The interaction of E. coli integration host factor and lambda cos DNA: multiple complex formation and protein-induced bending

Defining the Functionally Important Domain and Amino Acid Residues in Mycobacterium tuberculosis Integration Host Factor for Genome Stability, DNA Binding, and Integrative Recombination

The integration host factor of Mycobacterium tuberculosis (mIHF) consists of a single polypeptide chain, the product of the ihf gene. We previously revealed that mIHF is a novel member of a new class of nucleoid-associated proteins that have important roles in DNA damage response, nucleoid compaction, and integrative recombination. The mIHF contains a region of 86 amino acids at its N terminus, absent from both α- and β-subunits of Escherichia coli IHF. However, the functional significance of an extra 86-amino-acid region in the full-length protein remains unknown. Here, we report the structure/function relationship of the DNA-binding and integrative recombination-stimulating activity of mIHF. Deletion mutagenesis showed that an extra 86-amino-acid region at the N terminus is dispensable; the C-terminal region possesses the sequences essential for its known biological functions, including the ability to suppress the sensitivity of E. coli ΔihfA and ΔihfB cells to DNA-damaging agents, DNA binding, DNA multimerization-circularization, and stimulation of phage L5 integrase-catalyzed integrative recombination. Single and double alanine substitutions at positions Arg170 and Arg171, located at the mIHF DNA-binding site, abrogated its capacity to suppress the sensitivity of E. coli ΔihfA and ΔihfB cells to DNA-damaging agents. The variants encoded by these mutant alleles failed to bind DNA and stimulate integrative recombination. Interestingly, the DNA-binding activity of the mIHF-R173A variant remained largely unaffected; however, it was unable to stimulate integrative recombination, thus revealing a separation-of-function allele of mIHF. The functional and structural characterization of this separation-of-function allele of mIHF could reveal previously unknown functions of IHF.IMPORTANCE The integration host factor of Mycobacterium tuberculosis is a novel nucleoid-associated protein. mIHF plays a vital role in DNA damage response, nucleoid compaction, and integrative recombination. Intriguingly, mIHF contains an extra 86-amino-acid region at its N terminus, absent from both α- and β-subunits of Escherichia coli IHF, whose functional significance is unknown. Furthermore, a triad of arginine residues located at the mIHF-DNA interface have been implicated in a range of its functions. Here, we reveal the roles of N- and C-terminal regions of mIHF and the individual residues in the Arg triad for their ability to provide protection in vivo against DNA damage, bind DNA, and stimulate integrase-catalyzed site-specific recombination.

DNA Topology and the Initiation of Virus DNA Packaging

During progeny assembly, viruses selectively package virion genomes from a nucleic acid pool that includes host nucleic acids. For large dsDNA viruses, including tailed bacteriophages and herpesviruses, immature viral DNA is recognized and translocated into a preformed icosahedral shell, the prohead. Recognition involves specific interactions between the viral packaging enzyme, terminase, and viral DNA recognition sites. Generally, viral DNA is recognized by terminase’s small subunit (TerS). The large terminase subunit (TerL) contains translocation ATPase and endonuclease domains. In phage lambda, TerS binds a sequence repeated three times in cosB, the recognition site. TerS binding to cosB positions TerL to cut the concatemeric DNA at the adjacent nicking site, cosN. TerL introduces staggered nicks in cosN, generating twelve bp cohesive ends. Terminase separates the cohesive ends and remains bound to the cosB-containing end, in a nucleoprotein structure called Complex I. Complex I docks on the prohead’s portal vertex and translocation ensues. DNA topology plays a role in the TerS^λ-cosB^λ interaction. Here we show that a site, I2, located between cosN and cosB, is critically important for an early DNA packaging step. I2 contains a complex static bend. I2 mutations block DNA packaging. I2 mutant DNA is cut by terminase at cosN in vitro, but in vivo, no cos cleavage is detected, nor is there evidence for Complex I. Models for what packaging step might be blocked by I2 mutations are presented.

DNA Packaging Specificity of Bacteriophage N15 with an Excursion into the Genetics of a Cohesive End Mismatch

During DNA replication by the λ-like bacteriophages, immature concatemeric DNA is produced by rolling circle replication. The concatemers are processed into mature chromosomes with cohesive ends, and packaged into prohead shells, during virion assembly. Cohesive ends are generated by the viral enzyme terminase, which introduces staggered nicks at cos, an approx. 200 bp-long sequence containing subsites cosQ, cosN and cosB. Interactions of cos subsites of immature concatemeric DNA with terminase orchestrate DNA processing and packaging. To initiate DNA packaging, terminase interacts with cosB and nicks cosN. The cohesive ends of N15 DNA differ from those of λ at 2/12 positions. Genetic experiments show that phages with chromosomes containing mismatched cohesive ends are functional. In at least some infections, the cohesive end mismatch persists through cyclization and replication, so that progeny phages of both allelic types are produced in the infected cell. N15 possesses an asymmetric packaging specificity: N15 DNA is not packaged by phages λ or 21, but surprisingly, N15-specific terminase packages λ DNA. Implications for genetic interactions among λ-like bacteriophages are discussed.

Novel DNA packaging recognition in the unusual bacteriophage N15

Phage lambda's cosB packaging recognition site is tripartite, consisting of 3 TerS binding sites, called R sequences. TerS binding to the critical R3 site positions the TerL endonuclease for nicking cosN to generate cohesive ends. The N15 cos (cos(N15)) is closely related to cos(λ), but whereas the cosB(N15) subsite has R3, it lacks the R2 and R1 sites and the IHF binding site of cosB(λ). A bioinformatic study of N15-like phages indicates that cosB(N15) also has an accessory, remote rR2 site, which is proposed to increase packaging efficiency, like R2 and R1 of lambda. N15 plus five prophages all have the rR2 sequence, which is located in the TerS-encoding 1 gene, approximately 200 bp distal to R3. An additional set of four highly related prophages, exemplified by Monarch, has R3 sequence, but also has R2 and R1 sequences characteristic of cosB-λ. The DNA binding domain of TerS-N15 is a dimer.

Modulation of the sensitivity of FimB recombination to branched-chain amino acids and alanine in Escherichia coli K-12

Phase variation of type 1 fimbriae of Escherichia coli requires the site-specific recombination of a short invertible element. Inversion is catalyzed by FimB (switching in either direction) or FimE (inversion mainly from on to off) and is influenced by auxiliary factors integration host factor (IHF) and leucine-responsive regulatory protein (Lrp). These proteins bind to sites (IHF site II and Lrp sites 1 and 2) within the invertible element to stimulate recombination, presumably by bending the DNA to enhance synapses. Interaction of Lrp with a third site (site 3) cooperatively with sites 1 and 2 (termed complex 1) impedes recombination. Inversion is stimulated by the branched-chain amino acids (particularly leucine) and alanine, and according to a current model, the amino acids promote the selective loss of Lrp from site 3 (complex 2). Here we show that the central portion of the fim invertible element, situated between Lrp site 3 and IHF site II, is dispensable for FimB recombination but that this region is also required for full amino acid stimulation of inversion. Further work reveals that the region is likely to contain multiple regulatory elements. Lrp site 3 is shown to bind the regulatory protein with low affinity, and a mutation that enhances binding to this element is found both to diminish the stimulatory effects of IVLA on FimB recombination and to inhibit recombination in the absence of the amino acids. The results obtained emphasize the importance of Lrp site 3 as a control element but also highlight the complexity of the regulatory system that affects this site.

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.

Biochemical characterization of bacteriophage lambda genome packaging in vitro

Bacteriophage lambda has been extensively studied, and the abundance of genetic and biochemical information available makes this an ideal model system to study virus DNA packaging at the molecular level. Limited in vitro packaging efficiency has hampered progress toward this end, however. It has been suggested that limited packaging efficiency is related to poor activity of purified procapsids. We describe the construction of a vector that expresses lambda procapsids with a yield that is 40-fold greater than existing systems. Consistent with previous studies, packaging of a mature lambda genome is very inefficient in vitro, with only 4% of the input procapsids utilized. Concatemeric DNA is the preferred packaging substrate in vivo, and procapsids interact with a nucleoprotein complex known as complex I to initiate genome packaging. When complex I is used as a packaging substrate in vitro, capsid utilization is extremely efficient, and 40% of the input DNA is packaged. Finally, we provide evidence for a packaging-stimulated ATPase activity, and kinetically characterize this reaction quantifying the energetic cost of DNA packaging in bacteriophage lambda.

Insights into specific DNA recognition during the assembly of a viral genome packaging machine

Terminase enzymes mediate genome "packaging" during the reproduction of DNA viruses. In lambda, the gpNu1 subunit guides site-specific assembly of terminase onto DNA. The structure of the dimeric DNA binding domain of gpNu1 was solved using nuclear magnetic resonance spectroscopy. Its fold contains a unique winged helix-turn-helix (wHTH) motif within a novel scaffold. Surprisingly, a predicted P loop ATP binding motif is in fact the wing of the DNA binding motif. Structural and genetic analysis has identified determinants of DNA recognition specificity within the wHTH motif and the DNA recognition sequence. The structure reveals an unexpected DNA binding mode and provides a mechanistic basis for the concerted action of gpNu1 and Escherichia coli integration host factor during assembly of the packaging machinery.

Alterations of the portal protein, gpB, of bacteriophage lambda suppress mutations in cosQ, the site required for termination of DNA packaging

The cosQ site of bacteriophage lambda is required for DNA packaging termination. Previous studies have shown that cosQ mutations can be suppressed in three ways: by a local suppressor within cosQ, an increase in the length of the lambda chromosome, and missense mutations affecting the prohead's portal protein, gpB. In the present work, revertants of a set of lethal cosQ mutants were screened for suppressors. Seven new cosQ suppressors affected gene B, which encodes the portal protein of the prohead. All seven were allele-nonspecific suppressors of cosQ mutations. Experiments with several phages having two cosQ suppressors showed that the suppression effects were additive. Furthermore, these double suppressors had minimal effects on the growth of cosQ(+) phages. These trans-acting suppressors affecting the portal protein are proposed to allow the mutant cosQ site to be more efficiently recognized, due to the slowing of the rate of translocation.

Endonuclease and helicase activities of bacteriophage lambda terminase: changing nearby residue 515 restores activity to the gpA K497D mutant enzyme

Terminase, the DNA packaging enzyme of bacteriophage lambda, is a heteromultimer of gpNu1 and gpA subunits. In an earlier investigation, a lethal mutation changing gpA residue 497 from lysine to aspartic acid (K497D) was found to cause a mild change in the high-affinity ATPase that resides in gpA and a severe defect in the endonuclease activity of terminase. The K497D terminase efficiently sponsored packaging of mature lambda DNA into proheads. In the present work, K497D terminase was found to have a severe defect in the cohesive end separation, or helicase, activity. Plaque-forming pseudorevertants of lambda A K497D were found to carry mutations in A that suppressed the lethality of the A K497D mutation. The two suppressor mutations identified, A E515G and A E515K, affected residue 515, which is located near the putative P-loop of gpA. A codon substitution study of codon 515 showed that hydrophobic and basic residues suppress the K497D defect, but hydrophilic and acidic residues do not. The E515G change was demonstrated to reverse the endonuclease and helicase defects caused by the K497D change. Moreover, the gpA K497D E515G enzyme was found to have kinetic constants for the high-affinity ATPase center similar to those of the wild type enzyme, and the endonuclease activity of the K497D E515G enzyme was stimulated by ATP to an extent similar to the ATP stimulation of the endonuclease activity of the wild type enzyme.

DNA bending and twisting properties of integration host factor determined by DNA cyclization

The binding of many proteins to DNA is profoundly affected by DNA bending, twisting, and supercoiling. When protein binding alters DNA conformation, interaction between inherent and induced DNA conformation can affect protein binding affinity and specificity. Integration host factor (IHF), a sequence-specific, DNA-binding protein of Escherichia coli, strongly bends the DNA upon binding. To assess the influence of inherent DNA bending on IHF binding, we took advantage of the high degree of natural static curvature associated with an IHF site on a 163-bp minicircle and measured the binding affinity of IHF for its recognition site contained on this DNA in both circular and linear form. IHF showed a higher affinity for the circular form of the DNA when compared to the linear form. In addition, the presence of IHF during DNA cyclization changed the topology of cyclization products and their ability to bind IHF, consistent with IHF untwisting DNA. These results show that inherent DNA conformation anisotropy is an important determinant of IHF binding affinity and suggests a mechanism for modulation of IHF activity by local DNA conformation.

A mutation correcting the DNA interaction defects of a mutant phage lambda terminase, gpNu1 K35A terminase

Terminase, the DNA packaging enzyme of bacteriophage lambda, is a heteromultimer composed of gpNu1 (181 aa) and gpA (641 aa) subunits, encoded by the lambda Nu1 and A genes, respectively. Similarity between the deduced amino acid sequences of gpNu1 and gpA and the nucleotide binding site consensus sequence suggests that each terminase subunit has an ATP reactive center. Terminase has been shown to have two distinct ATPase activities. The gpNu1 subunit has a low-affinity ATPase stimulated by nonspecific DNA and gpA has a high-affinity ATPase. In previous work, a mutant terminase, gpNu1 K35A holoterminase, had a mild defect in interactions with DNA, such that twofold increased DNA concentrations were required both for full stimulation of the low-affinity ATPase and for saturation of the cos cleavage reaction. In addition, the gpNu1 K35A terminase exhibited a post-cleavage defect in DNA packaging that accounted for the lethality of the Nu1 K35A mutation [Y. Hwang and M. Feiss (1997) Virology 231, 218-230]. In the work reported here, a mutation in the turn of the putative helix-turn-helix DNA binding domain has been isolated as a suppressor of the gpNu1 K35A change. This suppressor mutation causes the change A14V in gpNu1. A14V reverses the DNA-binding defects of gpNu1 K35A terminase, both for stimulation of the low-affinity ATPase and for saturation of the cos cleavage defect. A14V suppresses the post-cleavage DNA packaging defect caused by the gpNu1 K35A change.

The extended promoters for two outer membrane lipoprotein genes of Borrelia spp. uniquely include a T-rich region

OspA and B proteins of Borrelia burgdorferi and Vmp proteins of Borrelia hermsii are abundant outer membrane lipoproteins, whose expression varies with the environment. The genes for these proteins have the '-35' and '-10' elements of a sigma70-type promoter. Deletions of the promoters for these genes were analysed with a chloramphenicol acetyltransferase (CAT) reporter gene and plasmid constructs that were stably maintained in Escherichia coli or transiently transfected into B. burgdorferi. Reporter expression was measured as susceptibility of transformed E. coli cells to chloramphenicol and the CAT activity of E. coli and B. burgdorferi lysates in vitro. Presence of the '-10' element was essential for full activity in both B. burgdorferi and E. coli. Upstream of the '-35' elements of the ospAB and vmp promoters were tracts with Ts in 16 of 20 positions for B. burgdorferi and 18 of 20 positions for B. hermsii. Deletion of the T-rich region from the ospAB or vmp promoter caused a greater reduction of CAT activity in B. burgdorferi than in E. coli. The findings indicate that ospAB and vmp promoters are extended promoters with two parts: (i) a core region containing typical '-35' and '-10' elements and (ii) a unique T-rich region.

Transcription regulation by repressosome and by RNA polymerase contact

The original model of repression of transcription initiation is steric interference of RNA polymerase binding to a promoter by its repressor protein bound to a DNA site that overlaps the promoter. From the results described here, we propose two other mechanisms of repressor action, both of which involve formation of higher-order DNA-multiprotein complexes. These models also explain the problem of RNA polymerase gaining access to a promoter in the condensed nucleoid in response to an inducing signal to initiate transcription.

Mutations that extend the specificity of the endonuclease activity of lambda terminase

Terminase, an enzyme encoded by the Nu1 and A genes of bacteriophage lambda, is crucial for packaging concatemeric DNA into virions. cosN, a 22-bp segment, is the site on the virus chromosome where terminase introduces staggered nicks to cut the concatemer to generate unit-length virion chromosomes. Although cosN is rotationally symmetric, mutations in cosN have asymmetric effects. The cosN G2C mutation (a G-to-C change at position 2) in the left half of cosN reduces the phage yield 10-fold, whereas the symmetric mutation cosN C11G, in the right half of cosN, does not affect the burst size. The reduction in phage yield caused by cosN G2C is correlated with a defect in cos cleavage. Three suppressors of the cosN G2C mutation, A-E515G, A-N509K, and A-R504C, have been isolated that restore the yield of lambda cosN G2C to the wild-type level. The suppressors are missense mutations that alter amino acids located near an ATPase domain of gpA. lambda A-E515G, A-N509K, and A-R504C phages, which are cosN+, also had wild-type burst sizes. In vitro cos cleavage experiments on cosN G2C C11G DNA showed that the rate of cleavage for A-E515G terminase is three- to fourfold higher than for wild-type terminase. The A-E515G mutation changes residue 515 of gpA from glutamic acid to glycine. Uncharged polar and hydrophobic residues at position 515 suppressed the growth defect of lambda cosN G2C C11G. In contrast, basic (K, R) and acidic (E, D) residues at position 515 failed to suppress the growth defect of lambda cosN G2C C11G. In a lambda cosN+ background, all amino acids tested at position 515 were functional. These results suggest that A-E515G plays an indirect role in extending the specificity of the endonuclease activity of lambda terminase.

Gene activation by the AraC protein can be inhibited by DNA looping between AraC and a LexA repressor that interacts with AraC: possible applications as a two-hybrid system

The Escherichia coli activator and repressor proteins AraC and LexA bind DNA as homodimers. Here we show that their heterodimerization through fused cognate dimerization domains results in repression of AraC-dependent gene activation by LexA. Repression also requires a LexA operator half-site located several helical turns downstream of the AraC operator. This requirement for a specific spatial organization of the operators suggests the formation of a DNA loop between operator-bound Ara/LexA heterodimers, and we propose that heterodimerization with the AraC hybrid provides co-operativity for operator binding and repression by the LexA hybrid. Consistent with a mechanism that involves DNA looping, repression increases when the E. coli DNA looping and transcriptional effector protein IHF binds between the AraC and LexA operators. Thus, we have combined the functions of three distinct transcriptional effector proteins to achieve a new mode of gene regulation by DNA looping, in which the activator protein is an essential part of the repressor complex. The flexibility of the DNA loop may facilitate this novel combinatorial arrangement of those proteins on the DNA. The requirement for protein interactions between the AraC and LexA hybrids for gene regulation suggests that this regulatory circuit may prove useful as an E. coli-based two-hybrid system.

Termination of packaging of the bacteriophage lambda chromosome: cosQ is required for nicking the bottom strand of cosN

Termination of packaging of the lambda chromosome involves completion of translocation of the DNA into the head shell, and conversion of the translocation complex into a cleavage complex. The cleavage reaction introduces staggered nicks into the downstream cosN to generate the right cohesive end of the chromosome. cosQ, a site adjacent to cosN, was found to be required for nicking the bottom strand of cosN; bottom strand nicking was also sequence-specific for bps at the nick site. Nicking of the top strand of cosN (cosNL) was stimulated by cosQ, but fidelity and efficiency of cosNL nicking were largely dictated by other cos subsites (i.e. cosB and I2). Aberrant top-strand cleavage within cosQ was observed in the absence of I2, and nicking at a site 8 nt 5' to the normal cosNL nick site occurred in the absence of cosB. The presence of cosQ was found to be insufficient to arrest DNA translocation in vivo, indicating that cosQ, per se, is not a packaging stop signal. A model is presented in which the role of cosQ is to depolarize the asymmetric arrangement of terminase protomers in the translocation complex so that protomers are configured to match the 2-fold rotational symmetry of cosN.

Leucine alters the interaction of the leucine-responsive regulatory protein (Lrp) with the fim switch to stimulate site-specific recombination in Escherichia coli

The leucine-responsive regulatory protein (Lrp) is a global regulator that controls the expression of numerous operons in Escherichia coli. Lrp can act as a repressor or as an activator of transcription with its effects being potentiated, repressed or unaffected by the presence of exogenous leucine. The phase variation of type 1 fimbria in E. coli provides a unique system in which to investigate the effects of leucine on Lrp, as it is the only known example in which Lrp is a positive regulator and leucine potentiates this effect. Previous studies determined that Lrp binds with high affinity to two sites within the fim switch (fim sites 1 and 2), and binding to these sites stimulates recombination. Here, it is shown that, even though leucine stimulates the fim switch in vivo, it nevertheless causes a slight decrease in Lrp binding to the fim switch in vitro. These contradictory results are explicable by the finding that Lrp binding to a third region adjacent to fim sites 1 and 2 inhibits recombination. According to this model, leucine stimulates recombination by selectively disrupting Lrp binding to this newly characterized region, while having little or no effect on Lrp binding to fim sites 1 and 2.

Nuclear magnetic resonance-based model of a TF1/HmU-DNA complex

Transcription factor 1 (TF1), a type II DNA-binding protein encoded by the Bacillus subtilis bacteriophage SPO1, has the capacity for sequence-selective DNA binding and a preference for 5-hydroxymethyl-2'-deoxyuridine (HmU)-containing DNA. In NMR studies of the TF1/HmU-DNA complex, intermolecular NOEs indicate that the flexible beta-ribbon and C-terminal alpha-helix are involved in the DNA-binding site of TF1, placing it in the beta-sheet category of DNA-binding proteins proposed to bind by wrapping two beta-ribbon "arms" around the DNA. Intermolecular and intramolecular NOEs were used to generate an energy-minimized model of the protein-DNA complex in which both DNA bending and protein structure changes are evident.

Genetic evidence that recognition of cosQ, the signal for termination of phage lambda DNA packaging, depends on the extent of head filling

Packaging a phage lambda chromosome involves cutting the chromosome from a concatemer and translocating the DNA into a prohead. The cutting site, cos, consists of three subsites: cosN, the nicking site; cosB, a site required for packaging initiation; and cosQ a site required for termination of packaging. cosB contains three binding sites (R sequences) for gpNu1, the small subunit of terminase. Because cosQ has sequence identity to the R sequences, it has been proposed that cosQ is also recognized by gpNu1. Suppressors of cosB mutations were unable to suppress a cosQ point mutation. Suppressors of a cosQ mutation (cosQ1) were isolated and found to be of three sorts, the first affecting a base pair in cosQ. The second type of cosQ suppression involved increasing the length of the phage chromosome to a length near to the maximum capacity of the head shell. A third class of suppressors were missense mutations in gene B, which encodes the portal protein of the virion. It is speculated that increasing DNA length and altering the portal protein may reduce the rate of translocation, thereby increasing the efficiency of recognition of the mutant cosQ. None of the cosQ suppressors was able to suppress cosB mutations. Because cosQ and cosB mutations are suppressed by very different types of suppressors, it is concluded that cosQ and the R sequences of cosB are recognized by different DNA-binding determinants.

Mutations in Nu1, the gene encoding the small subunit of bacteriophage lambda terminase, suppress the postcleavage DNA packaging defect of cosB mutations

The linear double-stranded DNA molecules in lambda virions are generated by nicking of concatemeric intracellular DNA by terminase, the lambda DNA packaging enzyme. Staggered nicks are introduced at cosN to generate the cohesive ends of virion DNA. After nicking, the cohesive ends are separated by terminase; terminase bound to the left end of the DNA to be packaged then binds the empty protein shell, i.e., the prohead, and translocation of DNA into the prohead occurs. cosB, a site adjacent to cosN, is a terminase binding site. cosB facilitates the rate and fidelity of the cosN cleavage reaction by serving as an anchoring point for gpNu1, the small subunit of terminase. cosB is also crucial for the formation of a stable terminase-DNA complex, called complex I, formed after cosN cleavage. The role of complex I is to bind the prohead. Mutations in cosB affect both cosB functions, causing mild defects in cosN cleavage and severe packaging defects. The lethal cosB R3- R2- R1- mutation contains a transition mutation in each of the three gpNu1 binding sites of cosB. Pseudorevertants of lambda cosB R3- R2- R1- DNA contain suppressor mutations affecting gpNu1. Results of experiments that show that two such suppressors, Nu1ms1 and Nu1ms3, do not suppress the mild cosN cleavage defect caused by the cosB R3- R2- R1- mutation but strongly suppress the DNA packaging defect are presented. It is proposed that the suppressing terminases, unlike the wild-type enzyme, are able to assemble a stable complex I with cosB R3- R2- R1- DNA. Observations on the adenosine triphosphatase activities and protease susceptibilities of gpNu1 of the Nu1ms1 and Nu1ms3 terminases indicate that the conformation of gpNu1 is altered in the suppressing terminases.

Coactivation in vitro of the sigma54-dependent promoter Pu of the TOL plasmid of Pseudomonas putida by HU and the mammalian HMG-1 protein

The mechanism by which the prokaryotic histone-like protein HU replaces the integration host factor (IHF) in the coactivation of the sigma54-dependent promoter Pu of Pseudomonas putida has been investigated. By using a preactivated form of the cognate activator protein XylR, we show that the functional replacement of IHF with HU previously suggested in vivo can be faithfully reproduced in vitro with purified components. Furthermore, the coactivation effect of IHF on Pu could be mimicked not only by HU but also by the mammalian nonhistone chromatin protein HMG-1 and could be bypassed by intrinsically curved DNA. These results suggest that either of two different mechanisms (generation of a site-specific static DNA bend or a general flexibilization of the promoter region) gives rise to the same structural effect of stimulating transcription from Pu through changes in promoter architecture.

Influence of DNA geometry on transcriptional activation in Escherichia coli

Transcription from many Escherichia coli promoters can be activated by the cAMP-CRP complex bound at different locations upstream of the promoter. At some locations the mechanism of activation involves direct protein-protein contacts between CRP and the RNA polymerase. We positioned the CRP binding site at various distances from the transcription start site of the malT promoter and measured the in vivo activities of these promoter variants. From the activation profiles we deduce that the protein-protein interactions involved in transcriptional activation are rather rigid. A heterologous protein (IHF) that bends the DNA to a similar degree as does CRP activates transcription when bound at sites equivalent to activating positions for CRP. DNA geometry makes a major contribution to the process of transcriptional activation and DNA upstream of the activator binding site participates in this process. Removal of this DNA decreases the capacity of the malT promoter to be activated by CRP in vitro. We conclude that both DNA topology and direct protein-protein contacts contribute to transcriptional activation and that the relative importance of these two modes of activation depends on the nature of the activator and on the location of the activator binding site.

The in vitro translocase activity of lambda terminase and its subunits. Kinetic and biochemical analysis

The terminase holoenzyme of bacteriophage lambda is a multifunctional protein composed of two subunits, gpNu1 and gpA. In vitro, under certain conditions, terminase can render DNAs from various sources, of varying lengths and termini, resistant to degradation by high concentrations of DNase I. This reaction is completely dependent on the presence of terminase, proheads, a hydrolyzable triphosphate, and a divalent metal ion, and we propose that it is the result of translocation of DNA into proheads by terminase. This reaction is stoichiometric with respect to terminase, DNA, and proheads and can be supported by all deoxyribo- and ribonucleoside triphosphates, but not by the corresponding diphosphates or nonhydrolyzable ATP analogs. Mg2+ and Ca2+ promote the reaction, but Mn2+ and Zn2+ do not. In the absence of spermidine, translocase activity is low, but addition of the Escherichia coli protein integration host factor (IHF) promotes specific translocation of only those DNA fragments containing the terminase-binding site, cosB. When spermidine is present, nonspecific translocation of DNA from any source is stimulated. Under these conditions IHF no longer promotes specificity, but translocation of only cosB-containing DNA fragments can be restored by addition of small amounts of a dialyzed and RNase-treated E. coli extract, suggesting that additional host factor(s) may be involved in determination of packaging specificity. To a limited extent, gpA alone can promote translocation, but gpNu1, which has no translocase activity on its own, must be added to approach the holoenzyme-like activity levels. Formation of viable phage cannot be accomplished by gpA in the absence of gpNu1.

Studies on the binding of integration host factor (IHF) and TraM to the origin of transfer of the IncFV plasmid pED208

The origin of transfer (oriT) of the IncFV plasmid pED208 contains a region with three binding sites for both the plasmid-encoded TraM protein and the integration host factor (IHF) of Escherichia coli, a sequence-specific DNA-binding protein. One region, containing overlapping TraM and IHF binding sites, could be interpreted as containing two binding sites for each protein. Using gel retardation assays, an affinity constant for IHF binding to the three main sites was estimated in the presence and absence of 0.1 M potassium glutamate, which increased the avidity of IHF binding to the weaker sites by two orders of magnitude. DNase I protection analyses and electron microscopy were used to determine the affinity of IHF for oriT-containing DNA in the presence and absence of TraM. The binding of IHF and TraM was found to be non-cooperative by the two techniques employed. Electron microscopy also demonstrated that IHF bent the oriT region in a manner consistent with its previously determined mode of action, while TraM had no discernible effect on the appearance of the DNA. This suggested that IHF and TraM interact with a 295 bp sequence in the oriT region and organize it into a higher order structure that may have a role in the initiation of DNA transfer and control of traM expression.

Mutual stabilisation of bacteriophage Mu repressor and histone-like proteins in a nucleoprotein structure

Integration host factor (IHF) binds in a sequence-specific manner to the bacteriophage Mu early operator. It participates with bound Mu repressor, c, in building stable, large molecular mass nucleoprotein complexes in vitro and enhances repression of early transcription in vivo. We demonstrate that, when the specific IHF binding site with the operator is mutated, the appearance of large molecular mass complexes still depends on IHF and c, but the efficiency of their formation is reduced. Moreover, the IHF-like HU protein, which binds DNA in a non-sequence-specific way, can substitute for IHF and participate in complex formation. Since the complexes require both c and a host factor (IHF or HU), the results imply that these proteins stabilise each other within the nucleoprotein structures. These results suggest that IHF and HU are directed to the repressor-operator complexes, even in the absence of detectable sequence-specific binding. This could be a consequence of their preferential recognition of DNA containing a distortion such as that introduced by repressor binding to the operator. The histone-like proteins could then stabilise the nucleoprotein complexes simply by their capacity to maintain a bend in DNA rather than by specific protein-protein interactions with c. This model is supported by the observation that the unrelated eukaryotic HMG-1 protein, which exhibits a similar marked preference for structurally deformed DNA, is also able to participate in the formation of higher-order complexes with c and the operator DNA.

Virus DNA packaging: the strategy used by phage lambda

Phage lambda, like a number of other large DNA bacteriophages and the herpesviruses, produces concatemeric DNA during DNA replication. The concatemeric DNA is processed to produce unit-length, virion DNA by cutting at specific sites along the concatemer. DNA cutting is co-ordinated with DNA packaging, the process of translocation of the cut DNA into the preformed capsid precursor, the prohead. A key player in the lambda DNA packaging process is the phage-encoded enzyme terminase, which is involved in (i) recognition of the concatemeric lambda DNA; (ii) initiation of packaging, which includes the introduction of staggered nicks at cosN to generate the cohesive ends of virion DNA and the binding of the prohead; (iii) DNA packaging, possibly including the ATP-driven DNA translocation; and (iv) following translocation, the cutting of the terminal cosN to complete DNA packaging. To one side of cosN is the site cosB, which plays a role in the initiation of packaging; along with ATP, cosB stimulates the efficiency and adds fidelity to the endonuclease activity of terminase in cutting cosN. cosB is essential for the formation of a post-cleavage complex with terminase, complex I, that binds the prohead, forming a ternary assembly, complex II. Terminase interacts with cosN through its large subunit, gpA, and the small terminase subunit, gpNu1, interacts with cosB. Packaging follows complex II formation. cosN is flanked on the other side by the site cosQ, which is needed for termination, but not initiation, of DNA packaging. cosQ is required for cutting of the second cosN, i.e. the cosN at which termination occurs. DNA packaging in lambda has aspects that differ from other lambda DNA transactions. Unlike the site-specific recombination system of lambda, for DNA packaging the initial site-specific protein assemblage gives way to a mobile, translocating complex, and unlike the DNA replication system of lambda, the same protein machinery is used for both initiation and translocation during lambda DNA packaging.

Specific binding of the NikA protein to one arm of 17-base-pair inverted repeat sequences within the oriT region of plasmid R64

Products of the nikA and nikB genes of plasmid R64 have been shown to form a relaxation complex with R64 oriT DNA and to function together as an oriT-specific nickase. We purified the protein product of the nikA gene. The purified NikA protein bound specifically to the oriT region of R64 DNA. Gel retardation assays and DNase I footprinting analyses indicated that the NikA protein bound only to the right arm of 17-bp inverted repeat sequences; the right arm differed from the left arm by a single nucleotide. The binding site is proximal to the nick site and within the 44-bp oriT core sequence. Binding of the NikA protein induced DNA bending within the R64 oriT sequence.

Integration host factor and sequences downstream of the Pseudomonas aeruginosa algD transcription start site are required for expression

Pseudomonas aeruginosa is an extremely important opportunistic pathogen in immunocompromised individuals. Strains of P. aeruginosa isolated from chronic lung infections in patients with the genetic disease cystic fibrosis have a mucoid colony morphology. This phenotype is due to overproduction of the exopolysaccharide alginate, which is believed to confer a selective advantage on P. aeruginosa in cystic fibrosis lungs. Alginate biosynthesis is controlled by a complex regulatory mechanism. Genes located in the 34-min region of the P. aeruginosa chromosome form an operon which encodes most of the biosynthetic enzymes necessary for alginate production. algD, the first gene in the operon and a critical point for the transcriptional regulation of alginate biosynthesis, is controlled by several trans, cis, and environmental factors. In this study, the involvement of the histone-like protein integration host factor (IHF) in algD expression was examined. Sequences with similarity to consensus IHF-binding sites of Escherichia coli were identified 75 bp upstream (site 1) and 90 bp downstream (site 2) of the start of algD transcription. In gel band mobility shift assays, DNA fragments containing either site bind IHF but site 2 has an approximately 90-fold higher affinity for IHF. Mutations in each of the elements were generated, and they resulted in the reduction or loss of in vitro IHF binding and a three- to fourfold decrease in algD-cat expression. This indicates that IHF binding is necessary for high-level algD transcription. The presence of a high-affinity IHF-binding site located 3' of the algD transcription start site suggested that sequences further downstream of this element are involved in algD expression. When a fragment located downstream of site 2 and upstream of the promoterless cat gene (+110 to +835) was deleted, algD-cat expression was reduced 10-fold supporting the notion that 3' enhancer elements are required for algD transcription. This is the first direct evidence of a 3' element involved in the control of a P. aeruginosa gene. It is postulated that IHF mediates the formation of a higher-order looped structure which is necessary for efficient algD transcription.

Growth phase variation of integration host factor level in Escherichia coli

We have measured the intracellular abundance of integration host factor (IHF), a site-specific, heterodimeric DNA-binding protein, in exponential- and stationary-phase cultures of Escherichia coli K-12. Western immunoblot analysis showed that cultures that had been growing exponentially for several generations contained 0.5 to 1.0 ng of IHF subunits per microgram of total protein and that this increased to 5 to 6 ng/microgram in late-stationary-phase cultures. IHF is about one-third to one-half as abundant in exponentially growing cells as HU, a structurally related protein that binds DNA with little or no site specificity. Wild-type IHF is metabolically stable, but deletion mutations that eliminated one subunit reduced the abundance of the other when cells enter stationary phase. We attribute this reduction to the loss of stabilizing interactions between subunits. A mutation that inactivates IHF function but not subunit interaction increased IHF abundance, consistent with results of previous work showing that IHF synthesis is negatively autoregulated. We estimate that steady-state exponential-phase cultures contain about 8,500 to 17,000 IHF dimers per cell, a surprisingly large number for a site-specific DNA-binding protein with a limited number of specific sites. Nevertheless, small reductions in IHF abundance had significant effects on several IHF-dependent functions, suggesting that the wild-type exponential phase level is not in large excess of the minimum required for occupancy of physiologically important IHF-binding sites.

Analysis of the cos region of the Lactococcus lactis bacteriophage sk1

The location, structure and nature of the cos site of the Lactococcus lactis bacteriophage sk1 was determined using a Taq DNA polymerase runoff sequencing technique. The cos site contains a single-stranded 3' overhang of 11 nucleotides. The region surrounding cos contains several features which may be involved in the binding and catalytic action of a phage terminase. These include four putative terminase-binding sites which show some homology to lambda R-sites, an 11-bp direct repeat, a 10-bp inverted repeat, a string of eight consecutive C residues and six copies of the pentanucleotide, AATCT. The spacing between adjacent copies of the pentanucleotides would place them on the same side of the DNA helix.

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.

Multiple molecules of integration host factor (IHF) at a single DNA binding site, the bacteriophage lambda cos I1 site

Integration host factor (IHF) is an E coli protein that binds DNA sequence-specifically and serves as a cofactor in many intracellular processes including lambda DNA packaging. In gel shift experiments, cos DNA, a DNA fragment containing the recognition signal for lambda DNA packaging, forms multiple protein-DNA complexes when combined with pure IHF. Copper(II)-1,10 orthophenanthroline footprinting of individual IHF-cos DNA complexes shows that multiple complex formation does not result from IHF binding to successive sites on the cos DNA fragment. Instead, the footprinting of DNA from two IHF-cos complexes shows protection at one site alone. DNA in the first complex is only partially protected from nucleolytic cleavage, while DNA in the second, slower-moving, complex is completely protected at the same binding site. Quantitative Western blotting experiments determined the relative stoichiometry of IHF to DNA in the two complexes. The results confirm that two molecules of IHF bind at a single site in the cos fragment. This site, cos I1, has two matches to the IHF consensus sequence, but the two matches overlap by eight of thirteen nucleotides. A search of the DNA sequence around cos, using an expanded IHF consensus sequence, has revealed additional, low-affinity consensus matches, contiguous to these. The extent of the copper(II)-1,10 orthophenanthroline footprint and the stoichiometry of the IHF-cos I1 complexes suggest that either two molecules of IHF bind to overlapping sites, or IHF binds to a site of low affinity contiguous to a strong site. Application of a thermodynamic model to the results of gel shift experiments with IHF and cos DNA suggests that multiple complex formation requires cooperative interaction between the two IHF binding sites.

A site required for termination of packaging of the phage lambda chromosome

Lambda chromosomes are cut and packaged from concatemeric DNA by phage enzyme terminase. Terminase initiates DNA packaging by binding at a site called cosB and introducing staggered nicks at an adjacent site, cosN, to generate the left cohesive end of the DNA molecule to be packaged. After DNA packaging terminase recognizes and cuts the terminal cosN, an event that does not require a wild-type cosB. In this work a site, called cosQ, has been identified that is required for termination of DNA packaging. cosQ, defined by mutations in a sequence called R4, is located approximately 30 bp upstream from cosN. The order of sites is cosQ-cosN-cosB. Helper packaging of repressed, tandem prophage chromosomes demonstrated that a cosQ point mutation affects DNA packaging only when placed at the terminal cos site, whereas cosB mutations only affect packaging initiation. In vitro packaging studies confirmed that cosQ mutations do not affect packaging initiation. In vivo studies indicated that cosQ mutations do not affect cutting of initial cos sites but do cause a defect in packaging termination. cosQ mutants accumulated expanded phage heads, indicating that cosQ mutations affect a step that occurs after packaging of a substantial length of phage DNA. These results show that cosQ mutations define a site required for use of cos sites present at the ends of lambda chromosomes undergoing packaging. Available evidence suggests that other viruses, including phages T3 and T7 and the herpesviruses, may ultimately prove to use cosQ-like sites for packaging termination.

Mechanistic and structural complexity in the site-specific recombination pathways of Int and FLP

This review focuses on two of the approximately 30 members of the diverse Int family of site-specific recombinases. The lambda recombination system represents those reactions involving accessory proteins and a complex higher-order structure. The FLP system represents the most streamlined reactions and has been the subject of detailed and informative studies on the mechanisms of DNA cleavage and ligation.

Two-dimensional gel selection of protein binding sites on DNA

We have developed a gel electrophoretic approach for visualizing and cloning protein binding sites from complete genomes. This system consists of a simple two-dimensional band shift, in which protein-DNA complexes are retarded in the first dimension, performed at low temperature, and disrupted in the second dimension, performed at high temperature. We present here results obtained with the integration host factor (IHF) and cAMP receptor protein (CRP) proteins of Escherichia coli, and discuss some of the important methodological aspects of the technique.

Deformation of DNA during site-specific recombination of bacteriophage lambda: replacement of IHF protein by HU protein or sequence-directed bends

Escherichia coli IHF protein is a prominent component of bacteriophage lambda integration and excision that binds specifically to DNA. We find that the homologous protein HU, a nonspecific DNA binding protein, can substitute for IHF during excisive recombination of a plasmid containing the prophage attachment sites attL and attR but not during integrative recombination between attP and attB. We have examined whether IHF and HU function in excisive recombination is mediated through DNA bending. Our strategy has been to construct chimeric attachment sites in which IHF binding sites are replaced by an alternative source of DNA deformation. Previously, we demonstrated that properly phased bends can substitute for the binding of IHF at one site in attP. Although this result is highly suggestive of a critical role of IHF-promoted bending in lambda integration, its interpretation is obscured by the continued need for IHF binding to the remaining IHF sites of these constructs. In the present work, we engineered a population of sequence-directed bends in the vicinity of the two essential IHF sites found in attR and attL. Even in the absence of IHF or HU, pairs of these attachment sites with properly phased bends are active for both in vitro and in vivo excision. This success, although tempered by the limited efficiency of these systems, reinforces our interpretation that IHF functions primarily as an architectural element.

Genetic analysis of cosB, the binding site for terminase, the DNA packaging enzyme of bacteriophage lambda

cosB, the binding site for terminase, the DNA packaging enzyme of bacteriophage lambda, consists of three binding sites (called R3, R2 and R1) for gpNu1, the small subunit of terminase; and I1, a binding site for integration host factor (IHF), the DNA bending protein of Escherichia coli. cosB is located between cosN, the site where terminase introduces staggered nicks to generate cohesive ends, and the Nu1 gene; the order of sites is: cosN-R3-I1-R2-R1-Nu1. A series of lambda mutants have been constructed that have single base-pair C-to-T transition mutations in R3, R2 and R1. A single base-pair transition mutation within any one of the gpNul binding sites renders lambda dependent upon IHF for plaque formation. lambda phage with mutations in both R2 and R3 are incapable of plaque formation even in the presence of IHF. Phages that carry DNA insertions between R1 and R2, from 7 to 20 base-pairs long, are also IHF-dependent, demonstrating the requirement for a precise spacing of gpNu1 binding sites within cosB. The IHF-dependent phenotype of a lambda mutant carrying a deletion of the R1 sequence indicates that IHF obviates the need for terminase binding to the R1 site. In contrast, a lambda mutant deleted for R2 and R1 fails to form plaques on either IHF+ or IHF- cells, indicating terminase binding of R2 is involved in suppression of R mutants by IHF. A fourth R sequence, R4, is situated on the left side of cosN; a phage with a mutant R4 sequence shows a reduced burst size on both an IHF+ and an IHF- host. The inability of the R4- mutant to be suppressed by IHF, plus the fact that R4 does not bind gpNu1, suggests R4 is not part of cosB and may play a role in DNA packaging that is distinct from that of cosB.

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.

A developmentally regulated Caulobacter flagellar promoter is activated by 3' enhancer and IHF binding elements

The transcription of a group of flagellar genes is temporally and spatially regulated during the Caulobacter crescentus cell cycle. These genes all share the same 5' cis-regulatory elements: a sigma 54 promoter, a binding site for integration host factor (IHF), and an enhancer sequence, known as the ftr element. We have partially purified the ftr-binding proteins, and we show that they require the same enhancer sequences for binding as are required for transcriptional activation. We have also partially purified the Caulobacter homolog of IHF and demonstrate that it can facilitate in vitro integrase-mediated lambda recombination. Using site-directed mutagenesis, we provide the first demonstration that natural enhancer sequences and IHF binding elements that reside 3' to the sigma 54 promoter of a bacterial gene, flaNQ, are required for transcription of the operon, in vivo. The IHF protein and the ftr-binding protein is primarily restricted to the predivisional cell, the cell type in which these promoters are transcribed. flaNQ promoter expression is localized to the swarmer pole of the predivisional cell, as are other flagellar promoters that possess these regulatory sequences 5' to the start site. The requirement for an IHF binding site and an ftr-enhancer element in spatially transcribed flagellar promoters indicates that a common mechanism may be responsible for both temporal and polar transcription.

Lambda Int protein bridges between higher order complexes at two distant chromosomal loci attL and attR

The excisive recombination reaction of bacteriophage lambda involves a specific and efficient juxtaposition of two distant higher order protein-DNA complexes on the chromosome of Escherichia coli. These complexes, which mediate synapsis and strand exchange, consist of two DNA sequences, attL and attR, the bivalent DNA binding protein Int, and the sequence-specific DNA bending proteins, IHF, Xis, and Fis. The protein-protein and protein-DNA interactions within, and between, these complexes were studied by various biochemical techniques and the patterns of synergism among pairs of mutants with marginally impaired recombination function were analyzed. The DNA bending proteins facilitated long-range tethering of high- and low-affinity DNA sites by the bivalent Int protein, and a specific map is proposed for the resulting Int bridges. These structural motifs provide a basis for postulating the mechanism of site-specific recombination and may also be relevant to other pathways in which two distant chromosomal sites become associated.

In vitro interactions of integration host factor with the ompF promoter-regulatory region of Escherichia coli

Previous work has shown that integration host factor (IHF) mutants have increased expression and altered osmoregulation of OmpF, a major Escherichia coli outer membrane protein. By in vitro analysis the possibility was investigated that IHF interacts directly with the ompF promoter region. Gel retardation assays and DNase I protection experiments showed that IHF binds to two sites in the ompF promoter region centered at positions -180 and -60 relative to the start of transcription. Gel electrophoresis studies with circularly permuted ompF promoter fragments indicated that IHF binding strongly increased a small intrinsic bend in the ompF promoter region. The addition of IHF to a purified in vitro transcription system strongly and specifically inhibited ompF transcription. This inhibition was reversed by increasing the concentration of OmpR, a positive activator required for ompF expression, suggesting that IHF may inhibit ompF transcription by altering how OmpR interacts with the ompF promoter.

Crystal structure of a CAP-DNA complex: the DNA is bent by 90 degrees

The 3 angstrom resolution crystal structure of the Escherichia coli catabolite gene activator protein (CAP) complexed with a 30-base pair DNA sequence shows that the DNA is bent by 90 degrees. This bend results almost entirely from two 40 degrees kinks that occur between TG/CA base pairs at positions 5 and 6 on each side of the dyad axis of the complex. DNA sequence discrimination by CAP derives both from sequence-dependent distortion of the DNA helix and from direct hydrogen-bonding interactions between three protein side chains and the exposed edges of three base pairs in the major groove of the DNA. The structure of this transcription factor--DNA complex provides insights into possible mechanisms of transcription activation.

Structure of the bacteriophage lambda cohesive end site. Genetic analysis of the site (cosN) at which nicks are introduced by terminase

A collection of mutations affecting the site (cosN) at which the bacteriophage lambda DNA packaging enzyme, terminase, introduces nicks to generate mature lambda chromosomes has been studied. A good correlation was found for mutational effects on burst size, accumulation of unused proheads, packaging of DNA into heads and cos cutting by terminase in vitro, indicating that defective cosN cleavage by terminase is the molecular explanation for the phenotypic effects of the mutations. Although the base-pairs of cosN display partial twofold rotational symmetry, cosN was found to be asymmetric functionally. Certain mutations to the left side of the center of rotational symmetry have more pronounced phenotypic effects than rotationally symmetric mutations to the right. The cosN11G mutation has no phenotypic effects when present as a single mutation, but does affect DNA packaging and cosN cutting in the presence of the symmetrically disposed cosN2C mutation. Mutations that decrease cosN cleavage result in the accumulation of unexpanded proheads, indicating that prohead expansion depends on cosN cutting.