The Cro-like Apl repressor of coliphage 186 is required for prophage excision and binds near the phage attachment site

Analysis of Infection Time Courses Shows CII Levels Determine the Frequency of Lysogeny in Phage 186

Engineered phage with properties optimised for the treatment of bacterial infections hold great promise, but require careful characterisation by a number of approaches. Phage–bacteria infection time courses, where populations of bacteriophage and bacteria are mixed and followed over many infection cycles, can be used to deduce properties of phage infection at the individual cell level. Here, we apply this approach to analysis of infection of Escherichia coli by the temperate bacteriophage 186 and explore which properties of the infection process can be reliably inferred. By applying established modelling methods to such data, we extract the frequency at which phage 186 chooses the lysogenic pathway after infection, and show that lysogenisation increases in a graded manner with increased expression of the lysogenic establishment factor CII. The data also suggest that, like phage λ, the rate of lysogeny of phage 186 increases with multiple infections.

Instability of CII is needed for efficient switching between lytic and lysogenic development in bacteriophage 186

The CII protein of temperate coliphage 186, like the unrelated CII protein of phage λ, is a transcriptional activator that primes expression of the CI immunity repressor and is critical for efficient establishment of lysogeny. 186-CII is also highly unstable, and we show that in vivo degradation is mediated by both FtsH and RseP. We investigated the role of CII instability by constructing a 186 phage encoding a protease resistant CII. The stabilised-CII phage was defective in the lysis-lysogeny decision: choosing lysogeny with close to 100% frequency after infection, and forming prophages that were defective in entering lytic development after UV treatment. While lysogenic CI concentration was unaffected by CII stabilisation, lysogenic transcription and CI expression was elevated after UV. A stochastic model of the 186 network after infection indicated that an unstable CII allowed a rapid increase in CI expression without a large overshoot of the lysogenic level, suggesting that instability enables a decisive commitment to lysogeny with a rapid attainment of sensitivity to prophage induction.

A quantitative binding model for the Apl protein, the dual purpose recombination-directionality factor and lysis-lysogeny regulator of bacteriophage 186

The Apl protein of bacteriophage 186 functions both as an excisionase and as a transcriptional regulator; binding to the phage attachment site (att), and also between the major early phage promoters (pR-pL). Like other recombination directionality factors (RDFs), Apl binding sites are direct repeats spaced one DNA helix turn apart. Here, we use in vitro binding studies with purified Apl and pR-pL DNA to show that Apl binds to multiple sites with high cooperativity, bends the DNA and spreads from specific binding sites into adjacent non-specific DNA; features that are shared with other RDFs. By analysing Apl's repression of pR and pL, and the effect of operator mutants in vivo with a simple mathematical model, we were able to extract estimates of binding energies for single specific and non-specific sites and for Apl cooperativity, revealing that Apl monomers bind to DNA with low sequence specificity but with strong cooperativity between immediate neighbours. This model fit was then independently validated with in vitro data. The model we employed here is a simple but powerful tool that enabled better understanding of the balance between binding affinity and cooperativity required for RDF function. A modelling approach such as this is broadly applicable to other systems.

Repression of the lysogenic PR promoter in bacteriophage TP901-1 through binding of a CI-MOR complex to a composite OM-OR operator

A functional genetic switch from the lactococcal bacteriophage TP901-1, deciding which of two divergently transcribing promoters becomes most active and allows this bi-stable decision to be inherited in future generations requires a DNA region of less than 1 kb. The fragment encodes two repressors, CI and MOR, transcribed from the P_R and P_L promoters respectively. CI can repress the transcription of the mor gene at three operator sites (O_R, O_L, and O_D), leading to the immune state. Repression of the cI gene, leading to the lytic (anti-immune) state, requires interaction between CI and MOR by an unknown mechanism, but involving a CI:MOR complex. A consensus for putative MOR binding sites (O_M sites), and a common topology of three O_M sites adjacent to the O_R motif was here identified in diverse phage switches that encode CI and MOR homologs, in a search for DNA sequences similar to the TP901-1 switch. The O_R site and all putative O_M sites are important for establishment of the anti-immune repression of P_R, and a putative DNA binding motif in MOR is needed for establishment of the anti-immune state. Direct evidence for binding between CI and MOR is here shown by pull-down experiments, chemical crosslinking, and size exclusion chromatography. The results are consistent with two possible models for establishment of the anti-immune repression of cI expression at the P_R promoter.

Sequential induction of three recombination directionality factors directs assembly of tripartite integrative and conjugative elements

Tripartite integrative and conjugative elements (ICE³) are a novel form of ICE that exist as three separate DNA regions integrated within the genomes of Mesorhizobium spp. Prior to conjugative transfer the three ICE³ regions of M. ciceri WSM1271 ICEMcSym¹²⁷¹ combine and excise to form a single circular element. This assembly requires three coordinated recombination events involving three site-specific recombinases IntS, IntG and IntM. Here, we demonstrate that three excisionases–or recombination directionality factors—RdfS, RdfG and RdfM are required for ICE³ excision. Transcriptome sequencing revealed that expression of ICE³ transfer and conjugation genes was induced by quorum sensing. Quorum sensing activated expression of rdfS, and in turn RdfS stimulated transcription of both rdfG and rdfM. Therefore, RdfS acts as a “master controller” of ICE³ assembly and excision. The dependence of all three excisive reactions on RdfS ensures that ICE³ excision occurs via a stepwise sequence of recombination events that avoids splitting the chromosome into a non-viable configuration. These discoveries expose a surprisingly simple control system guiding molecular assembly of these novel and complex mobile genetic elements and highlight the diverse and critical functions of excisionase proteins in control of horizontal gene transfer.

Bacteria evolve and adapt quickly through the horizontal transfer of DNA. A major mechanism facilitating this transfer is conjugation. Conjugative DNA elements that integrate into the chromosome are termed ‘Integrative and Conjugative Elements’ (ICE). We recently discovered a unique form of ICE that undergoes a complex series of recombination events with the host chromosome to split itself into three separate parts. This tripartite ICE must also precisely order its recombination when leaving the current host to avoid splitting the host chromosome and the ICE into non-viable parts. In this work, we show that the tripartite ICEs use chemical cell-cell communication to stimulate recombination and that recombination events are specifically ordered through cascaded transcriptional activation of small DNA-binding proteins called recombination directionality factors. Despite the inherent complexity of tripartite ICEs this work exposes a surprisingly simple system to stimulate their precise and ordered molecular assembly prior to horizontal transfer.

Coevolution of bacteria and their viruses

Coevolution between bacteria and bacteriophages can be characterized as an infinitive constant evolutionary battle (phage-host arm race), which starts during phage adsorption and penetration into host cell, continues during phage replication inside the cells, and remains preserved also during prophage lysogeny. Bacteriophage may exist inside the bacterial cells in four forms with different evolutionary strategies: as a replicating virus during the lytic cycle, in an unstable carrier state termed pseudolysogeny, as a prophage with complete genome during the lysogeny, or as a defective cryptic prophage. Some defensive mechanisms of bacteria and virus countermeasures are characterized, and some evolutionary questions concerning phage-host relationship are discussed.

Purification and characterization of bacteriophage P22 Xis protein

The temperate bacteriophages lambda and P22 share similarities in their site-specific recombination reactions. Both require phage-encoded integrase (Int) proteins for integrative recombination and excisionase (Xis) proteins for excision. These proteins bind to core-type, arm-type, and Xis binding sites to facilitate the reaction. lambda and P22 Xis proteins are both small proteins (lambda Xis, 72 amino acids; P22 Xis, 116 amino acids) and have basic isoelectric points (for P22 Xis, 9.42; for lambda Xis, 11.16). However, the P22 Xis and lambda Xis primary sequences lack significant similarity at the amino acid level, and the linear organizations of the P22 phage attachment site DNA-binding sites have differences that could be important in quaternary intasome structure. We purified P22 Xis and studied the protein in vitro by means of electrophoretic mobility shift assays and footprinting, cross-linking, gel filtration stoichiometry, and DNA bending assays. We identified one protected site that is bent approximately 137 degrees when bound by P22 Xis. The protein binds cooperatively and at high protein concentrations protects secondary sites that may be important for function. Finally, we aligned the attP arms containing the major Xis binding sites from bacteriophages lambda, P22, L5, HP1, and P2 and the conjugative transposon Tn916. The similarity in alignments among the sites suggests that Xis-containing bacteriophage arms may form similar structures.

Bacteriophage P4 Vis protein is needed for prophage excision

Upon infection of its host Escherichia coli, satellite bacteriophage P4 can integrate its genome into the bacterial chromosome by Int-mediated site-specific recombination between the attP and the attB sites. The opposite event, excision, may either occur spontaneously or be induced by a superinfecting P2 helper phage. In this work, we demonstrate that the product of the P4 vis gene, a regulator of the P4 late promoters P(LL) and P(sid), is needed for prophage excision. This conclusion is supported by the following evidence: (i) P4 mutants carrying either a frameshift mutation or a deletion of the vis gene were unable to excise both spontaneously or upon P2 phage superinfection; (ii) expression of the Vis protein from a plasmid induced P4 prophage excision; (iii) excision depended on a functional integrase (Int) protein, thus suggesting that Vis is involved in the formation of the excision complex, rather than in the excision recombination event per se; (iv) Vis protein bound P4 DNA in the attP region at two distinct boxes (Box I and Box II), located between the int gene and the attP core region, and caused bending of the bound DNA. Furthermore, we mapped by primer extension the 5' end of the int transcript and found that ectopic expression of Vis reduced its signal intensity, suggesting that Vis is also involved in negative regulation of the int promoter.

Action at a distance in CI repressor regulation of the bacteriophage 186 genetic switch

The non-lambdoid coliphage 186 provides an alternative model to the lytic-lysogenic switch of phage lambda. Like lambda, the key switch regulator, the CI repressor, associates to octamers. Unlike lambda, the lytic promoter (pR) and the lysogenic promoter (pL) are face-to-face, 62 bp apart and are flanked by distal CI binding sites (FL and FR) located approximately 300 bp away. Using reporter and footprinting studies, we show that the outcome, but not the mechanism, of regulation by 186 CI is very similar to lambda. 186 CI stimulates pL transcription indirectly by repressing convergent interfering transcription from pR. However, in the absence of the flanking FL and FR sites, CI bound at pR interacts co-operatively with a weak CI binding site at pL and represses both promoters. FL and FR play a critical role; they assist repression of pR and simultaneously alleviate repression of pL, thus allowing high pL activity. We propose that the 186 switch is regulated by a novel mechanism in which a CI octamer bound at pR forms alternative DNA loops to pL or to a flanking site, depending on CI concentration.

The helix-turn-helix motif of the coliphage 186 immunity repressor binds to two distinct recognition sequences

The CI protein of coliphage 186 is responsible for maintaining the stable lysogenic state. To do this CI must recognize two distinct DNA sequences, termed A type sites and B type sites. Here we investigate whether CI contains two separate DNA binding motifs or whether CI has one motif that recognizes two different operator sequences. Sequence alignment with 186-like repressors predicts an N-terminal helix-turn-helix (HTH) motif, albeit with poor homology to a large master set of such motifs. The domain structure of CI was investigated by linker insertion mutagenesis and limited proteolysis. CI consists of an N-terminal domain, which weakly dimerizes and binds both A and B type sequences, and a C-terminal domain, which associates to octamers but is unable to bind DNA. A fusion protein consisting of the 186 N-terminal domain and the phage lambda oligomerization domain binds A and B type sequences more efficiently than the isolated 186 CI N-terminal domain, hence the 186 C-terminal domain likely mediates oligomerization and cooperativity. Site-directed mutation of the putative 186 HTH motif eliminates binding to both A and B type sites, supporting the idea that binding to the two distinct DNA sequences is mediated by a variant HTH motif.

Characterization of the developmental switch region of bacteriophage P2 Hy dis

In this work, the DNA sequence of the transcriptional switch that affects the development of the P2 Hy dis bacteriophage was determined. The switch contains two face-to-face-located promoters and two repressors, Cox and C. The locations of the Pc and Pe promoters were determined by primer extension analysis. The P2 Hy dis homolog of the P2 multifunctional Cox protein was shown to be able to substitute for P2 Cox in repression of the P2 Pc promoter, excision of the P2 prophage, and activation of the satellite phage P4 PLL promoter. A directly repeated sequence, flanking the--35 region of the Pe promoter, was found to be important for C repressor binding as well as for repression. The P4 E protein was shown to derepress the developmental switch of P2 Hy dis in a plasmid-based derepression assay.

Control of directionality in integrase-mediated recombination: examination of recombination directionality factors (RDFs) including Xis and Cox proteins

Similarity between the DNA substrates and products of integrase-mediated site-specific recombination reactions results in a single recombinase enzyme being able to catalyze both the integration and excision reactions. The control of directionality in these reactions is achieved through a class of small accessory factors that favor one reaction while interfering with the other. These proteins, which we will refer to collectively as recombination directionality factors (RDFs), play architectural roles in reactions catalyzed by their cognate recombinases and have been identified in conjunction with both tyrosine and serine integrases. Previously identified RDFs are typically small, basic and have diverse amino acid sequences. A subset of RDFs, the cox genes, also function as transcriptional regulators. We present here a compilation of all the known RDF proteins as well as those identified through database mining that we predict to be involved in conferring recombination directionality. Analysis of this group of proteins shows that they can be grouped into distinct sub-groups based on their sequence similarities and that they are likely to have arisen from several independent evolutionary lineages. This compilation will prove useful in recognizing new proteins that confer directionality upon site-specific recombination reactions encoded by plasmids, transposons, phages and prophages.

Establishing lysogenic transcription in the temperate coliphage 186

A single-copy chromosomal reporter system was used to measure the intrinsic strengths and interactions between the three promoters involved in the establishment of lysogeny by coliphage 186. The maintenance lysogenic promoter p(L) for the immunity repressor gene cI is intrinsically approximately 20-fold weaker than the lytic promoter p(R). These promoters are arranged face-to-face, and transcription from p(L) is further weakened some 14-fold by the activity of p(R). Efficient establishment of lysogeny requires the p(E) promoter, which lies upstream of p(L) and is activated by the phage CII protein to a level comparable to that of p(R). Transcription of p(E) is less sensitive to converging p(R) transcription and raises cI transcription at least 55-fold. The p(E) promoter does not occlude p(L) but inhibits lytic transcription by 50%. This interference is not due to bound CII preventing elongation of the lytic transcript. The p(E) RNA is antisense to the anti-immune repressor gene apl, but any role of this in the establishment of lysogeny appears to be minimal.

Establishment of lysogeny in bacteriophage 186. DNA binding and transcriptional activation by the CII protein

The CII protein of bacteriophage 186 is a transcriptional activator of the helix-turn helix family required for establishment of the lysogenic state. DNA binding by 186 CII is unusual in that the invertedly repeated half sites are separated by 20 base pairs, or two turns of the DNA helix, rather than the one turn usually associated with this class of proteins. Here, we investigate quantitatively the DNA binding properties of CII and its interaction with RNA polymerase at the establishment promoter, p(E). The stoichiometry of CII binding was determined by sedimentation equilibrium experiments using a fluorescein-labeled oligonucleotide and purified CII. These experiments indicate that the CII species bound to DNA is a dimer, with additional weak binding of a tetrameric species at high concentrations. Examination of the thermodynamic linkages between CII self-association and DNA binding shows that CII binds to the DNA as a preformed dimer (binding free energy, 9.9 kcal/mol at 4 degrees C) rather than by association of monomers on the DNA. CII binding induces in the DNA a bend of 41 (+/- 5) degrees. The spacing between the binding half sites was shown to be important for CII binding, insertion or removal of just 1 base pair significantly reducing the affinity for CII. Removal of 5 or 10 base pairs between binding half sites eliminated binding, as did insertion of an additional 10 base pairs. CII binding at p(E) was improved marginally by the presence of RNA polymerase (DeltaDeltaG = -0.5 (+/- 0.3) kcal/mol). In contrast, the binding of RNA polymerase at p(E) was undetectable in the absence of CII but was improved markedly by the presence of CII. Thus, CII appears to recruit RNA polymerase to the promoter. The nature of the base pair changes in mutant phage, selected by their inability to establish lysogeny, are consistent with this mechanism of CII action.

The transcriptional switch of bacteriophage WPhi, a P2-related but heteroimmune coliphage

Phage WPhi is a member of the nonlambdoid P2 family of temperate phages. The DNA sequence of the whole early-control region and the int and attP region of phage WPhi has been determined. The phage integration site was located at 88.6 min of the Escherichia coli K-12 map, where a 47-nucleotide sequence was found to be identical in the host and phage genomes. The WPhi Int protein belongs to the Int family of site-specific recombinases, and it seems to have the same arm binding recognition sequence as P2 Int, but the core sequence differs. The transcriptional switch contains two face-to-face promoters, Pe and Pc, and two repressors, C and Cox, controlling Pe and Pc, respectively. The early Pe promoter was found to be much stronger than the Pc promoter. Furthermore, the Pe transcript was shown to interfere with Pc transcription. By site-directed mutagenesis, the binding site of the immunity repressor was located to two direct repeats spanning the Pe promoter. A point mutation in one or the other repeat does not affect repression by C, but when it is included in both, C has no effect on the Pe promoter. The Cox repressor efficiently blocks expression from the Pc promoter, but its DNA recognition sequence was not evident. Most members of the P2 family of phages are able to function as helpers for satellite phage P4, which lacks genes encoding structural proteins and packaging and lysis functions. In this work it is shown that P4 E, known to function as an antirepressor by binding to P2 C, also turns the transcriptional switch of WPhi from the lysogenic to the lytic mode. However, in contrast to P2 Cox, WPhi Cox is unable to activate the P4 Pll promoter.

The Tum protein of coliphage 186 is an antirepressor

The tum gene of coliphage 186, encoded on a LexA controlled operon, is essential for UV induction of a 186 prophage. Primer extension analysis is used to confirm that Tum is the sole phage function required for prophage induction and that it acts against the maintenance repressor, CI, to relieve repression of the lytic promoters, pR and pB, and thereby bring about lytic development. In vitro experiments with purified proteins demonstrate that Tum prevents CI binding to its operator sites. Tum does not compete with CI for binding sites on DNA, and unlike RecA mediated induction of lambda prophage, the action of Tum on CI is reversible. Mechanisms by which Tum may act against CI are discussed.

Reciprocal regulation of the early promoter region of bacteriophage HP1 by the Cox and Cl proteins

We have identified a transcriptional switch at the early promoter region of bacteriophage HP1. This switch controls the transcription of the early lytic operon from the P(R1) and P(R2) promoters and the transcription of the lysogenic operon from the P(L) promoter. The start sites of the three promoters were mapped, and using a chloramphenicol acetyl transferase assay, we have investigated the levels of transcription from the promoters in the absence or in the presence of two phage-encoded transcription factors: HP1 Cox and HP1 Cl. The HP1 Cox protein repressed the production of P(L) transcripts 30-fold, while the HP1 Cl protein repressed lytic transcription at least 70-fold. Binding sites for HP1 Cox and Cl were identified in the early promoter region; mutations of these sites eliminated transcriptional repression. In addition, a mutant Cl protein was isolated which is temperature sensitive for repression. Taken together, these data demonstrate the reciprocal regulation of a transcriptional switch in which the actions of the two phage-encoded proteins at the phage early promoters determine the choice between lytic and lysogenic growth.

Purification and characterization of HP1 Cox and definition of its role in controlling the direction of site-specific recombination

The protein that activates site-specific excision of the HP1 genome from the Hemophilus influenzae chromosome, HP1 Cox, was purified. Native Cox consists of four 8.9-kDa protomers. Tetrameric Cox self-associates to octamers; the apparent dissociation constant was 8 microM protomer, suggesting that under reaction conditions Cox is largely tetrameric. Cox binding sites consist of two direct repeats of the consensus motif 5'-GGTMAWWWWA; one Cox tetramer binds to each motif. Cox binding interfered with the interaction of HP1 integrase with one of its binding sites, IBS5. This competition is central to directional control, as shown by studies on mutated sites. Both Cox binding sites were necessary for Cox to fully inhibit integration and activate excision, although Cox continued to affect recombination when the single binding site proximal to IBS5 remained intact. Eliminating the IBS5 site completely prevented integration but greatly enhanced excision. Excisive recombination continued to require Cox even when IBS5 was inactivated. Cox must therefore play a positive role in assembling the nucleoprotein complexes producing excisive recombination, by inducing the formation of a critical conformation in those complexes.

Purification and self-association equilibria of the lysis-lysogeny switch proteins of coliphage 186

The CI repressor protein, responsible for maintenance of the lysogenic state, and the Apl protein, required for efficient prophage induction, are the two control proteins of the lysis-lysogeny transcriptional switch of coliphage 186. These proteins have been overexpressed, purified, and their self-association behavior examined by sedimentation equilibrium. Phage 186 CI dimers self-associate in solution through tetramers to octamers in a concerted process. The Apl protein of 186 is an unusual example of a helix-turn-helix protein which is monomeric in solution.

DNA binding by the coliphage 186 repressor protein CI

The cI gene of coliphage 186 maintains lysogeny and confers immunity to 186 infection by repressing the major early promoter, p(R), and the promoter for the late transcription activator gene, p(B). Gel mobility shirt and DNase I footprinting show that CI protein binds to the DNA at p(R) and p(B) and also to sites approximately 300 base pairs upstream and downstream of p(R), called FL and FR. Mutations which cause virulence reduce CI binding to p(R). The biochemical and genetic data identify three CI operators at p(R), two at p(B), and single operators at FL and FR. The operators at the p(B), FL, FR, and central p(R) sites are inverted repeat sequences, separated by 5 base pairs (Type A) or, in the case of p(R), by 4 base pairs (Type A'). A different inverted repeat operator sequence (Type B) is proposed for the binding sites on each side of the central site at p(R). Thus, CI appears to recognize two distinct DNA sequences. CI binds cooperatively to adjacent operators, and binding at p(R) is strongly dependent on these cooperative interactions. A high order CI multimer appears to be the active DNA binding species, even at single operators.

Novel organization of the site-specific integration and excision recombination functions of the Staphylococcus aureus serotype F virulence-converting phages phi 13 and phi 42

Functions required for site-specific integration and excision of the Staphylococcus aureus serotype F virulence-converting phages phi 13 and phi 42 were localized and characterized. Like other temperate phages, integration of phi 13 and phi 42 sequences was found to require the product of an int gene located close to the phage attP site. Both int genes are almost identical, express proteins possessing characteristic features of the Int (integrase) family of recombinases, but share very little homology with previously described int genes, including those of the serotype B S. aureus phages L54a and phi 11. Nevertheless, all four S. aureus phages share an almost identical short sequence located immediately 5' to these distinct int genes, suggesting a common mechanism of int gene regulation. Upstream from these common sequences, the sequences of phi 13 and phi 42 are quite distinct from each other, and from the corresponding regions of phi 11 and L54a which encode the Xis proteins that are required with Int to mediate site-specific excision of the latter phages. Surprisingly, phi 13 and phi 42 sequences encompassing the attP sites and int genes, but lacking either an adjacent or more distant phage excision protein gene, were sufficient to mediate site-specific excision of integrated phage DNA sequences.

Identification of an HP1 phage protein required for site-specific excision

Transposon insertion mutagenesis and transformation were used to locate genes responsible for excision in the temperature phage HP1 of Haemophilus influenzae. A 6.5 kb segment of DNA near the left end of the phage genome was sequenced, and 11 new open reading frames were identified. Two face-to-face overlapping promoter sequences organized these open reading frames into two operons transcribed in opposite directions. Interruption of the first open reading frame in the rightward operon created lysogens unable to produce phages. Provision of the uninterrupted open reading frame in trans restored phage production. The gene identified by this procedure, cox, was cloned and the protein product was expressed at high levels in Escherichia coli. The Cox protein is a 79-residue basic protein with a predicted strong helix-turn-helix DNA-binding motif. Extracts induced to express high levels of Cox contained a 9 kDa protein. These extracts inhibited integrative recombination and were required for excisive recombination mediated by HP1 integrase. The HP1 cox gene location is similar to that of the homologous excisive and regulatory genes from coliphages P2 and 186. These phages appear to share a distinctive organization of recombination proteins and transcriptional domains differing markedly from phage lambda and its relatives.