Lysogenization of Escherichia coli him+, himA, and himD hosts by bacteriophage Mu

Bacteriophage self-counting in the presence of viral replication

When host cells are in low abundance, temperate bacteriophages opt for dormant (lysogenic) infection. Phage lambda implements this strategy by increasing the frequency of lysogeny at higher multiplicity of infection (MOI). However, it remains unclear how the phage reliably counts infecting viral genomes even as their intracellular number increases because of replication. By combining theoretical modeling with single-cell measurements of viral copy number and gene expression, we find that instead of hindering lambda's decision, replication facilitates it. In a nonreplicating mutant, viral gene expression simply scales with MOI rather than diverging into lytic (virulent) and lysogenic trajectories. A similar pattern is followed during early infection by wild-type phage. However, later in the infection, the modulation of viral replication by the decision genes amplifies the initially modest gene expression differences into divergent trajectories. Replication thus ensures the optimal decision-lysis upon single-phage infection and lysogeny at higher MOI.

The landscape of lysogeny across microbial community density, diversity and energetics

Lysogens are common at high bacterial densities, an observation that contrasts with the prevailing view of lysogeny as a low-density refugium strategy. Here, we review the mechanisms regulating lysogeny in complex communities and show that the additive effects of coinfections, diversity and host energic status yield a bimodal distribution of lysogeny as a function of microbial densities. At high cell densities (above 10⁶  cells ml^-1 or g^-1 ) and low diversity, coinfections by two or more phages are frequent and excess energy availability stimulates inefficient metabolism. Both mechanisms favour phage integration and characterize the Piggyback-the-Winner dynamic. At low densities (below 10⁵  cells ml^-1 or g^-1 ), starvation represses lytic genes and extends the time window for lysogenic commitment, resulting in a higher frequency of coinfections that cause integration. This pattern follows the predictions of the refugium hypothesis. At intermediary densities (between 10⁵ and 10⁶  cells ml^-1 or g^-1 ), encounter rates and efficient energy metabolism favour lysis. This may involve Kill-the-Winner lytic dynamics and induction. Based on these three regimes, we propose a framework wherein phage integration occurs more frequently at both ends of the host density gradient, with distinct underlying molecular mechanisms (coinfections and host metabolism) dominating at each extreme.

Quantification of Lysogeny Caused by Phage Coinfections in Microbial Communities from Biophysical Principles

The association of temperate phages and bacterial hosts during lysogeny manipulates microbial dynamics from the oceans to the human gut. Lysogeny is well studied in laboratory models, but its environmental drivers remain unclear. Here, we quantified the probability of lysogenization caused by phage coinfections, a well-known trigger of lysogeny, in marine and gut microbial environments. Coinfections were quantified by developing a biophysical model that incorporated the traits of viral and bacterial communities. Lysogenization via coinfection was more frequent in highly productive environments like the gut, due to higher microbial densities and higher phage adsorption rates. At low cell densities, lysogenization occurred in bacteria with long duplication times. These results bridge the molecular understanding of lysogeny with the ecology of complex microbial communities.

Temperate phages can associate with their bacterial host to form a lysogen, often modifying the phenotype of the host. Lysogens are dominant in the microbially dense environment of the mammalian gut. This observation contrasts with the long-standing hypothesis of lysogeny being favored at low microbial densities, such as in oligotrophic marine environments. Here, we hypothesized that phage coinfections—a well-understood molecular mechanism of lysogenization—increase at high microbial abundances. To test this hypothesis, we developed a biophysical model of coinfection for marine and gut microbiomes. The model stochastically sampled ranges of phage and bacterial concentrations, adsorption rates, lysogenic commitment times, and community diversity from each environment. In 90% of the sampled marine communities, less than 10% of the bacteria were predicted to be lysogenized via coinfection. In contrast, 25% of the sampled gut communities displayed more than 25% of lysogenization. The probability of lysogenization in the gut was a consequence of the higher densities and higher adsorption rates. These results suggest that, on average, coinfections can form two trillion lysogens in the human gut every day. In marine microbiomes, which were characterized by lower densities and phage adsorption rates, lysogeny via coinfection was still possible for communities with long lysogenic commitment times. Our study indicates that different physical factors causing coinfections can reconcile the traditional view of lysogeny at poor host growth (long commitment times) and the recent Piggyback-the-Winner framework proposing that lysogeny is favored in rich environments (high densities and adsorption rates).

IMPORTANCE The association of temperate phages and bacterial hosts during lysogeny manipulates microbial dynamics from the oceans to the human gut. Lysogeny is well studied in laboratory models, but its environmental drivers remain unclear. Here, we quantified the probability of lysogenization caused by phage coinfections, a well-known trigger of lysogeny, in marine and gut microbial environments. Coinfections were quantified by developing a biophysical model that incorporated the traits of viral and bacterial communities. Lysogenization via coinfection was more frequent in highly productive environments like the gut, due to higher microbial densities and higher phage adsorption rates. At low cell densities, lysogenization occurred in bacteria with long duplication times. These results bridge the molecular understanding of lysogeny with the ecology of complex microbial communities.

Chromosomal integration mechanism of infecting mu virion DNA

DNA transposition is central to the propagation of temperate phage Mu. A long-standing problem in Mu biology has been the mechanism by which the linear genome of an infecting phage, which is linked at both ends to DNA acquired from a previous host, integrates into the new host chromosome. If Mu were to use its well-established cointegrate mechanism for integration (single-strand nicks at Mu ends, joined to a staggered double-strand break in the target), the flanking host sequences would remain linked to Mu; target-primed replication of the linear integrant would subsequently break the chromosome. The absence of evidence for chromosome breaks has led to speculation that infecting Mu might use a cut-and-paste mechanism, whereby Mu DNA is cut away from the flanking sequences prior to integration. In this study we have followed the fate of the flanking DNA during the time course of Mu infection. We have found that these sequences are still attached to Mu upon integration and that they disappear soon after. The data rule out a cut-and-paste mechanism and suggest that infecting Mu integrates to generate simple insertions by a variation of its established cointegrate mechanism in which, instead of a "nick, join, and replicate" pathway, it follows a "nick, join, and process" pathway. The results show similarities with human immunodeficiency virus integration and provide a unifying mechanism for development of Mu along either the lysogenic or lytic pathway.

DNA gyrase requirements distinguish the alternate pathways of Mu transposition

The MuA transposase mediates transposition of bacteriophage Mu through two distinct mechanisms. The first integration event following infection occurs through a non-replicative mechanism. In contrast, during lytic growth, multiple rounds of replicative transposition amplify the phage genome. We have examined the influence of gyrase and DNA supercoiling on these two transposition pathways using both a gyrase-inhibiting drug and several distinct gyrase mutants. These experiments reveal that gyrase activity is not essential for integration; both lysogens and recombination intermediates are detected when gyrase is inhibited during Mu infection. In contrast, gyrase inhibition causes severe defects in replicative transposition. In two of the mutants, as well as in drug-treated cells, replicative transposition is almost completely blocked. Experiments probing for formation of MuA-DNA complexes in vivo reveal that this block occurs very early, during assembly of the transposase complex required for the catalytic steps of recombination. The findings establish that DNA structure-based signals are used differently for integrative and replicative transposition. We propose that transposase assembly, the committed step for recombination, has evolved to depend on different DNA /architectural signals to control the reaction outcome during these two distinct phases of the phage life cycle.

Characterization of the cts4 repressor mutation in transposable bacteriophage Mu

Mucts4 was isolated more than 30 years ago and was the first available thermoinducible derivative of transposable phage Mu. We have characterized the cts4 mutation and the corresponding mutant protein. Contrary to previously characterized thermoinducible Mu prophages (e.g., Mucts62), Mucts4 lysogenizes at reduced frequency even at 30 degrees C. The cts4 mutation (Leu129Val) was located in this central repressor region. The cts4 protein was thermosensitive for operator DNA binding in vitro. Temperature-dependent changes in protein-protein cross-linking patterns in the absence of DNA were detected for purified wild type, cts62 and cts4 repressor proteins. The cts4 protein exhibited a subtly different electrophoretic profile, which became more marked at higher temperatures, from both the wild type and cts62. In addition the cts4 repressor generated a significantly different pattern of binding to DNA fragments carrying the early operator region. Consistent with the predicted involvement of the central leucine-rich region of the Mu repressor in the formation of multimeric forms, the cts4 mutation thus appeared to affect protein-protein interactions.

Starvation-induced Mucts62-mediated coding sequence fusion: a role for ClpXP, Lon, RpoS and Crp

The formation of araB-lacZ coding sequence fusions in Escherichia coli is a particular type of chromosomal rearrangement induced by Mucts62, a thermoinducible mutant of mutator phage Mu. Fusion formation is controlled by the host physiology. It only occurs after aerobic carbon starvation and requires the phage-encoded transposase pA, suggesting that these growth conditions trigger induction of the Mucts62 prophage. Here, we show that thermal induction of the prophage accelerated araB-lacZ fusion formation, confirming that derepression is a rate-limiting step in the fusion process. Nonetheless, starvation conditions remained essential to complete fusions, suggesting additional levels of physiological regulation. Using a transcriptional fusion indicator system in which the Mu early lytic promoter is fused to the reporter E. coli lacZ gene, we confirmed that the Mucts62 prophage was derepressed in stationary phase (S derepression) at low temperature. S derepression did not apply to prophages that expressed the Mu wild-type repressor. It depended upon the host ClpXP and Lon ATP-dependent proteases and the RpoS stationary phase-specific sigma factor, but not upon Crp. None of these four functions was required for thermal induction. Crp was required for fusion formation, but only when the Mucts62 prophage encoded the transposition/replication activating protein pB. Finally, we found that thermally induced cultures did not return to the repressed state when shifted back to low temperature and, hence, remained activated for accelerated fusion formation upon starvation. The maintenance of the derepressed state required the ClpXP and Lon host proteases and the prophage Ner-regulatory protein. These observations illustrate how the cts62 mutation in Mu repressor provides the prophage with a new way to respond to growth phase-specific regulatory signals and endows the host cell with a new potential for adaptation through the controlled use of the phage transposition machinery.

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.

Involvement of the alginate algT gene and integration host factor in the regulation of the Pseudomonas aeruginosa algB gene

Strains of Pseudomonas aeruginosa causing pulmonary infection in cystic fibrosis patients are often mucoid because of the synthesis of a capsular polysaccharide called alginate. Regulation of alginate biosynthesis includes the algB gene product (AlgB), which belongs to a class of proteins that control gene transcription in response to environmental stimuli. In this study, a homolog of the DNA-binding-and-bending protein integration host factor (IHF) and the positive regulatory gene algT were shown to be involved in algB expression. An algB-cat gene fusion was constructed on a low-copy-number, broad-host-range plasmid. In alginate-producing (Alg+) P. aeruginosa, levels of chloramphenicol acetyltransferase from algB-cat were twofold higher than in spontaneous Alg- or algT::Tn501 mutant strains, indicating that the mucoid status of the cell influences algB transcription. An algB transcription initiation site was identified 286 nucleotides upstream of translation initiation and revealed an Escherichia coli sigma 70-like promoter. Sequences in the algB promoter region were highly similar to the consensus E. coli IHF binding site. In DNA gel band mobility shift assays, a protein present in extracts from IHF+ E. coli strains and IHF purified from E. coli bound specifically to these algB DNA fragments, while extracts prepared from isogenic IHF- E. coli strains failed to alter the mobility of algB DNA fragments containing the consensus IHF binding site. A protein in cell extracts prepared from P. aeruginosa strains also demonstrated binding to algB fragments containing the IHF binding site, and the position of the complex formed with these extracts was identical to that of the complex formed with purified IHF. Moreover, this binding could be inhibited by anti-IHF antibodies. To test the role of the IHF site in algB regulation, site-specific mutations in the algB IHF site, based on changes which severely affect IHF binding in E. coli, were generated. When either purified E. coli IHF or extracts from P. aeruginosa were used in DNA binding studies, the algB mutant DNAs were severely reduced in IHF binding. Mutations affecting IHF binding at the algB promoter were introduced into the algB-cat plasmid, and all resulted in severely impaired transcriptional activity in Alg- and algT mutant strains of P. aeruginosa. However, these mutations resulted in similar or slightly reduced algB-cat transcription in Alg+ and algB::Tn501 mutant strains. Thus, the algT product plays a positive role in the high-level expression of algB in mucoid cells, whereas as protein present in P.aeruginosa extracts which is likely an IHF homolog plays a positive role in maintaining a basal level of algB expression in nonmucoid strains.

Temperature-sensitive mutations in the bacteriophage Mu c repressor locate a 63-amino-acid DNA-binding domain

Phage Mu's c gene product is a cooperative regulatory protein that binds to a large, complex, tripartite 184-bp operator. To probe the mechanism of repressor action, we isolated and characterized 13 phage mutants that cause Mu to undergo lytic development when cells are shifted from 30 to 42 degrees C. This collection contained only four mutations in the repressor gene, and all were clustered near the N terminus. The cts62 substitution of R47----Q caused weakened specific DNA recognition and altered cooperativity in vitro. A functional repressor with only 63 amino acids of Mu repressor fused to a C-terminal fragment of beta-galactosidase was constructed. This chimeric protein was an efficient repressor, as it bound specifically to Mu operator DNA in vitro and its expression conferred Mu immunity in vivo. A DNA looping model is proposed to explain regulation of the tripartite operator site and the highly cooperative nature of repressor binding.

Identification of a positive regulator of the Mu middle operon

Transcription of bacteriophage Mu occurs in a regulatory cascade consisting of three phases: early, middle, and late. The 1.2-kb middle transcript is initiated at Pm and encodes the C protein, the activator of late transcription. A plasmid containing a Pm-lacZ operon fusion was constructed. beta-Galactosidase expression from the plasmid increased 23-fold after Mu prophage induction. Infection of plasmid-containing cells with lambda phages carrying different segment of the Mu early region localized the Pm-lacZ transactivation function to the region containing open reading frames E16 and E17. Deletion and linker insertion analyses of plasmids containing this region identified E17 as the transactivator; therefore we call this gene mor, for middle operon regulator. Expression of mor under the control of a T7 promoter and T7 RNA polymerase resulted in the production of a single polypeptide of 17 kDa as detected by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Insertion of a linker into mor substantially reduced the ability of Mu to form plaques. When growth of the mor mutant was assayed in liquid, lysis was delayed by about 50 min and the burst size was approximately one-fifth that of wild-type Mu. The mor requirement for plaque formation and normal growth kinetics was abolished when C protein was provided in trans, indicating that the primary function of Mor is to provide sufficient C for late gene expression. Comparison of the predicted amino acid sequence of Mor with other proteins revealed that Mor and C share substantial amino acid sequence homology.

Intermediates in bacteriophage Mu lysogenization of Escherichia coli him hosts

Characterization of a putative intermediate in the Mu lysogenization pathway is possible in a variant Escherichia coli himD strain which exhibits greatly diminished lysogen formation. In this strain, most infecting Mu genomes form stable, transcribable, nonreplicating structures. Many of these genomes can be mobilized to form lysogens by a second Mu infection, which can be delayed by at least 100 min. This intermediate structure can be formed in the absence of Mu A or B function. We suggest that the inferred intermediate could be the previously reported protein-linked circular form of the Mu genome. Providing Mu B function from a plasmid enhances Mu lysogenization in this him strain, and the enhancement is much greater when both Mu A and B functions are provided.