Supercoiling, integration host factor, and a dual promoter system, participate in the control of the bacteriophage lambda pL promoter

Role of cis-acting sites in stimulation of the phage λ P(RM) promoter by CI-mediated looping

The lysogenic state of phage λ is maintained by the CI repressor. CI binds to three operators each in the right operator (O(R)) and left operator (O(L)) regions, which lie 2.4 kb apart. At moderate CI levels, the predominant binding pattern is two dimers of CI bound cooperatively at each regulatory region. The resulting tetramers can then interact, forming an octamer and a loop of the intervening DNA. CI is expressed from the P(RM) promoter, which lies in the O(R) region and is subjected to multiple regulatory controls. Of these, the most recently discovered is stimulation by loop formation. In this work, we have investigated the mechanism by which looping stimulates P(RM). We find that two cis-acting sites lying in the O(L) region are involved. One site, an UP element, is required for stimulation. Based on the behavior of other promoters with UP elements located upstream of the -35 region, we suggest that a subunit of RNA polymerase (RNAP) bound at P(RM) binds to the UP element located in the O(L) region. In addition, adjacent to the UP element lies a binding site for integration host factor (IHF); this site plays a less critical role but is required for stimulation of the weak prm240 allele. A loop with CI at the O(L)2 and O(L)3 operators does not stimulate P(RM), while one with CI only at O(L)2 provides some stimulation. We discuss possible mechanisms for stimulation.

Multilevel autoregulation of λ repressor protein CI by DNA looping in vitro

The prophage state of bacteriophage λ is extremely stable and is maintained by a highly regulated level of λ repressor protein, CI, which represses lytic functions. CI regulates its own synthesis in a lysogen by activating and repressing its promoter, P(RM). CI participates in long-range interactions involving two regions of widely separated operator sites by generating a loop in the intervening DNA. We investigated the roles of each individual site under conditions that permitted DNA loop formation by using in vitro transcription assays for the first time on supercoiled DNA that mimics in vivo situation. We confirmed that DNA loops generated by oligomerization of CI bound to its operators influence the autoactivation and autorepression of P(RM) regulation. We additionally report that different configurations of DNA loops are central to this regulation--one configuration further enhances autoactivation and another is essential for autorepression of P(RM).

Influence of the Escherichia coli oxyR gene function on lambda prophage maintenance

In Escherichia coli hosts, hydrogen peroxide is one of the factors that may cause induction of λ prophage. Here, we demonstrate that H₂O₂-mediated λ prophage induction is significantly enhanced in the oxyR mutant host. The mRNA levels for cI gene expression were increased in a λ lysogen in the presence of H₂O₂. On the other hand, stimulation of the p_M promoter by cI857 overproduced from a multicopy plasmid was decreased in the ΔoxyR mutant in the presence of H₂O₂ but not under normal growth conditions. The purified OxyR protein did bind specifically to the p_M promoter region. This binding impaired efficiency of interaction of the cI protein with the OR3 site, while stimulating such a binding to OR2 and OR1 sites, in the regulatory region of the p_M promoter. We propose that changes in cI gene expression, perhaps in combination with moderately induced SOS response, may be responsible for enhanced λ prophage induction by hydrogen peroxide in the oxyR mutant. Therefore, OxyR seems to be a factor stimulating λ prophage maintenance under conditions of oxidative stress. This proposal is discussed in the light of efficiency of induction of lambdoid prophages bearing genes coding for Shiga toxins.

The C-terminal domain of the Escherichia coli RNA polymerase alpha subunit plays a role in the CI-dependent activation of the bacteriophage lambda pM promoter

The bacteriophage lambda p(M) promoter is required for maintenance of the lambda prophage in Escherichia coli, as it facilitates transcription of the cI gene, encoding the lambda repressor (CI). CI levels are maintained through a transcriptional feedback mechanism whereby CI can serve as an activator or a repressor of p(M). CI activates p(M) through cooperative binding to the O(R)1 and O(R)2 sites within the O(R) operator, with the O(R)2-bound CI dimer making contact with domain 4 of the RNA polymerase sigma subunit (sigma(4)). Here we demonstrate that the 261 and 287 determinants of the C-terminal domain of the RNA polymerase alpha subunit (alphaCTD), as well as the DNA-binding determinant, are important for CI-dependent activation of p(M). We also show that the location of alphaCTD at the p(M) promoter changes in the presence of CI. Thus, in the absence of CI, one alphaCTD is located on the DNA at position -44 relative to the transcription start site, whereas in the presence of CI, alphaCTD is located at position -54, between the CI-binding sites at O(R)1 and O(R)2. These results suggest that contacts between CI and both alphaCTD and sigma are required for efficient CI-dependent activation of p(M).

Transcription start sites in the promoter region of the Escherichia coli pcnB (plasmid copy number) gene coding for poly(A) polymerase I

Escherichia coli pcnB gene was discovered as a regulator of ColE1 plasmid copy number about 20 years ago. Further studies indicated that this gene codes for poly(A) polymerase I (PAP I). However, although importance of RNA polyadenylation has been demonstrated and biochemical properties of PAP I have been studied extensively, little is known about regulation of the pcnB gene transcription. Here, we demonstrate that there are three transcription start sites upstream of the pcnB coding sequence. Activities of at least two of these promoters were in inverse correlation to bacterial growth rates, which agrees with recently published results indicating increased abundance of PAP I and higher levels of RNA polyadenylation in slowly growing bacteria.

Ler is a negative autoregulator of the LEE1 operon in enteropathogenic Escherichia coli

Enteropathogenic Escherichia coli (EPEC) causes severe diarrhea in young children. Essential for colonization of the host intestine is the LEE pathogenicity island, which comprises a cluster of operons encoding a type III secretion system and related proteins. The LEE1 operon encodes Ler, which positively regulates many EPEC virulence genes in the LEE region and elsewhere in the chromosome. We found that Ler acts as a specific autorepressor of LEE1 transcription. We further show that Ler specifically binds upstream of the LEE1 operon in vivo and in vitro. A comparison of the Ler affinities to different DNA regions suggests that the autoregulation mechanism limits the steady-state level of Ler to concentrations that are just sufficient for activation of the LEE2 and LEE3 promoters and probably other LEE promoters. This mechanism may reflect the need of EPEC to balance maximizing the colonization efficiency by increasing the expression of the virulence genes and minimizing the immune response of the host by limiting their expression. In addition, we found that the autoregulation mechanism reduces the cell-to-cell variability in the levels of LEE1 expression. Our findings point to a new negative regulatory circuit that suppresses the noise and optimizes the expression levels of ler and other LEE1 genes.

Mechanism of transcription activation at the comG promoter by the competence transcription factor ComK of Bacillus subtilis

The development of genetic competence in Bacillus subtilis is regulated by a complex signal transduction cascade, which results in the synthesis of the competence transcription factor, encoded by comK. ComK is required for the transcription of the late competence genes that encode the DNA binding and uptake machinery and of genes required for homologous recombination. In vivo and in vitro experiments have shown that ComK is responsible for transcription activation at the comG promoter. In this study, we investigated the mechanism of this transcription activation. The intrinsic binding characteristics of RNA polymerase with and without ComK at the comG promoter were determined, demonstrating that ComK stabilizes the binding of RNA polymerase to the comG promoter. This stabilization probably occurs through interactions with the upstream DNA, since a deletion of the upstream DNA resulted in an almost complete abolishment of stabilization of RNA polymerase binding. Furthermore, a strong requirement for the presence of an extra AT box in addition to the common ComK-binding site was shown. In vitro transcription with B. subtilis RNA polymerase reconstituted with wild-type alpha-subunits and with C-terminal deletion mutants of the alpha-subunits was performed, demonstrating that these deletions do not abolish transcription activation by ComK. This indicates that ComK is not a type I activator. We also show that ComK is not required for open complex formation. A possible mechanism for transcription activation is proposed, implying that the major stimulatory effect of ComK is on binding of RNA polymerase.

Role of the RNA polymerase alpha subunits in CII-dependent activation of the bacteriophage lambda pE promoter: identification of important residues and positioning of the alpha C-terminal domains

The bacteriophage lambda CII protein stimulates the activity of three phage promoters, p(E), p(I) and p(aQ), upon binding to a site overlapping the -35 element at each promoter. Here we used preparations of RNA polymerase carrying a DNA cleavage reagent attached to specific residues in the C-terminal domain of the RNA polymerase alpha subunit (alphaCTD) to demonstrate that one alphaCTD binds near position -41 at p(E), whilst the other alphaCTD binds further upstream. The alphaCTD bound near position -41 is oriented such that its 261 determinant is in close proximity to sigma(70). The location of alphaCTD in CII-dependent complexes at the p(E) promoter is very similar to that found at many activator-independent promoters, and represents an alternative configuration for alphaCTD at promoters where activators bind sites overlapping the -35 region. We also used an in vivo alanine scan analysis to show that the DNA-binding determinant of alphaCTD is involved in stimulation of the p(E) promoter by CII, and this was confirmed by in vitro transcription assays. We also show that whereas the K271E substitution in alphaCTD results in a drastic decrease in CII-dependent activation of p(E), the p(I) and p(aQ) promoters are less sensitive to this substitution, suggesting that the role of alphaCTD at the three lysogenic promoters may be different.

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.

Effect of varying the supercoiling of DNA on transcription and its regulation

The effect of superhelicity of DNA templates on transcription is well documented in several cases. However, the amount of supercoiling that is needed to bring about any changes and the steps at which such effects are exerted were not systematically studied. We investigated the effect of DNA supercoiling on transcription from a set of promoters present on a plasmid by using a series of topoisomers with different superhelical densities ranging from totally relaxed to more than physiological. In vitro transcription assays with these topoisomers in the absence and presence of gene regulatory proteins showed that the effect of negative supercoiling on intrinsic transcription varies from promoter to promoter. Some of those promoters, in which DNA superhelicity stimulated transcription, displayed specific optima of superhelical density while others did not. The results also showed that the amounts of abortive RNA synthesis from two of the promoters decreased and full-length RNA increased with increasing supercoiling, indicating for the first time an inverse relationship between full-length and abortive RNA synthesis and supporting a role of DNA superhelicity in promoter clearance. DNA supercoiling might also influence the point of RNA chain termination. Furthermore, the effect of varying the amount of supercoiling on the action of gene regulatory proteins suggested the mode of action, which is consistent with previous results. Our results underscore the importance of DNA supercoiling in fine-tuning promoter activities, which should be relevant in cell physiology given that local changes in chromosomal supercoiling must occur in different environments.

Growth-rate dependent RNA polyadenylation in Escherichia coli

RNA polyadenylation occurs not only in eukaryotes but also in bacteria. In prokaryotes, polyadenylated RNA molecules are usually degraded more efficiently than non-modified transcripts. Here we demonstrate that two transcripts, which were shown previously to be substrates for poly(A) polymerase I (PAP I), Escherichia coli lpp messenger RNA and bacteriophage lambda oop RNA, are polyadenylated more efficiently in slowly growing bacteria than in rapidly growing bacteria. Intracellular levels of PAP I varied in inverse proportion to bacterial growth rate. Moreover, transcription from a promoter for the pcnB gene (encoding PAP I) was shown to be more efficient under conditions of low bacterial growth rates. We conclude that efficiency of RNA polyadenylation in E. coli is higher in slowly growing bacteria because of more efficient expression of the pcnB gene. This may allow regulation of the stability of certain transcripts (those subjected to PAP I-dependent polyadenylation) in response to various growth conditions.

The cell surface protein Ag43 facilitates phage infection of Escherichia coli in the presence of bile salts and carbohydrates

It was found that infection of Escherichia coli by bacteriophage lambda is inhibited in the presence of certain bile salts and carbohydrates when cells are in the "OFF" state for production of the phase-variable cell surface protein antigen 43 (Ag43). The inhibition of phage growth was found to be due to a significant impairment in the process of phage adsorption. Expression of the gene encoding Ag43 (agn43) from a plasmid or inactivation of the oxyR gene (encoding an activator of genes important for defence against oxidative stress) suppressed this inhibition. A mutation, rpoA341, in the gene encoding the alpha subunit of RNA polymerase also facilitated phage adsorption in the presence of bile salts and carbohydrates. The rpoA341 mutation promoted efficient production of Ag43 in a genetic background that would otherwise be in the "OFF" phase for expression of the agn43 gene. Analysis of a reporter gene fusion demonstrated that the promoter for the agn43 gene was more active in the rpoA341 mutant than in the otherwise isogenic rpoA(+) strain. The combined inhibitory action of bile salts and carbohydrates on phage adsorption and the abolition of this inhibition by production of Ag43 was not restricted to lambda, as a similar phenomenon was observed for the coliphages P1 and T4.

The regulation of pap and type 1 fimbriation in Escherichia coli

The ability of bacterial pathogens to bind to the host mucosa is a critical step in the pathogenesis of many bacterial infections and, for Escherichia coli, a large number of different fimbrial adhesins have been implicated as virulence factors. In this chapter, our current understanding of the regulatory mechanisms that control the expression of two of the best characterized fimbrial adhesins, pyelonephritis-associated pilus (encoded by pap) and the type 1 fimbria (encoded by fim), will be described. The expression of both fimbrial adhesins is controlled by phase variation (the reversible and apparently random switching between expressing ('on') and non-expressing ('off') states), and is regulated in response to environmental conditions. The phase variation of pap (and of some other fimbriae in Escherichia coli) is determined by the formation of alternative nucleoprotein complexes that either activate (phase 'on') or suppress (phase 'off') transcription of the fimbria genes. Formation of each complex protects a single Dam methylation site (5' GATC) from modification (GATCdist in phase 'on' cells and GATCprox in phase 'off' cells). Furthermore, complex formation is inhibited by methylation of the two 5' GATC sites. Both the phase variation of pap and the transcription of the pap genes in phase 'on' cells, are regulated and expression is subject to both positive and negative feedback control. In contrast to pap, the phase variation of fim is determined by the site-specific inversion of a short element of DNA (the fim switch). In phase 'on' cells, a promoter within the invertible element directs the transcription of the fim structural genes, whereas in phase 'off' cells transcription of the fimbrial genes is silenced. Despite the very different molecular mechanisms controlling the expression of pap and fim, the two systems share many features in common and have probably evolved to fulfill the same function. In addition to details about the molecular mechanisms that control pap and fim, the possible physiological significance of the observed regulation will be discussed.

The regulation of the Escherichia coli mazEF promoter involves an unusual alternating palindrome

The Escherichia coli mazEF system is a chromosomal "addiction module" that, under starvation conditions in which guanosine-3',5'-bispyrophosphate (ppGpp) is produced, is responsible for programmed cell death. This module specifies for the toxic stable protein MazF and the labile antitoxic protein MazE. Upstream from the mazEF module are two promoters, P(2) and P(3) that are strongly negatively autoregulated by MazE and MazF. We show that the expression of this module is positively regulated by the factor for inversion stimulation. What seems to be responsible for the negative autoregulation of mazEF is an unusual DNA structure, which we have called an "alternating palindrome." The middle part, "a," of this structure may complement either the downstream fragment, "b," or the upstream fragment, "c". When the MazE.MazF complex binds either of these arms of the alternating palindrome, strong negative autoregulation results. We suggest that the combined presence of the two promoters, the alternating palindrome structure and the factor for inversion stimulation-binding site, all permit the expression of the mazEF module to be sensitively regulated under various growth conditions.

Global gene expression profiling in Escherichia coli K12. The effects of integration host factor

We have used nylon membranes spotted in duplicate with full-length polymerase chain reaction-generated products of each of the 4,290 predicted Escherichia coli K12 open reading frames (ORFs) to measure the gene expression profiles in otherwise isogenic integration host factor IHF(+) and IHF(-) strains. Our results demonstrate that random hexamer rather than 3' ORF-specific priming of cDNA probe synthesis is required for accurate measurement of gene expression levels in bacteria. This is explained by the fact that the currently available set of 4,290 unique 3' ORF-specific primers do not hybridize to each ORF with equal efficiency and by the fact that widely differing degradation rates (steady-state levels) are observed for the 25-base pair region of each message complementary to each ORF-specific primer. To evaluate the DNA microarray data reported here, we used a linear analysis of variance (ANOVA) model appropriate for our experimental design. These statistical methods allowed us to identify and appropriately correct for experimental variables that affect the reproducibility and accuracy of DNA microarray measurements and allowed us to determine the statistical significance of gene expression differences between our IHF(+) and IHF(-) strains. Our results demonstrate that small differences in gene expression levels can be accurately measured and that the significance of differential gene expression measurements cannot be assessed simply by the magnitude of the fold difference. Our statistical criteria, supported by excellent agreement between previously determined effects of IHF on gene expression and the results reported here, have allowed us to identify new genes regulated by IHF with a high degree of confidence.

Replication of oriJ-based plasmid DNA during the stringent and relaxed responses of Escherichia coli

The oriJ-based plasmids contain the origin of DNA replication from the cryptic Rac prophage, present in the chromosomes of most Escherichia coli K-12 strains. The organization of the oriJ replication region resembles that of the bacteriophage lambda, although sequence similarity is small. Here we investigated the regulation of replication of the oriJ-based plasmid in E. coli relA(+) and relA(-) hosts during amino acid starvation and limitation, i.e., during the stringent and relaxed responses. We found that, contrary to plasmids derived from phage lambda, replication of the oriJ-based plasmid proceeds efficiently during both stringent and relaxed responses. On the other hand, density shift experiments and measurement of the stability of a putative replication initiator protein (the lambda O protein homologue) suggest that this replication may be carried out by the heritable replication complex, as previously demonstrated for lambda plasmids. We demonstrate that contrary to bacteriophage lambda p(R) promoter, an analogous promoter from the oriJ region is activated rather than inhibited at increased ppGpp levels. We propose that various responses of these promoters (p(R) and p(R-Rac), which are necessary for transcriptional activation of orilambda and perhaps oriJ, respectively) to ppGpp are responsible for differences in the replication regulation between orilambda- and oriJ-based plasmids during the stringent response.

Participation of IHF and a distant UP element in the stimulation of the phage lambda PL promoter

We have previously identified a UP element in the phage lambda PL promoter, centred at position -90 from the transcription start site. Integration host factor (IHF), a heterodimeric DNA-binding and -bending protein, binds upstream of the lambda PL promoter in a region overlapping the UP element. Stimulation of transcription by IHF requires an intact alphaCTD and affects the initial binding of RNA polymerase to the promoter. We propose a model for the stimulation of PL by IHF in which IHF bends the DNA to bring the distal UP sequence in closer proximity to the promoter core sequences to allow the docking of the alphaCTD of RNA polymerase. Furthermore, IHF may also participate in protein-protein interactions with the alphaCTD. In support of this model, we found that alanine substitutions in alphaCTD at positions 265, 268, 270 and 275 reduced PL promoter activity. Mutations in the IHF DNA binding site, as well as IHF mutant proteins exhibiting a decreased ability to bend the DNA, were both defective in stimulating the PL promoter. In addition, some of the mutated IHF residues are clustered at a protein surface that interacts with the UP DNA sequence. These residues may also participate in protein-protein interactions with the alphaCTD.

Maximal transcriptional activation by the IHF protein of Escherichia coli depends on optimal DNA bending by the activator

Transcriptional activation in prokaryotes can be mediated by at least two different mechanisms: direct contacts between the activator and RNA polymerase or modulation of the overall geometry of DNA. In the latter case, an activator protein that bends DNA favours contacts between the DNA upstream of the activator binding site and the back of RNA polymerase. The architectural protein integration host factor (IHF) of Escherichia coli bends DNA and activates transcription at several promoters. We have isolated mutants of IHF that maximize transcriptional activation by adjusting the bending angle of the DNA. The amino acid residues of IHF that adjust the bending angle are close to the DNA and probably make electrostatic interactions with the DNA. We show that transcriptional activation is maintained when the IHF binding site is moved further upstream or when its orientation is inverted, and we conclude from these data that direct interactions between IHF and RNA polymerase do not participate in activation. IHF acts merely by bending DNA; weaker bending leading to stronger activation. We propose that wild-type IHF induces too strong a DNA bend (180 degrees) for optimal interactions between DNA upstream of the IHF binding site and the back of RNA polymerase.

DnaA-mediated regulation of phage lambda-derived replicons in the absence of pR and Cro function

Bacteriophage lambda-derived replicons can replicate in Escherichia coli cells as plasmids. In the control of replication of these plasmids, an important role was ascribed to the lambda Cro repressor autoregulatory loop. However, the oR/pR-cro-tR-cII' region could be replaced by the ptetA promoter under the control of the TetR repressor, producing plasmid pTClambda. Here, we demonstrate that stable maintenance of pTClambda depends on the host DnaA function because deletion of one of DnaA-binding sequences present in pTClambda resulted in a decrease in the plasmid (pTClambda) copy number and poor maintenance of pTClambda in E. coli. Moreover, in contrast to the replication of the wild-type lambda plasmid, previously found to be positively regulated by DnaA (acting on a relaxed DnaA box situated immediately downstream of the pR promoter), the replication of pTC plasmids (devoid of pR) was found to be negatively regulated by DnaA. Contrary to wild-type lambda plasmids, in cells harboring lambda cro[temperature-sensitive (ts)] or pTClambda (but not pTClambda) plasmid, the lambda replication complex was heat shock resistant; this complex, however, disassembled after inactivation of DnaA function. This disassembly was blocked by DNA gyrase inhibitors. According to our model outlined previously, we propose that the heat shock resistance of the replication complex of lambdacro- plasmids depends on the interaction of the DNA-bound DnaA protein with the DNA-bound lambda replication complex. The replication complex-DnaA-lambda DNA structure may be directly related to the role of DnaA as the Cro-replacing negative regulator of lambdacro- plasmid replication.

DNA microloops and microdomains: a general mechanism for transcription activation by torsional transmission

Prokaryotic transcriptional activation often involves the formation of DNA microloops upstream of the polymerase binding site. There is substantial evidence that these microloops function to bring activator and polymerase into close spatial proximity. However additional functions are suggested by the ability of certain activators, of which FIS is the best characterised example, to facilitate polymerase binding, promoter opening and polymerase escape. We review here the evidence for the concept that the topology of the microloop formed by such activators is tightly coupled to the structural transitions in DNA mediated by RNA polymerase. In this process, which we term torsional transmission, a major function of the activator is to act as a local topological homeostat. We argue that the same mechanism may also be employed in site-specific DNA inversion.

Polyadenylation of oop RNA in the regulation of bacteriophage lambda development

We have shown that Escherichia coli pcnB mutants are lysogenized by bacteriophage lambda with lower efficiency as compared to the pcnB+ strains. Our genetic analysis revealed that expression of the lambda cII gene is decreased in the pcnB mutants. However, using various lacZ fusions we demonstrated that neither activities of pL and pR promoters nor transcription termination at tR1 were significantly impaired in the pcnB- host. On the other hand, we found that oop RNA, an antisense RNA for cII expression, is involved in this regulation. Primer protection experiments revealed that oop RNA was polyadenylated and that this polyadenylation was impaired in the pcnB mutant. We found that the oop RNA was more abundant in the pcnB mutant than in the pcnB+ strain. Furthermore, we showed that activity of the pO promoter was not stimulated in the pcnB mutant. Such findings indicated that degradation of oop RNA in the pcnB strain was slower because of inefficient polyadenylation, which could lead to more effective inhibition of cII expression by the antisense oop RNA, resulting in less efficient lysogenization of the host. The oop RNA was found previously to play a role in phage lambda development only under conditions of overproduction of this transcript. Here we demonstrate for the first time, the physiological function of oop RNA in lambda development, confirming that this short transcript plays an important role in the negative regulation of cII gene expression during lambda infection. Moreover, polyadenylation of oop RNA is one of very few known examples of specific RNA polyadenylation by PAP I in prokaryotic cells and its role in gene expression regulation.

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.

DnaA-stimulated transcriptional activation of orilambda: Escherichia coli RNA polymerase beta subunit as a transcriptional activator contact site

We present evidence that Escherichia coli RNA polymerase beta subunit may be a transcriptional activator contact site. Stimulation of the activity of the pR promoter by DnaA protein is necessary for replication of plasmids derived from bacteriophage lambda. We found that DnaA activates the pR promoter in vitro. Particular mutations in the rpoB gene were able to suppress negative effects that certain dnaA mutations had on the replication of lambda plasmids; this suppression was allele-specific. When a potential DnaA-binding sequence located several base pairs downstream of the pR promoter was scrambled by in vitro mutagenesis, the pR promoter was no longer activated by DnaA both in vivo and in vitro. Therefore, we conclude that DnaA may contact the beta subunit of RNA polymerase during activation of the pR promoter. A new classification of prokaryotic transcriptional activators is proposed.

Deletion analysis of the fis promoter region in Escherichia coli: antagonistic effects of integration host factor and Fis

Fis is a small DNA-binding and -bending protein in Escherichia coli that is involved in several different biological processes, including stimulation of specialized DNA recombination events and regulation of gene expression. fis protein and mRNA levels rapidly increase during early logarithmic growth phase in response to a nutritional upshift but become virtually undetectable during late logarithmic and stationary phases. We present evidence that the growth phase-dependent fis expression pattern is not determined by changes in mRNA stability, arguing in favor of regulation at the level of transcription. DNA deletion analysis of the fis promoter (fis P) region indicated that DNA sequences from -166 to -81, -36 to -26, and +107 to +366 relative to the transcription start site are required for maximum expression. A DNA sequence resembling the integration host factor (IHF) binding site centered approximately at -114 showed DNase I cleavage protection by IHF. In ihf cells, maximum cellular levels of fis mRNA were decreased more than 3-fold and transcription from fis P on a plasmid was decreased about 3.8-fold compared to those in cells expressing wild-type IHF. In addition, a mutation in the ihf binding site resulted in a 76 and 61% reduction in transcription from fis P on a plasmid in the presence or absence of Fis, respectively. Insertions of 5 or 10 bp between this ihf site and fis P suggest that IHF functions in a position-dependent manner. We conclude that IHF plays a role in stimulating transcription from fis P by interacting with a site centered approximately at -114 relative to the start of transcription. We also showed that although the fis P region contains six Fis binding sites, Fis site II (centered at -42) played a predominant role in autoregulation, Fis sites I and III (centered at +26 and -83, respectively) seemingly played smaller roles, and no role in negative autoregulation could be attributed to Fis sites IV, V, and VI (located upstream of site III). The fis P region from -36 to +7, which is not directly regulated by either IHF or Fis, retained the characteristic fis regulation pattern in response to a nutritional upshift.

Stability of CII is a key element in the cold stress response of bacteriophage lambda infection

Bacteria are known to adapt to environmental changes such as temperature fluctuations. It was found that temperature affects the lysis-lysogeny decision of lambda such that at body temperature (37 degrees C) the phage can select between the lytic and lysogenic pathways, while at ambient temperature (20 degrees C) the lytic pathway is blocked. This temperature-dependent discriminatory developmental pathway is governed mainly by the phage CII activity as a transcriptional activator. Mutations in cII or point mutations at the pRE promoter lead to an over-1,000-fold increase in mature-phage production at low temperature while mutations in cI cause a smaller increase in phage production. Interference with CII activity can restore lytic growth at low temperature. We found that at low temperature the stability of CII in vivo is greatly increased. It was also found that phage DNA replication is blocked at 20 degrees C but can be restored by supplying O and P in trans. It is proposed that CII hampers transcription of the rightward pR promoter, thus reducing the levels of the lambda O and P proteins, which are necessary for phage DNA replication. Our results implicate CII itself or host proteins affecting CII stability as a "molecular thermometer".

Translational repression by a transcriptional elongation factor

One of the classical positive regulators of gene expression is bacteriophage lambda N protein. N regulates the transcription of early phage genes by participating in the formation of a highly processive, terminator-resistant transcription complex and thereby stimulates the expression of genes lying downstream of transcriptional terminators. Also included in this antiterminating transcription complex are an RNA site (NUT) and host proteins (Nus). Here we demonstrate that N has an additional, hitherto unknown regulatory role, as a repressor of the translation of its own gene. N-dependent repression does not occur when NUT is deleted, demonstrating that N-mediated antitermination and translational repression both require the same cis-acting site in the RNA. In addition, we have identified one nut and several host mutations that eliminate antitermination and not translational repression, suggesting the independence of these two N-mediated mechanisms. Finally, the position of nutL with respect to the gene whose expression is repressed is important.

The integration host factor-DNA complex upstream of the early promoter of bacteriophage Mu is functionally symmetric

Inversion of the ihf site in the promoter region of the early promoter of bacteriophage Mu did not influence the integration host factor (IHF)-mediated functions. IHF bound to this inverted site could counteract H-NS-mediated repression, directly activate transcription, and support lytic growth of bacteriophage Mu. This implies that the IHF heterodimer and its asymmetrical binding site form a functionally symmetrical complex.

Function of the C-terminal domain of the alpha subunit of Escherichia coli RNA polymerase in basal expression and integration host factor-mediated activation of the early promoter of bacteriophage Mu

Integration host factor (IHF) can activate transcription from the early promoter (Pe) of bacteriophage Mu both directly and indirectly. Indirect activation occurs through alleviation of H-NS-mediated repression of the Pe promoter (P. Van Ulsen, M. Hillebrand, L. Zulianello, P. Van de Putte, and N. Goosen, Mol. Microbiol. 21:567-578, 1996). The direct activation involves the C-terminal domain of the alpha subunit (alphaCTD) of RNA polymerase. We investigated which residues in the alphaCTD are important for IHF-mediated activation of the Pe promoter. Initial in vivo screening, using a set of substitution mutants derived from an alanine scan (T. Gaal, W. Ross, E. E. Blatter, T. Tang, X. Jia, V. V. Krishnan, N. Assa-Munt, R. Ebright, and R. L. Gourse, Genes Dev. 10:16-26, 1996; H. Tang, K. Severinov, A. Goldfarb, D. Fenyo, B. Chait, and R. H. Ebright, Genes Dev. 8:3058-3067, 1994), indicated that the residues, which are required for transcription activation by the UP element of the rrnB P1 promoter (T. Gaal, W. Ross, E. E. Blatter, T. Tang, X. Jia, V. V. Krishnan, N. Assa-Munt, R. Ebright, and R. L. Gourse, Genes Dev. 10:16-26, 1996), are also important for Pe expression in the presence of IHF. Two of the RNA polymerase mutants, alphaR265A and alphaG296A, that affected Pe expression most in vivo were subsequently tested in in vitro transcription experiments. Mutant RNA polymerase with alphaR265A showed no IHF-mediated activation and a severely reduced basal level of transcription from the Pe promoter. Mutant RNA polymerase with alphaG296A resulted in a slightly reduced transcription from the Pe promoter in the absence of IHF but could still be activated by IHF. These results indicate that interaction of the alphaCTD with DNA is involved not only in the IHF-mediated activation of Pe transcription but also in maintaining the basal level of transcription from this promoter. Mutational analysis of the upstream region of the Pe promoter identified a sequence, positioned from -39 to -51 with respect to the transcription start site, that is important for basal Pe expression, presumably through binding of the alphaCTD. The role of the alphaCTD in IHF-mediated stimulation of transcription from the Pe promoter is discussed.

Structure and function of the Pseudomonas putida integration host factor

Integration host factor (IHF) is a DNA-binding and -bending protein that has been found in a number of gram-negative bacteria. Here we describe the cloning, sequencing, and functional analysis of the genes coding for the two subunits of IHF from Pseudomonas putida. Both the ihfA and ihfB genes of P. putida code for 100-amino-acid-residue polypeptides that are 1 and 6 residues longer than the Escherichia coli IHF subunits, respectively. The P. putida ihfA and ihfB genes can effectively complement E. coli ihf mutants, suggesting that the P. putida IHF subunits can form functional heterodimers with the IHF subunits of E. coli. Analysis of the amino acid differences between the E. coli and P. putida protein sequences suggests that in the evolution of IHF, amino acid changes were mainly restricted to the N-terminal domains and to the extreme C termini. These changes do not interfere with dimer formation or with DNA recognition. We constructed a P. putida mutant strain carrying an ihfA gene knockout and demonstrated that IHF is essential for the expression of the P(U) promoter of the xyl operon of the upper pathway of toluene degradation. It was further shown that the ihfA P. putida mutant strain carrying the TOL plasmid was defective in the degradation of the aromatic model compound benzyl alcohol, proving the unique role of IHF in xyl operon promoter regulation.

Strategies for achieving high-level expression of genes in Escherichia coli

Progress in our understanding of several biological processes promises to broaden the usefulness of Escherichia coli as a tool for gene expression. There is an expanding choice of tightly regulated prokaryotic promoters suitable for achieving high-level gene expression. New host strains facilitate the formation of disulfide bonds in the reducing environment of the cytoplasm and offer higher protein yields by minimizing proteolytic degradation. Insights into the process of protein translocation across the bacterial membranes may eventually make it possible to achieve robust secretion of specific proteins into the culture medium. Studies involving molecular chaperones have shown that in specific cases, chaperones can be very effective for improved protein folding, solubility, and membrane transport. Negative results derived from such studies are also instructive in formulating different strategies. The remarkable increase in the availability of fusion partners offers a wide range of tools for improved protein folding, solubility, protection from proteases, yield, and secretion into the culture medium, as well as for detection and purification of recombinant proteins. Codon usage is known to present a potential impediment to high-level gene expression in E. coli. Although we still do not understand all the rules governing this phenomenon, it is apparent that "rare" codons, depending on their frequency and context, can have an adverse effect on protein levels. Usually, this problem can be alleviated by modification of the relevant codons or by coexpression of the cognate tRNA genes. Finally, the elucidation of specific determinants of protein degradation, a plethora of protease-deficient host strains, and methods to stabilize proteins afford new strategies to minimize proteolytic susceptibility of recombinant proteins in E. coli.

RNA polymerase signals UvrAB landing sites

Transcription when coupled to nucleotide excision repair specifies the location in active genes where preferential DNA repair is to take place. During DNA damage-induced recruitment of RNA polymerase (RNAP), there is a physical association of the beta subunit of Escherichia coli RNAP and the UvrA component of the repair apparatus (G. C. Lin and L. Grossman, submitted for publication). This molecular affinity is reflected in the ability of the RNAP to increase, in a promoter-dependent manner, DNA supercoiling by the UvrAB complex. In the presence of the RNAP, the UvrAB complex is able to bind to promoter regions and to translocate in a 5' to 3' direction along the non-transcribed strand. As a consequence of this helicase-catalyzed translocation, preferential incision of DNA damaged sites occurs downstream on the transcribed strand. Because of the helicase directionality, the initial binding of the UvrAB complex to the transcribed strand would inevitably lead to its collision with the RNAP. These results imply that the RNAP-induced DNA structure in the vicinity of the transcription start site signals a landing or entry site for the UvrAB complex on DNA.

Integration host factor alleviates the H-NS-mediated repression of the early promoter of bacteriophage Mu

Integration host factor (IHF), which is a histone-like protein, has been shown to positively regulate transcription in two different ways. It can either help the formation of a complex between a transcription factor and RNA polymerase or it can itself activate RNA polymerase without the involvement of other transcription factors. In this study, we present a third mechanism for IHF-stimulated gene expression, by counteracting the repression by another histone-like protein, H-NS. The early (Pe) promoter of bacteriophage Mu is specifically inhibited by H-NS, both in vivo and in vitro. For this inhibition, H-NS binds to a large DNA region overlapping the Pe promoter. Binding of IHF to a binding site just upstream of Pe alleviates the H-NS-mediated repression of transcription. This same ihf site is also involved in the direct activation of Pe by IHF. In contrast to the direct activation by IHF, however, the alleviating effect of IHF appears not to be dependent on the relevant position of the ihf site on the DNA helix, and it also does not require the presence of the C-terminal domain of the alpha subunit of RNA polymerase. Footprint analysis shows that binding of IHF to the ihf site destabilizes the interaction of H-NS with the DNA, not only in the IHF-binding region but also in the DNA regions flanking the ihf site. These results suggest that IHF disrupts a higher-order nucleoprotein complex that is formed by H-NS and the DNA.

Enhanced activity of the bacteriophage lambda PL promoter at low temperature

We found that the activity of the phage lambda PL promoter is inversely dependent on temperature. Both in vivo and in vitro transcription assays revealed that the rather unique temperature response of PL is a sum of an intrinsic property of the promoter and its activation by integration host factor. We also found that at low temperature, phage lambda can lysogenize efficiently but cannot complete the lytic cycle. We hypothesize that by sensing the low environmental temperature the PL promoter plays a role in determining the direction of phage lambda development.

Identification of related genes in phages phi 80 and P22 whose products are inhibitory for phage growth in Escherichia coli IHF mutants

Bacteriophage lambda grows in both IHF+ and IHF- host strains, but the lambdoid phage phi 80 and hybrid phage lambda (QSRrha+)80 fail to grow in IHF- host strains. We have identified a gene, rha, in the phi80 region of the lambda(QSRrha+)80 genome whose product, Rha, inhibits phage growth in an IHF- host. A search of the GenBank database identified a homolog of rha, ORF201, a previously identified gene in phage P22, which similarly inhibits phage growth in IHF- hosts. Both rha and ORF201 contain two possible translation start sites and two IHF binding site consensus sequences flanking the translation start sites. Mutations allowing lambda (QSRrha+)80 and P22 to grow in IHF- hosts map in rha and ORF201, respectively. We present evidence suggesting that, in an IHF+ host, lambda(QSRrha+)80 expresses Rha only late in infection but in an IHF- host the phage expresses Rha at low levels early in infection and at levels higher than those in an IHF+ host late in infection. We suspect that the deregulation of rha expression and, by analogy, ORF201 expression, is responsible for the failure of phi80, lambda(QSRrha+)80, and P22 to grow in IHF mutants.

The regulation of transcription initiation by integration host factor

Integration host factor (IHF) of Escherichia coli is an asymmetric histone-like protein that binds and bends the DNA at specific sequences. IHF functions as an accessory factor in a wide variety of processes including replication, site-specific recombination and transcription. In many of these processes IHF was shown to act as an architectural element which helps the formation of nucleo-protein complexes by bending of the DNA at specific sites. This MicroReview shows how such a structural role of IHF can influence the initiation of transcription. In addition, it summarizes the evidence indicating that IHF can stimulate transcription via a direct interaction with RNA polymerase and explores the possibility that the asymmetry of the IHF protein might reflect such an interaction.

Enhanced activity of the bacteriophage lambda PL promoter at low temperature

The response of the early phage lambda PL promoter to temperature was investigated. Experiments with lacZ reporter gene fusions demonstrated that the activity of the phage lambda PL promoter is inversely dependent on temperature. The bacterial DNA-binding protein integration host factor (IHF) further enhances lambda PL promoter activity at low temperature, although no apparent changes in the cellular level of IHF protein were observed at the different temperatures. IHF protein binds DNA in vitro more avidly at low temperatures. In vitro transcription assays further revealed that the temperature response of PL is the result of an intrinsic property of the promoter as well as its activation by IHF.

Dynamical behaviour of biological regulatory networks--II. Immunity control in bacteriophage lambda

A number of bacterial and viral genes take part in the decision between lysis and lysogenization in temperate bacteriophages. In the lambda case, at least five viral genes (cI, cro, cII, N and cIII) and several bacterial genes are involved. Several attempts have been made to model this complex regulatory network. Our approach is based on a logical method described in the first paper of the series which formalizes the interactions between the elements of a regulatory network in terms of discrete variables, functions and parameters. In this paper two models are described and discussed, the first (two-variable model) focused on cI and cro interactions, the second (four-variable model) considering, in addition, genes cII and N. The treatment presented emphasizes the roles of positive and negative feedback loops and their interactions in the development of the phage. The role of the loops between cI and cro, and of cI on itself (which both have to be positive loops) was discovered earlier; this group's contribution to this aspect mainly deals with the possibility of treating these loops as parts of a more extended network. In contrast, the role of the negative loop of cro on itself had apparently remained unexplained. We realized that this loop buffers the expression of genes cro itself. cII, O and P against the inflation due to the rapid replication of the phage. More generally, negative auto-control of a gene appears an efficient way to render its expression insensitive (or less sensitive) to gene dosage, whereas a simple negative control would not provide this result.

Expression of the genes coding for the Escherichia coli integration host factor are controlled by growth phase, rpoS, ppGpp and by autoregulation

Transcriptional control of the himA and the himD/hip genes coding for the two subunits of the integration host factor (IHF) was investigated. The promoters for the two genes were identified by the use of primer extension and S1 analysis. Expression from both promoters was found to increase as the cells enter stationary phase. Mutation in rpoS, known to be induced upon entry to stationary phase, dramatically reduced the growth-phase response of the himA P4 promoter but had only a small effect on the induction of the himD/hip promoter. The increased activity of both promoters required the presence of the relA and spoT genes, suggesting that ppGpp plays a major role in the response to stationary phase. An artificial increase in ppGpp in exponentially growing cells induced a rapid increase in himA P4 and himD/hip mRNA levels. Experiments with a mutant defective in rpoS showed that the response of the himA P4 promoter to high ppGpp levels was greatly reduced while that of himD/hip was only slightly affected. Therefore, it seems that different mechanisms involving RpoS and ppGpp regulate the growth-phase response of the two promoters. We propose that the effect of ppGpp on himA P4 is mediated via RpoS whereas the himD/hip promoter is affected by ppGpp independently of RpoS. Expression of the himD/hip and himA genes was found to be subject to negative autoregulation. IHF-binding sites, implicated in autoregulation, were found to overlap both the himD/hip and himA P4 promoters. An additional IHF-binding site was found upstream of the himD/hip promoter. All three sites show low binding affinity to IHF suggesting that autoregulation can take place only after sufficiently high levels of IHF accumulate in the cell.

Promoters responsive to DNA bending: a common theme in prokaryotic gene expression

The early notion of DNA as a passive target for regulatory proteins has given way to the realization that higher-order DNA structures and DNA-protein complexes are at the basis of many molecular processes, including control of promoter activity. Protein binding may direct the bending of an otherwise linear DNA, exacerbate the angle of an intrinsic bend, or assist the directional flexibility of certain sequences within prokaryotic promoters. The important, sometimes essential role of intrinsic or protein-induced DNA bending in transcriptional regulation has become evident in virtually every system examined. As discussed throughout this article, not every function of DNA bends is understood, but their presence has been detected in a wide variety of bacterial promoters subjected to positive or negative control. Nonlinear DNA structures facilitate and even determine proximal and distal DNA-protein and protein-protein contacts involved in the various steps leading to transcription initiation.

Genetic and biochemical analysis of IHF/HU hybrid proteins

Integration host factor (IHF) is a small heterodimeric DNA-binding protein of E coli composed of two subunits, alpha and beta, encoded by the himA and hip genes, respectively. IHF binds to DNA at a consensus sequence and bends DNA. HU protein, encoded by the hupA and hupB genes, is similar to IHF except that it does not bind to a specific DNA sequence. To investigate the protein determinants for IHF specificity we exchanged progressively longer segments from the C-terminus of Hip with those of HupA, and followed the activity in vivo and in vitro of four such IHF/HU hybrids. Replacement of 11 residues from the C-terminal alpha helix of Hip by the complementary eight residues of HupA (hybrid 1), had only minor effects on the DNA binding activity of the protein. As progressively longer segments of Hip were replaced by HupA, a precipitous decrease in IHF activity was observed. The hybrid with the longest substitution, hybrid 4, was totally inactive in vivo and could not be purified. None of the hybrid proteins could complement HU activity. Comparing the activities of hybrid 1, hybrid 2 and IHF point mutants, led us to conclude that the structural integrity of the C-terminal alpha helix and its spatial position, but not its amino acid sequence, are important for DNA binding specificity. We favor the hypothesis that alpha helices 3 of both IHF subunits interact with the body of IHF so as to anchor the arms. This interaction stabilizes the arms to permit DNA binding specificity. Thus the C-termini of IHF influence, in an indirect way, the recognition of specific sites on DNA.

Promoter resurrection by activators--a minireview

Frequently, in nature, defective promoters can be resurrected by activator proteins in response to cellular demands. The activators bind to nearby DNA sites for action. Various protein-protein and DNA-protein contacts involving activators, RNA polymerase, and different segments of DNA in and around a defective promoter form a DNA-multiprotein complex (cage) which enhances transcription.

Integration host factor (IHF) modulates the expression of the pyrimidine-specific promoter of the carAB operons of Escherichia coli K12 and Salmonella typhimurium LT2

We report the identification of Integration Host Factor (IHF) as a new element involved in modulation of P1, the upstream pyrimidine-specific promoter of the Escherichia coli K12 and Salmonella typhimurium carAB operons. Band-shift assays, performed with S-30 extracts of the wild type and a himA, hip double mutant or with purified IHF demonstrate that, in vitro, this factor binds to a region 300 bp upstream of the transcription initiation site of P1 in both organisms. This was confirmed by deletion analysis of the target site. DNase I, hydroxyl radical and dimethylsulphate footprinting experiments allowed us to allocate the IHF binding site to a 38 bp, highly A+T-rich stretch, centred around nucleotide -305 upstream of the transcription initiation site. Protein-DNA contacts are apparently spread over a large number of bases and are mainly located in the minor groove of the helix. Measurements of carbamoyl-phosphate synthetase (CPSase) and beta-galactosidase specific activities from car-lacZ fusion constructs of wild type or IHF target site mutants introduced into several genetic backgrounds affected in the himA gene or in the pyrimidine-mediated control of P1 (carP6 or pyrH+/-), or in both, indicate that, in vivo, IHF influences P1 activity as well as its control by pyrimidines. IHF stimulates P1 promoter activity in minimal medium, but increases the repressibility of this promoter by pyrimidines. These antagonistic effects result in a two- to threefold reduction in the repressibility of promoter P1 by pyrimidines in the absence of IHF binding. IHF thus appears to be required for maximal expression as well as for establishment of full repression. IHF could exert this function by modulating the binding of a pyrimidine-specific regulatory molecule.

Positive and negative effects of DNA bending on activation of transcription from a distant site

Transcription of the Escherichia coli glnHPQ operon, which encodes components of the high-affinity glutamine transport system, is activated by nitrogen regulator I (NRI)-phosphate in response to nitrogen limitation. NRI-phosphate binds to sites upstream from the sigma 54-dependent glnHp2 promoter and activates transcription by catalyzing the isomerization of the closed sigma 54-RNA polymerase promoter complex to an open complex. On linear DNA, the initiation of glnHp2 transcription requires in addition to NRI-phosphate the presence of integration host factor (IHF), which binds to a site located between the NRI-binding sites and the promoter. On supercoiled DNA, IHF does not play an essential role, but enhances the activation of transcription by NRI-phosphate. We found that at a mutant glnHp2 promoter with increased affinity for sigma 54-RNA polymerase, the initiation of transcription can be activated equally well by NRI-phosphate in the presence or absence of IHF. Binding of IHF to its site does not increase the binding of sigma 54-RNA polymerase to the glnHp2 promoter; instead, our data suggest that IHF bends the DNA to align the activator with the closed sigma 54-RNA polymerase promoter complex to facilitate the interactions that result in open complex formation. In the absence of IHF, NRI-phosphate can activate transcription whether its binding sites are on the same face of the DNA helix as the sigma 54-RNA polymerase or on the opposite face. IHF enhances transcription when the three proteins are located on the same face of the helix, but strongly inhibits transcription when any one of the proteins is located on the opposite face.

Stimulation of the phage lambda pL promoter by integration host factor requires the carboxy terminus of the alpha-subunit of RNA polymerase

Escherichia coli integration host factor (IHF) binds with high affinity to two tandem IHF consensus sequences located upstream from the pL promoter of bacteriophage lambda. IHF was shown to stimulate transcription initiation from the pL promoter by increasing close complex formation (KB). We show here, by the use of reconstituted mutant RNA polymerases, that the C-terminal portion of the alpha subunit of RNA polymerase plays an essential role in the stimulation of transcription by IHF. Our results are in agreement with the hypothesis that IHF, like the cAMP-CRP activator, increases the affinity of RNA polymerase to the promoter by protein-protein interaction.

Interaction between bacteriophage lambda and its Escherichia coli host

Bacteriophage lambda relies to a large extent on processes requiring interactions between viral- and host-encoded proteins for its lytic growth, establishment of lysogeny, and release from the prophage state. Both biochemical and genetic studies of these interactions have yielded new information about important host and lambda functions. In particular, mutations in Escherichia coli that compromise lambda DNA replication, genome packaging, transcription elongation, and site-specific recombination have led to the identification of bacterial genes whose products are chaperones, transcription factors, or DNA-binding proteins.

DNA topology-mediated regulation of transcription initiation from the tandem promoters of the ilvGMEDA operon of Escherichia coli

It is becoming increasingly clear that the intrinsic and protein-induced topological properties of the DNA helix influence transcriptional efficiency. In this report we describe the properties of two upstream activating regions that influence transcription from the non-overlapping tandem promoters of the ilvGMEDA operon of Escherichia coli. One 20 base-pair region between the promoter sites contains an intrinsic DNA bend that activates transcription from the downstream promoter. The other region contains an integration host factor (IHF) binding site that overlaps the upstream promoter site. IHF binding at this site represses transcription from the upstream promoter and enhances transcription from the downstream promoter. IHF also induces a severe bend in the DNA at its target binding site in the upstream promoter region. The activating property of the 20 base-pair DNA sequence located between the promoters is dependent upon the helical phasing of the sequence-directed DNA bend that it encodes. However, the IHF-mediated activation of transcription is not dependent upon the helical phasing (spatial orientation) of the upstream IHF and downstream promoter sites. The IHF-mediated activation of transcription is also uninfluenced by the presence or absence of the intrinsic DNA bend between its binding site and the downstream promoter site. These results suggest the interesting possibility that IHF activates transcription from the nearby downstream promoter simply by bending the DNA helix in the absence of specific IHF-RNA polymerase or upstream DNA-RNA polymerase interactions.