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

Effects of Glycosylation Combined with Phosphate Treatment on the Allergenicity and Structure of Tropomyosin in Litopenaeus vannamei

Tropomyosin (TM) is the main allergen in shrimp (Litopenaeus vannamei). In this study, the effects of allergenicity and structure of TM by glycosylation (GOS-TM), phosphate treatment (SP-TM), and glycosylation combined with phosphate treatment (GOS-SP-TM) were investigated. Compared to GOS-TM and SP-TM, the IgG/IgE binding capacity of GOS-SP-TM was significantly decreased with 63.9 ± 2.0 and 49.7 ± 2.7%, respectively. Meanwhile, the α-helix content reduced, surface hydrophobicity increased, and 10 specific amino acids (K30, K38, S39, K48, K66, K74, K128, K161, S210, and K251) were modified by glycosylation on six IgE linear epitopes of GOS-SP-TM. In the BALB/c mice allergy model, GOS-SP-TM could significantly reduce the levels of specific IgE, IgG1, and CD4+IL-4+, while the levels of IgG2a, CD4+CD25+Foxp3+, and CD4+IFN-γ+ were increased, which equilibrated Th1 and Th2 cells, thus alleviating allergic symptoms. These results indicated that glycosylation combined with phosphate treatment can provide a new insight into developing hypoallergenic shrimp food.

Insight into the conformational and allergenicity alterations of shrimp tropomyosin induced by Sargassum fusiforme polyphenol

Tropomyosin (TM) is the main allergen in shrimp food. Algae polyphenol reportedly could affect the structures and allergenicity of shrimp TM. In this study, the alterations of conformational structures and allergenicity of TM induced by Sargassum fusiforme polyphenol (SFP) were investigated. Compared to TM, the conjugation of SFP to TM induced conformational structure instability, the IgG-binding capacity and IgE-binding capacity of TM gradually decreased with more conjugation of SFP to TM, and the conjugation of SFP to TM could significantly reduce degranulation, histamine secretion and release of IL-4 and IL-13 from RBL-2H3 mast cells. Therefore, the conjugation of SFP to TM led to conformational instability, significantly decreased the IgG-binding capacity and IgE-binding capacity, weakened the allergic responses of TM-stimulated mast cell, and performed in vivo anti-allergic properties in BALB/c mouse model. Therefore, SFP could serve as candidate natural anti-allergic substances to reduce shrimp TM-induced food allergy.

Inverted Regulation of Multidrug Efflux Pumps, Acid Resistance, and Porins in Benzoate-Evolved Escherichia coli K-12

Benzoic acid, a partial uncoupler of the proton motive force (PMF), selects for sensitivity to chloramphenicol and tetracycline during the experimental evolution of Escherichia coli K-12. Transcriptomes of E. coli isolates evolved with benzoate showed the reversal of benzoate-dependent regulation, including the downregulation of multidrug efflux pump genes, the gene for the Gad acid resistance regulon, the nitrate reductase genes narHJ, and the gene for the acid-consuming hydrogenase Hyd-3. However, the benzoate-evolved strains had increased expression of OmpF and other large-hole porins that admit fermentable substrates and antibiotics. Candidate genes identified from benzoate-evolved strains were tested for their roles in benzoate tolerance and in chloramphenicol sensitivity. Benzoate or salicylate tolerance was increased by deletion of the Gad activator ariR or of the acid fitness island from slp to the end of the gadX gene encoding Gad regulators and the multidrug pump genes mdtEF Benzoate tolerance was also increased by deletion of multidrug component gene emrA, RpoS posttranscriptional regulator gene cspC, adenosine deaminase gene add, hydrogenase gene hyc (Hyd-3), and the RNA chaperone/DNA-binding regulator gene hfq Chloramphenicol resistance was decreased by mutations in genes for global regulators, such as RNA polymerase alpha subunit gene rpoA, the Mar activator gene rob, and hfq Deletion of lipopolysaccharide biosynthetic kinase gene rfaY decreased the rate of growth in chloramphenicol. Isolates from experimental evolution with benzoate had many mutations affecting aromatic biosynthesis and catabolism, such as aroF (encoding tyrosine biosynthesis) and apt (encoding adenine phosphoribosyltransferase). Overall, benzoate or salicylate exposure selects for the loss of multidrug efflux pumps and of hydrogenases that generate a futile cycle of PMF and upregulates porins that admit fermentable nutrients and antibiotics.IMPORTANCE Benzoic acid is a common food preservative, and salicylic acid (2-hydroxybenzoic acid) is the active form of aspirin. At high concentrations, benzoic acid conducts a proton across the membrane, depleting the proton motive force. In the absence of antibiotics, benzoate exposure selects against proton-driven multidrug efflux pumps and upregulates porins that admit fermentable substrates but that also allow the entry of antibiotics. Thus, evolution with benzoate and related molecules, such as salicylates, requires a trade-off for antibiotic sensitivity, a trade-off that could help define a stable gut microbiome. Benzoate and salicylate are naturally occurring plant signal molecules that may modulate the microbiomes of plants and animal digestive tracts so as to favor fermenters and exclude drug-resistant pathogens.

Determination of RNA polymerase binding surfaces of transcription factors by NMR spectroscopy

In bacteria, RNA polymerase (RNAP), the central enzyme of transcription, is regulated by N-utilization substance (Nus) transcription factors. Several of these factors interact directly, and only transiently, with RNAP to modulate its function. As details of these interactions are largely unknown, we probed the RNAP binding surfaces of Escherichia coli (E. coli) Nus factors by nuclear magnetic resonance (NMR) spectroscopy. Perdeuterated factors with [¹H,¹³C]-labeled methyl groups of Val, Leu, and Ile residues were titrated with protonated RNAP. After verification of this approach with the N-terminal domain (NTD) of NusG and RNAP we determined the RNAP binding site of NusE. It overlaps with the NusE interaction surface for the NusG C-terminal domain, indicating that RNAP and NusG compete for NusE and suggesting possible roles for the NusE:RNAP interaction, e.g. in antitermination and direct transcription:translation coupling. We solved the solution structure of NusA-NTD by NMR spectroscopy, identified its RNAP binding site with the same approach we used for NusG-NTD, and here present a detailed model of the NusA-NTD:RNAP:RNA complex.

The Role of α-CTD in the Genome-Wide Transcriptional Regulation of the Bacillus subtilis Cells

The amino acid sequence of the RNA polymerase (RNAP) α-subunit is well conserved throughout the Eubacteria. Its C-terminal domain (α-CTD) is important for the transcriptional regulation of specific promoters in both Escherichia coli and Bacillus subtilis, through interactions with transcription factors and/or a DNA element called the "UP element". However, there is only limited information regarding the α-CTD regulated genes in B. subtilis and the importance of this subunit in the transcriptional regulation of B. subtilis. Here, we established strains and the growth conditions in which the α-subunit of RNAP was replaced with a C-terminally truncated version. Transcriptomic and ChAP-chip analyses revealed that α-CTD deficiency reduced the transcription and RNAP binding of genes related to the utilization of secondary carbon sources, transition state responses, and ribosome synthesis. In E. coli, it is known that α-CTD also contributes to the expression of genes related to the utilization of secondary carbon sources and ribosome synthesis. Our results suggest that the biological importance of α-CTD is conserved in B. subtilis and E. coli, but that its specific roles have diversified between these two bacteria.

Exploring RNA polymerase regulation by NMR spectroscopy

RNA synthesis is a central process in all organisms, with RNA polymerase (RNAP) as the key enzyme. Multisubunit RNAPs are evolutionary related and are tightly regulated by a multitude of transcription factors. Although Escherichia coli RNAP has been studied extensively, only little information is available about its dynamics and transient interactions. This information, however, are crucial for the complete understanding of transcription regulation in atomic detail. To study RNAP by NMR spectroscopy we developed a highly efficient procedure for the assembly of active RNAP from separately expressed subunits that allows specific labeling of the individual constituents. We recorded [¹H,¹³C] correlation spectra of isoleucine, leucine, and valine methyl groups of complete RNAP and the separately labeled β’ subunit within reconstituted RNAP. We further produced all RNAP subunits individually, established experiments to determine which RNAP subunit a certain regulator binds to, and identified the β subunit to bind NusE.

Helicobacter pylori RNA polymerase α-subunit C-terminal domain shows features unique to ɛ-proteobacteria and binds NikR/DNA complexes

Bacterial RNA polymerase is a large, multi-subunit enzyme responsible for transcription of genomic information. The C-terminal domain of the α subunit of RNA polymerase (αCTD) functions as a DNA and protein recognition element localizing the polymerase on certain promoter sequences and is essential in all bacteria. Although αCTD is part of RNA polymerase, it is thought to have once been a separate transcription factor, and its primary role is the recruitment of RNA polymerase to various promoters. Despite the conservation of the subunits of RNA polymerase among bacteria, the mechanisms of regulation of transcription vary significantly. We have determined the tertiary structure of Helicobacter pylori αCTD. It is larger than other structurally determined αCTDs due to an extra, highly amphipathic helix near the C-terminal end. Residues within this helix are highly conserved among ɛ-proteobacteria. The surface of the domain that binds A/T rich DNA sequences is conserved and showed binding to DNA similar to αCTDs of other bacteria. Using several NikR dependent promoter sequences, we observed cooperative binding of H. pylori αCTD to NikR:DNA complexes. We also produced αCTD lacking the 19 C-terminal residues, which showed greatly decreased stability, but maintained the core domain structure and binding affinity to NikR:DNA at low temperatures. The modeling of H. pylori αCTD into the context of transcriptional complexes suggests that the additional amphipathic helix mediates interactions with transcriptional regulators.

Predicting the strength of UP-elements and full-length E. coli σE promoters

Predicting the location and strength of promoters from genomic sequence requires accurate sequenced-based promoter models. We present the first model of a full-length bacterial promoter, encompassing both upstream sequences (UP-elements) and core promoter modules, based on a set of 60 promoters dependent on σ(E), an alternative ECF-type σ factor. UP-element contribution, best described by the length and frequency of A- and T-tracts, in combination with a PWM-based core promoter model, accurately predicted promoter strength both in vivo and in vitro. This model also distinguished active from weak/inactive promoters. Systematic examination of promoter strength as a function of RNA polymerase (RNAP) concentration revealed that UP-element contribution varied with RNAP availability and that the σ(E) regulon is comprised of two promoter types, one of which is active only at high concentrations of RNAP. Distinct promoter types may be a general mechanism for increasing the regulatory capacity of the ECF group of alternative σ's. Our findings provide important insights into the sequence requirements for the strength and function of full-length promoters and establish guidelines for promoter prediction and for forward engineering promoters of specific strengths.

A novel method for the production of in vivo-assembled, recombinant Escherichia coli RNA polymerase lacking the α C-terminal domain

The biochemical characterization of the bacterial transcription cycle has been greatly facilitated by the production and characterization of targeted RNA polymerase (RNAP) mutants. Traditionally, RNAP preparations containing mutant subunits have been produced by reconstitution of denatured RNAP subunits, a process that is undesirable for biophysical and structural studies. Although schemes that afford the production of in vivo-assembled, recombinant RNAP containing amino acid substitutions, insertions, or deletions in either the monomeric β or β' subunits have been developed, there is no such system for the production of in vivo-assembled, recombinant RNAP with mutations in the homodimeric α-subunits. Here, we demonstrate a strategy to generate in vivo-assembled, recombinant RNAP preparations free of the α C-terminal domain. Furthermore, we describe a modification of this approach that would permit the purification of in vivo-assembled, recombinant RNAP containing any α-subunit variant, including those variants that are lethal. Finally, we propose that these related approaches can be extended to generate in vivo-assembled, recombinant variants of other protein complexes containing homomultimers for biochemical, biophysical, and structural analyses.

Structure of the Escherichia coli RNA polymerase alpha subunit C-terminal domain

The alpha subunit C-terminal domain (alphaCTD) of RNA polymerase (RNAP) is a key element in transcription activation in Escherichia coli, possessing determinants responsible for the interaction of RNAP with DNA and with transcription factors. Here, the crystal structure of E. coli alphaCTD (alpha subunit residues 245-329) determined to 2.0 A resolution is reported. Crystals were obtained after reductive methylation of the recombinantly expressed domain. The crystals belonged to space group P2(1) and possessed both pseudo-translational symmetry and pseudo-merohedral twinning. The refined coordinate model (R factor = 0.193, R(free) = 0.236) has improved geometry compared with prior lower resolution determinations of the alphaCTD structure [Jeon et al. (1995), Science, 270, 1495-1497; Benoff et al. (2002), Science, 297, 1562-1566]. An extensive dimerization interface formed primarily by N- and C-terminal residues is also observed. The new coordinates will facilitate the improved modeling of alphaCTD-containing multi-component complexes visualized at lower resolution using X-ray crystallography and electron-microscopy reconstruction.

A targeted releasable affinity probe (TRAP) for in vivo photocrosslinking

Protein crosslinking, especially coupled to mass-spectrometric identification, is increasingly used to determine protein binding partners and protein-protein interfaces for isolated protein complexes. The modification of crosslinkers to permit their targeted use in living cells is of considerable importance for studying protein-interaction networks, which are commonly modulated through weak interactions that are formed transiently to permit rapid cellular response to environmental changes. We have therefore synthesized a targeted and releasable affinity probe (TRAP) consisting of a biarsenical fluorescein linked to benzophenone that binds to a tetracysteine sequence in a protein engineered for specific labeling. Here, the utility of TRAP for capturing protein binding partners upon photoactivation of the benzophenone moiety has been demonstrated in living bacteria and mammalian cells. In addition, ligand exchange of the arsenic-sulfur bonds between TRAP and the tetracysteine sequence to added dithiols results in fluorophore transfer to the crosslinked binding partner. In isolated protein complexes, this release from the original binding site permits the identification of the proximal binding interface through mass spectrometric fragmentation and computational sequence identification.

Two structurally independent domains of E. coli NusG create regulatory plasticity via distinct interactions with RNA polymerase and regulators

NusG is a conserved regulatory protein that interacts with elongation complexes (ECs) of RNA polymerase, DNA, and RNA to modulate transcription in multiple and sometimes opposite ways. In Escherichia coli, NusG suppresses pausing and increases elongation rate, enhances termination by E. coli rho and phage HK022 Nun protein, and promotes antitermination by lambdaN and in ribosomal RNA operons. We report NMR studies that suggest that E. coli NusG consists of two largely independent N- and C-terminal structural domains, NTD and CTD, respectively. Based on tests of the functions of the NTD and CTD and variants of NusG in vivo and in vitro, we find that NTD alone is sufficient to suppress pausing and enhance transcript elongation in vitro. However, neither domain alone can enhance rho-dependent termination or support antitermination, indicating that interactions of both domains with ECs are required for these processes. We propose that the two domains of NusG mediate distinct interactions with ECs: the NTD interacts with RNA polymerase and the CTD interacts with rho and other regulators, providing NusG with different combinations of interactions to effect different regulatory outcomes.

The UP element is necessary but not sufficient for growth rate-dependent control of the Escherichia coli guaB promoter

The Escherichia coli guaB promoter (P(guaB)) regulates the transcription of two genes, guaB and guaA, that are required for de novo synthesis of GMP, a precursor for the synthesis of guanine nucleoside triphosphates. The activity of P(guaB) is subject to growth rate-dependent control (GRDC). Here we show that the A+T-rich sequence located between positions -59 and -38 relative to the guaB transcription start site stimulates transcription from P(guaB) approximately 8- to 10-fold and, in common with other UP elements, requires the C-terminal domain of the RNA polymerase alpha subunit for activity. Like the rrnB P1 UP element, the P(guaB) UP element contains two independently acting subsites located at positions -59 to -47 and -46 to -38 and can stimulate transcription when placed upstream of the lacP1 promoter. We reveal a novel role for the P(guaB) UP element by demonstrating that it is required for GRDC. The involvement of the UP element in GRDC also requires the participation of sequences located at least 100 bp upstream of the guaB transcription start site. These sequences are required for down-regulation of P(guaB) activity at lower growth rates.

Identification of the WW domain-interaction sites in the unstructured N-terminal domain of EBV LMP 2A

Epstein-Barr virus latency is maintained by the latent membrane protein (LMP) 2A, which mimics the B-cell receptor (BCR) and perturbs BCR signaling. The cytoplasmic N-terminal domain of LMP2A is composed of 119 amino acids. The N-terminal domain of LMP2A (LMP2A NTD) contains two PY motifs (PPPPY) that interact with the WW domains of Nedd4 family ubiquitin-protein ligases. Based on our analysis of NMR data, we found that the LMP2A NTD adopts an overall random-coil structure in its native state. However, the region between residues 60 and 90 was relatively ordered, and seemed to form the hydrophobic core of the LMP2A NTD. This region resides between two PY motifs and is important for WW domain binding. Mapping of the residues involved in the interaction between the LMP2A NTD and WW domains was achieved by chemical shift perturbation, by the addition of WW2 and WW3 peptides. Interestingly, the binding of the WW domains mainly occurred in the hydrophobic core of the LMP2A NTD. In addition, we detected a difference in the binding modes of the two PY motifs against the two WW peptides. The binding of the WW3 peptide caused the resonances of five residues (Tyr(60), Glu(61), Asp(62), Trp(65), and Gly(66)) just behind the N-terminal PY motif of the LMP2A NTD to disappear. A similar result was obtained with WW2 binding. However, near the C-terminal PY motif, the chemical shift perturbation caused by WW2 binding was different from that due to WW3 binding, indicating that the residues near the PY motifs are involved in selective binding of WW domains. The present work represents the first structural study of the LMP2A NTD and provides fundamental structural information about its interaction with ubiquitin-protein ligase.

Similarity and divergence between the RNA polymerase α subunits from hyperthermophilic Thermotoga maritima and mesophilic Escherichia coli bacteria

The alpha subunit (alphaTm) of Thermotoga maritima RNA polymerase has been characterized to investigate its role in transcriptional regulation in one of the few known anaerobic hyperthermophilic bacteria. The highly thermostable alphaTm shares 54% similarity with its Escherichia coli analogue (alphaEc). The T. maritima rpoA gene coding the alpha subunit does not complement the thermosensitive rpoA112 mutation of E. coli. However, alphaTm and alphaEc show similar folding patterns as determined by circular dichroism. Purified alphaTm binds to the T. maritima PargGo promoter region (probably to a UP-element) and Arg282 appears to be crucial for DNA binding. The thermostable protein is also able to interact with transcription regulatory proteins, like ArgR from T. neapolitana or CRP from E. coli. These data indicate that the RNA polymerase alpha subunit might play a crucial role in the modulation of gene expression in hyperthermophiles.

Molecular basis for the exploitation of spore formation as survival mechanism by virulent phage phi29

Phage phi29 is a virulent phage of Bacillus subtilis with no known lysogenic cycle. Indeed, lysis occurs rapidly following infection of vegetative cells. Here, we show that phi29 possesses a powerful strategy that enables it to adapt its infection strategy to the physiological conditions of the infected host to optimize its survival and proliferation. Thus, the lytic cycle is suppressed when the infected cell has initiated the process of sporulation and the infecting phage genome is directed into the highly resistant spore to remain dormant until germination of the spore. We have also identified two host-encoded factors that are key players in this adaptive infection strategy. We present evidence that chromosome segregation protein Spo0J is involved in spore entrapment of the infected phi29 genome. In addition, we demonstrate that Spo0A, the master regulator for initiation of sporulation, suppresses phi29 development by repressing the main early phi29 promoters via different and novel mechanisms and also by preventing activation of the single late phi29 promoter.

Crystal structure of bacteriophage lambda cII and its DNA complex

The tetrameric cII protein from bacteriophage lambda activates transcription from the phage promoters P(RE), P(I), and P(AQ) by binding to two direct repeats that flank the promoter -35 element. Here, we present the X-ray crystal structure of cII alone (2.8 A resolution) and in complex with its DNA operator from P(RE) (1.7 A resolution). The structures provide a basis for modeling of the activation complex with the RNA polymerase holoenzyme, and point to the key role for the RNA polymerase alpha subunit C-terminal domain (alphaCTD) in cII-dependent activation, which forms a bridge of protein/protein interactions between cII and the RNA polymerase sigma subunit. The model makes specific predictions for protein/protein interactions between cII and alphaCTD, and between alphaCTD and sigma, which are supported by previous genetic studies.

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

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

Location of the Escherichia coli RNA polymerase alpha subunit C-terminal domain at an FNR-dependent promoter: analysis using an artificial nuclease

The Escherichia coli FNR protein is a global transcription regulator that activates gene expression via interactions with the RNA polymerase alpha subunit C-terminal domain. Using preparations of E. coli RNA polymerase holoenzyme, specifically labelled with a DNA cleavage reagent, we have determined the location and orientation of the C-terminal domain of the RNA polymerase alpha subunit in transcriptionally competent complexes at a class II FNR-dependent promoter. We conclude that one alpha subunit C-terminal domain binds immediately upstream of FNR, and that its position and orientation is the same as at similar promoters dependent on CRP, another E. coli transcription activator that is related to FNR. In complementary experiments, we show that the second alpha subunit C-terminal domain of RNA polymerase can be repositioned by upstream-bound CRP, but not by upstream-bound FNR.

Relevance of UP elements for three strong Bacillus subtilis phage phi29 promoters

Various Escherichia coli promoters contain, in addition to the classical -35 and -10 hexamers, a third recognition element, named the UP element. Located upstream of the -35 box, UP elements stimulate promoter activity by forming a docking site for the C-terminal domain of the RNA polymerase alpha subunit (alphaCTD). Accumulating genetic, biochemical and structural information has provided a detailed picture on the molecular mechanism underlying UP element-dependent promoter stimulation in E.coli. However, far less is known about functional UP elements of Bacillus subtilis promoters. Here we analyse the strong early sigma(A)-RNA polymerase-dependent promoters C2, A2c and A2b of the lytic B.subtilis phage phi29. We demonstrate that the phage promoters contain functional UP elements although their contribution to promoter strength is very different. Moreover, we show that the UP element of the A2b promoter, being critical for its activity, is located further upstream of the -35 box than most E.coli UP elements. The importance of the UP elements for the phage promoters and how they relate to other UP elements are discussed.

Exploitation of a Chemical Nuclease to Investigate the Location and Orientation of the Escherichia coli RNA Polymerase α Subunit C-terminal Domains at Simple Promoters That Are Activated by Cyclic AMP Receptor Protein

The C-terminal domain of the alpha subunit (alphaCTD) of bacterial RNA polymerase plays an important role in promoter recognition. It is known that alphaCTD binds to the DNA minor groove at different locations at different promoters via a surface-exposed determinant, the 265 determinant. Here we describe experiments that permit us to determine the location and orientation of binding of alphaCTD at any promoter. In these experiments, a DNA cleavage reagent is attached to specific locations on opposite faces of the RNA polymerase alpha subunit. After incorporation of the tagged alpha subunits into holo-RNA polymerase, patterns of DNA cleavage due to the reagent are determined in open complexes. The locations of DNA cleavage due to the reagent attached at different positions allow the position and orientation of alphaCTD to be deduced. Here we present data from experiments with simple Escherichia coli promoters that are activated by the cyclic AMP receptor protein.

Recruitment of sigma54-RNA polymerase to the Pu promoter of Pseudomonas putida through integration host factor-mediated positioning switch of alpha subunit carboxyl-terminal domain on an UP-like element

The interactions between the sigma54-containing RNA polymerase (sigma54-RNAP) and the region of the Pseudomonas putida Pu promoter spanning from the enhancer to the binding site for the integration host factor (IHF) were analyzed both by DNase I and hydroxyl radical footprinting. A short Pu region centered at position -104 was found to be involved in the interaction with sigma54-RNAP, both in the absence and in the presence of IHF protein. Deletion or scrambling of the -104 region strongly reduced promoter affinity in vitro and promoter activity in vivo, respectively. The reduction in promoter affinity coincided with the loss of IHF-mediated recruitment of the sigma54-RNAP in vitro. The experiments with oriented-alpha sigma54-RNAP derivatives containing bound chemical nuclease revealed interchangeable positioning of only one of the two alpha subunit carboxyl-terminal domains (alphaCTDs) both at the -104 region and in the surroundings of position -78. The addition of IHF resulted in perfect position symmetry of the two alphaCTDs. These results indicate that, in the absence of IHF, the sigma54-RNAP asymmetrically uses only one alphaCTD subunit to establish productive contacts with upstream sequences of the Pu promoter. In the presence of IHF-induced curvature, the closer proximity of the upstream DNA to the body of the sigma54-RNAP can allow the other alphaCTD to be engaged in and thus favor closed complex formation.

An intersubunit contact stimulating transcription initiation by E coli RNA polymerase: interaction of the alpha C-terminal domain and sigma region 4

The C-terminal domain of the Escherichia coli RNA polymerase (RNAP) alpha subunit (alphaCTD) stimulates transcription initiation by interacting with upstream (UP) element DNA and a variety of transcription activators. Here we identify specific substitutions in region 4.2 of sigma 70 (sigma(70)) and in alphaCTD that decrease transcription initiation from promoters containing some, but not all, UP elements. This decrease in transcription derives from a decrease in the initial equilibrium constant for RNAP binding (K(B)). The open complexes formed by the mutant and wild-type RNAPs differ in DNAse I sensitivity at the junction of the alphaCTD and sigma DNA binding sites, correlating with the differences in transcription. A model of the DNA-alphaCTD-sigma region 4.2 ternary complex, constructed from the previously determined X-ray structures of the Thermus aquaticus sigma region 4.2-DNA complex and the E. coli alphaCTD-DNA complex, indicates that the residues identified by mutation in sigma region 4.2 and in alphaCTD are in very close proximity. Our results strongly suggest that alphaCTD, when bound to an UP element proximal subsite, contacts the RNAP sigma(70) subunit, increasing transcription. Previous data from the literature suggest that this same sigma-alphaCTD interaction also plays a role in transcription factor-mediated activation.

Structural basis of transcription initiation: an RNA polymerase holoenzyme-DNA complex

The crystal structure of Thermus aquaticus RNA polymerase holoenzyme (alpha2betabeta'omegasigmaA) complexed with a fork-junction promoter DNA fragment has been determined by fitting high-resolution x-ray structures of individual components into a 6.5-angstrom resolution map. The DNA lies across one face of the holoenzyme, completely outside the RNA polymerase active site channel. All sequence-specific contacts with core promoter elements are mediated by the sigma subunit. A universally conserved tryptophan is ideally positioned to stack on the exposed face of the base pair at the upstream edge of the transcription bubble. Universally conserved basic residues of the sigma subunit provide critical contacts with the DNA phosphate backbone and play a role in directing the melted DNA template strand into the RNA polymerase active site. The structure explains how holoenzyme recognizes promoters containing variably spaced -10 and -35 elements and provides the basis for models of the closed and open promoter complexes.

Determinants of the C-terminal domain of the Escherichia coli RNA polymerase alpha subunit important for transcription at class I cyclic AMP receptor protein-dependent promoters

Alanine scanning of the Escherichia coli RNA polymerase alpha subunit C-terminal domain (alphaCTD) was used to identify amino acid side chains important for class I cyclic AMP receptor protein (CRP)-dependent transcription. Key residues were investigated further in vivo and in vitro. Substitutions in three regions of alphaCTD affected class I CRP-dependent transcription from the CC(-61.5) promoter and/or the lacP1 promoter. These regions are (i) the 287 determinant, previously shown to contact CRP during class II CRP-dependent transcription; (ii) the 265 determinant, previously shown to be important for alphaCTD-DNA interactions, including those required for class II CRP-dependent transcription; and (iii) the 261 determinant. We conclude that CRP contacts the same target in alphaCTD, the 287 determinant, at class I and class II CRP-dependent promoters. We also conclude that the relative contributions of individual residues within the 265 determinant depend on promoter sequence, and we discuss explanations for effects of substitutions in the 261 determinant.

The C-terminal domains of the RNA polymerase alpha subunits: contact site with Fis and localization during co-activation with CRP at the Escherichia coli proP P2 promoter

Fis is a versatile transactivator that functions at many different promoters. Fis activates transcription at the RpoS-dependent proP P2 promoter when bound to a site that overlaps the minus sign35 hexamer by a mechanism that requires the C-terminal domain of the alpha subunit of RNA polymerase (alphaCTD). The region on Fis responsible for activating transcription through the alphaCTD has been localized to a short beta-turn near the DNA-binding determinant on one subunit of the Fis homodimer. We report here that Fis-dependent activation of proP P2 transcription requires two discrete regions on the alphaCTD. One region, consisting of residues 264-265 and 296-297, mediates DNA binding. A second patch, comprising amino acid residues 271-273, forms a ridge on the surface of the alphaCTD that we propose interacts with Fis. The accompanying paper shows that these same regions on alphaCTD are utilized for transcriptional activation at the rrnB and rrnE P1 promoters by Fis bound to a site upstream of the core promoter (centered at minus sign71/minus sign72). In addition to stimulation of proP P2 transcription by Fis, CRP co-activates this promoter when bound to a remote site upstream from the promoter (centered at -121.5). RNA polymerase preparations lacking one alphaCTD of the alpha dimer were employed to demonstrate that the beta'-associated alpha(II)CTD was utilized preferentially by Fis at proP P2 in the presence and absence of CRP. These experiments define the overall architecture of the proP P2 initiation complex where Fis and CRP each function through a different alphaCTD.

Interaction of the alpha-subunit of Escherichia coli RNA polymerase with DNA: rigid body nature of the protein-DNA contact

The alpha-subunit of Escherichia coli RNA polymerase plays an important role in the activity of many promoters by providing a direct protein-DNA contact with a specific sequence (UP element) located upstream of the core promoter sequence. To obtain insight into the nature of thermodynamic forces involved in the formation of this protein-DNA contact, the binding of the alpha-subunit of E. coli RNA polymerase to a fluorochrome-labeled DNA fragment containing the rrnB P1 promoter UP element sequence was quantitatively studied using fluorescence polarization. The alpha dimer and DNA formed a 1:1 complex in solution. Complex formation at 25 degrees C was enthalpy-driven, the binding was accompanied by a net release of 1-2 ions, and no significant specific ion effects were observed. The van't Hoff plot of temperature dependence of binding was linear suggesting that the heat capacity change (Deltac(p)) was close to zero. Protein footprinting with hydroxyradicals showed that the protein did not change its conformation upon protein-DNA contact formation. No conformational changes in the DNA molecule were detected by CD spectroscopy upon protein-DNA complex formation. The thermodynamic characteristics of the binding together with the lack of significant conformational changes in the protein and in the DNA suggested that the alpha-subunit formed a rigid body-like contact with the DNA in which a tight complementary recognition interface between alpha-subunit and DNA was not formed.

Contributions of UP elements and the transcription factor FIS to expression from the seven rrn P1 promoters in Escherichia coli

The high activity of the rrnB P1 promoter in Escherichia coli results from a cis-acting DNA sequence, the UP element, and a trans-acting transcription factor, FIS. In this study, we examine the effects of FIS and the UP element at the other six rrn P1 promoters. We find that UP elements are present at all of the rrn P1 promoters, but they make different relative contributions to promoter activity. Similarly, FIS binds upstream of, and activates, all seven rrn P1 promoters but to different extents. The total number of FIS binding sites, as well as their positions relative to the transcription start site, differ at each rrn P1 promoter. Surprisingly, the FIS sites upstream of site I play a much larger role in transcription from most rrn P1 promoters compared to rrnB P1. Our studies indicate that the overall activities of the seven rrn P1 promoters are similar, and the same contributors are responsible for these high activities, but these inputs make different relative contributions and may act through slightly different mechanisms at each promoter. These studies have implications for the control of gene expression of unlinked multigene families.

UP element-dependent transcription at the Escherichia coli rrnB P1 promoter: positional requirements and role of the RNA polymerase alpha subunit linker

The UP element stimulates transcription from the rrnB P1 promoter through a direct interaction with the C-terminal domain of the RNA polymerase alpha subunit (alphaCTD). We investigated the effect on transcription from rrnB P1 of varying both the location of the UP element and the length of the alpha subunit interdomain linker, separately and in combination. Displacement of the UP element by a single turn of the DNA helix resulted in a large decrease in transcription from rrnB P1, while displacement by half a turn or two turns totally abolished UP element-dependent transcription. Deletions of six or more amino acids from within the alpha subunit linker resulted in a decrease in UP element-dependent stimulation, which correlated with decreased binding of alphaCTD to the UP element. Increasing the alpha linker length was less deleterious to RNA polymerase function at rrnB P1 but did not compensate for the decrease in activation that resulted from displacing the UP element. Our results suggest that the location of the UP element at rrnB P1 is crucial to its function and that the natural length of the alpha subunit linker is optimal for utilisation of the UP element at this promoter.

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

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

Fine structure of E. coli RNA polymerase-promoter interactions: alpha subunit binding to the UP element minor groove

The alpha subunit of E. coli RNAP plays an important role in the recognition of many promoters by binding to the A+T-rich UP element, a DNA sequence located upstream of the recognition elements for the sigma subunit, the -35 and -10 hexamers. We examined DNA-RNAP interactions using high resolution interference and protection footprinting methods and using the minor groove-binding drug distamycin. Our results suggest that alpha interacts with bases in the DNA minor groove and with the DNA backbone along the minor groove, but that UP element major groove surfaces do not make a significant contribution to alpha binding. On the basis of these and previous results, we propose a model in which alpha contacts UP element DNA through amino acid residues located in a pair of helix-hairpin-helix motifs. Furthermore, our experiments extend existing information about recognition of the core promoter by sigma(70) by identifying functional groups in the major grooves of the -35 and -10 hexamers in which modifications interfere with RNAP binding. These studies greatly improve the resolution of our picture of the promoter-RNAP interaction.

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

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

Escherichia coli RNA polymerase core and holoenzyme structures

Multisubunit RNA polymerase is an essential enzyme for regulated gene expression. Here we report two Escherichia coli RNA polymerase structures: an 11.0 A structure of the core RNA polymerase and a 9.5 A structure of the sigma(70) holoenzyme. Both structures were obtained by cryo-electron microscopy and angular reconstitution. Core RNA polymerase exists in an open conformation. Extensive conformational changes occur between the core and the holoenzyme forms of the RNA polymerase, which are largely associated with movements in ss'. All common RNA polymerase subunits (alpha(2), ss, ss') could be localized in both structures, thus suggesting the position of sigma(70) in the holoenzyme.

Mechanism for a transcriptional activator that works at the isomerization step

Transcriptional activators in prokaryotes have been shown to stimulate different steps in the initiation process including the initial binding of RNA polymerase (RNAP) to the promoter and a postbinding step known as the isomerization step. Evidence suggests that activators that affect initial binding can work by a cooperative binding mechanism by making energetically favorable contacts with RNAP, but the mechanism by which activators affect the isomerization step is unclear. A well-studied example of an activator that normally exerts its effect exclusively on the isomerization step is the bacteriophage lambda cI protein (lambdacI), which has been shown genetically to interact with the C-terminal region of the final sigma(70) subunit of RNAP. We show here that the interaction between lambdacI and final sigma can stimulate transcription even when the relevant portion of final sigma is transplanted to another subunit of RNAP. This activation depends on the ability of lambdacI to stabilize the binding of the transplanted final sigma moiety to an ectopic -35 element. Based on these and previous findings, we discuss a simple model that explains how an activator's ability to stabilize the binding of an RNAP subdomain to the DNA can account for its effect on either the initial binding of RNAP to a promoter or the isomerization step.

Coactivation of the RpoS-dependent proP P2 promoter by fis and cyclic AMP receptor protein

The Escherichia coli proP P2 promoter, which directs the expression of an integral membrane transporter of proline, glycine betaine, and other osmoprotecting compounds, is induced upon entry into stationary phase to protect cells from osmotic shock. Transcription from the P2 promoter is completely dependent on RpoS (sigma(38)) and Fis. Fis activates transcription by binding to a site centered at -41, which overlaps the promoter, where it makes a specific contact with the C-terminal domain of the alpha subunit of RNA polymerase (alpha-CTD). We show here that Fis and cyclic AMP (cAMP) receptor protein (CRP)-cAMP collaborate to activate transcription synergistically in vitro. Coactivation both in vivo and in vitro is dependent on CRP binding to a site centered at -121.5, but CRP without Fis provides little activation. The contribution by CRP requires the correct helical phasing of the CRP site and a functional activation region 1 on CRP. We provide evidence that coactivation is achieved by Fis and CRP independently contacting each of the two alpha-CTDs. Efficient transcription in vitro requires that both activators must be preincubated with the DNA prior to addition of RNA polymerase.

UPs and downs in bacterial transcription initiation: the role of the alpha subunit of RNA polymerase in promoter recognition

In recent years, it has become clear that promoter recognition by bacterial RNA polymerase involves interactions not only between core promoter elements and the sigma subunit, but also between a DNA element upstream of the core promoter and the alpha subunit. DNA binding by alpha can increase transcription dramatically. Here we review the current state of our understanding of the alpha interaction with DNA during basal transcription initiation (i.e. in the absence of proteins other than RNA polymerase) and activated transcription initiation (i.e. when stimulated by transcription factors).

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

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

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

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

Mapping of subunit-subunit contact surfaces on the beta' subunit of Escherichia coli RNA polymerase

The RNA polymerase core enzyme of Escherichia coli with the catalytic activity of RNA polymerization is assembled sequentially under the order: 2alpha --> alpha(2) --> alpha(2)beta --> alpha(2)betabeta'. The core enzyme gains the activities of promoter recognition and transcription initiation after binding the sigma subunit. The subunit-subunit contact surfaces of beta' subunit (1407 residues) were analyzed by testing complex formation between various beta' fragments and either the alpha(2)beta complex or the sigma(70) subunit. Results indicate that two regions, one central region between residues 515 and 842 and the other COOH-terminal proximal region downstream from residue 1141, are involved in binding the alpha(2)beta complex; and the NH(2)-terminal proximal region between residues 201 and 345 plays a major role in binding the sigma(70) subunit. However, both alpha(2)beta binding sites have weak activity of the sigma(70) subunit; likewise, the sigma(70) subunit-contact surface has weak binding activity of the alpha(2)beta complex. The sites involved in the catalytic function of RNA polymerization are all located within two spacer regions sandwiched between these three subunit-subunit contact surfaces.

Transcription activation by catabolite activator protein (CAP)

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

Bacterial promoter architecture: subsite structure of UP elements and interactions with the carboxy-terminal domain of the RNA polymerase alpha subunit

We demonstrate here that the previously described bacterial promoter upstream element (UP element) consists of two distinct subsites, each of which, by itself, can bind the RNA polymerase holoenzyme alpha subunit carboxy-terminal domain (RNAP alphaCTD) and stimulate transcription. Using binding-site-selection experiments, we identify the consensus sequence for each subsite. The selected proximal subsites (positions -46 to -38; consensus 5'-AAAAAARNR-3') stimulate transcription up to 170-fold, and the selected distal subsites (positions -57 to -47; consensus 5'-AWWWWWTTTTT-3') stimulate transcription up to 16-fold. RNAP has subunit composition alpha(2)betabeta'sigma and thus contains two copies of alphaCTD. Experiments with RNAP derivatives containing only one copy of alphaCTD indicate, in contrast to a previous report, that the two alphaCTDs function interchangeably with respect to UP element recognition. Furthermore, function of the consensus proximal subsite requires only one copy of alphaCTD, whereas function of the consensus distal subsite requires both copies of alphaCTD. We propose that each subsite constitutes a binding site for a copy of alphaCTD, and that binding of an alphaCTD to the proximal subsite region (through specific interactions with a consensus proximal subsite or through nonspecific interactions with a nonconsensus proximal subsite) is a prerequisite for binding of the other alphaCTD to the distal subsite.

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.

Insights into Escherichia coli RNA polymerase structure from a combination of x-ray and electron crystallography

Our goal is to understand the mechanism of transcription and its regulation. Determining structures of RNA polymerase and transcription complexes is an essential step. Because of their large size and complexity, determination of these structures will require a combination of electron microscopy, biophysical methods, and biochemical methods to identify functionally and structurally relevant subassemblies and domains and x-ray crystallography to determine high-resolution structures of RNA polymerase components and accessory factors. We recently solved the 2.5-A crystal structure of the Escherichia coli RNA polymerase alpha subunit N-terminal domain, which is the first high-resolution structure of a core component required for RNA polymerase assembly and basal transcription. This structure, combined with a new 19-A resolution structure determined by cryo-electron microscopy of helical crystals of E. coli core RNAP embedded in vitreous ice, leads to a model for the organization of the RNAP subunits.

Upstream A-tracts increase bacterial promoter activity through interactions with the RNA polymerase alpha subunit

Upstream A-tracts stimulate transcription from a variety of bacterial promoters, and this has been widely attributed to direct effects of the intrinsic curvature of A-tract-containing DNA. In this work we report experiments that suggest a different mechanism for the effects of upstream A-tracts on transcription. The similarity of A-tract-containing sequences to the adenine- and thymine-rich upstream recognition elements (UP elements) found in some bacterial promoters suggested that A-tracts might increase promoter activity by interacting with the alpha subunit of RNA polymerase (RNAP). We found that an A-tract-containing sequence placed upstream of the Escherichia coli lac or rrnB P1 promoters stimulated transcription both in vivo and in vitro, and that this stimulation required the C-terminal (DNA-binding) domain of the RNAP alpha subunit. The A-tract sequence was protected by wild-type RNAP but not by alpha-mutant RNAPs in footprints. The effect of the A-tracts on transcription was not as great as that of the most active UP elements, consistent with the degree of similarity of the A-tract sequence to the UP element consensus. A-tracts functioned best when positioned close to the -35 hexamer rather than one helical turn farther upstream, similar to the positioning optimal for UP element function. We conclude that A-tracts function as UP elements, stimulating transcription by providing binding site(s) for the RNAP alphaCTD, and we suggest that these interactions could contribute to the previously described wrapping of promoter DNA around RNAP.

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

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

Identification of an UP element consensus sequence for bacterial promoters

The UP element, a component of bacterial promoters located upstream of the -35 hexamer, increases transcription by interacting with the RNA polymerase alpha-subunit. By using a modification of the SELEX procedure for identification of protein-binding sites, we selected in vitro and subsequently screened in vivo for sequences that greatly increased promoter activity when situated upstream of the Escherichia coli rrnB P1 core promoter. A set of 31 of these upstream sequences increased transcription from 136- to 326-fold in vivo, considerably more than the natural rrnB P1 UP element, and was used to derive a consensus sequence: -59 nnAAA(A/T)(A/T)T(A/T)TTTTnnAAAAnnn -38. The most active selected sequence contained the derived consensus, displayed all of the properties of an UP element, and the interaction of this sequence with the alpha C-terminal domain was similar to that of previously characterized UP elements. The identification of the UP element consensus should facilitate a detailed understanding of the alpha-DNA interaction. Based on the evolutionary conservation of the residues in alpha responsible for interaction with UP elements, we suggest that the UP element consensus sequence should be applicable throughout eubacteria, should generally facilitate promoter prediction, and may be of use for biotechnological applications.