Long-range cooperativity between gene regulatory sequences in a prokaryote

The loopometer: a quantitative in vivo assay for DNA-looping proteins

Proteins that can bring together separate DNA sites, either on the same or on different DNA molecules, are critical for a variety of DNA-based processes. However, there are no general and technically simple assays to detect proteins capable of DNA looping in vivo nor to quantitate their in vivo looping efficiency. Here, we develop a quantitative in vivo assay for DNA-looping proteins in Escherichia coli that requires only basic DNA cloning techniques and a LacZ assay. The assay is based on loop assistance, where two binding sites for the candidate looping protein are inserted internally to a pair of operators for the E. coli LacI repressor. DNA looping between the sites shortens the effective distance between the lac operators, increasing LacI looping and strengthening its repression of a lacZ reporter gene. Analysis based on a general model for loop assistance enables quantitation of the strength of looping conferred by the protein and its binding sites. We use this ‘loopometer’ assay to measure DNA looping for a variety of bacterial and phage proteins.

A Small Regulatory RNA Contributes to the Preferential Colonization of Escherichia coli O157:H7 in the Large Intestine in Response to a Low DNA Concentration

Enterohemorrhagic Escherichia coli (EHEC) serotype O157:H7 (O157) is one of the most notorious human pathogens, causing severe disease in humans worldwide. O157 specifically colonizes the large intestine of mammals after passing through the small intestine, and this process is influenced by differential signals between the two regions. Small regulatory RNAs (sRNAs) are able to sense and respond to environmental changes and regulate diverse physiological processes in pathogenic bacteria. Although some sRNAs of O157 have been extensively investigated, whether these molecules can sense differences between the small and large intestine and influence the preferential colonization in the large intestine by O157 remains unknown. In this study, we identified a new sRNA, Esr055, in O157 which senses the low DNA concentration in the large intestine and contributes to the preferential colonization of the bacteria in this region. The number of O157 wild-type that adhered to the colon is 30.18 times higher than the number that adhered to the ileum of mice, while the number of the ΔEsr055 mutant that adhered to the colon decreased to 13.27 times higher than the number adhered to the ileum. Furthermore, we found that the expression of Esr055 is directly activated by the regulator, DeoR, and its expression is positively affected by DNA, which is significantly more abundant in the ileum than in the colon of mice. Additionally, combining the results of informatics predictions and transcriptomic analysis, we found that several virulence genes are up-regulated in the ΔEsr055 mutant and five candidate genes (z0568, z0974, z1356, z1926, and z5187) may be its direct targets.

Transcription Factor Binding Site Mapping Using ChIP-Seq

Transcription factors (TFs) play a central role in regulating gene expression in all bacteria. Yet until recently, studies of TF binding were limited to a small number of factors at a few genomic locations. Chromatin immunoprecipitation followed by sequencing (ChIP-Seq) provides the ability to map binding sites globally for TFs, and the scalability of the technology enables the ability to map binding sites for every DNA binding protein in a prokaryotic organism. We have developed a protocol for ChIP-Seq tailored for use with mycobacteria and an analysis pipeline for processing the resulting data. The protocol and pipeline have been used to map over 100 TFs from Mycobacterium tuberculosis, as well as numerous TFs from related mycobacteria and other bacteria. The resulting data provide evidence that the long-accepted spatial relationship between TF binding site, promoter motif, and the corresponding regulated gene may be too simple a paradigm, failing to adequately capture the variety of TF binding sites found in prokaryotes. In this article we describe the protocol and analysis pipeline, the validation of these methods, and the results of applying these methods to M. tuberculosis.

From adjacent activation in Escherichia coli and DNA cyclization to eukaryotic enhancers: the elements of a puzzle

Deoxyribonucleic acid cyclization, Escherichia coli lac repressor binding to two spaced lac operators and repression enhancement can be successfully used for a better understanding of the conditions required for interaction between eukaryotic enhancers and the machinery of transcription initiation. Chronologically, the DNA looping model has first accounted for the properties initially defining enhancers, i.e., independence of action with distance or orientation with respect to the start of transcription. It has also predicted enhancer activity or its disruption at short distance (site orientation, alignment between promoter and enhancer sites), with high-order complexes of protein, or with transcription factor concentrations close or different from the wild-type situation. In another step, histones have been introduced into the model to further adapt it to eukaryotes. They in fact favor DNA cyclization in vitro. The resulting DNA compaction might explain the difference counted in base pairs in the distance of action between eukaryotic transcription enhancers and prokaryotic repression enhancers. The lac looping system provides a potential tool for analysis of this discrepancy and of chromatin state directly in situ. Furthermore, as predicted by the model, the contribution of operators O2 and O3 to repression of the lac operon clearly depends on the lac repressor level in the cell and is prevented in strains overproducing lac repressor. By extension, gene regulation especially that linked to cell fate, should also depend on transcription factor levels, providing a potential tool for cellular therapy. In parallel, a new function of the O1–O3 loop completes the picture of lac repression. The O1–O3 loop would at the same time ensure high efficiency of repression, inducibility through the low-affinity sites and limitation of the level of repressor through self-repression of the lac repressor. Last, the DNA looping model can be successfully adapted to the enhancer auxiliary elements known as insulators.

Transcription-factor-mediated DNA looping probed by high-resolution, single-molecule imaging in live E. coli cells

DNA looping mediated by transcription factors plays critical roles in prokaryotic gene regulation. The "genetic switch" of bacteriophage λ determines whether a prophage stays incorporated in the E. coli chromosome or enters the lytic cycle of phage propagation and cell lysis. Past studies have shown that long-range DNA interactions between the operator sequences O(R) and O(L) (separated by 2.3 kb), mediated by the λ repressor CI (accession number P03034), play key roles in regulating the λ switch. In vitro, it was demonstrated that DNA segments harboring the operator sequences formed loops in the presence of CI, but CI-mediated DNA looping has not been directly visualized in vivo, hindering a deep understanding of the corresponding dynamics in realistic cellular environments. We report a high-resolution, single-molecule imaging method to probe CI-mediated DNA looping in live E. coli cells. We labeled two DNA loci with differently colored fluorescent fusion proteins and tracked their separations in real time with ∼40 nm accuracy, enabling the first direct analysis of transcription-factor-mediated DNA looping in live cells. Combining looping measurements with measurements of CI expression levels in different operator mutants, we show quantitatively that DNA looping activates transcription and enhances repression. Further, we estimated the upper bound of the rate of conformational change from the unlooped to the looped state, and discuss how chromosome compaction may impact looping kinetics. Our results provide insights into transcription-factor-mediated DNA looping in a variety of operator and CI mutant backgrounds in vivo, and our methodology can be applied to a broad range of questions regarding chromosome conformations in prokaryotes and higher organisms.

Genome conformation capture reveals that the Escherichia coli chromosome is organized by replication and transcription

To fit within the confines of the cell, bacterial chromosomes are highly condensed into a structure called the nucleoid. Despite the high degree of compaction in the nucleoid, the genome remains accessible to essential biological processes, such as replication and transcription. Here, we present the first high-resolution chromosome conformation capture-based molecular analysis of the spatial organization of the Escherichia coli nucleoid during rapid growth in rich medium and following an induced amino acid starvation that promotes the stringent response. Our analyses identify the presence of origin and terminus domains in exponentially growing cells. Moreover, we observe an increased number of interactions within the origin domain and significant clustering of SeqA-binding sequences, suggesting a role for SeqA in clustering of newly replicated chromosomes. By contrast, ‘histone-like’ protein (i.e. Fis, IHF and H-NS) -binding sites did not cluster, and their role in global nucleoid organization does not manifest through the mediation of chromosomal contacts. Finally, genes that were downregulated after induction of the stringent response were spatially clustered, indicating that transcription in E. coli occurs at transcription foci.

DNA looping in prokaryotes: experimental and theoretical approaches

Transcriptional regulation is at the heart of biological functions such as adaptation to a changing environment or to new carbon sources. One of the mechanisms which has been found to modulate transcription, either positively (activation) or negatively (repression), involves the formation of DNA loops. A DNA loop occurs when a protein or a complex of proteins simultaneously binds to two different sites on DNA with looping out of the intervening DNA. This simple mechanism is central to the regulation of several operons in the genome of the bacterium Escherichia coli, like the lac operon, one of the paradigms of genetic regulation. The aim of this review is to gather and discuss concepts and ideas from experimental biology and theoretical physics concerning DNA looping in genetic regulation. We first describe experimental techniques designed to show the formation of a DNA loop. We then present the benefits that can or could be derived from a mechanism involving DNA looping. Some of these are already experimentally proven, but others are theoretical predictions and merit experimental investigation. Then, we try to identify other genetic systems that could be regulated by a DNA looping mechanism in the genome of Escherichia coli. We found many operons that, according to our set of criteria, have a good chance to be regulated with a DNA loop. Finally, we discuss the proposition recently made by both biologists and physicists that this mechanism could also act at the genomic scale and play a crucial role in the spatial organization of genomes.

ChIP-Seq and the complexity of bacterial transcriptional regulation

Transcription factors (TFs) play a central role in regulating gene expression in all bacteria. Yet, until recently, studies of TF binding were limited to a small number of factors at a few genomic locations. Chromatin immunoprecipitation followed by sequencing enables mapping of binding sites for TFs in a global and high-throughput fashion. The NIAID funded TB systems biology project http://www.broadinstitute.org/annotation/tbsysbio/home.html aims to map the binding sites for every transcription factor in the genome of Mycobacterium tuberculosis (MTB), the causative agent of human TB. ChIP-Seq data already released through TBDB.org have provided new insight into the mechanisms of TB pathogenesis. But in addition, data from MTB are beginning to challenge many simplifying assumptions associated with gene regulation in all bacteria. In this chapter, we review the global aspects of TF binding in MTB and discuss the implications of these data for our understanding of bacterial gene regulation. We begin by reviewing the canonical model of bacterial transcriptional regulation using the lac operon as the standard paradigm. We then review the use of ChIP-Seq to map the binding sites of DNA-binding proteins and the application of this method to mapping TF binding sites in MTB. Finally, we discuss two aspects of the binding discovered by ChIP-Seq that were unexpected given the canonical model: the substantial binding outside the proximal promoter region and the large number of weak binding sites.

An enhancer-like element present in the promoter of a T-DNA gene from the Ti plasmid of Agrobacterium tumefaciens

The promoter of the 780 gene of T-right [Thomashow, M., Nutter, R., Montoya, A., Gordon, M. & Nester, E. (1980) Cell 19, 729-739] from Agrobacterium tumefaciens Ti plasmid (pTi15955) was shown to contain an upstream cis-acting element (activator) having enhancer-like properties. To characterize the properties of this promoter element, it was placed in both polarities, upstream and downstream of a Delta-37 deletion mutant of the 780 gene. The Delta-37 deletion contains the entire 780 gene with the 5' flanking sequences deleted upstream of TATA to -37. The effect of the activator on in vivo transcriptional activity was assessed by S1 nuclease mapping utilizing a homologous reference gene as an internal standard. Transcript levels from sunflower crown gall tumors were between 127% and 90% of the wild-type 780 gene depending on the polarity of the activator element when placed directly upstream to the 780 gene Delta-37 promoter. Repositioning the activator element 613 base pairs further upstream increased transcription by 2-fold regardless of polarity. However, the activator element did not promote transcription when placed in either polarity approximately 200 base pairs downstream of the poly(A) addition site. Upstream promoter fragments (TATA-distal) from the octopine synthase (ocs) and agropine synthase (ags) genes were also tested for activation of the Delta-37 construction. The ocs sequences activated transcription of the Delta-37 deletion to 14% of wild-type levels when placed upstream in the B (reverse) orientation. All other constructions with the ocs and ags sequences showed no enhancement of promoter activity.

The DeoR-type transcriptional regulator SugR acts as a repressor for genes encoding the phosphoenolpyruvate:sugar phosphotransferase system (PTS) in Corynebacterium glutamicum

BACKGROUND

The major uptake system responsible for the transport of fructose, glucose, and sucrose in Corynebacterium glutamicum ATCC 13032 is the phosphoenolpyruvate:sugar phosphotransferase system (PTS). The genes encoding PTS components, namely ptsI, ptsH, and ptsF belong to the fructose-PTS gene cluster, whereas ptsG and ptsS are located in two separate regions of the C. glutamicum genome. Due to the localization within and adjacent to the fructose-PTS gene cluster, two genes coding for DeoR-type transcriptional regulators, cg2118 and sugR, are putative candidates involved in the transcriptional regulation of the fructose-PTS cluster genes.

RESULTS

Four transcripts of the extended fructose-PTS gene cluster that comprise the genes sugR-cg2116, ptsI, cg2118-fruK-ptsF, and ptsH, respectively, were characterized. In addition, it was shown that transcription of the fructose-PTS gene cluster is enhanced during growth on glucose or fructose when compared to acetate. Subsequently, the two genes sugR and cg2118 encoding for DeoR-type regulators were mutated and PTS gene transcription was found to be strongly enhanced in the presence of acetate only in the sugR deletion mutant. The SugR regulon was further characterized by microarray hybridizations using the sugR mutant and its parental strain, revealing that also the PTS genes ptsG and ptsS belong to this regulon. Binding of purified SugR repressor protein to a 21 bp sequence identified the SugR binding site as an AC-rich motif. The two experimentally identified SugR binding sites in the fructose-PTS gene cluster are located within or downstream of the mapped promoters, typical for transcriptional repressors. Effector studies using electrophoretic mobility shift assays (EMSA) revealed the fructose PTS-specific metabolite fructose-1-phosphate (F-1-P) as a highly efficient, negative effector of the SugR repressor, acting in the micromolar range. Beside F-1-P, other sugar-phosphates like fructose-1,6-bisphosphate (F-1,6-P) and glucose-6-phosphate (G-6-P) also negatively affect SugR-binding, but in millimolar concentrations.

CONCLUSION

In C. glutamicum ATCC 13032 the DeoR-type regulator SugR acts as a pleiotropic transcriptional repressor of all described PTS genes. Thus, in contrast to most DeoR-type repressors described, SugR is able to act also on the transcription of the distantly located genes ptsG and ptsS of C. glutamicum. Transcriptional repression of the fructose-PTS gene cluster is observed during growth on acetate and transcription is derepressed in the presence of the PTS sugars glucose and fructose. This derepression of the fructose-PTS gene cluster is mainly modulated by the negative effector F-1-P, but reduced sensitivity to the other effectors, F-1,6-P or G-6-P might cause differential transcriptional regulation of genes of the general part of the PTS (ptsI, ptsH) and associated genes encoding sugar-specific functions (ptsF, ptsG, ptsS).

Weak Interaction Induces an ON/OFF Switch, whereas Strong Interaction Causes Gradual Change: Folding Transition of a Long Duplex DNA Chain by Poly-l-lysine

A large-scale conformational change in genomic DNA is an essential feature of gene activation in living cells. Considerable effort has been applied to explain the mechanism in terms of key-lock interaction between sequence-specific regulatory proteins and DNA, in addition to the modification of DNA and histones such as methylation and acetylation. However, it is still unclear whether these mechanisms can explain the ON/OFF switching of a large number of genes that accompanies differentiation, carcinogenesis, etc. In this study, using single-molecule observation of DNA molecules by fluorescence microscopy with the addition of poly-L-lysine with different numbers of monomer units (n = 3, 5, 9, and 92), we found that an ON/OFF discrete transition in the higher-order structure of long duplex DNA is induced by short poly-L-lysine, whereas a continuous gradual change is induced by long poly-L-lysine. On the other hand, polycations with a lower positive charge have less potential to induce DNA compaction. Such a drastic difference in the conformational transition of a giant DNA between short and large oligomers is discussed in relation to the mechanisms of gene regulation in a living cell.

Gene regulation at-a-distance in E. coli: new insights

The number of E. coli genes/operons regulated from sites distant from the gene, though limited, steadily increases. The regulation of the ula genes, in charge of L-ascorbate utilization, as well as the negative autoregulation of the non-related lambdaCI and 186CI repressors, for efficient switching of the corresponding phages from lysogeny to lysis, are recent examples. The interaction between the two GalR dimers, separated by 114 bp, undetectable in vitro, has been genetically mapped. lac repressor-operator loops might insulate a gene and its expression from the genomic environment. The genes in charge of nitrogen assimilation sequentially react to ammonia deprivation, via an increasing intracellular NRI concentration. Other sigma54-dependent genes are activated in response to various stimuli.

Cooperativity in long-range gene regulation by the lambda CI repressor

Effective repression of cI transcription from PRM by the bacteriophage lambda CI repressor requires binding sites (OL) located 2.4 kb from the promoter. A CI tetramer bound to OL1.OL2 interacts with a tetramer bound near PRM (OR1.OR2), looping the intervening DNA. We previously proposed that in this CI octamer:DNA complex, the distant OL3 operator and the weak OR3 operator overlapping PRM are juxtaposed so that a CI dimer at OL3 can cooperate with a CI dimer binding to OR3. Here we show that OL3 is necessary for effective repression of PRM and that the repressor at OL3 appears to interact specifically with the repressor at OR3. The OL3-CI-OR3 interaction involves the same CI interface used for short-range dimer-dimer interactions and does not occur without the other four operators. The long-range interactions were incorporated into a physicochemical model, allowing estimation of the long-range interaction energies and showing the lysogenic state to be ideally poised for CI negative autoregulation. The results establish the lambda system as a powerful tool for examining long-range gene regulatory interactions in vivo.

Regulation of expression of the 2-deoxy-D-ribose utilization regulon, deoQKPX, from Salmonella enterica serovar typhimurium

Salmonella enterica, in contrast to Escherichia coli K12, can use 2-deoxy-D-ribose as the sole carbon source. The genetic determinants for this capacity in S. enterica serovar Typhimurium include four genes, of which three, deoK, deoP, and deoX, constitute an operon. The fourth, deoQ, is transcribed in the opposite direction. The deoK gene encodes deoxyribokinase. In silico analyses indicated that deoP encodes a permease and deoQ encodes a regulatory protein of the deoR family. The deoX gene product showed no match to known proteins in the databases. Deletion analyses showed that both a functional deoP gene and a functional deoX gene were required for optimal utilization of deoxyribose. Using gene fusion technology, we observed that deoQ and the deoKPX operon were transcribed from divergent promoters located in the 324-bp intercistronic region between deoQ and deoK. The deoKPX promoter was 10-fold stronger than the deoQ promoter, and expression was negatively regulated by DeoQ as well as by DeoR, the repressor of the deoxynucleoside catabolism operon. Transcription of deoKPX but not of deoQ was regulated by catabolite repression. Primer extension analysis identified the transcriptional start points of both promoters and showed that induction by deoxyribose occurred at the level of transcription initiation. Gel retardation experiments with purified DeoQ illustrated that it binds independently to tandem operator sites within the deoQ and deoK promoter regions with K(d) values of 54 and 2.4 nM, respectively.

Distant cis-active sequences and sialic acid control the expression of fimB in Escherichia coli K-12

The phase variation of type 1 fimbriation in Escherichia coli is controlled by the inversion of a 314 bp element of DNA, determined by FimB (switching in both directions) or FimE (switching from the ON-to-OFF orientation predominantly), and influenced by auxiliary factors IHF, Lrp and H-NS. The fimB gene is separated from the divergently transcribed yjhATS operon by a large (1.4 kbp) intergenic region of unknown function. Here, we show that fimB expression is regulated by multiple cis-active sequences that lie far upstream (>600 bp) of the transcription start sites for the recombinase gene. Two regions characterized further (regions 1 and 2) show sequence identity, and each coincides with a methylation-protected Dam (5'-GATC) site. Regions 1 and 2 apparently control fimB expression by an antirepression mechanism that involves additional sequences proximal to yjhA. Region 1 encompasses a 27 bp DNA sequence conserved upstream of genes known (nanAT ) or suspected (yjhBC) to be involved in sialic acid metabolism, and we show that FimB expression and recombination are suppressed by N-acetylneuraminic acid. We propose that E. coli recognizes the amino sugars as a harbinger of potential host defence activation, and suppresses the expression of type 1 fimbriae in response.

Identification of operator sites of the CI repressor of phage TP901-1: evolutionary link to other phages

The repressor encoded by the cI gene of the temperate Lactococcus lactis subsp. cremoris bacteriophage TP901-1 has been purified. Gel-retardation and footprinting analyses identified three palindromic operator sites (O(R), O(L), and O(D)). The operator site O(R) is located between the two divergent early promoters P(R) and P(L), O(L) overlaps the transcriptional start of the lytic P(L) promoter, and O(D) is located downstream of the mor gene, the first gene in the lytic gene cluster. The function of O(L) was verified by mutational analysis. Binding was found to be specific and cooperative. Multimeric forms of the repressor were observed, thus indicating that the repressor may bind simultaneously to all three operator sites. Inverted repeats with homology to the operator sites of TP901-1 were identified in phage genomes encoding repressors homologous to CI of TP901-1. Interestingly, the locations of these repeats on the phage genomes correspond to those found in TP901-1, indicating that the same system of cooperative repression of early phage promoters has been inherited by modular evolution.

DNA binding sites for the Mlc and NagC proteins: regulation of nagE, encoding the N-acetylglucosamine-specific transporter in Escherichia coli

The NagC and Mlc proteins are homologous transcriptional regulators that control the expression of several phosphotransferase system (PTS) genes in Escherichia coli. NagC represses nagE, encoding the N:-acetylglucosamine-specific transporter, while Mlc represses three PTS operons, ptsG, manXYZ and ptsHIcrr, involved in the uptake of glucose. NagC and Mlc can bind to each others operator, at least in vitro. A binding site selection procedure was used to try to distinguish NagC and Mlc sites. The major difference was that all selected NagC binding sites had a G or a C at positions +11/-11 from the centre of symmetry. This is also the case for most native NagC sites, but not the nagE operator, which thus looks like a potential Mlc target. The nagE operator does exhibit a higher affinity for Mlc than NagC, but no regulation of nagE by physiological concentrations of Mlc was detected in vivo. Regulation of wild-type nagE by NagC is achieved because of the chelation effect due to a second high affinity NagC operator covering the nagB promoter. Replacing the A/T at +11/-11 with C/G allows repression by NagC in the absence of the nagB operator.

Purification and characterization of the DeoR repressor of Bacillus subtilis

Transcription of the Bacillus subtilis dra-nupC-pdp operon is repressed by the DeoR repressor protein. The DeoR repressor with an N-terminal His tag was overproduced with a plasmid under control of a phage T5 promoter in Escherichia coli and was purified to near homogeneity by one affinity chromatography step. Gel filtration experimental results showed that native DeoR has a mass of 280 kDa and appears to exist as an octamer. Binding of DeoR to the operator DNA of the dra-nupC-pdp operon was characterized by using an electrophoretic gel mobility shift assay. An apparent dissociation constant of 22 nM was determined for binding of DeoR to operator DNA, and the binding curve indicated that the binding of DeoR to the operator DNA was cooperative. In the presence of low-molecular-weight effector deoxyribose-5-phosphate, the dissociation constant was higher than 1,280 nM. The dissociation constant remained unchanged in the presence of deoxyribose-1-phosphate. DNase I footprinting exhibited a protected region that extends over more than 43 bp, covering a palindrome together with a direct repeat to one half of the palindrome and the nucleotides between them.

Identification and characterization of a DeoR-specific operator sequence essential for induction of dra-nupC-pdp operon expression in Bacillus subtilis

The deoR gene located just upstream the dra-nupC-pdp operon of Bacillus subtilis encodes the DeoR repressor protein that negatively regulates the expression of the operon at the level of transcription. The control region upstream of the operon was mapped by the use of transcriptional lacZ fusions. It was shown that all of the cis-acting elements, which were necessary for full DeoR regulation of the operon, were included in a 141-bp sequence just upstream of dra. The increased copy number of this control region resulted in titration of the DeoR molecules of the cell. By using mutagenic PCR and site-directed mutagenesis techniques, a palindromic sequence located from position -60 to position -43 relative to the transcription start point was identified as a part of the operator site for the binding of DeoR. Furthermore, it was shown that a direct repeat of five nucleotides, which was identical to the 3' half of the palindrome and was located between the -10 and -35 regions of the dra promoter, might function as a half binding site involved in cooperative binding of DeoR to the regulatory region. Binding of DeoR protein to the operator DNA was confirmed by a gel electrophoresis mobility shift assay. Moreover, deoxyribose-5-phosphate was shown to be a likely candidate for the true inducer of the dra-nupC-pdp expression.

Four dimers of lambda repressor bound to two suitably spaced pairs of lambda operators form octamers and DNA loops over large distances

Transcription factors that are bound specifically to DNA often interact with each other over thousands of base pairs [1] [2]. Large DNA loops resulting from such interactions have been observed in Escherichia coli with the transcription factors deoR [3] and NtrC [4], but such interactions are not, as yet, well understood. We propose that unique protein complexes, that are not present in solution, may form specifically on DNA. Their uniqueness would make it possible for them to interact tightly and specifically with each other. We used the repressor and operators of coliphage lambda to construct a model system in which to test our proposition. lambda repressor is a dimer at physiological concentrations, but forms tetramers and octamers at a hundredfold higher concentration. We predict that two lambda repressor dimers form a tetramer in vitro when bound to two lambda operators spaced 24 bp apart and that two such tetramers interact to form an octamer. We examined, in vitro, relaxed circular plasmid DNA in which such operator pairs were separated by 2,850 bp and 2,470 bp. Of these molecules, 29% formed loops as seen by electron microscopy (EM). The loop increased the tightness of binding of lambda repressor to lambda operator. Consequently, repression of the lambda PR promoter in vivo was increased fourfold by the presence of a second pair of lambda operators, separated by a distance of 3,600 bp.

Oligomeric properties and DNA binding specificities of repressor isoforms from the Streptomyces bacteriophage phiC31

Three protein isoforms (74, 54 and 42 kDa) are expressed from repressor gene c in the Streptomyces temperate bacteriophage phiC31. Because expression of the two smaller isoforms, 54 and 42 kDa, is sufficient for superinfection immunity, the interaction between these isoforms was studied. The native 42 kDa repressor (Nat42) and an N-terminally 6x histidine-tagged 54 kDa isoform (His54) were shown by co-purification on a Ni-NTA column to interact in Streptomyces lividans . In vitro three repressor preparations, containing Nat42, His54 and the native 54 and 42 kDa isoforms expressed together (Nat54&42), were subjected to chemical crosslinking and gel filtration analysis. Homo- and hetero-tetramers were observed. Previous work showed that the smallest isoform bound to 17 bp operators containing aconservedinvertedrepeat (CIR) and that the CIRs were located at 16 loci throughout the phiC31 genome. One of the CIRs (CIR6) is believed to be critical for regulating the lytic pathway. The DNA binding activities of the three repressor preparations were studied using fragments containing CIRs (CIR3-CIR6) from the essential early region as templates for DNase I footprinting. Whereas Nat42 bound to CIR6, poorly to CIR5 but undetectably to CIR3 or CIR4, the Nat54&42 preparation could bind to all CIRs tested, albeit poorly to CIR3 and CIR4. The His54 isoform bound all CIRs tested. Isoforms expressed from the phiC31 repressor gene, like those which are expressed from many eukaryotic transcription factor genes, apparently have different binding specificities.

DNA bending and expression of the divergent nagE-B operons

Repression of the divergent nagE - B operons requires NagC binding to two operators which overlap the nagE and nagB promoters, resulting in formation of a DNA loop. Binding of the cAMP/CAP activator to its site, adjacent to the nagE operator, stabilizes the DNA loop in vitro. The DNA of the nagE-B intergenic region is intrinsically bent, with the bend centred on the CAP site. We show that displacement of the CAP site by 6 bp results in complete derepression of the two operons. This derepression is observed even in the absence of cAMP/CAP binding and despite the fact that the two NagC operators are still in phase, demonstrating that the inherently bent structure of the DNA loop is important for repression. Since no interaction between NagC and CAP has been detected, we propose that the role of CAP in the repression loop is architectural, stabilizing the intrinsic bend. The cAMP/CAP complex is necessary for activation of the nagE-B promoters. In this case protein-protein contacts between CAP and RNA polymerase are necessary for full activation, but at least a part of the activation is likely due to an effect of CAP binding altering DNA structure.

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.

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.

Multiple specific CytR binding sites at the Escherichia coli deoP2 promoter mediate both cooperative and competitive interactions between CytR and cAMP receptor protein

Binding of cAMP receptor protein (CRP) and CytR mediates both positive and negative control of transcription from Escherichia coli deoP2. Transcription is activated by CRP and repressed by a multi-protein CRP.CytR.CRP complex. The latter is stabilized by cooperative interactions between CRP and CytR. Similar interactions at the other transcriptional units of the CytR regulon coordinate expression of the transport proteins and enzymes required for nucleoside catabolism. A fundamental question in both prokaryotic and eukaryotic gene regulation is how combinatorial mechanisms of this sort regulate differential expression. To understand the combinatorial control mechanism at deoP2, we have used quantitative footprint and gel shift analysis of CRP and CytR binding to evaluate the distribution of ligation states. By comparison to distributions for other CytR-regulated promoters, we hope to understand the roles of individual states in differential gene expression. The results indicate that CytR binds specifically to multiple sites at deoP2, including both the well recognized CytR site flanked by CRP1 and CRP2 and also sites coincident with CRP1 and CRP2. Binding to these multiple sites yields both cooperative and competitive interactions between CytR and CRP. Based on these findings we propose that CytR functions as a differential modulator of CRP1 versus CRP2-mediated activation. Additional high affinity specific sites are located at deoP1 and near the middle of the 600-base pair sequence separating P1 and P2. Evaluation of the DNA sequence requirement for specific CytR binding suggests that a limited array of contiguous and overlapping CytR sites exists at deoP2. Similar extended arrays, but with different arrangements of overlapping CytR and CRP sites, are found at the other CytR-regulated promoters. We propose that competition and cooperativity in CytR and CRP binding are important to differential regulation of these 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.

Twist, writhe, and geometry of a DNA loop containing equally spaced coplanar bends

The formation of a topologically closed DNA loop is important in many biological processes, including the regulation of transcription, recombination, and replication. Modeling DNA as an isotropic elastic rod, we use finite element analysis to show that the dependence of the twist (delta Tw) and the writhe (Wr) upon the linking number deficit (delta Lk) is strongly influenced by intrinsic bends. We determine how the geometry of a DNA loop changes as a function of the number of uniformly spaced coplanar 20 degrees bends, oriented so as to open toward the center of the loop. We also calculate the geometry of DNA rods that are smoothly bent to the same extent. The response of both delta Tw and Wr of a bent DNA to changes in delta Lk falls into one of three categories, depending upon the number of bends. For a single bend of 20 degrees, Wr increases monotonically with delta Lk and the change in delta Tw with distance is constant along the entire DNA axis. For two to ten 20 degrees bends, Wr passes first through a local maximum, then through a local minimum, and finally increases monotonically as delta Lk increases. For eleven to eighteen 20 degrees bends, Wr again varies monotonically with delta Lk. For all numbers of bends greater than two, the delta Tw per unit length depends upon the distribution of intrinsic bends, being constant between any two adjoining bends but varying with their position relative to the cut location. Accompanying these delta Lk-associated changes in Wr and delta Tw per unit length are characteristic changes in geometry that are specific for each category. The results of these calculations raise the possibility that intrinsic bends can serve as a control factor in the biological functions associated with loop formation in DNA.

Dra-nupC-pdp operon of Bacillus subtilis: nucleotide sequence, induction by deoxyribonucleosides, and transcriptional regulation by the deoR-encoded DeoR repressor protein

The genes encoding deoxyriboaldolase (dra), nucleoside uptake protein (nupC), and pyrimidine nucleoside sequences were determined. Sequence analysis showed that the genes were localized immediately downstream of the hut operon. Insertional gene disruption studies indicated that the three genes constitute an operon with the gene order dra-nupC-pdp. A promoter mapping immediately upstream of the dra gene was identified, and downstream of the pdp gene the nucleotide sequence indicated the existence of a factor-independent transcription terminator structure. In wild-type cells growing in succinate minimal medium, the pyrimidine nucleoside phosphorylase and deoxyriboaldolase levels were five- to eightfold higher in the presence of thymidine and fourfold higher in the presence of deoxyadenosine. By the use of lacZ fusions, the regulation was found to be at the level of transcription. The operon expression was subject to glucose repression. Upstream of the dra gene an open reading frame of 313 amino acids was identified. Inactivation of this gene led to an approximately 10-fold increase in the levels of deoxyriboaldolase and pyrimidine nucleoside phosphorylase, and no further induction was seen upon the addition of deoxyribonucleosides. The upstream gene most likely encodes the regulator for the dra-nupC-pdp operon and was designated deoR (stands for deoxyribonucleoside regulator).

Crystal structure of lac repressor core tetramer and its implications for DNA looping

The crystal structure of the tryptic core fragment of the lac repressor of Escherichia coli (LacR) complexed with the inducer isopropyl-beta-D-thiogalactoside was determined at 2.6 A resolution. The quaternary structure consists of two dyad-symmetric dimers that are nearly parallel to each other. This structure places all four DNA binding domains of intact LacR on the same side of the tetramer, and results in a deep, V-shaped cleft between the two dimers. Each monomer contributes a carboxyl-terminal helix to an antiparallel four-helix bundle that functions as a tetramerization domain. Some of the side chains whose mutation reduce DNA binding form clusters on a surface near the amino terminus. Placing the structure of the DNA binding domain complexed with operator previously determined by nuclear magnetic resonance onto this surface results in two operators being adjacent and nearly parallel to each other. Structural considerations suggest that the two dimers of LacR may flexibly alter their relative orientation in order to bind to the known varied spacings between two operators.

A new T7 RNA polymerase-driven expression system induced via thermoamplification of a recombinant plasmid carrying a T7 promoter-Escherichia coli lac operator

A new temperature-regulated T7 RNA polymerase-driven transcription system has been developed. This system is based on a hybrid regulatory region: the phage T7 late promoter (PT7) linked to the Escherichia coli lac operator (Olac) [Giordano et al., Gene 84 (1989) 209-219], which was located in an earlier obtained [Mashko et al., Gene 97 (1991) 259-266] temperature-controlled amplifiable plasmid, carrying cat under the control of PT7-Olac and, in addition, lambda major early promoter-operator regions and gene cIts857. Plasmids of the pT7-Olac-cat-tsr series were stably maintained at a low-copy-number when grown at low temperature (28 degrees C). In E. coli BL21(DE3), carrying the Plac-controllable T7 RNA polymerase-encoding gene, efficient repression of cat transcription was observed, that was provided by the LacI repressor and, probably, the thermolabile repressor CIts857. At low and moderate temperatures (28/37 degrees C), this 'cooperative' repression was so tight that cat expression was not observed in the cells carrying PT7-Olac on the plasmids, even after IPTG-inducible T7 RNA polymerase biosynthesis. As a result of the thermo-amplification of the recombinant plasmids and temperature-inactivation of CIts857, expression of the T7 RNA polymerase-encoding gene was derepressed due to the titration of LacI by the increasing copies of Olac which in turn, led to the highly efficient T7 RNA polymerase-driven accumulation of CAT in the cells.

On the role of the Escherichia coli integration host factor (IHF) in repression at a distance of the pyrimidine specific promoter P1 of the carAB operon

Binding of integration host factor to its target site, centered around nucleotide -305 upstream of the transcription startpoint, exerts antagonistic effects on the expression of P1, the upstream pyrimidine specific promoter of the E coli and S typhimurium carAB operons. IHF stimulates P1 promoter activity in minimal medium, but also increases the repressibility of this promoter by pyrimidines. We present evidence strongly suggesting that IHF exerts these effects by modulating the binding of another pyrimidine specific regulatory molecule, probably the product of gene carP. The carAB control region contains a GATC Dam methylation site, 106 bp upstream of the P1 transcription startpoint, which can be protected in vivo against methylation. This protection requires at least the regulatory carP gene product and a high pyrimidine nucleotide pool and, as shown here, the integration host factor. Whether CarP directly binds to this site or exerts its protective effect indirectly is not yet known. In the absence of IHF (himA) or in mutants affected in the IHF target site this protection is strongly impaired, suggesting that IHF positively influences the formation or the stability of the protective protein-DNA complex some 200 bp downstream. Furthermore, we have demonstrated that the distance separating the IHF and GATC Dam methylase target sites is crucial for the in vivo protection and for pyrimidine mediated regulation of P1 promoter expression. Indeed, shortening this distance by 6 bp, and more surprisingly also by 11 bp, results in a severe reduction of the degree of in vivo protection of the GATC site against methylation and concomitantly of the repressibility by pyrimidines of P1 promoter activity. The absence of both these effects in a double, deletion-duplication, mutant resulting in a net increase of the intervening sequence by 1 bp, clearly demonstrates that these effects are not due to the disruption of an important regulatory site, but must be attributed to variations in the distance separating different protein binding sites.

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.

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.

DNA specificity of Escherichia coli deoP1 operator-DeoR repressor recognition

We have studied the importance of the specific DNA sequence of the deo operator site for DeoR repressor binding by introducing symmetrical, single basepair substitutions at all positions in the deo operator and tested the ability of these variants to titrate DeoR in vivo. Our results show that a 16 bp palindromic sequence constitutes the deo operator. Positions outside this palindrome (positions +/- 9, +/- 10) can be changed without any major effect on DeoR binding. Most of the central 6-8 bp of the palindrome (positions +/- 1, +/- 2, +/- 3) can be substituted with other nucleotides with no or only minor effects on DeoR binding, while changes at position +/- 4 and +/- 5 give a more heterogeneous response. Finally, changes at positions +/- 6, +/- 7 and +/- 8 severely disrupt DeoR binding.

The use of lac-type promoters in control analysis

For control analysis, it is necessary to modulate the activity of an enzyme around its normal level and measure the changes in steady-state fluxes or concentrations. We describe an improved method for effecting the modulation, as elaborated for Escherichia coli. The chromosomal gene, encoding the enzyme of interest, is put under the control of a lacUV5 or a tacI promoter. The alternative use of the two promoters leads to an expression range which should make it suitable for the use in control analysis of many enzymes. The lacUV5 promoter should be used when the wild-type expression level is low, the tacI promoter when the latter is high. The endogenous lac operon is placed under the control of a second copy of the lacUV5 promoter and a lacY7am mutation (eliminating lactose permease, the transport system for the inducer isopropyl-thio-beta-D- galactoside) is introduced. The method was demonstrated experimentally by constructing E. coli strains, in which the chromosomal atp operon is transcribed from the lacUV5 and the tacI promoter. We measured the concentration of the c subunit of H(+)-ATPase, and found that the expression of this enzyme could be modulated between non-detectable levels and up to five times the wild-type level. Thus, in the absence of inducer, no expression of atp genes could be detected when the atp operon was controlled by the lacUV5 promoter, and we estimate that the expression was less than 0.0025 times the wild-type level. We show that the introduction of a lacY mutation facilitated the attainment of steady induction levels of partially induced cells. The mutation also reduced positive cooperativity in the dependence of expression on the concentration of isopropyl-thio-beta-D-galactoside (the inducer) and shifted the concentration of inducer needed for half maximum induction to higher values. These properties should facilitate the experimental modulation of the enzyme activity by varying the concentration of the inducer.

DeoR repression at-a-distance only weakly responds to changes in interoperator separation and DNA topology

The interoperator distance between a synthetic operator Os and the deoP2O2-galK fusion was varied between 46 and 176 bp. The repression of the deoP2 directed galK expression as a function of the interoperator distance (center-to-center) was measured in vivo in a single-copy system. The results show that the DeoR repressor efficiently can repress transcription at all the interoperator distances tested. The degree of repression depends very little on the spacing between the operators, however, a weak periodic dependency of 8-11 bp may exist.

DNA looping

DNA-looping mechanisms are part of networks that regulate all aspects of DNA metabolism, including transcription, replication, and recombination. DNA looping is involved in regulation of transcriptional initiation in prokaryotic operons, including ara, gal, lac, and deo, and in phage systems. Similarly, in eukaryotic organisms, the effects of enhancers appear to be mediated at least in part by loop formation, and examples of DNA looping by hormone receptor proteins and developmental regulatory proteins have been found. In addition, instances of looped structures have been found in replication and in recombination in both prokaryotes and eukaryotes. DNA loop formation may have different functions in different cellular contexts; in some cases, the loop itself is requisite for regulation, while in others the increase in the effective local concentration of protein may account for the effects observed. The ability of DNA to form loops is affected by the distance between binding sites; by the DNA sequence, which determines deformability and bendability; and by the presence of other proteins that exert an influence on the conformation of a particular sequence. Alteration of the stability of DNA loops and/or protein-DNA binding by extra- or intracellular signals provides responsivity to changing metabolic or environmental conditions. The fundamental property of site-specific protein binding to DNA can be combined with protein-protein and protein-ligand interaction to generate a broad range of physiological states.

deoP1 promoter and operator mutants in Escherichia coli: isolation and characterization

Plasmid DNA containing deoP1, one of the two major promoters of the deo operon, has been mutagenized using hydroxylamine, and promoter down-mutations and operator mutations were selected. The isolated mutants are all located within a 16 bp palindromic sequence containing the -10 region of deoP1. The results show that RNA polymerase and DeoR repressor compete for the same DNA target. The deoP1 promotor activity is dependent on a TG motif one base pair upstream of the -10 consensus sequence. The sequence of the deo operator site was further verified by use of a synthetic linker.

The remote control of transcription, DNA looping and DNA compaction

mRNA synthesis can be controlled at some distance from the start of transcription in eukaryotes and prokaryotes. It is generally assumed that the distal elements of the transcriptional machinery directly interact with the proximal elements, forcing the DNA to bend in a loop. DNA loop formation and transcription can be affected by the distance between the sites, their helical positioning, their orientation, their concentration (responsible for a cis- or a trans-effect of the DNA sequences), and DNA compaction in chromatin. The corresponding in vitro and in vivo situations have been critically examined for a number of systems, mostly prokaryotic.

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.

CAP and Nag repressor binding to the regulatory regions of the nagE-B and manX genes of Escherichia coli

The divergent nagE-BACD operons located at 15.5 min on the Escherichia coli chromosome encode genes involved in the uptake and metabolism of N-acetylglucosamine. The start sites of the divergent transcripts are separated by 133 base-pairs (bp). A repressor protein for the regulon is encoded by the gene nagC, one of the genes of the nagBACD operon. Strains overproducing the NagC protein have been used to investigate the binding of repressor to the intergenic nagE-B regulatory region. Two binding sites have been detected, overlapping the promoters of the nagE and nagB genes. NagC binding produces a series of DNase I hypersensitive sites separated by 9 to 11 bp in the region between the two NagC binding sites, supporting a model where the NagC proteins bind co-operatively to these two sites on the DNA and interact to form a DNA loop. A strong CAP binding site exists between the two operator sites. It is located at -61.5 and -71.5 relative to the nagE and nagB transcription start sites. CAP and NagC can bind simultaneously and produce a complex more stable than the binary NagC-DNA complex. In addition NagC and CAP binding sites have been found upstream from the manXYZ operon. Although the sites exhibit a similar organization there is no evidence for formation of a DNA loop in this operon.

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.