Both fis-dependent and factor-independent upstream activation of the rrnB P1 promoter are face of the helix dependent

Cooperative stabilization of Mycobacterium tuberculosis rrnAP3 promoter open complexes by RbpA and CarD

The essential mycobacterial transcriptional regulators RbpA and CarD act to modulate transcription by associating to the initiation complex and increasing the flux of transcript production. Each of these factors interacts directly with the promoter DNA template and with RNA polymerase (RNAP) holoenzyme. We recently reported on the energetics of CarD-mediated open complex stabilization on the Mycobacterium tuberculosis rrnAP3 ribosomal promoter using a stopped-flow fluorescence assay. Here, we apply this approach to RbpA and show that RbpA stabilizes RNAP-promoter open complexes (RPo) via a distinct mechanism from that of CarD. Furthermore, concentration-dependent stopped-flow experiments with both factors reveal positive linkage (cooperativity) between RbpA and CarD with regard to their ability to stabilize RPo The observation of positive linkage between RbpA and CarD demonstrates that the two factors can act on the same transcription initiation complex simultaneously. Lastly, with both factors present, the kinetics of open complex formation is significantly faster than in the presence of either factor alone and approaches that of E. coli RNAP on the same promoter. This work provides a quantitative framework for the molecular mechanisms of these two essential transcription factors and the critical roles they play in the biology and pathology of mycobacteria.

Mechanisms of Very Long Abortive Transcript Release during Promoter Escape

A phage T5 N25 promoter variant, DG203, undergoes the escape transition at the +16 to +19 positions after transcription initiation. By specifically examining the abortive activity of the initial transcribing complex at position +19 (ITC19), we observe the production of both GreB-sensitive and GreB-resistant VLAT19. This suggests that ITC19, which is perched on the brink of escape, is highly unstable and can achieve stabilization through either backtracking or forward translocation. Of the forward-tracked fraction, only a small percentage escapes normally (followed by stepwise elongation) to produce full-length RNA; the rest presumably hypertranslocates to release GreB-resistant VLATs. VLAT formation is dependent not only on consensus -35/-10 promoters with 17 bp spacing but also on sequence characteristics of the spacer DNA. Analysis of DG203 promoter variants containing different spacer sequences reveals that AT-rich spacers intrinsically elevate the level of VLAT formation. The AT-rich spacer of DG203 joined to the -10 box presents an UP element sequence capable of interacting with the polymerase α subunit C-terminal domain (αCTD) during the escape transition, which in turn enhances VLAT release. Utilization of the spacer/-10 region UP element by αCTD subunits requires a 10-15 bp hypertranslocation. We document the physical occurrence of hyper forward translocation using ExoIII footprinting analysis.

Biosynthesis and Regulation of the Branched-Chain Amino Acids†

This review focuses on more recent studies concerning the systems biology of branched-chain amino acid biosynthesis, that is, the pathway-specific and global metabolic and genetic regulatory networks that enable the cell to adjust branched-chain amino acid synthesis rates to changing nutritional and environmental conditions. It begins with an overview of the enzymatic steps and metabolic regulatory mechanisms of the pathways and descriptions of the genetic regulatory mechanisms of the individual operons of the isoleucine-leucine-valine (ilv) regulon. This is followed by more-detailed discussions of recent evidence that global control mechanisms that coordinate the expression of the operons of this regulon with one another and the growth conditions of the cell are mediated by changes in DNA supercoiling that occur in response to changes in cellular energy charge levels that, in turn, are modulated by nutrient and environmental signals. Since the parallel pathways for isoleucine and valine biosynthesis are catalyzed by a single set of enzymes, and because the AHAS-catalyzed reaction is the first step specific for valine biosynthesis but the second step of isoleucine biosynthesis, valine inhibition of a single enzyme for this enzymatic step might compromise the cell for isoleucine or result in the accumulation of toxic intermediates. The operon-specific regulatory mechanisms of the operons of the ilv regulon are discussed in the review followed by a consideration and brief review of global regulatory proteins such as integration host factor (IHF), Lrp, and CAP (CRP) that affect the expression of these operons.

CarD stabilizes mycobacterial open complexes via a two-tiered kinetic mechanism

CarD is an essential and global transcriptional regulator in mycobacteria. While its biological role is unclear, CarD functions by interacting directly with RNA polymerase (RNAP) holoenzyme promoter complexes. Here, using a fluorescent reporter of open complex, we quantitate RP_o formation in real time and show that Mycobacterium tuberculosis CarD has a dramatic effect on the energetics of RNAP bound complexes on the M. tuberculosis rrnAP3 ribosomal RNA promoter. The data reveal that Mycobacterium bovis RNAP exhibits an unstable RP_o that is stabilized by CarD and suggest that CarD uses a two-tiered, concentration-dependent mechanism by associating with open and closed complexes with different affinities. Specifically, the kinetics of open-complex formation can be explained by a model where, at saturating concentrations of CarD, the rate of bubble collapse is slowed and the rate of opening is accelerated. The kinetics and open-complex stabilities of CarD mutants further clarify the roles played by the key residues W85, K90 and R25 previously shown to affect CarD-dependent gene regulation in vivo. In contrast to M. bovis RNAP, Escherichia coli RNAP efficiently forms RP_o on rrnAP3, suggesting an important difference between the polymerases themselves and highlighting how transcriptional machinery can vary across bacterial genera.

CarD integrates three functional modules to promote efficient transcription, antibiotic tolerance, and pathogenesis in mycobacteria

Although the basic mechanisms of prokaryotic transcription are conserved, it has become evident that some bacteria require additional factors to allow for efficient gene transcription. CarD is an RNA polymerase (RNAP)-binding protein conserved in numerous bacterial species and essential in mycobacteria. Despite the importance of CarD, its function at transcription complexes remains unclear. We have generated a panel of mutations that individually target three independent functional modules of CarD: the RNAP interaction domain, the DNA-binding domain, and a conserved tryptophan residue. We have dissected the roles of each functional module in CarD activity and built a model where each module contributes to stabilizing RNAP-promoter complexes. Our work highlights the requirement of all three modules of CarD in the obligate pathogen Mycobacterium tuberculosis, but not in Mycobacterium smegmatis. We also report divergent use of the CarD functional modules in resisting oxidative stress and pigmentation. These studies provide new information regarding the functional domains involved in transcriptional regulation by CarD while also improving understanding of the physiology of M. tuberculosis.

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.

Activation of the promoter of the fengycin synthetase operon by the UP element

Bacillus subtilis F29-3 produces an antifungal peptidic antibiotic that is synthesized nonribosomally by fengycin synthetases. Our previous work established that the promoter of the fengycin synthetase operon is located 86 nucleotides upstream of the translational initiation codon of fenC. This investigation involved transcriptional fusions with a DNA fragment that contains the region between positions -105 and +80 and determined that deleting the region between positions -55 and -42 reduces the promoter activity by 64.5%. Transcriptional fusions in the B. subtilis DB2 chromosome also indicated that mutating the sequence markedly reduces the promoter activity. An in vitro transcription analysis confirmed that the transcription is inefficient when the sequence in this region is mutated. Electrophoretic mobility shift and footprinting analyses demonstrated that the C-terminal domain of the RNA polymerase alpha subunit binds to the region between positions -55 and -39. These results indicated that the sequence is an UP element. Finally, this UP element is critical for the production of fengycin, since mutating the UP sequence in the chromosome of B. subtilis F29-3 reduces the transcription of the fen operon by 85% and prevents the cells from producing enough fengycin to suppress the germination of Paecilomyces variotii spores on agar plates.

Real-time footprinting of DNA in the first kinetically significant intermediate in open complex formation by Escherichia coli RNA polymerase

The architecture of cellular RNA polymerases (RNAPs) dictates that transcription can begin only after promoter DNA bends into a deep channel and the start site nucleotide (+1) binds in the active site located on the channel floor. Formation of this transcriptionally competent "open" complex (RP(o)) by Escherichia coli RNAP at the lambdaP(R) promoter is greatly accelerated by DNA upstream of base pair -47 (with respect to +1). Here we report real-time hydroxyl radical (*OH) and potassium permanganate (KMnO4) footprints obtained under conditions selected for optimal characterization of the first kinetically significant intermediate (I(1)) in RP(o) formation. .OH footprints reveal that the DNA backbone from -71 to -81 is engulfed by RNAP in I(1) but not in RP(o); downstream protection extends to approximately +20 in both complexes. KMnO4 footprinting detects solvent-accessible thymine bases in RP(o), but not in I(1). We conclude that upstream DNA wraps more extensively on RNAP in I(1) than in RP(o) and that downstream DNA (-11 to +20) occupies the active-site channel in I(1) but is not yet melted. Mapping of the footprinting data onto available x-ray structures provides a detailed model of a kinetic intermediate in bacterial transcription initiation and suggests how transient contacts with upstream DNA in I(1) might rearrange the channel to favor entry of downstream duplex DNA.

The seven E. coli ribosomal RNA operon upstream regulatory regions differ in structure and transcription factor binding efficiencies

Ribosomal RNAs in E. coli are transcribed from seven operons, which are highly conserved in their organization and sequence. However, the upstream regulatory DNA regions differ considerably, suggesting differences in regulation. We have therefore analyzed the conformation of all seven DNA elements located upstream of the major E. coli rRNA P1 promoters. As judged by temperature-dependent gel electrophoresis with isolated DNA fragments comprising the individual P1 promoters and the complete upstream regulatory regions, all seven rRNA upstream sequences are intrinsically curved. The degree of intrinsic curvature was highest for the rrnB and rrnD fragments and less pronounced for the rrnA and rrnE operons. Comparison of the experimentally determined differences in curvature with programs for the prediction of DNA conformation revealed a generally high degree of conformity. Moreover, the analysis showed that the center of curvature is located at about the same position in all fragments. The different upstream regions were analyzed for their capacity to bind the transcription factors FIS and H-NS, which are known as antagonists in the regulation of rRNA synthesis. Gel retardation experiments revealed that both proteins interact with the upstream promoter regions of all seven rDNA fragments, with the affinities of the different DNA fragments for FIS and H-NS and the structure of the resulting complexes deviating considerably. FIS binding was non-cooperative, and at comparable protein concentrations the occupancy of the different DNA fragments varied between two and four binding sites. In contrast, H-NS was shown to bind cooperatively and intermediate states of occupancy could not be resolved for each fragment. The different gel electrophoretic mobilities of the individual DNA/protein complexes indicate variable structures and topologies of the upstream activating sequence regulatory complexes. Our results are highly suggestive of differential regulation of the individual rRNA operons.

Bacterial repression loops require enhanced DNA flexibility

The Escherichia coli lac operon provides a classic paradigm for understanding regulation of gene transcription. It is now appreciated that lac promoter repression involves cooperative binding of the bidentate lac repressor tetramer to pairs of lac operators via DNA looping. We have adapted components of this system to create an artificial assay of DNA flexibility in E.coli. This approach allows for systematic study of endogenous and exogenous proteins as architectural factors that enhance apparent DNA flexibility in vivo. We show that inducer binding does not completely remove repression loops but it does alter their geometries. Deletion of the E.coli HU protein drastically destabilizes small repression loops, an effect that can be partially overcome by expression of a heterologous mammalian HMG protein. These results emphasize that the inherent torsional inflexibility of DNA restrains looping and must be modulated in vivo.

The mechanism of upstream activation in the rrnB operon of Mycobacterium smegmatis is different from the Escherichia coli paradigm

Mycobacteria are slow-growing bacteria with a generation time of from 2-3 h up to several weeks. Consistent with the low growth rate, mycobacterial species have a maximum of two rRNA operons, rrnA and rrnB. The rrnA operon is present in all mycobacteria and has between two and five promoters, depending on species, whereas the rrnB operon, with a single promoter, is only found in some of the faster-growing species. The promoter region of the rrnB operon of a typical fast grower, Mycobacterium smegmatis, was investigated. By using lacZ reporter gene fusions it was demonstrated that the rrnB operon contains a highly activating region upstream of the core promoter, comparable to other bacterial rrn operons. However, the results suggest that, unlike the situation in, for example, Escherichia coli, the activating mechanism is solely factor dependent, and that no UP element is involved.

The effects of upstream DNA on open complex formation by Escherichia coli RNA polymerase

Binding of activators to upstream DNA sequences regulates transcription initiation by affecting the stability of the initial RNA polymerase (RNAP)-promoter complex and/or the rate of subsequent conformational changes required to form the open complex (RP(O)). Here we observe that the presence of nonspecific upstream DNA profoundly affects an early step in formation of the transcription bubble. Kinetic studies with the lambdaP(R) promoter and Escherichia coli RNAP reveal that the presence of DNA upstream of base pair -47 greatly increases the rate of forming RP(O), without significantly affecting its rate of dissociation. We find that this increase is largely due to an acceleration of the rate-limiting step (isomerization) in RP(O) formation, a step that occurs after polymerase binds. Footprinting experiments reveal striking structural differences downstream of the transcription start site (+1) in the first kinetically significant intermediate when upstream DNA is present. On the template strand, the DNase I downstream boundary of this early intermediate is +20 when upstream DNA is present but is shortened by approximately two helical turns when upstream DNA beyond -47 is removed. KMnO(4) footprinting reveals an identical initiation bubble (-11 to +2), but unusual reactivity of template strand upstream cytosines (-12, -14, and -15) on the truncated promoter. Based on this work, we propose that early wrapping interactions between upstream DNA and the polymerase exterior strongly affect the events that control entry and subsequent unwinding of the DNA start site in the jaws of polymerase.

Sequence-independent upstream DNA-alphaCTD interactions strongly stimulate Escherichia coli RNA polymerase-lacUV5 promoter association

The C-terminal domains of the two alpha-subunits (alphaCTD) in Escherichia coli RNA polymerase (RNAP) recognize specific sequences called UP elements in some promoters. These interactions can increase transcription dramatically. Previously, effects of upstream DNA-alphaCTD interactions on transcription were quantified relative to control promoters with nonspecific DNA sequences substituted for UP elements. However, contributions of nonspecific upstream DNA-alphaCTD interactions to promoter activity have not been evaluated extensively. Here, we examine effects of removal of alphaCTD, upstream promoter DNA, or both on the rate of open-complex formation with promoters that lack UP elements. Deletion of alphaCTD decreased the composite second-order association rate constant, k(a), of RNAP for the lacUV5 promoter by approximately 10-fold. Much of this effect was attributable to a decrease in the isomerization rate constant, k(2). Removal of promoter DNA upstream of the -35 element also decreased both k(a) and k(2) approximately 10-fold. Upstream DNA extending approximately to base pair -100 was sufficient for maximal association rates of wild-type RNAP with lacUV5 promoter fragments. The alphaCTD and upstream DNA did not affect dissociation rates from the open complex. We suggest that sequence-independent upstream DNA interactions with alphaCTD are major contributors to initiation at many (or all) promoters (not merely promoters containing UP elements) and that these interactions facilitate isomerization events occurring well downstream of the alpha-binding sites. In addition to highlighting the functional importance of nonspecific protein-DNA interactions, these results suggest also that UP element-alphaCTD interactions play an even larger role in transcription initiation than appreciated previously.

Activation of transcription initiation from a stable RNA promoter by a Fis protein-mediated DNA structural transmission mechanism

The leuV operon of Escherichia coli encodes three of the four genes for the tRNA1Leu isoacceptors. Transcription from this and other stable RNA promoters is known to be affected by a cis-acting UP element and by Fis protein interactions with the carboxyl-terminal domain of the alpha-subunits of RNA polymerase. In this report, we suggest that transcription from the leuV promoter also is activated by a Fis-mediated, DNA supercoiling-dependent mechanism similar to the IHF-mediated mechanism described previously for the ilvP(G) promoter (S. D. Sheridan et al., 1998, J Biol Chem 273: 21298-21308). We present evidence that Fis binding results in the translocation of superhelical energy from the promoter-distal portion of a supercoiling-induced DNA duplex destabilized (SIDD) region to the promoter-proximal portion of the leuV promoter that is unwound within the open complex. A mutant Fis protein, which is defective in contacting the carboxyl-terminal domain of the alpha-subunits of RNA polymerase, remains competent for stimulating open complex formation, suggesting that this DNA supercoiling-dependent component of Fis-mediated activation occurs in the absence of specific protein interactions between Fis and RNA polymerase. Fis-mediated translocation of superhelical energy from upstream binding sites to the promoter region may be a general feature of Fis-mediated activation of transcription at stable RNA promoters, which often contain A+T-rich upstream sequences.

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.

Sphingolipids are essential for differentiation but not growth in Leishmania

Sphingolipids (SLs) play critical roles in eukaryotic cells in the formation of lipid rafts, membrane trafficking, and signal transduction. Here we created a SL null mutant in the protozoan parasite Leishmania major through targeted deletion of the key de novo biosynthetic enzyme serine palmitoyltransferase subunit 2 (SPT2). Although SLs are typically essential, spt2- Leishmania were viable, yet were completely deficient in de novo sphingolipid synthesis, and lacked inositol phosphorylceramides and other SLs. Remarkably, spt2- parasites maintained 'lipid rafts' as defined by Triton X-100 detergent resistant membrane formation. Upon entry to stationary phase spt2- failed to differentiate to infective metacyclic parasites and died instead. Death occurred not by apoptosis or changes in metacyclic gene expression, but from catastrophic problems leading to accumulation of small vesicles characteristic of the multivesicular body/multivesicular tubule network. Stage specificity may reflect changes in membrane structure as well as elevated demands in vesicular trafficking required for parasite remodeling during differentiation. We suggest that SL-deficient Leishmania provide a useful biological setting for tests of essential SL enzymes in other organisms where SL perturbation is lethal.

Mechanism of transcriptional activation by FIS: role of core promoter structure and DNA topology

The Escherichia coli DNA architectural protein FIS activates transcription from stable RNA promoters on entry into exponential growth and also reduces the level of negative supercoiling. Here we show that such a reduction decreases the activity of the tyrT promoter but that activation by FIS rescues tyrT transcription at non-optimal superhelical densities. Additionally we show that three different "up" mutations in the tyrT core promoter either abolish or reduce the dependence of tyrT transcription on both high negative superhelicity and FIS in vivo and infer that the specific sequence organisation of the core promoter couples the control of transcription initiation by negative superhelicity and FIS. In vitro all the mutations potentiate FIS-independent untwisting of the -10 region while at the wild-type promoter FIS facilitates this step. We propose that this untwisting is a crucial limiting step in the initiation of tyrT RNA synthesis. The tyrT core promoter structure is thus optimised to combine high transcriptional activity with acute sensitivity to at least three major independent regulatory inputs: negative superhelicity, FIS and ppGpp.

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.

DNA topology-mediated control of global gene expression in Escherichia coli

Because the level of DNA superhelicity varies with the cellular energy charge, it can change rapidly in response to a wide variety of altered nutritional and environmental conditions. This is a global alteration, affecting the entire chromosome and the expression levels of all operons whose promoters are sensitive to superhelicity. In this way, the global pattern of gene expression may be dynamically tuned to changing needs of the cell under a wide variety of circumstances. In this article, we propose a model in which chromosomal superhelicity serves as a global regulator of gene expression in Escherichia coli, tuning expression patterns across multiple operons, regulons, and stimulons to suit the growth state of the cell. This model is illustrated by the DNA supercoiling-dependent mechanisms that coordinate basal expression levels of operons of the ilv regulon both with one another and with cellular growth conditions.

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.

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.

RNA polymerase--promoter recognition. Specific features of electrostatic potential of "early" T4 phage DNA promoters

Comparative analysis of electrostatic potential distribution for "early" T4 phage promoters was undertaken, along with calculation of topography of electrostatic potential around the native and ADP-ribosylated C-terminal domain of RNA polymerase alpha-subunit. The data obtained indicate that there is specific difference in the patterns of electrostatic potential distribution in far upstream regions of T4 promoters differing by their response to ADP-ribosylation of RNA polymerase. A specific change in profiles of electrostatic potential distribution for the native and ADP-ribosylated forms of RNA polymerase alpha-subunit was observed suggesting that this factor may be responsible for modulating T4 promoter activities in response to the enzyme modification.

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 bacterial DNA-binding protein H-NS represses ribosomal RNA transcription by trapping RNA polymerase in the initiation complex

The interaction of the bacterial regulatory protein H-NS with RNA polymerase and the ribosomal RNA P1 promoter was analyzed to better understand the mechanism of H-NS-dependent transcriptional repression. We could show that initial binding of RNA polymerase to the promoter was not inhibited by the simultaneous interaction of H-NS, although H-NS binding sites extend into the core promoter region. Binding of sigma(70)-saturated RNA polymerase and H-NS to the promoter DNA occurs cooperatively and results in a stable complex of slower gel electrophoretic mobility as compared to complexes formed with the single proteins. The presence of the upstream curved H-NS binding site contributes strongly to the cooperative RNA polymerase-promoter interaction. By KMnO(4) modification of single-stranded template nucleotides we could show that open complex formation at the rrnB P1 promoter was not inhibited by H-NS binding. An increased KMnO(4) reactivity of several positions within the open complex rather supports the view that open complex formation is stimulated in presence of H-NS. Moreover, subtle changes in the modification pattern indicate that the open complex formed in the presence of H-NS are structurally distinct from the H-NS-free complex. In vitro transcriptional analysis of the abortive and productive yields revealed that the formation of transcription products longer than three nucleotides is dramatically reduced in the presence of H-NS, while the amount of shorter abortive products remained unaffected. Together the results demonstrate that H-NS inhibits transcription at the rrnB P1 promoter not by interfering with initial RNA polymerase binding but by blocking chain elongation steps subsequent to the first (two) phosphodiester bond formations. The mechanism of H-NS dependent repression at rRNA promoters can thus be explained as a trap which inhibits substrate NTP incorporation beyond template position +3 into the initial transcribing complex.

Reiterative transcription initiation from galP2 promoter of Escherichia coli

The expression of gal operon in Escherichia coli is driven by two promoters, P1 and P2 separated by 5 bp. The transcription initiated from the P2 generates a large amount of abortive transcripts to produce a comparable amount of full-length transcript as P1 in vitro. In this study, we investigated the source of the abortive transcripts by employing a quantitative potassium permanganate footprinting method that determines the extent of open promoter complex formation. The extents of open promoter complex formation at the two gal promoters were about the same during the given reaction time while the amount of transcription initiation determined by in vitro transcription assay showed a considerable difference: several hundred-fold more transcription initiation from the P2 than the P1, most of which was abortive. Thus, it was concluded that the abortive transcripts are generated reiteratively by a small fraction of RNA polymerase. An in vitro transcription assay using an immobilized DNA template revealed that the fraction of RNA polymerase generating abortive transcripts never produces the full-length transcript and it remains bound to the promoter. We concluded that there are two kinds of RNA polymerase-promoter complexes formed at galP2, at least in vitro, productive complex and nonproductive complex; and, the nonproductive complex is responsible for generating large amount of abortive transcripts from the P2.

A DNA architectural protein couples cellular physiology and DNA topology in Escherichia coli

In Escherichia coli, the transcriptional activity of many promoters is strongly dependent on the negative superhelical density of chromosomal DNA. This, in turn, varies with the growth phase, and is correlated with the overall activity of DNA gyrase, the major topoisomerase involved in the elevation of negative superhelicity. The DNA architectural protein FIS is a regulator of the metabolic reorganization of the cell during early exponential growth phase. We have previously shown that FIS modulates the superhelical density of plasmid DNA in vivo, and on binding reshapes the supercoiled DNA in vitro. Here, we show that, in addition, FIS represses the gyrA and gyrB promoters and reduces DNA gyrase activity. Our results indicate that FIS determines DNA topology both by regulation of topoisomerase activity and, as previously inferred, by directly reshaping DNA. We propose that FIS is involved in coupling cellular physiology to the topology of the bacterial chromosome.

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.

An inactive open complex mediated by an UP element at Escherichia coli promoters

A specific interaction between the alpha subunit of RNA polymerase and an A+T-rich upstream sequence (UP element) stimulates transcription at some promoters in Escherichia coli. We found that RNA polymerase formed a heparin-resistant nonproductive initiation complex at the malT promoter which has an A+T-rich upstream sequence that begins 9 bp upstream of the -35 region. Substitution of other sequences for the A+T-rich sequence eliminated both the formation of heparin-resistant complexes and alpha binding to the malT promoter. A 5-bp deletion between the A+T-rich sequence and the -35 region increased promoter activity. The UP element derived from the rrnB P1 promoter stimulated transcription of the malT core promoter when placed 4 bp upstream from the malT -35 region, but insertion of an additional 4 bp between the rrnB P1 UP element and the -35 element eliminated transcription activity without eliminating heparin-resistant complex formation. Similar UP element effects were observed in hybrids with the lac core promoter, even though the region around the transcription start site was melted in both productive and nonproductive complexes. We conclude that UP elements can mediate the formation of both productive and nonproductive open complexes, depending on their location with respect to the core promoter.

Promoter upstream bent DNA activates the transcription of the Clostridium perfringens phospholipase C gene in a low temperature-dependent manner

The phospholipase C gene (plc) of Clostridium perfringens possesses three phased A-tracts forming bent DNA upstream of the promoter. An in vitro transcription assay involving C.perfringens RNA polymerase (RNAP) showed that the phased A-tracts have a stimulatory effect on the plc promoter, and that the effect is proportional to the number of A-tracts, and more prominent at lower temperature. A gel retardation assay and hydroxyl radical footprinting revealed that the phased A-tracts facilitate the formation of the RNAP-plc promoter complex through extension of the contact region. The upstream (UP) element of the Escherichia coli rrnB P1 promoter stimulated the downstream promoter activity temperature independently, differing from the phased A-tracts. When the UP element was placed upstream of the plc promoter, low temperature-dependent stimulation was observed, although this effect was less prominent than that of the phased A-tracts. These results suggest that both the phased A-tracts and UP element cause low temperature-dependent activation of the plc promoter through a similar mechanism, and that the more efficient low temperature-dependent activation by the phased A-tracts may be due to an increase in the bending angle at a lower temperature.

Conformational changes of the upstream DNA mediated by H-NS and FIS regulate E. coli RrnB P1 promoter activity

The two proteins FIS and H-NS had previously been shown to regulate ribosomal RNA (rRNA) transcription by interacting with the promoter upstream DNA. FIS is known as an activator whereas H-NS had been demonstrated to function as a repressor. Details of the antagonistic control mechanisms are not yet solved. Here, we have addressed the question how the two proteins cooperate to exert both, positive and negative control of rRNA transcription. By mobility shift experiments and footprinting studies we show that FIS and H-NS binding sites partially overlap but appear to interact with different sites of a curved DNA helix. Although not mutually exclusive, the two proteins compete each other for binding. Both proteins, by changing the DNA curvature, effect circularization reactions of DNA fragments in different ways. Our results imply that binding of the proteins induces alternate DNA conformations with favourable or unfavourable topology for the formation of active transcription complexes. Together the findings presented here help to answer some of the open questions about the concerted molecular mechanism of transcription factors for the regulation of stable RNA synthesis.

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

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

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.

Regulation of crp transcription by oscillation between distinct nucleoprotein complexes

FIS belongs to the group of small abundant DNA-binding proteins of Escherichia coli. We recently demonstrated that, in vivo, FIS regulates the expression of several genes needed for catabolism of sugars and nucleic acids, a majority of which are also transcriptionally regulated by cAMP-cAMP-receptor protein (CRP) complex. Here we provide evidence that FIS represses transcription of the crp gene both in vivo and in vitro. Employing crp promoter-lacZ fusions, we demonstrate that both FIS and cAMP-CRP are required to keep the crp promoter in a repressed state. We have identified in the crp promoter other transcription initiation sites which are located 73, 79 and 80 bp downstream from the previously mapped start site. Two CRP- and several FIS-binding sites with different affinities are located in the crp promoter region, one of them overlapping the downstream transcription initiation sites. We show that initiation of transcription at the crp promoter is affected by the composition of nucleoprotein complexes resulting from the outcome of competition between proteins for overlapping binding sites. Our results suggest that the control of crp transcription is achieved by oscillation in the composition of these regulatory nucleoprotein complexes in response to the physiological state of the cell.

Activation of Escherichia coli rRNA transcription by FIS during a growth cycle

rRNA transcription in Escherichia coli is activated by the FIS protein, which binds upstream of rrnp1 promoters and interacts directly with RNA polymerase. Analysis of the contribution of FIS to rrn transcription under changing physiological conditions is complicated by several factors: the wide variation in cellular FIS concentrations with growth conditions, the contributions of several other regulatory systems to rRNA synthesis, and the pleiotropy of fis mutations. In this report, we show by in vivo footprinting and Western blot analysis that occupancy of the rrnBp1 FIS sites correlates with cellular levels of FIS. We find, using two methods of measurement (pulse induction of a FIS-activated hybrid promoter and primer extension from an unstable transcript made from rrnBp1), that the extent of transcription activation by FIS parallels the degree of FIS site occupancy and therefore cellular FIS levels. FIS activates transcription throughout exponential growth at low culture density, but rrnp1 transcription increases independently of FIS immediately following upshift, before FIS accumulates. These results support the model that FIS is one of a set of overlapping signals that together contribute to transcription from rrnp1 promoters during steady-state growth.

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

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

DNA bending and the curious case of Fos/Jun

DNA bending has been implicated as an important regulatory mechanism in several processes involving protein-DNA interactions. Various methods for examining intrinsic and protein-induced DNA bending may lead to different conclusions. For the Fos and Jun transcription factors, this has resulted in controversy over whether these factors significantly bend DNA at all.

Information analysis of Fis binding sites

Originally discovered in the bacteriophage Mu DNA inversion system gin, Fis (Factor for Inversion Stimulation) regulates many genetic systems. To determine the base frequency conservation required for Fis to locate its binding sites, we collected a set of 60 experimentally defined wild-type Fis DNA binding sequences. The sequence logo for Fis binding sites showed the significance and likely kinds of base contacts, and these are consistent with available experimental data. Scanning with an information theory based weight matrix within fis, nrd, tgt/sec and gin revealed Fis sites not previously identified, but for which there are published footprinting and biochemical data. DNA mobility shift experiments showed that a site predicted to be 11 bases from the proximal Salmonella typhimurium hin site and a site predicted to be 7 bases from the proximal P1 cin site are bound by Fis in vitro. Two predicted sites separated by 11 bp found within the nrd promoter region, and one in the tgt/sec promoter, were also confirmed by gel shift analysis. A sequence in aldB previously reported to be a Fis site, for which information theory predicts no site, did not shift. These results demonstrate that information analysis is useful for predicting Fis DNA binding.

Induction and repair of cyclobutane pyrimidine dimers in the Escherichia coli tRNA gene tyrT: Fis protein affects dimer induction in the control region and suppresses preferential repair in the coding region of the transcribed strand, except in a short region near the transcription start site

We analysed induction and repair of UV induced pyrimidine dimers in the Escherichia coli tRNA gene tyrT. In wild-type (WT) log or stationary phase different patterns of induction occurred in the three Fis binding sites and the core promoter -35 sequence of the control region: this was absent in fis- cells. In stationary WT cells, slow, similar rates of repair occurred throughout the non-transcribed strand (NTS). Faster repair occurred in the NTS control region in WT log phase. NTS repair in fis- cells was similar, except the control region differed less between phases. Heterogeneous repair occurred along the transcribed strand (TS). In the control region repair was faster than in the NTS. Repair in the TS coding region changed between growth phases or if repair took place in different media. When irradiated log phase WT cells were in rich medium, two TS domains were evident: a fast-repaired domain within 31 nucleotides from the transcription start site; and a more slowly repaired domain composed of the rest of the TS. A sharp gradient existed in the small domain with very fast repair at the beginning and diminished repair towards the end. Fast transcription coupled repair (TCR) in the small domain was absent in the TS large domain, where repair was similar to the NTS and to the entire TS in mfd- cells. In similarly treated stationary phase WT cells, TCR occurred in the large domain. Depletion of Fis reinstates TCR to a lesser extent, whilst a substitution of five nucleotides at the Fis binding sites in the upstream activating sequence reinstates TCR. Reinstatement of TCR was also achieved by incubating irradiated WT cells in minimal salt medium without the required amino acid. Our results suggest that Fis indirectly suppresses preferential repair in the TS large domain by stimulating transcription.

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

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

rRNA transcription and growth rate-dependent regulation of ribosome synthesis in Escherichia coli

The synthesis of ribosomal RNA is the rate-limiting step in ribosome synthesis in bacteria. There are multiple mechanisms that determine the rate of rRNA synthesis. Ribosomal RNA promoter sequences have evolved for exceptional strength and for regulation in response to nutritional conditions and amino acid availability. Strength derives in part from an extended RNA polymerase (RNAP) recognition region involving at least two RNAP subunits, in part from activation by a transcription factor and in part from modification of the transcript by a system that prevents premature termination. Regulation derives from at least two mechanistically distinct systems, growth rate-dependent control and stringent control. The mechanisms contributing to rRNA transcription work together and compensate for one another when individual systems are rendered inoperative.

A positive control mutant of the transcription activator protein FIS

The FIS protein is a transcription activator of rRNA and other genes in Escherichia coli. We have identified mutants of the FIS protein resulting in reduced rrnB P1 transcription activation that nevertheless retain the ability to bind DNA in vivo. The mutations map to amino acid 74, the N-terminal amino acid of the protein's helix-turn-helix DNA binding motif, and to amino acids 71 and 72 in the adjoining surface-exposed loop. In vitro analyses of one of the activation-defective mutants (with a G-to-S mutation at position 72) indicates that it binds to and bends rrnB P1 FIS site I DNA the same as wild-type FIS. These data suggest that amino acids in this region of FIS are required for transcription activation by contacting RNA polymerase directly, independent of any other role(s) this region may play in DNA binding or protein-induced bending.

DNA-binding determinants of the alpha subunit of RNA polymerase: novel DNA-binding domain architecture

The Escherichia coli RNA polymerase alpha-subunit binds through its carboxy-terminal domain (alpha CTD) to a recognition element, the upstream (UP) element, in certain promoters. We used genetic and biochemical techniques to identify the residues in alpha CTD important for UP-element-dependent transcription and DNA binding. These residues occur in two regions of alpha CTD, close to but distinct from, residues important for interactions with certain transcription activators. We used NMR spectroscopy to determine the secondary structure of alpha CTD, alpha CTD contains a nonstandard helix followed by four alpha-helices. The two regions of alpha CTD important for DNA binding correspond to the first alpha-helix and the loop between the third and fourth alpha-helices. The alpha CTD DNA-binding domain architecture is unlike any DNA-binding architecture identified to date, and we propose that alpha CTD has a novel mode of interaction with DNA. Our results suggest models for alpha CTD-DNA and alpha CTD-DNA-activator interactions during transcription initiation.

Control of rRNA transcription in Escherichia coli

The control of rRNA synthesis in response to both extra- and intracellular signals has been a subject of interest to microbial physiologists for nearly four decades, beginning with the observations that Salmonella typhimurium cells grown on rich medium are larger and contain more RNA than those grown on poor medium. This was followed shortly by the discovery of the stringent response in Escherichia coli, which has continued to be the organism of choice for the study of rRNA synthesis. In this review, we summarize four general areas of E. coli rRNA transcription control: stringent control, growth rate regulation, upstream activation, and anti-termination. We also cite similar mechanisms in other bacteria and eukaryotes. The separation of growth rate-dependent control of rRNA synthesis from stringent control continues to be a subject of controversy. One model holds that the nucleotide ppGpp is the key effector for both mechanisms, while another school holds that it is unlikely that ppGpp or any other single effector is solely responsible for growth rate-dependent control. Recent studies on activation of rRNA synthesis by cis-acting upstream sequences has led to the discovery of a new class of promoters that make contact with RNA polymerase at a third position, called the UP element, in addition to the well-known -10 and -35 regions. Lastly, clues as to the role of antitermination in rRNA operons have begun to appear. Transcription complexes modified at the antiterminator site appear to elongate faster and are resistant to the inhibitory effects of ppGpp during the stringent response.

Effects of different growth conditions on the in vivo activity of the tandem Escherichia coli ribosomal RNA promoters P1 and P2

We have analyzed the relative activities of the Escherichia coli ribosomal RNA promoters P1 and P2 in vivo under different physiological conditions. Promoter efficiencies were determined by quantitative comparison of the transcript-specific primer extension products obtained from total RNA preparations. Cells were analyzed at different stages of the growth cycle, at different growth rates, and under conditions of stringent control. In addition, the rRNA gene dosage was altered by transformation with plasmids containing additional rrnD or rrnB transcription units, or rRNA operons in which one of the tandem promoters (P1) had been deleted. Under conditions of amino acid starvation (stringent control) we observed the expected strong reduction in P1-directed transcription. In contrast to the previous assumption that the P2 promoter is not regulated, we simultaneously noticed a smaller but significant repression of P2-directed transcription. In strains in which the rRNA gene dosage was increased by transformation with plasmids bearing rRNA transcription units, a similar degree of repression was observed. Repression of the P1 promoter activity was increased, however, when cells contained extra rRNA operons with P2 promoters only. As demonstrated under stringent control conditions, changes in the growth cycle also affected the activity of promoters P1 and P2. A greater proportion of P2-derived transcripts was observed when cells changed from exponential to stationary growth or if cultures were grown in minimal medium. Under steady-state, slow growth conditions (minimal medium) we obtained evidence showing that the ratio of P1/P2 transcription products is much lower for cells with extra rrnB as compared to extra rrnD operons or cells lacking extra rRNA operons, implying an operon-specific regulation.(ABSTRACT TRUNCATED AT 250 WORDS)

Transcription activation at the Escherichia coli uhpT promoter by the catabolite gene activator protein

Transport and utilization of sugar phosphates in Escherichia coli depend on the transport protein encoded by the uhpT gene. Transmembrane induction of uhpT expression by external glucose 6-phosphate is positively regulated by the promoter-specific activator protein UhpA and the global regulator catabolite gene activator protein (CAP). Activation by UhpA requires a promoter element centered at -64 bp, relative to the start of transcription, and activation by CAP requires a DNA site centered at position -103.5. This DNA site binds the cyclic AMP-CAP complex in vitro, and its deletion from the promoter reduces transcription activity to 7 to 9% of the wild-type level. Ten uhpT promoter derivatives with altered spacing between the DNA site for CAP and the remainder of the promoter were constructed. Their transcription activities indicated that the action of CAP at this promoter is dependent on proper helical phasing of promoter elements, with CAP binding on the same face of the helix as RNA polymerase does. Five CAP mutants defective in transcription activation at class I and class II CAP-dependent promoters but not defective in DNA binding or DNA bending (positive control mutants) were tested for the ability to activate transcription. These CAPpc mutants exhibited little or no defect in transcription activation at uhpT, indicating that CAP action at uhpTp involves a different mechanism than that which is used for its action at other classes of CAP-dependent promoters.

Characterization of the activating region of Escherichia coli catabolite gene activator protein (CAP). II. Role at Class I and class II CAP-dependent promoters

CAP-dependent promoters can be divided into classes based on the position of the DNA site for CAP. In class I CAP-dependent promoters, the DNA site for CAP is located upstream of the DNA site for polymerase; the DNA site for CAP can be located at various distances from the transcription start point, provided that the DNS site for CAP and the DNA site for RNA polymerase are on the same face of the DNA helix. In class II CAP-dependent promoters, the DNA site for CAP overlaps the DNA site for RNA polymerase, replacing the -35 determinants for binding of RNA polymerase. In previous work, we have shown that a surface loop consisting of amino acid residues 152 to 166 of CAP is essential for transcription activation at the best-characterized class I CAP-dependent promoter, the lac promoter, and we proposed that this surface loop makes direct protein-protein contact with RNA polymerase in the ternary complex of lac promoter, CAP, and RNA polymerase. Here, we show that the surface loop consisting of amino acid residues 152 to 166 is essential for transcription activation at other class I CAP-dependent promoters and at a class II CAP-dependent promoter. We show further that the effects of alanine substitutions of residues 152 to 166 are qualitatively identical at the lac promoter and other class I CAP-dependent promoters, but are different at a class II CAP-dependent promoter. We propose that the surface loop consisting of residues 152 to 166 makes identical molecular interactions in transcription activation at all class I CAP-dependent promoters, irrespective of distance between the DNA site for CAP and the transcription start point, but makes a different set of molecular interactions in transcription activation at class II CAP-dependent promoters.

Domain organization of RNA polymerase alpha subunit: C-terminal 85 amino acids constitute a domain capable of dimerization and DNA binding

Using limited proteolysis, we show that the Escherichia coli RNA polymerase alpha subunit consists of an N-terminal domain comprised of amino acids 8-241, a C-terminal domain comprised of amino acids 249-329, and an unstructured and/or flexible interdomain linker. We have carried out a detailed structural and functional analysis of an 85 amino acid proteolytic fragment corresponding to the C-terminal domain (alpha CTD-2). Our results establish that alpha CTD-2 has a defined secondary structure (approximately 40% alpha helix, approximately 0% beta sheet). Our results further establish that alpha CTD-2 is a dimer and that alpha CTD-2 exhibits sequence-specific DNA binding activity. Our results suggest a model for the mechanism of involvement of alpha in transcription activation by promoter upstream elements and upstream-binding activator proteins.