively regulated by the CytR repressor protein. Activation of these three promoters occurs by binding of cAMP-CRP to two sites separated by 53 bp. Moreover, one of the cAMP-CRP complexes is involved in the activation of both a Class I and a Class II promoter. Repression takes place by the formation of a CytR/cAMP-CRP/DNA nucleoprotein complex consisting of the two cAMP-CRP molecules and CytR bound in between. The two regulators bind co-operatively to the DNA overlapping the three upstream promoters, simultaneously quenching the cAMP-CRP activator function. These results expand the CytR regulon to include a gene whose product has no known function in ribo- and deoxyribonucleoside catabolism or transport.

Synthesis of a carboxamide linked T*T dimer and its incorporation in oligonucleotides

The condensation of 5'-O-protected 3'-O-(2-aminoethyl)thymidine with 1,2-dideoxy-1-thyminyl-beta-D-erythro-pentofuranuronic acid gives a T*T dimer with * representing a 3'-OCH2CH2NHC(O)-4' linkage connecting the two pentofuranosyl moieties. The incorporation of this dimer in oligonucleotide sequences show only moderately lowered Tm values when hybridized with a complementary DNA relative to the unmodified DNA duplex. Consistently, no looped-out or bubble-type structure could be detected in DNA duplexes with an internal T*T module. Moreover, the 5-atom carboxamide linker causes complete stop on DNA polymerization and on exonuclease III degradation.

Protein-protein interactions in gene regulation: the cAMP-CRP complex sets the specificity of a second DNA-binding protein, the CytR repressor

Maximal repression by the CytR protein depends on the formation of nucleoprotein complexes in which CytR interacts with DNA and with cAMP-cAMP receptor protein (CRP). Here we demonstrate that CytR regulates transcription from deoP2 promoters in which the entire CytR recognition sequence has been eliminated. Furthermore, CytR proteins deleted for the DNA-binding domain repress deoP2 in vivo and interact with deoP2 in vitro in a strictly cAMP-CRP-dependent fashion. These experiments show that the site of action of CytR can be specified by protein-protein interactions to cAMP-CRP, whereas CytR-DNA interactions may primarily serve to stabilize the nucleo-protein complex. This type of specificity mechanism may represent a general concept in the recruitment of DNA-binding proteins in combinatorial regulatory systems.

Characterization of promoter recognition complexes formed by CRP and CytR for repression and by CRP and RNA polymerase for activation of transcription on the Escherichia coli deoP2 promoter

The structure of the cAMP-CRP-CytR repression complex and the cAMP CRP-RNA polymerase initiation complex at the deoP2 promoter of E. coli have been probed by DNase I and uranyl footprinting. In the CRP2-CytR complex all protein DNA-phosphate contacts at CRP-1 and CRP-2 are retained, and in addition two new minor groove contacts, ascribed to phosphate-CytR interactions, are observed at -60 between the CRP sites. The contacts are compatible with a model in which the promoter DNA is wrapped around a complex of two CRPs and one CytR. In the RNA polymerase-CRP complex, the CRP-1 phosphate contacts are almost identical to those seen in the repression complex and strong RNA polymerase contacts are seen in the -10 and in the +10 regions. Most noteworthy are minor groove contacts in the -60 region ascribed to RNA polymerase contacts upstream from the CRP. Furthermore, binding of CRP to the CRP-2 target does not seem to interfere with RNA polymerase binding. Thus, a model is suggested in which the DNA is wrapped around a complex of RNA polymerase and one CRP. Finally, the results show that CytR and RNA polymerase are rivals that compete for binding with CRP at deoP2 and that CytR functions as an antiactivator.

Identification of the nucleotide sequence recognized by the cAMP-CRP dependent CytR repressor protein in the deoP2 promoter in E. coli

In E. coli repression of transcription initiation by the CytR protein relies on CytR-DNA interactions as well as on interactions between CytR and the cAMP-CRP activator complex. To identify the nucleotide sequence recognized by CytR, mutants of the deoP2 promoter with a reduced regulatory response to CytR have been isolated. Five single bp mutation derivatives of deoP2 with a 2-5-fold decrease in CytR regulation have been characterized. In vitro, the only effect of the mutations was a decrease in the binding affinity of CytR, and a clear correlation was observed between the reduction in CytR regulation in vivo and the reduction in CytR binding in vitro. The mutations all reside in a sequence element that contains an imperfect direct as well as an imperfect inverted repeat. As the active form of CytR, most likely, is an oligomer with two-fold rotational symmetry, CytR probably interacts with the inverted repeat. Degenerate versions of the inverted repeat are present in all CytR binding sites characterized so far, however, the distance between the half-sites varies.

The cAMP-CRP/CytR nucleoprotein complex in Escherichia coli: two pairs of closely linked binding sites for the cAMP-CRP activator complex are involved in combinatorial regulation of the cdd promoter

Transcription initiation at CytR regulated promoters in Escherichia coli is controlled by a combinatorial regulatory system in which the cAMP receptor protein (CRP) functions as both an activator and a co-repressor. By combining genetic studies and footprinting analyses, we demonstrate that regulated expression of the CytR controlled cdd promoter requires three CRP-binding sites: a high affinity site (CRP-1) and two overlapping low affinity sites (CRP-2 and CRP-3) centred at positions -41, -91 and -93, respectively. In the absence of CytR, cAMP-CRP interacts at one set of sites (CRP-1 and CRP-2) and both of these binding sites are required for full promoter activation. In the presence of CytR, however, the two regulators bind cooperatively to cddP forming a nucleoprotein complex in which cAMP-CRP binds to CRP-1 and CRP-3 and CytR occupies the sequence between these sites. Thus, association of the two regulators involves a repositioning of the cAMP-CRP complex. Moreover, mutant cdd promoters in which CRP-2 and CRP-3 have been deleted are partially regulated by CytR, and cAMP-CRP and CytR still bind cooperatively to these promoters. These findings provide clues to an understanding of how cAMP-CRP and CytR interact at a structurally diverse set of promoters.

cAMP-CRP activator complex and the CytR repressor protein bind co-operatively to the cytRP promoter in Escherichia coli and CytR antagonizes the cAMP-CRP-induced DNA bend

Initiation of transcription from the cytRP promoter in Escherichia coli is activated by the cAMP-CRP complex and negatively regulated by the CytR repressor protein. By combining gel retardation and footprinting assays, we show that cAMP-CRP binds to a single site centered at position -64 and induces a considerable bend in the DNA. CytR binds to a region immediately downstream from, and partially overlapping, the CRP site, and induces a modest bend into the DNA. In combination, cAMP-CRP and CytR bind co-operatively to cytRP forming a nucleoprotein complex in which the proteins directly interact with each other and bind to the same face of the DNA helix. CytR binding concomitantly antagonizes the cAMP-CRP-induced bend. This study indicates that the minimal DNA region required to obtain CytR regulation consists of a single binding site for each of cAMP-CRP and CytR. The case described here, in which a protein-induced DNA bend is modulated by a second protein, may illustrate a mechanism that applies to other regulatory systems.

Restored DNA-binding of the cAMP-CRP activator complex reestablishes negative regulation by the CytR repressor in the deoP2 promoter in Escherichia coli

We have investigated in vivo the coupling between CytR regulation of the deoP2 promoter in Escherichia coli and the DNA-binding specificity of the cAMP-CRP (cAMP receptor protein) complex in order to obtain a more detailed picture of the role played by cAMP-CRP in CytR regulation. By introducing CRP proteins that exhibit an altered DNA binding specificity into a strain containing a mutant deoP2 promoter in which cAMP-CRP activation was decreased and CytR regulation completely abolished, we show that CytR regulation of this promoter can be reestablished by restored the DNA binding of the cAMP-CRP complex. Hence, CytR regulation of deoP2 can be modulated by simply varying DNA binding of cAMP-CRP. These data confirm the crucial role played by the cAMP-CRP activator complex in CytR regulation of the deoP2 promoter.

Heterologous cooperativity in Escherichia coli. The CytR repressor both contacts DNA and the cAMP receptor protein when binding to the deoP2 promoter

Promoters in Escherichia coli that are negatively regulated by the CytR repressor are also activated by the cAMP receptor protein (CRP) complexed to cAMP; as a characteristic, these promoters encode two binding sites for the cAMP.CRP complex. Biochemical and genetic studies have shown that CytR relies on interactions with the cAMP.CRP complex in order to bind promoter DNA and repress transcription. Here we have purified CytR to near homogeneity and addressed the question of how it interacts with the deoP2 promoter. Gel retardation and DNase I footprinting analyses show that CytR is a true sequence-specific DNA-binding protein that binds to the sequence between the two CRP sites in deoP2 with a relatively low affinity. In the presence of the cAMP.CRP complex the two protein species bind cooperatively to deoP2, forming a complex in which CytR occupies the sequence between the two DNA bound cAMP.CRP complexes. Furthermore, the inducer (cytidine) does not affect independent DNA binding of CytR, rather the CytR/cAMP.CRP cooperativity is perturbed. These results indicate that CytR binding to deoP2 relies on both repressor-DNA interactions and protein-protein interactions to cAMP.CRP. This combinatorial repression mechanism, in which an activator functions as an adaptor for a repressor that is not capable of blocking transcription on its own, is unprecedented in prokaryotes; it is, however, reminiscent of repression mechanisms found in eukaryotes.

The cyclic AMP (cAMP)-cAMP receptor protein complex functions both as an activator and as a corepressor at the tsx-p2 promoter of Escherichia coli K-12

The tsx-p2 promoter is one of at least seven Escherichia coli promoters that are activated by the cyclic AMP (cAMP)-cAMP receptor protein (CRP) complex and negatively regulated by the CytR repressor. DNase I footprinting assays were used to study the interactions of these regulatory proteins with the tsx-p2 promoter region and to characterize tsx-p2 regulatory mutants exhibiting an altered response to CytR. We show that the cAMP-CRP activator complex recognizes two sites in tsx-p2 that are separated by 33 bp: a high-affinity site (CRP-1) overlaps the -35 region, and a low-affinity site (CRP-2) is centered around position -74 bp. The CytR repressor protects a DNA segment that is located between the two CRP sites and partially overlaps the CRP-1 target. In combination, the cAMP-CRP and CytR proteins bind cooperatively to tsx-p2, and the nucleoprotein complex formed covers a region of 78 bp extending from the CRP-2 site close to the -10 region. The inducer for the CytR repressor, cytidine, does not prevent in vitro DNA binding of CytR, but releases the repressor from the nucleoprotein complex and leaves the cAMP-CRP activator bound to its two DNA targets. Thus, cytidine interferes with the cooperative DNA binding of cAMP-CRP and CytR to tsx-p2. We characterized four tsx-p2 mutants exhibiting a reduced response to CytR; three carried mutations in the CRP-2 site, and one carried a mutation in the region between CRP-1 and the -10 sequence. Formation of the cAMP-CRP-CytR DNA nucleoprotein complex in vitro was perturbed in each mutant. These data indicate that the CytR repressor relies on the presence of the cAMP-CRP activator complex to regulate tsx-p2 promoter activity and that the formation of an active repression complex requires the combined interactions of cAMP-CRP and CytR at tsx-p2.

Single amino acid substitutions in the cAMP receptor protein specifically abolish regulation by the CytR repressor in Escherichia coli

Promoters in Escherichia coli that are negatively regulated by the CytR repressor are also activated by the cAMP receptor protein (CRP) complexed to cAMP; as a characteristic, these promoters encode tandem binding sites for cAMP-CRP. In one such promoter, deoP2, CytR binds to the region between the tandem CRP binding sites with a relatively low affinity; in the presence of cAMP-CRP, however, the repressor and activator bind cooperatively to the DNA. Here we have investigated this cooperativity by isolating mutants of the CRP protein that abolish CytR regulation without exhibiting a concomitant loss in their ability to activate transcription. Four different, single amino acid substitutions in CRP give rise to this phenotype. These amino acids lie in close proximity on the surface of the CRP tertiary structure in a portion of the protein that is not in contact with the DNA. In vitro analyses of one of the CRP mutants show that it interacts with the DNA in a manner indistinguishable from wild-type CRP, whereas its interaction with CytR is perturbed. These results strongly indicate that cooperative DNA binding of CytR and cAMP-CRP is achieved through protein-protein interactions.

A novel function of the cAMP-CRP complex in Escherichia coli: cAMP-CRP functions as an adaptor for the CytR repressor in the deo operon

Unlike classical bacterial repressors, the CytR repressor of Escherichia coli cannot independently regulate gene expression. Here we show that CytR binding to the deoP2 promoter relies on interaction with the master gene regulatory protein, CRP, and, furthermore, that cAMP-CRP and CytR bind co-operatively to deoP2. Using mutant promoters we show that tandem, properly spaced DNA-bound cAMP-CRP complexes are required for this co-operative binding. These data suggest that CytR forms a bridge between tandem cAMP-CRP complexes, and that cAMP-CRP functions as an adaptor for CytR. The implications of this new version of negative control in E. coli on bacterial gene expression and on combinatorial gene regulation in higher organisms are discussed.

Design of cAMP-CRP-activated promoters in Escherichia coli

We have studied the deoP2 promoter of Escherichia coli to define features that are required for optimal activation by the complex of adenosine 3',5' monophosphate (cAMP) and the cAMP receptor protein (CRP). Systematic mutagenesis of deoP2 shows that the distance between the CRP site and the -10 hexamer is the crucial factor in determining whether the promoter is activated by cAMP-CRP. Based on these observations, we propose that cAMP-CRP-activated promoters can be created by correctly aligning a CRP target and a -10 hexamer. This idea has been successfully tested by converting both a CRP-independent promoter and a sequence resembling the consensus -10 hexamer to strongly cAMP-CRP-activated promoters.

Analysis of the tsx gene, which encodes a nucleoside-specific channel-forming protein (Tsx) in the outer membrane of Escherichia coli

The tsx gene of Escherichia coli encodes an outer membrane protein, Tsx, which constitutes the receptor for colicin K and bacteriophage T6, and functions as a substrate-specific channel for nucleosides and deoxynucleosides. The mini-Mu element pEG5005 was used to prepare a gene bank in vivo, and this bank was used to identify T6-sensitive strains carrying the cloned tsx gene. Subcloning of the tsx gene into the multicopy plasmid, pBR322, resulted in a strong overproduction of Tsx. The sequence of a 1477-bp DNA segment containing tsx and its flanking regions was determined. An open reading frame (ORF) was found which was followed by a pair of repetitive extragenic palindromic sequences. This ORF translated into a protein of 294 amino acids (aa), the first 22 aa of which showed the characteristic features of a bacterial signal sequence peptide. The putative mature form of Tsx is composed of 272 aa with a calculated Mr of 31418. The aa sequence of Tsx shows an even distribution of charged residues (52 aa) and lacks extensive hydrophobic stretches. No significant homologies of Tsx to the channel-forming proteins OmpC, OmpF, PhoE and LamB from the E. coli outer membrane were detected. Using nuclease S1, we identified two transcription start points for the tsx mRNA which were separated by approx. 150 bp. Genetic data suggest that the synthesis of the larger mRNA species is directed by a weak promoter (P1) that is controlled by the DeoR repressor, whereas the smaller mRNA species is directed by the main promoter P2, which is negatively controlled by the CytR repressor and positively affected by the cyclic AMP/catabolite activator protein complex.

The CytR repressor antagonizes cyclic AMP-cyclic AMP receptor protein activation of the deoCp2 promoter of Escherichia coli K-12

We have investigated the regulation of the Escherichia coli deoCp2 promoter by the CytR repressor and the cyclic AMP (cAMP) receptor protein (CRP) complexed to cAMP. Promoter regions controlled by these two proteins characteristically contain tandem cAMP-CRP binding sites. Here we show that (i) CytR selectively regulated cAMP-CRP-dependent initiations, although transcription started from the same site in deoCp2 in the absence or presence of cAMP-CRP; (ii) deletion of the uppermost cAMP-CRP target (CRP-2) resulted in loss of CytR regulation, but had only a minor effect on positive control by the cAMP-CRP complex; (iii) introduction of point mutations in either CRP target resulted in loss of CytR regulation; and (iv) regulation by CytR of deletion mutants lacking CRP-2 could be specifically reestablished by increasing the intracellular concentration of CytR. These findings indicate that both CRP targets are required for efficient CytR repression of deoCp2. Models for the action of CytR are discussed in light of these findings.

Tandem DNA-bound cAMP-CRP complexes are required for transcriptional repression of the deoP2 promoter by the CytR repressor in Escherichia coli

We have studied the deoP2 promoter in Escherichia coli to define features important for its interaction with the CytR repressor. As is characteristic for CytR-regulated promoters, deoP2 encodes tandem binding sites for the activating complex cAMP-CRP. One of these sites, CRP-1, overlaps the -35 region, and is sufficient for activation; the second site, CRP-2, centred around -93, is indispensable for repression. Here we demonstrate, by means of in vivo titration, that CytR interaction with deoP2 depends not only on CRP-2, but also on CRP-1 and the length and possibly the sequence separating these two sites. Also, point mutations in either CRP site reduce or abolish CytR titration; however, no co-operativity is observed in the interaction of CytR with the two CRP binding sites. Furthermore, the reduction in CytR titration parallels the reduction in binding of cAMP-CRP to the mutated CRP sites in vitro. These observations are not easily explained by current models for the action of prokaryotic repressors; instead we favour a model in which the interaction of CytR with deoP2 depends on the presence of tandem DNA-bound cAMP-CRP complexes.

Transcriptional regulation of the cytR repressor gene of Escherichia coli: autoregulation and positive control by the cAMP/CAP complex

The Escherichia coli cytR-encoded repressor protein (CytR) controls the expression of several genes involved in nucleoside and deoxynucleoside uptake and metabolism. The cytR promoter was identified by determining the transcriptional initiation site of the cytR gene. A chromosomal cytR-lacZ+ operon fusion was isolated and used to study the regulation of cytR. We show that cytR expression is negatively controlled by the CytR protein and positively affected by the cAMP/CAP complex. Footprinting studies with purified CAP protein revealed two CAP binding sites upstream of the cytR promoter. A previously described mutation (cytR*) in the cloned cytR gene, which results in the phenotypic suppression of a CytR operator mutation in the tsx P2 promoter, was analysed. DNA sequence analysis of the cytR* mutation revealed a G-C to an A-T base pair transition at position -34 bp relative to the translational initiation site of cytR. This point mutation activates a cryptic promoter that is stronger than the wild-type cytR promoter and leads to overproduction of the CytR repressor.

CRP/cAMP- and CytR-regulated promoters in Escherichia coli K12: the cdd promoter

Transcriptional regulation of the deoP2 promoter by the cyclic AMP/cyclic AMP receptor protein complex (cAMP/CRP) and the CytR repressor requires two high-affinity CRP targets located around -41 and -93 bp preceding the start site for transcription. Here we report the structure of cddP, another CRP/CytR-regulated promoter. In common with what was found in deo, the cdd promoter also contains multiple CRP targets. Thus, using the DNasel footprinting procedure, tandem CRP binding sites were identified around -41 and -93. These findings support a general model for CytR binding and CytR regulation, in which (i) CytR and the CRP/cAMP complex bind to similar or identical targets, (ii) two or more targets are necessary for proper binding of CytR to a promoter region, and (iii) CytR represses transcription by antagonizing cAMP/CRP activation.

Analysis of the terminator region after the deoCABD operon of Escherichia coli K-12 using a new class of single copy number operon-fusion vectors

We describe the construction of low copy number operon-fusion vectors, and use one of these vectors for the cloning and transcriptional analysis of the terminator region after the deo operon of Escherichia coli K-12. The new vectors are miniderivatives of plasmid R1 containing the parB stability locus of this plasmid and the lac genes as a selectable marker. Since the copy number of the vectors is only one per genome-equivalent at temperatures below 37 degrees C this system is ideally suited for isolation and characterization of transcriptional and translational signals from E. coli. Our results show that a very strong terminator (deot), which resembles Rho-independent terminators, is located 60 bp downstream from the fourth structural gene of the deo operon. This confirms that deoD is the last gene in the operon. In addition, we have identified a new promoter just after the deot terminator and a short DNA sequence that is able to reduce lacZ expression by 85% when inserted between the deoP2 promoter and the lac genes.

Long-range cooperativity between gene regulatory sequences in a prokaryote

Regulation of transcription initiation by proteins binding at DNA sequences some distance from the promoter region itself seems to be a general phenomenon in both eukaryotes and prokaryotes. Proteins bound to an enhancer site in eukaryotes can turn on a distant gene, whereas efficient repression of some prokaryotic genes such as the gal, ara and deo operons of Escherichia coli, requires the presence of two operator sites, separated by 110, 200 and 600 base pairs (bp) respectively. In the deo operon, which encodes nucleoside catabolizing enzymes, we have shown that efficient and cooperative repression can be obtained when the distance between the two sites ranges from 224 to 997 bp. Here, we report that transcription initiation can be regulated from an operator site placed 1 to 5 kilobases (kb) downstream of the deoP2 promoter (and downstream of the transcribed gene), and present the first experimental data for prokaryotic regulation at distances greater than 1 kb. Our results support the model of DNA loop formation as a common regulatory mechanism explaining both some prokaryotic regulation and the action of eukaryotic enhancers.

DNA-protein recognition: demonstration of three genetically separated operator elements that are required for repression of the Escherichia coli deoCABD promoters by the DeoR repressor

The sequences required for full repression of the Escherichia coli deoP1 and P2 promoters by the deoR repressor (DeoR) have been analyzed in vivo. Using recombinant techniques, we have constructed a set of deo-lacZ fusions which contain different parts of the sequences involved in the regulation of deo expression on low copy number fusion vectors. Since these vectors are present in only one copy per chromosome at temperatures below 37 degrees C, this vector system allows very accurate studies of gene control signals. Our results show that three DeoR operator sites exist in the deoP1-P2 regulatory region. Two of these loci overlap the initiation sites for deoP1 (O1) and deoP2 (O2) transcription located 599 bp apart, whereas the third site (OE) is present approximately 270 bp upstream of P1. DeoR repression of both P1 and P2 transcription is weak on promoter fragments which only contain one operator site (O1 or O2). Enhanced repression by deoR is observed on promoter fragments containing two operator sites. However, all three sites are needed for full repression. These findings are discussed with respect to upstream and downstream control regions of eukaryotic genes.

Nucleotide sequence of the CytR regulatory gene of E. coli K-12

We have determined the nucleotide sequence of the cytR gene, which codes for the Cyt repressor (CytR). The coding region consists of 1023 or 1029 bp. The subunits of CytR are thus predicted to consist of 341 or 343 residues. It is shown that the N-terminal segment of the polypeptide is structurally similar to the DNA-binding region of known DNA-binding proteins. In addition, there exists an exceptionally high amino acid sequence homology between CytR and the Gal repressor, indicating a common origin of evolution.

The primary structure of the DeoR repressor from Escherichia coli K-12

The nucleotide sequence of the deoR gene of E. coli, which codes for the DeoR repressor, has been determined. This gene codes for a polypeptide that is 252 amino acids residues in length. Computer-assisted analysis of the nucleotide sequence strongly suggests that the DNA binding domain of the DeoR repressor is located in the N-terminal part of the protein. After the coding region there is a dyad symmetry similar to a palindromic unit present outside many structural genes on the E. coli chromosome.

The internal regulated promoter of the deo operon of Escherichia coli K-12

Previous studies of the structure and regulation of the deo operon in Escherichia coli have localized an internal regulated promoter, called deoP3, in front of the two distal genes in the operon. We report here the nucleotide sequence of the distal portion of the deoA, the deoA-deoB intercistronic region and the first part of the deoB gene, and show that deoP3 overlaps the distal segment of the deoA gene. The location of the internal promoter and the transcriptional start site were determined by means of 1) sequence homology to the consensus promoter sequence of E. coli, 2) high resolution S1 nuclease mapping of in vivo transcripts and 3) in vivo regulation of beta-galactosidase from low as well as high copy number P31acZ protein fusion vectors.

Structure and function of the intercistronic regulatory deoC-deoA element of Escherichia coli K-12

The deoC-deoA intercistronic region from Escherichia coli has been characterized by DNA and protein sequencing. This region consists of 129 bp and includes a regulatory element, which has also been found in other operons containing large intercistronic regions. Our results suggest that the regulatory element functions as a transcriptional attenuator, and therefore it seems likely that the primary role of this element is to effect differential expression of operon genes. Furthermore, we have unambiguously shown that the initiation codon for the deoA gene is UUG.

Nucleotide sequence of the Escherichia coli pyrE gene and of the DNA in front of the protein-coding region

Orotate phosphoribosyltransferase (EC 2.4.2.10) was purified to electrophoretic homogeneity from a strain of Escherichia coli containing the pyrE gene cloned on a multicopy plasmid. The relative molecular masses (Mr) of the native enzyme and its subunit were estimated by means of gel filtration and electrophoresis in the presence of dodecyl sulfate. The amino acid sequences at the N and C termini, as well as the amino acid composition, were determined. The nucleotide sequence of the structural pyrE gene, including 394 nucleotide residues preceding the beginning of the coding frame, was also established. From the results the following conclusions may be drawn. Orotate phosphoribosyltransferase is a dimeric protein with subunits of Mr 23 326 consisting of 211 amino acid residues. The pyrE gene is transcribed in a counter-clock wise direction from the E. coli chromosome as an mRNA with a considerable leader segment in front of the protein-coding region. This leader contains a structure with features characteristic for a (translated?) rho-independent transcriptional terminator, which is preceded by a cluster of uridylate residues. This indicates that the frequency of pyrE transcription is regulated by an RNA polymerase (UTP) modulated attenuation.

Tandem CRP binding sites in the deo operon of Escherichia coli K-12

The locations of DNA binding by the cyclic AMP receptor protein (CRP) in the deo operon of Escherichia coli have been determined by the DNase I footprinting procedure. Two high affinity sites were found around positions -35 and -90, preceding the second deo promoter. In vitro data on induction of gene fusions that join different parts of the deoP -2 regulatory region to the lac genes suggest that: (1) both CRP binding sites are needed for high expression from the deoP -2 region; and (2) negative regulation by the cytR repressor is accomplished by preventing the cAMP-CRP complex from binding to the second target.

The primary structure of Escherichia coli K12 2-deoxyribose 5-phosphate aldolase. Nucleotide sequence of the deoC gene and the amino acid sequence of the enzyme

The sequence of the deoC gene of Escherichia coli K12 and the amino acid sequence of the corresponding protein, deoxyriboaldolase, has been established. The protein consists of 259 amino acids with a molecular weight of 27 737. The purified enzyme may exist both as a monomer and as a dimer. On the basis of amino acid composition, molecular weight and catalytic properties, the enzymes from E. coli and Salmonella typhimurium seem to be almost similar. They belong to the class I aldolases, which form Schiff base intermediates. Using data for the S. typhimurium enzyme, the lysine residue involved in the active site in the E. coli enzyme was tentatively identified.

The structure of tandem regulatory regions in the deo operon of Escherichia coli K12

The transcription initiation sites of the deo operon of Escherichia coli K12 have been determined in vitro and in vivo. Initiation of transcription occurs at two, tandemly arranged, homologous regions which are located 600 base pairs apart from each other. Evidence for a novel regulation mechanism of deo gene expression involving the deoR repressor is presented.

Regulation of the deo operon in Escherichia coli: the double negative control of the deo operon by the cytR and deoR repressors in a DNA directed in vitro system

The synthesis of the four enzymes of the deo operon in Escherichia coli is known from in vivo experiments to be subject to a double negative control, exerted by the products of the cytR and deoR genes. A DNA-directed in vitro protein synthesizing system makes the deo enzymes (exemplified by thymidine phosphorylase) in agreement with in vivo results. Enzyme synthesis is stimulated by cyclic AMP and repressed by the cytR and deoR gene products. Repression by the cytR repressor is reversed by cytidine or adenosine in the presence of cyclic AMP, while repression by the deoR repressor is reversed by deoxyribose-5-phosphate. Assays for the presence of the cytR and deoR repressors were established by use of S-30 extracts prepared from the regulatory mutants. Dissociation constants for repressor-operator binding as well as for repressor-inducer interactions have been estimated from the results.