Carriage of λ Latent Virus Is Costly for Its Bacterial Host due to Frequent Reactivation in Monoxenic Mouse Intestine

Temperate phages, the bacterial viruses able to enter in a dormant prophage state in bacterial genomes, are present in the majority of bacterial strains for which the genome sequence is available. Although these prophages are generally considered to increase their hosts’ fitness by bringing beneficial genes, studies demonstrating such effects in ecologically relevant environments are relatively limited to few bacterial species. Here, we investigated the impact of prophage carriage in the gastrointestinal tract of monoxenic mice. Combined with mathematical modelling, these experimental results provided a quantitative estimation of key parameters governing phage-bacteria interactions within this model ecosystem. We used wild-type and mutant strains of the best known host/phage pair, Escherichia coli and phage λ. Unexpectedly, λ prophage caused a significant fitness cost for its carrier, due to an induction rate 50-fold higher than in vitro, with 1 to 2% of the prophage being induced. However, when prophage carriers were in competition with isogenic phage susceptible bacteria, the prophage indirectly benefited its carrier by killing competitors: infection of susceptible bacteria led to phage lytic development in about 80% of cases. The remaining infected bacteria were lysogenized, resulting overall in the rapid lysogenization of the susceptible lineage. Moreover, our setup enabled to demonstrate that rare events of phage gene capture by homologous recombination occurred in the intestine of monoxenic mice. To our knowledge, this study constitutes the first quantitative characterization of temperate phage-bacteria interactions in a simplified gut environment. The high prophage induction rate detected reveals DNA damage-mediated SOS response in monoxenic mouse intestine. We propose that the mammalian gut, the most densely populated bacterial ecosystem on earth, might foster bacterial evolution through high temperate phage activity.     

Repair mechanisms involved in prophage reactivation and UV reactivation of UV-irradiated phage lambda

Survival of UV-irradiated phage λ is increased when the host is lysogenic for a homologous heteroimmune prophage such as λimm434 (prophage reactivation). Survival can also be increased by UV-irradiating slightly the non-lysogenic host (UV reactivation).Experiments on prophage reactivation were aimed at evaluating, in this recombination process, the respective roles of phage and bacterial genes as well as that of the extent of homology between phage and prophage.To test whether UV reactivation was dependent upon recombination between the UV-damaged phage and cellular DNAs, lysogenic host cells were employed. Such hosts had thus as much DNA homologous to the infecting phage as can be attained. Therefore, if recombination between phage and host DNAs was involved in this repair process, it could clearly be evidenced.By using unexposed or UV-exposed host cells of the same type, prophage reactivation and UV reactivation could be compared in the same genetic background.The following results were obtained: (1) Prophage reactivation is strongly decreased in a host carrying recA mutations but quite unaffected by mutation lex-I known to prevent UV reactivation; (2) In the absence of the recA⁺ function, the red⁺ but not the int⁺ function can substitute for recA⁺ to produce prophage reactivation, although less efficiently; (3) Prophage reactivation is dependent upon the number of prophages in the cell and upon their degree of homology to the infecting phage. The presence in a recA host of two prophages either in cis (on the chromosome) or in trans (on the chromosome and on an episome) increases the efficiency of prophage reactivation; (4) Upon prophage reactivation there is a high rate of recombination between phage and prophage but no phage mutagenesis; (5) The rate of recombination between phage and prophage decreases if the host has been UV-irradiated whereas the overall efficiency of repair is increased. Under these conditions UV reactivation of the phage occurs as in a non-lysogen, as attested by the high rate of mutagenesis of the restored phage.These results demonstrate that UV reactivation is certainty not dependent upon recombination between two pre-existing DNA duplexes. The hypothesis is offered that UV reactivation involves a repair mechanism different from excision and recombination repair processes.     

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 method to maintain introduced DNA sequences stably and safely on the bacterial chromosome: application of prophage integration and subsequent designed excision

By application of prophage integration and subsequent intended excision, a method to maintain an introduced DNA sequence stably onto a bacterial chromosome has been proposed. Recently-constructed integration plasmids using Campbell-type prophage integration system in Lactobacillus casei strain Shirota and its temperate phage phi FSW was modified for this purpose and a chloramphenicol (Cm)-resistance gene was used as a model passenger DNA. On the integration plasmid having an erythromycin (Em)-resistance gene as a selection marker, N- and C-terminally-truncated Cm-resistance genes were inserted into both sides of the attP of phi FSW, within which the site-specific recombination took place with the attB of phi FSW on the recipient chromosome through the phi FSW integrase. Primary integrants of the modified plasmid (integration-excision vector) exhibiting Em-resistant and Cm-sensitive phenotype generated Em-sensitive and Cm-resistant derivatives under the nonselective conditions. Sequence analyses showed that one copy of the complete Cm-resistance gene resided at the attachment site on the host chromosome and the other vector-derived sequences were excised probably by endogenous homologous recombination in the host cells to derive final integrants. The Cm-resistant phenotype of the final integrants was stable for more than 50 generations under non-selective conditions. Frequency of the homologous recombination suggests that negative selection is also adoptable. Thus, this method using the integration-excision vector gives a stable and safe derivatives of the strain and is likely to be applicable to various bacteria, since Campbell-type prophage integration system and homologous recombination are prevalent among bacteria.     

Viral Transmission Dynamics at Single-Cell Resolution Reveal Transiently Immune Subpopulations Caused by a Carrier State Association

Monitoring the complex transmission dynamics of a bacterial virus (temperate phage P22) throughout a population of its host (Salmonella Typhimurium) at single cell resolution revealed the unexpected existence of a transiently immune subpopulation of host cells that emerged from peculiarities preceding the process of lysogenization. More specifically, an infection event ultimately leading to a lysogen first yielded a phage carrier cell harboring a polarly tethered P22 episome. Upon subsequent division, the daughter cell inheriting this episome became lysogenized by an integration event yielding a prophage, while the other daughter cell became P22-free. However, since the phage carrier cell was shown to overproduce immunity factors that are cytoplasmically inherited by the P22-free daughter cell and further passed down to its siblings, a transiently resistant subpopulation was generated that upon dilution of these immunity factors again became susceptible to P22 infection. The iterative emergence and infection of transiently resistant subpopulations suggests a new bet-hedging strategy by which viruses could manage to sustain both vertical and horizontal transmission routes throughout an infected population without compromising a stable co-existence with their host.     

Evolutionary genomics of a temperate bacteriophage in an obligate intracellular bacteria (Wolbachia)

Genome evolution of bacteria is usually influenced by ecology, such that bacteria with a free-living stage have large genomes and high rates of horizontal gene transfer, while obligate intracellular bacteria have small genomes with typically low amounts of gene exchange. However, recent studies indicate that obligate intracellular species that host-switch frequently harbor agents of horizontal transfer such as mobile elements. For example, the temperate double-stranded DNA bacteriophage WO in Wolbachia persistently transfers between bacterial coinfections in the same host. Here we show that despite the phage's rampant mobility between coinfections, the prophage's genome displays features of constraint related to its intracellular niche. First, there is always at least one intact prophage WO and usually several degenerate, independently-acquired WO prophages in each Wolbachia genome. Second, while the prophage genomes are modular in composition with genes of similar function grouping together, the modules are generally not interchangeable with other unrelated phages and thus do not evolve by the Modular Theory. Third, there is an unusual core genome that strictly consists of head and baseplate genes; other gene modules are frequently deleted. Fourth, the prophage recombinases are diverse and there is no conserved integration sequence. Finally, the molecular evolutionary forces acting on prophage WO are point mutation, intragenic recombination, deletion, and purifying selection. Taken together, these analyses indicate that while lateral transfer of phage WO is pervasive between Wolbachia with occasional new gene uptake, constraints of the intracellular niche obstruct extensive mixture between WO and the global phage population. Although the Modular Theory has long been considered the paradigm of temperate bacteriophage evolution in free-living bacteria, it appears irrelevant in phages of obligate intracellular bacteria.     

Xis and Fis proteins prevent site-specific DNA inversion in lysogens of phage HK022.

HK022, a temperate coliphage related to lambda, forms lysogens by inserting its DNA into the bacterial chromosome through site-specific recombination. The Escherichia coli Fis and phage Xis proteins promote excision of HK022 DNA from the bacterial chromosome. These two proteins also act during lysogenization to prevent a prophage rearrangement: lysogens formed in the absence of either Fis or Xis frequently carried a prophage that had suffered a site-specific internal DNA inversion. The inversion is a product of recombination between the phage attachment site and a secondary attachment site located within the HK022 left operon. In the absence of both Fis and Xis, the majority of lysogens carried a prophage with an inversion. Inversion occurs during lysogenization at about the same time as prophage insertion but is rare during lytic phage growth. Phages carrying the inverted segment are viable but have a defect in lysogenization, and we therefore suggest that prevention of this rearrangement is an important biological role of Xis and Fis for HK022. Although Fis and Xis are known to promote excision of lambda prophage, they had no detectable effect on lambda recombination at secondary attachment sites. HK022 cIts lysogens that were blocked in excisive recombination because of mutation in fis or xis typically produced high yields of phage after thermal induction, regardless of whether they carried an inverted prophage. The usual requirement for prophage excision was bypassed in these lysogens because they carried two or more prophages inserted in tandem at the bacterial attachment site; in such lysogens, viable phage particles can be formed by in situ packaging of unexcised chromosomes.     

Prophage lambda at unusual chromosomal locations: III. The components of the secondary attachment sites

The integration of phage λ occurs by a reciprocal genetic exchange, promoted by the product of phage int gene, at specific sites on the phage and bacterial genomes (att's). Lysogenic bacteria thus contain two att's which bracket the inserted prophage. Genetically, the phage, bacterial and prophage att's differ from each other, indicating that each site has specific elements which segregate during recombination.In hosts that lack the bacterial att, phage integration occurs at about 0.5% the normal frequency. It results from Int-promoted recombination between the phage att and any one of many secondary sites in the bacterial genome. To analyze these sites, we measured Int-promoted recombination at the secondary prophage att's. We found that they differed from the normal prophage att's and from the phage att. The secondary sites, therefore, do not appear to carry any of the specific elements of the phage or bacterial att's.The transducing phage isolated from secondary site lysogens integrate at two loci. In the absence of helper, they insert via homology with the bacterial DNA. Co-infection with helper results in their integration at the normal bacterial att.     

Structural features of lambda site-specific recombination at a secondary att site in galT.

Integration of bacteriophage λ DNA into the chromosome of its E. coli host proceeds via a site-specific recombination between specific loci (att sites) on the phage and bacterial chromosomes. Infection of an E. coli host deleted for the primary bacterial att site results in λ integration with reduced efficiency at a number of different “secondary att sites” scattered around the E. coli chromosome. The first DNA sequence analysis of such a secondary att site, that occurring in the galT gene, is reported here, and several features pertinent to the mechanism of int-dependent site-specific recombination are discussed.Previous studies have shown that the crossover in int-dependent recombination must be somewhere within a 15 bp sequence (core region) common to the phage and primary bacterial att sites, as well as to the left and right prophage att sites which are at the junctures between prophage and host DNA. Comparison of the galT secondary prophage att sites with the primary prophage att sites allows determination of the analogous “core” region in the galT secondary att site. The 15 bp sequence thus identified shows an interrupted homology (8 out of 15) with the wild-type core. The extent and arrangement of nonhomologous bases allow precise placement of the crossover point for this recombination to the +4–+5 internucleotide bond of the core region.Sequences flanking the core region show no obvious homology with analogous sequences of the phage or primary bacterial att sites. Comparison of the galT left prophage att site with the analogous wild-type site is of particular interest and is discussed in relation to binding studies with purified int protein.     

Role of the recJ gene product in UV-induced illegitimate recombination at the hotspot.

Illegitimate recombination between a prophage and adjacent bacterial DNA is the first step in the formation of specialized transducing phage. Such recombination is rare, but it is greatly enhanced by UV irradiation. We studied the mechanism of UV-induced illegitimate recombination by examining the effect of rec mutations on the frequency of lambda bio transducing phage and found that an Escherichia coli recJ mutation reduces it by 3- to 10-fold. In addition, the recombination hotspot, which accounts for approximately 60% of lambda bio transducing phages in wild-type bacteria, was not detected in the recJ mutant. Introduction of a RecJ overexpression plasmid into the recJ mutant recovered the recombination at the hotspot. These results indicate that the RecJ protein preferentially stimulates illegitimate recombination at the hotspot. Both the hotspot and the non- hotspot sites have short regions of homology, but only the hotspot sites contain common direct-repeat sequences. We propose a model based on the 5'-3' exonuclease activity of RecJ to explain the involvement of this protein in illegitimate recombination at the hotspot.     

Abortive infection mechanisms and prophage sequences significantly influence the genetic makeup of emerging lytic lactococcal phages

In this study, we demonstrated the remarkable genome plasticity of lytic lactococcal phages that allows them to rapidly adapt to the dynamic dairy environment. The lytic double-stranded DNA phage ul36 was used to sequentially infect a wild-type strain of Lactococcus lactis and two isogenic derivatives with genes encoding two phage resistance mechanisms, AbiK and AbiT. Four phage mutants resistant to one or both Abi mechanisms were isolated. Comparative analysis of their complete genomes, as well as morphological observations, revealed that phage ul36 extensively evolved by large-scale homologous and nonhomologous recombination events with the inducible prophage present in the host strain. One phage mutant exchanged as much as 79% of its genome compared to the core genome of ul36. Thus, natural phage defense mechanisms and prophage elements found in bacterial chromosomes contribute significantly to the evolution of the lytic phage population.     

Genetic and physical characterization of lysogeny by bacteriophage MX8 in Myxococcus xanthus

Myxophage MX8 can initiate a lysogenic cycle in Myxococcus xanthus. The lysogenic phage was gentically stable in vegetative cells and persisted in the latent state through many cell generations in the absence of extracellular phage reinfection. The latent state also was stable during the host developmental cycle, since myxospores transmitted latent MX8 genetic information to future progeny cells. DNA hybridization experiments to probe the structure of the lysogenic phage provided physical evidence that MX8 formed a prophage. During lysogenization, MX8 DNA was cut at a specific site (attP) on phage DNA, and we have concluded that genetic recombination between attP and a bacterial DNA site (attB) leads to integration of MX8 DNA and formation of stable MX8 prophage. The genetic and physical properties of MX8 that we describe should make MX8 useful in the analysis of development of M. xanthus by genetic methods.     

Prophage spontaneous activation promotes DNA release enhancing biofilm formation in Streptococcus pneumoniae

Streptococcus pneumoniae (pneumococcus) is able to form biofilms in vivo and previous studies propose that pneumococcal biofilms play a relevant role both in colonization and infection. Additionally, pneumococci recovered from human infections are characterized by a high prevalence of lysogenic bacteriophages (phages) residing quiescently in their host chromosome. We investigated a possible link between lysogeny and biofilm formation. Considering that extracellular DNA (eDNA) is a key factor in the biofilm matrix, we reasoned that prophage spontaneous activation with the consequent bacterial host lysis could provide a source of eDNA, enhancing pneumococcal biofilm development. Monitoring biofilm growth of lysogenic and non-lysogenic pneumococcal strains indicated that phage-infected bacteria are more proficient at forming biofilms, that is their biofilms are characterized by a higher biomass and cell viability. The presence of phage particles throughout the lysogenic strains biofilm development implicated prophage spontaneous induction in this effect. Analysis of lysogens deficient for phage lysin and the bacterial major autolysin revealed that the absence of either lytic activity impaired biofilm development and the addition of DNA restored the ability of mutant strains to form robust biofilms. These findings establish that limited phage-mediated host lysis of a fraction of the bacterial population, due to spontaneous phage induction, constitutes an important source of eDNA for the S. pneumoniae biofilm matrix and that this localized release of eDNA favors biofilm formation by the remaining bacterial population.     

Linked Transformation of Bacterial and Prophage Markers in Bacillus subtilis 168 Lysogenic for Bacteriophage φ105

Level of competence reached by Bacillus subtilis 168 lysogenic for temperate phage phi 105 was reduced compared to that reached by nonlysogenic cells. This effect was probably related to an alteration of the bacterial surface. Deoxyribonucleic acid extracted from phi 105 lysogenic bacteria was used to transform other lysogenic bacteria. About 25% linkage was found between the bacterial phe-1 marker and prophage marker ts N15. The order of a few prophage markers relative to phe-1 was established in three-factor crosses. The usefulness of this system for a study of the linkage between an integrated prophage genome and that of its host was discussed.     

Seasonal variations of phage life strategies and bacterial physiological states in three northern temperate lakes

The current consensus concerning the prevalence of lytic and lysogenic phage life cycles in aquatic systems is that the host physiological state may influence viral strategies, lysogeny being favoured when hosts have reduced metabolic rates. We explored this hypothesis, by following phage cycle dynamics, host physiological state and metabolic activity over an annual cycle in three lakes subjected to strong seasonal fluctuations, including 4–5 months of ice cover. We observed marked seasonal dynamics of viral and bacterial communities, with low bulk and cell‐specific bacterial metabolism in winter, and a dramatic increase in injured bacteria under the ice cover in all lakes. This period was accompanied by contrasting patterns in the proportion of lysogenic cells. In the eutrophic lake, times of low bacterial metabolic rates and high proportion of damaged cells corresponded to highest levels of lysogeny, supporting the notion that hosts are a ‘refuge’ for viruses. In the two unproductive lakes, peaks of injured cells corresponded to a minimum of lysogeny, suggesting an ‘abandon the sinking ship’ response, where the prophage replicates before the loss of genome. We suggest that these diverging responses to the host physiological state are not contradictory, but rather that there may be thresholds of cell stress and metabolic activity leading to one or the other response.     

Mycobacteriophage Fruitloop gp52 inactivates Wag31 (DivIVA) to prevent heterotypic superinfection

Bacteriophages engage in complex dynamic interactions with their bacterial hosts and with each other. Bacteria have numerous mechanisms to resist phage infection, and phages must co‐evolve by overcoming bacterial resistance or by choosing an alternative host. Phages also compete with each other, both during lysogeny by prophage‐mediated defense against viral attack and by superinfection exclusion during lytic replication. Phages are enormously diverse genetically and are replete with small genes of unknown function, many of which are not required for lytic growth, but which may modulate these bacteria–phage and phage–phage dynamics. Using cellular toxicity of phage gene overexpression as an assay, we identified the 93‐residue protein gp52 encoded by Cluster F mycobacteriophage Fruitloop. The toxicity of Fruitloop gp52 overexpression results from interaction with and inactivation of Wag31 (DivIVA), an essential Mycobacterium smegmatis protein organizing cell wall biosynthesis at the growing cellular poles. Fruitloop gene 52 is expressed early in lytic growth and is not required for normal Fruitloop lytic replication but interferes with Subcluster B2 phages such as Hedgerow and Rosebush. We conclude that Hedgerow and Rosebush are Wag31‐dependent phages and that Fruitloop gp52 confers heterotypic superinfection exclusion by inactivating Wag31.     

Diversity in CRISPR‐based immunity protects susceptible genotypes by restricting phage spread and evolution

Diversity in host resistance often associates with reduced pathogen spread. This may result from ecological and evolutionary processes, likely with feedback between them. Theory and experiments on bacteria–phage interactions have shown that genetic diversity of the bacterial adaptive immune system can limit phage evolution to overcome resistance. Using the CRISPR–Cas bacterial immune system and lytic phage, we engineered a host–pathogen system where each bacterial host genotype could be infected by only one phage genotype. With this model system, we explored how CRISPR diversity impacts the spread of phage when they can overcome a resistance allele, how immune diversity affects the evolution of the phage to increase its host range and if there was feedback between these processes. We show that increasing CRISPR diversity benefits susceptible bacteria via a dilution effect, which limits the spread of the phage. We suggest that this ecological effect impacts the evolution of novel phage genotypes, which then feeds back into phage population dynamics.     

Non-conventional therapeutic technique to replace CRISPR bacteria from biofilm by inducible lysogen

ABSTRACT

Bacteriophage can be an effective means of regulating bacterial populations when conditions allow phage invasion of bacterial colonies. Phage can either infect and lyse a host cell, or insert their DNA into the host cell genome; the latter process is called lysogeny. The clustered regularly interspaced short palindromic repeat (CRISPR) system, linked with CRISPR-associated (Cas) genes, is a regulatory system present in a variety of bacteria which confers immunity against bacteriophage. Studies of the group behaviour of bacteria with CRISPR/Cas systems have provided evidence that CRISPR in lysogenized bacteria can cause an inability to form biofilm. This allows CRISPR-immune bacteria in biofilms to effectively resist phage therapy. Our recent work has described a potential therapeutic technique to eradicate CRISPR-immune bacteria from a biofilm by a continuous influx of lysogens carrying an identical phage sequence. However, this model predicted that the CRISPR-immune population could persist for long times before eradication. Our current focus is on the use of diverse lysogens against CRISPR-capable bacterial populations. The goal of this work is to find a suitable strategy which can eradicate bacteria with a CRISPR system through the influx of finite amounts of distinct lysogens over fixed intervals.     

Identification of Site-Specific Recombination Genes int and xis of the Rhizobium Temperate Phage 16-3

Phage 16-3 is a temperate phage of Rhizobium meliloti 41 which integrates its genome with high efficiency into the host chromosome by site-specific recombination through DNA sequences of attB and attP. Here we report the identification of two phage-encoded genes required for recombinations at these sites: int (phage integration) and xis (prophage excision). We concluded that Int protein of phage 16-3 belongs to the integrase family of tyrosine recombinases. Despite similarities to the cognate systems of the lambdoid phages, the 16-3 int xis att system is not active in Escherichia coli, probably due to requirements for host factors that differ in Rhizobium meliloti and E. coli. The application of the 16-3 site-specific recombination system in biotechnology is discussed.