Absence Of Integration Host Factor Research Articles

IHF stabilizes pathogenicity island I of uropathogenic Escherichia coli strain 536 by attenuating integrase I promoter activity

Pathogenicity islands (PAIs) represent horizontally acquired chromosomal regions and encode their cognate integrase, which mediates chromosomal integration and excision of the island. These site-specific recombination reactions have to be tightly controlled to maintain genomic stability, and their directionality depends on accessory proteins. The integration host factor (IHF) and the factor for inversion stimulation (Fis) are often involved in recombinogenic complex formation and controlling the directionality of the recombination reaction. We investigated the role of the accessory host factors IHF and Fis in controlling the stability of six PAIs in uropathogenic Escherichia coli strain 536. By comparing the loss of individual PAIs in the presence or absence of IHF or Fis, we showed that IHF specifically stabilized PAI I536 and that in particular the IHFB subunit seems to be important for this function. We employed complex genetic studies to address the role of IHF in PAI I536-encoded integrase (IntI) expression. Based on different YFP-reporter constructs and electrophoretic mobility shift assays we demonstrated that IntI acts a strong repressor of its own synthesis, and that IHF binding to the intI promoter region reduces the probability of intI promoter activation. Our results extend the current knowledge of the role of IHF in controlling directionality of site specific recombination reactions and thus PAI stability.

Integration Host Factor (IHF) Dictates the Structure of Polyamine-DNA Condensates: Implications for the Role of IHF in the Compaction of Bacterial Chromatin

Integration host factor (IHF), a nucleoid-associated protein in bacterial cells, is implicated in a number of chromosomal functions including DNA compaction. IHF binds to all duplex DNA with micromolar affinity and at sequence-specific sites with much higher affinity. IHF is known to induce sharp bends in the helical axis of DNA in both modes of binding, but the role of IHF in controlling DNA condensation within bacterial cells has remained undetermined. Here we demonstrate that IHF influences the morphology of DNA condensed by polyamines in vitro. In the absence of IHF, spermidine and spermine condense DNA primarily into toroidal structures, whereas in the presence of IHF, polyamines condense DNA primarily into rodlike structures. Computer simulations of DNA condensation in the absence and presence of IHF binding lend support to our model in which DNA bending proteins, such as IHF and HU, promote the condensation of DNA into rodlike structures by providing the free energy necessary to bend DNA at the ends of linear bundles of condensed DNA. We propose that a common function of IHF and HU in bacterial cells is to facilitate DNA organization in the nucleoid by the introduction of sharp bends in chromosomal DNA.

IHF- and SeqA-binding sites, present in plasmid cloning vectors, may significantly influence activities of promoters

Escherichia coli Integration Host Factor (IHF) regulates transcription from some bacterial and phage promoters by affecting DNA topology. Here we demonstrate that IHF affects transcription from bacteriophage λ pR promoter and the ptac promoter located on plasmids that contain IHF-binding sites. The IHF consensus sites are abundant and they can bind the IHF protein as shown in in vitro studies. The SeqA protein has a role in the complex regulation of pR activity, together with other factors altering DNA topology. Down-regulation of the transcription from ptac in the absence of IHF, together with IHF- and SeqA-mediated effects on pR, suggest that DNA topology cannot be underestimated when assessing in vivo promoters’ activity. This may have a significant impact on experiments employing recombinant genes cloned in plasmids and on choosing appropriate plasmid vectors.

Requirement for Vibrio cholerae Integration Host Factor in Conjugative DNA Transfer

The requirement for host factors in the transmission of integrative and conjugative elements (ICEs) has not been extensively explored. Here we tested whether integration host factor (IHF) or Fis, two host-encoded nucleoid proteins, are required for transfer of SXT, a Vibrio cholerae-derived ICE that can be transmitted to many gram-negative species. Fis did not influence the transfer of SXT to or from V. cholerae. In contrast, IHF proved to be required for V. cholerae to act as an SXT donor. In the absence of IHF, V. cholerae displayed a modest defect for serving as an SXT recipient. Surprisingly, SXT integration into or excision from the V. cholerae chromosome, which requires an SXT-encoded integrase related to lambda integrase, did not require IHF. Therefore, the defect in SXT transmission in the V. cholerae IHF mutant is probably not related to IHF's ability to promote DNA recombination. The V. cholerae IHF mutant was also highly impaired as a donor of RP4, a broad-host-range conjugative plasmid. Thus, the V. cholerae IHF mutant appears to have a general defect in conjugation. Escherichia coli IHF mutants were not impaired as donors or recipients of SXT or RP4, indicating that IHF is a V. cholerae-specific conjugation factor.

Role of Integration Host Factor in the Transcriptional Activation of Flagellar Gene Expression in Caulobacter crescentus

In the Caulobacter crescentus predivisional cell, class III and IV flagellar genes, encoding the extracytoplasmic components of the flagellum, are transcribed in the nascent swarmer compartment. This asymmetric expression pattern is attributable to the compartmentalized activity of the sigma54-dependent transcriptional activator FlbD. Additionally, these temporally transcribed flagellar promoters possess a consensus sequence for the DNA-binding protein integration host factor (IHF), located between the upstream FlbD binding site and the promoter sequences. Here, we deleted the C. crescentus gene encoding the beta-subunit of the IHF, ihfB (himD), and examined the effect on flagellar gene expression. The DeltaihfB strain exhibited a mild defect in cell morphology and impaired motility. Using flagellar promoter reporter fusions, we observed that expression levels of a subset of class III flagellar promoters were decreased by the loss of IHF. However, one of these promoters, fliK-lacZ, exhibited a wild-type cell cycle-regulated pattern of expression in the absence of IHF. Thus, IHF is required for maximal transcription of several late flagellar genes. The DeltaihfB strain was found to express significantly reduced amounts of the class IV flagellin, FljL, as a consequence of reduced transcriptional activity. Our results indicate that the motility defect exhibited by the DeltaihfB strain is most likely attributable to its failure to accumulate the class IV-encoded 27-kDa flagellin subunit, FljL.

Recruitment of σ54-RNA Polymerase to the Pu Promoter of Pseudomonas putida through Integration Host Factor-mediated Positioning Switch of α 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.

Imaging of IHF-induced DNA Bending Structure by AFM

Integration host factor (IHF) of Escherichia coli is a DNA-bending protein. Although first discovered as a host factor for bacteriophage λ integration, IHF functions in many processes that involve higher order protein-DNA complexes: e.g., in replication, where it binds to ori C; in transcriptional regulation, where it binds upstream of many σ-dependent promoters; and in a variety of site-specific recombination systems. The primary function of IHF appears to be architectural, i.e., introducing a sharp bend in the DNA that facilitates the interaction of other components in a nucleoprotein array. In this study, the structure of the DNA-IHF nucleoprotein complex in the OP1 promoter region on the Pseudomonas TOL plasmid was analyzed using atomic force microscopy (AFM), which can directly visualize biological structure under near-native conditions without crystallization. We found that IHF induced a DNA bend in the promoter regulatory region of OP1 upon its binding, supporting the DNA-loop model for the activation of OP1 transcription. The DNA fragment containing the OP1 promoter was purified from the palsmid, and it was amplified by PCR. The IHF protein was purified from E. coli strain D1210HP transformed with the plasmid pPL-hip him A-5. The IHF-DNA complexes were formed by mixing the both of solutions, and proteins not reacted with DNA fragments were removed by filtration. The NanoScopeIIIa Multi Mode system operated in tapping mode was used for observation of IHF-DNA complexes. The AFM image of the IHF-DNA complexes showed a sharp DNA bend at the IHF-binding site on the fragment. This sharp DNA bend can be used as a clear landmark of IHF-binding site on the templates. To investigate whether the binding of IHF to the IHF binding site induced bending of the template, a statistical analysis on images of IHF-DNA complexes was performed. Measurements of the DNA bending angles yielded a distribution with the mean bend angle of 123 °. Contrary, uncomplexed DNA molecules showed Gaussian distribution centered at 0 °, indicating no intrinsic curvature of the DNA fragments at these locations. This suggests that the bending observed on the complexed DNA molecules was dependent on the binding of IHF. The observed bend-angle distribution in the absence of IHF is to be accounted for by random thermal fluctuations. As shown in this study, AFM will be a useful tool for visualizing the effects of protein-DNA interactions and contribute to a better understanding of the complex mechanisms of transcriptional regulation.

Replacement of Integration Host Factor Protein-induced DNA Bending by Flexible Regions of DNA

The Escherichia coli integration host factor (IHF) protein is required for site-specific recombination of bacteriophage lambda DNA. Previously, we had shown that alternative modules of static DNA curvature could partially replace IHF in recombination. Now we use regions of single-stranded DNA as a flexible tether to address whether the function of IHF in recombination is simply to reduce persistence length. Although we find that these modules clearly enhance recombination in the absence of IHF, they are not perfect replacements. In addition, evidence is presented that the efficacy of a flexibility swap is specific to a particular IHF site. This may indicate that additional functions beyond simple deformation of DNA are required of IHF. During the course of these experiments we discovered that these flexible sequences are still specific sites for IHF binding and function.

Site-specific recombination of bacteriophage P22 does not require integration host factor.

Site-specific recombination by phages lambda and P22 is carried out by multiprotein-DNA complexes. Integration host factor (IHF) facilitates lambda site-specific recombination by inducing DNA bends necessary to form an active recombinogenic complex. Mutants lacking IHF are over 1,000-fold less proficient in supporting lambda site-specific recombination than wild-type cells. Although the attP region of P22 contains strong IHF binding sites, in vivo measurements of integration and excision frequencies showed that infecting P22 phages can perform site-specific recombination to its maximum efficiency in the absence of IHF. In addition, a plasmid integration assay showed that integrative recombination occurs equally well in wild-type and ihfA mutant cells. P22 integrative recombination is also efficient in Escherichia coli in the absence of functional IHF. These results suggest that nucleoprotein structures proficient for recombination can form in the absence of IHF or that another factor(s) can substitute for IHF in the formation of complexes.

Alterations in the directionality of λ site-specific recombination catalyzed by mutant integrases in vivo

Phage λ integrative and excisive recombination normally proceeds by a pair of sequential strand exchanges. During the first exchange reaction, the “top” strand in each recombination site is cleaved, exchanged, and religated generating a Holliday junction intermediate. This intermediate DNA structure is resolved through a pair of reciprocal “bottom” strand exchanges, leading to recombinant products. The strict co-ordination of exchange reactions ensures religation between correct partner strands only. Here we show that the directionality of recombination is altered in vivo by two mutant integrases, Int-h (E174 K) and a double mutant Int-h/218 (E174 K/E218 K). This change in directionality leads to deletion instead of inversion on substrates that carry inverted attachment sites and, depending on the pair of target sites employed, requires the presence or absence of integration host factor. Neither Fis nor Xis is involved in deletion. Sequence analyses of deletion products reveal that the newly generated hybrid attachment site exhibits a reversed genetic polarity. We demonstrate that only one of two possible hybrid site configurations is generated and discuss two pathways leading to deletion. In the first, deletion results from a wrong alignment of the two recombination sites within the synaptic complex. In the second pathway, the unco-ordinated cleavage by the mutant integrases of all four DNA strands present in a conventional Holliday junction intermediate leads to two double-stranded breaks, whereby the subsequent rejoining between “wrong” partner strands appears restricted to only two strands.

Effect ofEscherichia coliIHF Mutations on Plasmid p15A Copy Number

Four isogenic strains (himAhimDdouble mutant,himAandhimDsingle mutants, and their wild type counterpart) harboringorip15A plasmid (pACYC184 or pACYC184Amp or pACYC177) show different copy numbers of that plasmid in the early stationary phase of cultivation. The copy number oforip15A plasmid increases about four times in thehimAhimDdouble (65–70 copies per cell) andhimDsingle mutant cells (50–56 copies per cell) and was almost the same inhimAmutant (17–18 copies per cell) and wild type cells (14–16 copies per cell). The results suggest that HimD can form homodimers, which are functionally competent for the regulation oforip15A plasmid copy number. Complementation experiments ofhimAhimDdouble mutant cells using plasmid carryinghimAandhimDgenes (pPLhiphimA-5) confirm the effect of integration host factor (IHF) absence on increasing the copy number oforip15A plasmid (plasmid producing IHF complemented the defect of IHF mutant). The absence of IHF (usinghimAhimDdouble mutant as host) had no effect on the copy number of the pBR322 (oripMB1) plasmid.

PspF and IHF bind co-operatively in the psp promoter-regulatory region of Escherichia coli.

PspF bound to the psp enhancer activates E sigma54 holoenzyme-dependent transcription of the Escherichia coli phage-shock protein (psp) operon and autogenously represses its own sigma70-dependent transcription, thereby keeping its concentration at a low level. It has been demonstrated previously that integration host factor (IHF) bound to a DNA site located between the psp core promoter and the PspF binding sites stimulates psp expression. We show here that wild-type IHF strongly retards DNA containing the psp promoter region. In vitro, PspF binding to the psp enhancer facilitates IHF binding, while IHF binding to the pspF-pspA-E promoter-regulatory region increases the efficacy of PspF binding to the upstream activating sequences (UASs). This is the first demonstration of co-operative binding of an activator and IHF in a sigma54-dependent system. In the absence of IHF, in vivo autoregulation of pspF transcription is lifted and, consequently, PspF production is increased, indicating that IHF enhances PspF binding to the psp enhancer in vivo.

Integration host factor is required for 1,2-propanediol-dependent transcription of the cob/pdu regulon in Salmonella typhimurium LT2.

We show that integration host factor (IHF) is required for the activation of transcription of the cobalamin biosynthetic (cob) and 1,2-propanediol (1,2-PDL) utilization (pdu) operons in Salmonella typhimurium LT2. A lack of IHF affected transcription of the cob/pdu regulon in at least two ways. First, the level of the regulatory protein PocR was decreased in ihfB (formerly himD) mutants, as judged by Western blot analysis with polyclonal antiserum raised against PocR. Second, even when PocR was available, in the absence of IHF, PocR was unable to activate transcription of cob/pdu in response to 1,2-PDL. This result suggested an additional role for IHF in PocR-dependent transcription activation. Consistent with these findings, ihfB mutants of this bacterium were unable to use 1,2-PDL as a carbon or energy source.

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.

Effects of Integration Host Factor and DNA Supercoiling on Transcription from the ilvPG Promoter of Escherichia coli

Integration host factor (IHF) activates transcription from the ilvPG promoter by severely distorting the DNA helix in an upstream region of a supercoiled DNA template in a way that alters the structure of the DNA in the downstream promoter region and facilitates open complex formation. In this report, the in vivo and in vitro influence of DNA supercoiling on transcription from this promoter is examined. In the absence of IHF, promoter activity increases with increased DNA supercoiling. In the presence of IHF, the same increases in superhelical DNA densities result in larger increases in promoter activity until a maximal activation of 5-fold is obtained. However, the relative transcriptional activities of the promoter in the presence and absence of IHF at any given DNA superhelical density remains the same. Thus, IHF and increased DNA supercoiling activate transcription by different mechanisms. Also, IHF binds with equal affinities to its target site on linear and supercoiled DNA templates. Therefore, IHF binding does not activate transcription simply by increasing the local negative supercoiling of the DNA helix in the downstream promoter region or by differential binding to relaxed and supercoiled DNA templates.

Replication of Plasmid R6K γ Origin in Vivoand in Vitro:Dependence on IHF Binding to the ihf1 Site

The γ origin of plasmid R6K requires the specific initiator protein π for initiation of replication. However, increased π concentrations inhibit replication. The host-encoded integration host factor (IHF) protein permits γ origin replication at otherwise inhibitory π levels. IHF is thought to mediate this positive effect by directly binding to the γ origin. In this study we demonstrate that IHF binding to one IHF site in the γ origin, ihf1, but not to the other side, ihf2, is necessary for the γ origin to replicate at high π protein levels. We also show that in vitroreplication of the γ origin plasmid requires IHF binding to the ihf1 site. Finally, we demonstrate both in vivoand in vitrothat, when mutant π proteins (hyperactive) are provided instead of wild-type π, γ origin plasmids can replicate in the absence of IHF. This supports a previously proposed hypothesis that the π mutants can bypass the IHF requirement for γ origin replication.

Characterization of the Interaction between the Lambda Intasome andattB

Bacteriophage λ DNA integrates into the chromosome ofEscherichia coliby first forming an intasome at the phage attachment site on the phage DNA with the integrase Int and integration host factor. This intasome searches the host chromosome for the bacterial attachment site (attB) and then orchestrates two sequential strand exchange reactions to achieve integration. This study characterizes the weak interaction of the intasome andattB. The hypothesis that all of the proteins necessary for integration are brought to the reaction site by the intasome is given additional support by showing that the concentration of phage attachment site and notattB determines the optimal concentration of proteins for integration. The value of the dissocation constant of the complex formed between the intasome andattB is determined in two different ways. First, the rate of the integration reaction is measured as a function of theattB DNA concentration. The saturation constant reflects the dissociation constant of the complex. Second, a recomb ination reaction is inhibited by the inroduction of varying amounts of a secondattB with a sequence change that blocks recombination with this site. The inhibition constant reflects the dissociation constant of the intasome and alteredattB in this experiment. The two methods agree and give a dissociation constant of approximately 300 nM.attB contains two core binding sites for the intasome; it is shown that both are necessary for efficient capture. The value of the dissocation constants are considerably lower when a mutant integrase, IntE174K, is used. This increased affinity for core sites can explain how IntE174K can function in the absence of integration host factor. The inhibition constants also show dependence on the exact sequence of the inhibitingattB. Possible implications of this dependence are discussed.

Integration host factor suppresses promiscuous activation of the sigma 54-dependent promoter Pu of Pseudomonas putida.

In the presence of m-xylene, the Pu promoter of the TOL plasmid of Pseudomonas putida is activated by the prokaryotic enhancer-binding protein XylR. The intervening DNA segment between the upstream activating sequences (UASs) and those for RNA polymerase binding contains an integration host factor (IHF) attachment site that is required for full transcriptional activity. In the absence of IHF, the Pu promoter can be cross-activated by other members of the sigma 54-dependent family of regulatory proteins. Such illegitimate activation does not require the binding of the heterologous regulators to DNA and it is suppressed by bent DNA structures, either static or protein induced, between the promoter core elements (UAS and RNA polymerase recognition sequence). The role of IHF in some sigma 54 promoters is, therefore, not only a structural aid for assembling a correct promoter geometry but also that of an active suppressor (restrictor) of promiscuous activation by heterologous regulators for increased promoter specificity.

Isolation and characterization of plasmid mutations that enable partitioning of pSC101 replicons lacking the partition (par) locus.

Second-site mutations that allow stable inheritance of partition-defective pSC101 plasmids mapped to seven distinct sites in the 5' half of the plasmid repA gene. While the mutations also elevated pSC101 copy number, there was no correlation between copy number increase and plasmid stability. Combinations of mutations enabled pSC101 DNA replication in the absence of integration host factor and also stabilized par-deleted plasmids in cells deficient in DNA gyrase or defective in DnaA binding. Our findings suggest that repA mutations compensate for par deletion by enabling the origin region RepA-DNA-DnaA complex to form under suboptimal conditions. They also provide evidence that this complex has a role in partitioning that is separate from its known ability to promote plasmid DNA replication.

Analysis of DNA bend structure of promoter regulatory regions of xylene-metabolizing genes on the Pseudomonas TOL plasmid.

The transcription of both the upper operon (OP1) coding for m-xylene-degrading enzymes and the positive regulatory gene xylS on the TOL plasmid depends on sigma 54-RNA polymerase and requires the activator protein XylR that binds to the cis-acting upstream regulatory sequence of each promoter. For transcription of OP1 in Escherichia coli, integration host factor (IHF) is also required. IHF binds to DNA between the upstream regulatory sequence and the promoter sequence of OP1. We showed that IHF induced a DNA bend in the promoter regulatory region of OP1 upon its binding, supporting the DNA-loop model for the activation of OP1 transcription. In contrast to OP1, the transcriptional activation of xylS does not require IHF. In the absence of IHF, the promoter regulatory region of xylS promoter was shown to have a weak but significant intrinsic DNA bend, which may be involved in stabilizing the DNA-loop structure for the activation of xylS transcription. When IHF was highly produced in E. coli, the xylS transcription was repressed. We found two weak binding sites for IHF, each overlapping with the promoter sequence and the upstream regulatory sequence. The IHF binding to these sites might result in repression of xylS expression by overproduced IHF. Evidence is presented that binding of IHF to these sites induces a DNA bend.