Genes for the establishment and maintenance of lysogeny by the temperate coliphage 186

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.

Enhanced mutualistic symbiosis between soil phages and bacteria with elevated chromium-induced environmental stress

BACKGROUND

Microbe-virus interactions have broad implications on the composition, function, and evolution of microbiomes. Elucidating the effects of environmental stresses on these interactions is critical to identify the ecological function of viral communities and understand microbiome environmental adaptation. Heavy metal-contaminated soils represent a relevant ecosystem to study the interplay between microbes, viruses, and environmental stressors.

RESULTS

Metagenomic analysis revealed that Cr pollution adversely altered the abundance, diversity, and composition of viral and bacterial communities. Host-phage linkage based on CRISPR indicated that, in soils with high Cr contamination, the abundance of phages associated with heavy metal-tolerant hosts increased, as did the relative abundance of phages with broad host ranges (identified as host-phage linkages across genera), which would facilitate transfection and broader distribution of heavy metal resistance genes in the bacterial community. Examining variations along the pollutant gradient, enhanced mutualistic phage-bacterium interactions were observed in the face of greater environmental stresses. Specifically, the fractions of lysogens in bacterial communities (identified by integrase genes within bacterial genomes and prophage induction assay by mitomycin-C) were positively correlated with Cr contamination levels. Furthermore, viral genomic analysis demonstrated that lysogenic phages under higher Cr-induced stresses carried more auxiliary metabolic genes regulating microbial heavy metal detoxification.

CONCLUSION

With the intensification of Cr-induced environmental stresses, the composition, replication strategy, and ecological function of the phage community all evolve alongside the bacterial community to adapt to extreme habitats. These result in a transformation of the phage-bacterium interaction from parasitism to mutualism in extreme environments and underscore the influential role of phages in bacterial adaptation to pollution-related stress and in related biogeochemical processes. Video Abstract.

A Novel Jumbo Phage PhiMa05 Inhibits Harmful Microcystis sp

Microcystis poses a concern because of its potential contribution to eutrophication and production of microcystins (MCs). Phage treatment has been proposed as a novel biocontrol method for Microcystis. Here, we isolated a lytic cyanophage named PhiMa05 with high efficiency against MCs-producing Microcystis strains. Its burst size was large, with approximately 127 phage particles/infected cell, a short latent period (1 day), and high stability to broad salinity, pH and temperature ranges. The PhiMa05 structure was composed of an icosahedral capsid (100 nm) and tail (120 nm), suggesting that the PhiMa05 belongs to the Myoviridae family. PhiMa05 inhibited both planktonic and aggregated forms of Microcystis in a concentration-dependent manner. The lysis of Microcystis resulted in a significant reduction of total MCs compared to the uninfected cells. A genome analysis revealed that PhiMa05 is a double-stranded DNA virus with a 273,876 bp genome, considered a jumbo phage. Out of 254 predicted open reading frames (ORFs), only 54 ORFs were assigned as putative functional proteins. These putative proteins are associated with DNA metabolisms, structural proteins, host lysis and auxiliary metabolic genes (AMGs), while no lysogenic, toxin and antibiotic resistance genes were observed in the genome. The AMGs harbored in the phage genome are known to be involved in energy metabolism [photosynthesis and tricarboxylic acid cycle (TCA)] and nucleotide biosynthesis genes. Their functions suggested boosting and redirecting host metabolism during viral infection. Comparative genome analysis with other phages in the database indicated that PhiMa05 is unique. Our study highlights the characteristics and genome analysis of a novel jumbo phage, PhiMa05. PhiMa05 is a potential phage for controlling Microcystis bloom and minimizing MC occurrence.

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.

Characterization of extended-spectrum-β-lactamase producing Klebsiella pneumoniae phage KP1801 and evaluation of therapeutic efficacy in vitro and in vivo

Extended spectrum β lactamase-producing Klebsiellapneumoniae (ESBL-KP) is being reported with high morbidity and mortality rates and is considered as the highest priority for new antimicrobial strategies. To develop an alternative antimicrobial agent, phage KP1801 with broad lytic activity was isolated. The genome of phage KP1801 was double stranded DNA of 49,835 base pairs, with a GC content of 50.26%. There were 75 putative open reading frames. Phage KP1801 was classified as being in the order Caudovirales, belonging to the Siphoviridae family. About 323 proteins were detected by shotgun proteome analysis. The phage inhibited biofilm formation and reduced pre-formed biofilm in a dose dependent manner. Scanning electron microscopic studies demonstrated a membrane damage of bacterial cells treated with phage, resulting in cell death. Prophylactic and therapeutic efficacies of the phage were evaluated in Galleriamellonella. Administration of ESBL-KP infection with phage significantly improved the survival of G.mellonella. The number of intracellular bacteria in larvae showed a significant decrease compared with untreated control while the number of phage increased. These studies suggested that phage KP1801 has the potential for development as an alternative for antibiotics and biocontrol agents against ESBL-KP infection.

RNA polymerase pausing at a protein roadblock can enhance transcriptional interference by promoter occlusion

Convergent promoters exert transcriptional interference (TI) by several mechanisms including promoter occlusion, where elongating RNA polymerases (RNAPs) block access to a promoter. Here, we tested whether pausing of RNAPs by obstructive DNA‐bound proteins can enhance TI by promoter occlusion. Using the Lac repressor as a ‘roadblock’ to induce pausing over a target promoter, we found only a small increase in TI, with mathematical modelling suggesting that rapid termination of the stalled RNAP was limiting the occlusion effect. As predicted, the roadblock‐enhanced occlusion was significantly increased in the absence of the Mfd terminator protein. Thus, protein roadblocking of RNAP may cause pause‐enhanced occlusion throughout genomes, and the removal of stalled RNAP may be needed to minimize unwanted TI.

Soil Viruses Are Underexplored Players in Ecosystem Carbon Processing

Rapidly thawing permafrost harbors ∼30 to 50% of global soil carbon, and the fate of this carbon remains unknown. Microorganisms will play a central role in its fate, and their viruses could modulate that impact via induced mortality and metabolic controls. Because of the challenges of recovering viruses from soils, little is known about soil viruses or their role(s) in microbial biogeochemical cycling. Here, we describe 53 viral populations (viral operational taxonomic units [vOTUs]) recovered from seven quantitatively derived (i.e., not multiple-displacement-amplified) viral-particle metagenomes (viromes) along a permafrost thaw gradient at the Stordalen Mire field site in northern Sweden. Only 15% of these vOTUs had genetic similarity to publicly available viruses in the RefSeq database, and ∼30% of the genes could be annotated, supporting the concept of soils as reservoirs of substantial undescribed viral genetic diversity. The vOTUs exhibited distinct ecology, with different distributions along the thaw gradient habitats, and a shift from soil-virus-like assemblages in the dry palsas to aquatic-virus-like assemblages in the inundated fen. Seventeen vOTUs were linked to microbial hosts (in silico), implicating viruses in infecting abundant microbial lineages from Acidobacteria, Verrucomicrobia, and Deltaproteobacteria, including those encoding key biogeochemical functions such as organic matter degradation. Thirty auxiliary metabolic genes (AMGs) were identified and suggested virus-mediated modulation of central carbon metabolism, soil organic matter degradation, polysaccharide binding, and regulation of sporulation. Together, these findings suggest that these soil viruses have distinct ecology, impact host-mediated biogeochemistry, and likely impact ecosystem function in the rapidly changing Arctic. IMPORTANCE This work is part of a 10-year project to examine thawing permafrost peatlands and is the first virome-particle-based approach to characterize viruses in these systems. This method yielded >2-fold-more viral populations (vOTUs) per gigabase of metagenome than vOTUs derived from bulk-soil metagenomes from the same site (J. B. Emerson, S. Roux, J. R. Brum, B. Bolduc, et al., Nat Microbiol 3:870-880, 2018, https://doi.org/10.1038/s41564-018-0190-y). We compared the ecology of the recovered vOTUs along a permafrost thaw gradient and found (i) habitat specificity, (ii) a shift in viral community identity from soil-like to aquatic-like viruses, (iii) infection of dominant microbial hosts, and (iv) carriage of host metabolic genes. These vOTUs can impact ecosystem carbon processing via top-down (inferred from lysing dominant microbial hosts) and bottom-up (inferred from carriage of auxiliary metabolic genes) controls. This work serves as a foundation which future studies can build upon to increase our understanding of the soil virosphere and how viruses affect soil ecosystem services.

Characterization of Bacteriophages Infecting Clinical Isolates of Clostridium difficile

Clostridium difficile is recognized as a problematic pathogen, causing severe enteric diseases including antibiotic-associated diarrhea and pseudomembranous colitis. The emergence of antibiotic resistant C. difficile has driven a search for alternative anti-infection modalities. A promising strategy for controlling bacterial infection includes the use of bacteriophages and their gene products. Currently, knowledge of phages active against C. difficile is still relatively limited by the fact that the isolation of phages for this organism is a technically demanding method since bacterial host themselves are difficult to culture. To isolate and characterize phages specific to C. difficile, a genotoxic agent, mitomycin C, was used to induce temperate phages from 12 clinical isolates of C. difficile. Five temperate phages consisting of ΦHR24, ΦHN10, ΦHN16-1, ΦHN16-2, and ΦHN50 were successfully induced and isolated. Spotting assays were performed against a panel of 92 C. difficile isolates to screen for susceptible bacterial hosts. The results revealed that all the C. difficile phages obtained in this work displayed a relatively narrow host range of 0-6.5% of the tested isolates. Electron microscopic characterization revealed that all isolated phages contained an icosahedral head connected to a long contractile tail, suggesting that they belonged to the Myoviridae family. Restriction enzyme analysis indicated that these phages possess unique double-stranded DNA genome. Further electron microscopic characterization revealed that the ΦHN10 absorbed to the bacterial surface via attachment to cell wall, potentially interacting with S-layer protein. Bacteriophages isolated from this study could lead to development of novel therapeutic agents and detection strategies for C. difficile.

Promoter activation by CII, a potent transcriptional activator from bacteriophage 186

The lysogeny promoting protein CII from bacteriophage 186 is a potent transcriptional activator, capable of mediating at least a 400-fold increase in transcription over basal activity. Despite being functionally similar to its counterpart in phage λ, it shows no homology at the level of protein sequence and does not belong to any known family of transcriptional activators. It also has the unusual property of binding DNA half-sites that are separated by 20 base pairs, center to center. Here we investigate the structural and functional properties of CII using a combination of genetics, in vitro assays, and mutational analysis. We find that 186 CII possesses two functional domains, with an independent activation epitope in each. 186 CII owes its potent activity to activation mechanisms that are dependent on both the σ(70) and α C-terminal domain (αCTD) components of RNA polymerase, contacting different functional domains. We also present evidence that like λ CII, 186 CII is proteolytically degraded in vivo, but unlike λ CII, 186 CII proteolysis results in a specific, transcriptionally inactive, degradation product with altered self-association properties.

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.

A comparison of the DNA binding and bending capacities and the oligomeric states of the immunity repressors of heteroimmune coliphages P2 and WPhi

Bacteriophages P2 and WPhi are heteroimmune members of the P2-like family of temperate Escherichia coli phages. Temperate phages can grow lytically or form lysogeny after infection. A transcriptional switch that contains two con-vergent promoters, Pe and Pc, and two repressors regulate what life mode to enter. The immunity repressor C is the first gene of the lysogenic operon, and it blocks the early Pe promoter. In this work, some characteristics of the C proteins of P2 and WPhi are compared. An in vivo genetic analysis shows that WPhi C, like P2 C, has a strong dimerization activity in the absence of its DNA target. Both C proteins recognize two directly repeated sequences, termed half-sites and a strong bending is induced in the respective DNA target upon binding. P2 C is unable to bind to one half-site as opposed to WPhi, but both half-sites are required for repression of WPhi Pe. A reduction from three to two helical turns between the centers of the half-sites in WPhi has no significant effect on the capacity to repress Pe. However, the protein-DNA complexes formed differ, as determined by electrophoretic mobility shift experiments. A difference in spontaneous phage production is observed in isogenic lysogens.

Characterization of the global transcriptional responses to different types of DNA damage and disruption of replication in Bacillus subtilis

DNA damage and perturbations in DNA replication can induce global transcriptional responses that can help organisms repair the damage and survive. RecA is known to mediate transcriptional responses to DNA damage in several bacterial species by inactivating the repressor LexA and phage repressors. To gain insight into how Bacillus subtilis responds to various types of DNA damage, we measured the effects of DNA damage and perturbations in replication on mRNA levels by using DNA microarrays. We perturbed replication either directly with p-hydroxyphenylazo-uracil (HPUra), an inhibitor of DNA polymerase, or indirectly with the DNA-damaging reagents mitomycin C (MMC) and UV irradiation. Our results indicate that the transcriptional responses to HPUra, MMC, and UV are only partially overlapping. recA is the major transcriptional regulator under all of the tested conditions, and LexA appears to directly repress the expression of 63 genes in 26 operons, including the 18 operons previously identified as LexA targets. MMC and HPUra treatments caused induction of an integrative and conjugative element (ICEBs1) and resident prophages (PBSX and SPbeta), which affected the expression of many host genes. Consistent with previous results, the induction of these mobile elements required recA. Induction of the phage appeared to require inactivation of LexA. Unrepaired UV damage and treatment with MMC also affected the expression of some of the genes that are controlled by DnaA. Furthermore, MMC treatment caused an increase in origin-proximal gene dosage. Our results indicate that different types of DNA damage have different effects on replication and on the global transcriptional profile.

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.

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.

Characterization of the major control region of Vibrio cholerae bacteriophage K139: immunity, exclusion, and integration

The temperate bacteriophage K139 is highly associated with pathogenic O1 Vibrio cholerae strains. The nucleotide sequence of the major control region of K139 was determined. The sequences of four (cox, cII, cI, and int) of the six deduced open reading frames and their gene order indicated that K139 is related to the P2 bacteriophage family. Two genes of the lysogenic transcript from the mapped promoter PL encode homologs to the proteins CI and Int, with deduced functions in prophage formation and maintenance. Between the cI and int genes, two additional genes were identified: orf2, which has no significant similarity to any other gene, and the formerly characterized gene glo. Further analysis revealed that Orf2 is involved in preventing superinfection. In a previous report, we described that mutations in glo cause an attenuation effect in the cholera mouse model (J. Reidl and J. J. Mekalanos, Mol. Microbiol. 18:685-701, 1995). In this report, we present strong evidence that Glo participates in phage exclusion. Glo was characterized to encode a 13.6-kDa periplasmic protein which inhibits phage infection at an early step, hence preventing reinfection of vibriophage K139 into K139 lysogenic cells. Immediately downstream of gene int, the attP site was identified. Upon analysis of the corresponding attB site within the V. cholerae chromosome, it became evident that phage K139 is integrated between the flagellin genes flaA and flaC of O1 El Tor and O139 V. cholerae lysogenic strains.

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.

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.

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

The Apl protein of the temperature coliphage 186 represses transcription of the immunity repressor gene and down-regulates lytic transcription. It is shown here that an apl- mutant is competent for lytic development and establishes lysogeny normally but is defective in excision of the prophage. The Apl protein binds between the lytic and lysogenic promoters and also near the phage attachment site, suggesting that its role in excision is direct. Apl thus appears to act as an excisionase as well as a repressor. The pattern of Apl-induced DNase I enhancements indicates that the DNA is bent by Apl. Potential Apl recognition sequences are identified; these sequences are directly repeated several times across each binding region and are spaced 10 or 11 bases apart, suggesting that Apl binds to one face of the DNA helix.