Investigation of bacteriophage MS2 viral dynamics using model discrimination analysis and the implications for phage therapy

Lytic phages infect their bacterial hosts, use the host machinery to replicate, and finally lyse and kill their hosts, releasing progeny phages. Various mathematical models have been developed that describe these phage-host viral dynamics. The aim of this study was to determine which of these models best describes the viral dynamics of lytic RNA phage MS2 and its host Escherichia coli C-3000. Experimental data consisted of uninfected and infected bacterial cell densities, free phage density, and substrate concentration. Parameters of various models were either determined directly through other experimental techniques or estimated using regression analysis of the experimental data. The models were evaluated using a Bayesian-based model discrimination technique. Through model discrimination it was shown that phage-resistant cells inhibited the growth of phage population. It was also shown that the uninfected bacterial population was a quasispecies consisting of phage-sensitive and phage-resistant bacterial cells. When there was a phage attack the phage-sensitive cells died out and the phage-resistant cells were selected for and became the dominant strain of the bacterial population.     

Regulation of polar surface structures in Caulobacter crescentus: Pleiotropic mutations affect the coordinate morphogenesis of flagella, pili and phage receptors

Summary A large number of Caulobacter mutants resistant to DNA or RNA phages were isolated. These phage-resistant mutants exhibited phenotypic variations with respect to cell motility and sensitivity to other phages.The majority of the mutants was resistant to both DNA and RNA phages tested. In addition, these mutants were either motile or non-motile. The analysis of spontaneous revertants from these mutants indicated that a single mutation is involved in these phenotypic variations. Other mutants were resistant to RNA phages and only to a certain DNA phage tested, and were also motile or non-motile.Several temperature-sensitive phage-resistant mutants were also isolated. One of them, CB13 ple-801, exhibited the wild type phenotype when grown at 25°C. However, at a higher temperature (35°C), the mutant cells became non-motile and resistant to both DNA and RNA phages. These phenotypes seem to be attributed to the concommitant loss of flagella, pili and phage receptors. In other respects (cell growth and morphology, and asymmetric stalk formation), CB13 ple-801 was normal at 35°C. The spontaneous revertants from CB13 ple-801 simultaneously regained the wild type phenotypes in all respects.It is suggested that a single mutation pleiotropically affects the formation of flagella, pili and phage receptors.     

Characterization of Pseudomonas aeruginosa phage KPP21 belonging to family Podoviridae genus N4‐like viruses isolated in Japan

Bacteriophages (phages) belonging to the family Podoviridae genus N4‐like viruses have been used as therapeutic agent in phage therapy against Pseudomonas aeruginosa infections. P. aeruginosa phage KPP21 was isolated in Japan, and phylogenetically investigated the phages belonging to this viral genus. Morphological and genetic analyses confirmed that phage KPP21 belongs to the family Podoviridae genus N4‐like viruses. Moreover, phylogenetic analyses based on putative DNA polymerase and major virion protein showed that P. aeruginosa phages belonging to the genus N4‐like viruses are separated into two lineages and that phage KPP21 is in the same clade as phage LUZ7.     

Toward rational control of<Emphasis Type="Italic"> Escherichia coli</Emphasis> O157:H7 by a phage cocktail

Twenty six phages infected with Escherichia coli O157:H7 were screened from various sources. Among them, nine caused visible lysis of E. coli O157:H7 cells in LB liquid medium. However, prolonged incubation of E. coli cells and phage allowed the emergence of phage-resistant cells. The susceptibility of the phage-resistant cells to the nine phages was diverse. A rational procedure for selecting an effective cocktail of phage for controlling bacteria was investigated based on the mechanism of phage-resistant cell conversion. Deletion of OmpC from the E. coli cells facilitated the emergence of cells resistant to SP21 phage. After 8 h of incubation, SP21-resistant cells appeared. By contrast, alteration of the lipopolysaccharide (LPS) profile facilitated cell resistance to SP22 phage, which was observed following a 6-h incubation. When a cocktail of phages SP21 and SP22 was used to infect E. coli O157:H7 cells, 30 h was required for the emergence of cells (R-C) resistant to both phages. The R-C cells carried almost the same outer membrane and LPS components as the wild-type cells. However, the reduced binding ability of both phages to R-C cells suggested disturbance of phage adsorption to the R-C surface. Even though R-C cells resistant to both phages appeared, this work shows that rational selection of phages has the potential to at least delay the emergence of phage resistance.     

Comparison of Five Bacteriophages as Models for Viral Aerosol Studies

Bacteriophages are perceived to be good models for the study of airborne viruses because they are safe to use, some of them display structural features similar to those of human and animal viruses, and they are relatively easy to produce in large quantities. Yet, only a few studies have investigated them as models. It has previously been demonstrated that aerosolization, environmental conditions, and sampling conditions affect viral infectivity, but viral infectivity is virus dependent. Thus, several virus models are likely needed to study their general behavior in aerosols. The aim of this study was to compare the effects of aerosolization and sampling on the infectivity of five tail-less bacteriophages and two pathogenic viruses: MS2 (a single-stranded RNA [ssRNA] phage of the Leviviridae family), Φ6 (a segmented double-stranded RNA [dsRNA] phage of the Cystoviridae family), ΦX174 (a single-stranded DNA [ssDNA] phage of the Microviridae family), PM2 (a double-stranded DNA [dsDNA] phage of the Corticoviridae family), PR772 (a dsDNA phage of the Tectiviridae family), human influenza A virus H1N1 (an ssRNA virus of the Orthomyxoviridae family), and the poultry virus Newcastle disease virus (NDV; an ssRNA virus of the Paramyxoviridae family). Three nebulizers and two nebulization salt buffers (with or without organic fluid) were tested, as were two aerosol sampling devices, a liquid cyclone (SKC BioSampler) and a dry cyclone (National Institute for Occupational Safety and Health two-stage cyclone bioaerosol sampler). The presence of viruses in collected air samples was detected by culture and quantitative PCR (qPCR). Our results showed that these selected five phages behave differently when aerosolized and sampled. RNA phage MS2 and ssDNA phage ΦX174 were the most resistant to aerosolization and sampling. The presence of organic fluid in the nebulization buffer protected phages PR772 and Φ6 throughout the aerosolization and sampling with dry cyclones. In this experimental setup, the behavior of the influenza virus resembled that of phages PR772 and Φ6, while the behavior of NDV was closer to that of phages MS2 and ΦX174. These results provide critical information for the selection of appropriate phage models to mimic the behavior of specific human and animal viruses in aerosols.     

Bacteriophage-resistance mechanisms examined by transfection of Lactococcus lactis subsp. lactis 4513-5 mediated by high voltage electroporation

Summary Phage adsorption tests and transfection by electroporation were carried out to decide whether phage-resistance in Lactococcus lactis subsp. lactis strain 4513-5 is based on intracellular or extracellular mechanisms. Using high voltage (12.5 kV/cm) electroporation, untreated phage DNA was introduced into phage-sensitive and phage-resistant cells. Since phages showed low adsorption frequencies on resistant bacteria, resistance is localized in the cell wall preventing phage DNA from entering the cell. This is the only mechanism responsible for the resistance of L. lactis subsp. lactis 4513-5 against its homologous phage P4513-K12 and non-homologous phages P05M-13 and P05M-47, but not against phage P530-7 and phage P530-12. In the case of the latter two phage strains, intracellular resistance mechanisms are involved and discussed.     

In vivo phage display: identification of organ-specific peptides using deep sequencing and differential profiling across tissues

In vivo phage display is widely used for identification of organ- or disease-specific homing peptides. However, the current in vivo phage biopanning approaches fail to assess biodistribution of specific peptide phages across tissues during the screen, thus necessitating laborious and time-consuming post-screening validation studies on individual peptide phages. Here, we adopted bioinformatics tools used for RNA sequencing for analysis of high-throughput sequencing (HTS) data to estimate the representation of individual peptides during biopanning in vivo. The data from in vivo phage screen were analyzed using differential binding—relative representation of each peptide in the target organ versus in a panel of control organs. Application of this approach in a model study using low-diversity peptide T7 phage library with spiked-in brain homing phage demonstrated brain-specific differential binding of brain homing phage and resulted in identification of novel lung- and brain-specific homing peptides. Our study provides a broadly applicable approach to streamline in vivo peptide phage biopanning and to increase its reproducibility and success rate.     

Biological Activity and Mode of Action of a Specific Antiphage Substance,AFS

Purified AFS (anti-filamentous phage substance) produced by Streptomyces lavendulae AM–7a showed specific antiphage activity against the male specific, deoxyribonucleic acid-containing filamentous phages of Escherichia coli without any activity against other DNA-phages nor the male-specific ribonucleic acid-containing phages of E. coli. AFS brought about no inactivation of free particles of filamentous phage, fl, nor the receptor of the host cells for the phage, while it showed strong killing effect against the fl-infected host cells at the concentration below 0.01 μg/ml. Antiphage activity of AFS might be due to its highly specific killing effect only on the E. coli cells infected with the filamentous DNA phages, while it exerted no effect on the growth of the unifected E. coli nor other microorganisms. Killing by AFS seemed to require the energy metabolism of the phage-infected host cells. Macro-molecular synthesis and respiration of the infected host cells were inhibited soon after the addition of small amounts of AFS without any cell lysis.     

A special case of lysogeny inMycobacterium avium

Phage-producing colonies of cells resistant to homologous phage F4II have been isolated after infection ofMycobacterium avium. About one per cent phage-free, sensitive clones can usually be obtained after treatment of the cell suspension with phage antiserum. Because of the relatively high free phage titer in the culture, the presence of very dense particles, probably phage equivalents, in the cytoplasm of many cells and the varied sensitivity of intracellular phage to UV irradiation at different stages of growth, one can assume that a great part of the cells in the population burst and liberate phages. The relationship between phage and the host cell is discussed as a particular case of abortive lysogeny.     

Argentinean Lactococcus lactis bacteriophages: genetic characterization and adsorption studies

Aims: Characterization of four virulent Lactococcus lactis phages (CHD, QF9, QF12 and QP4) isolated from whey samples obtained from Argentinean cheese plants. Methods and Results: Phages were characterized by means of electron microscopy, host range and DNA studies. The influence of Ca²⁺, physiological cell state, pH and temperature on cell adsorption was also investigated. The double‐stranded DNA genomes of these lactococcal phages showed distinctive restriction patterns. Using a multiplex PCR, phage QP4 was classified as a member of the P335 polythetic species while the three others belong to the 936 group. Ca²⁺ was not needed for phage adsorption but indispensable to complete cell lysis by phage QF9. The lactococci phages adsorbed normally between pH 5 and pH 8, and from 0°C to 40°C, with the exception of phage QF12 which had an adsorption rate significantly lower at pH 8 and 0°C. Conclusions: Lactococcal phages from Argentina belong to the same predominant groups of phages found in other countries and they have the same general characteristics. Significance and Impact of the Study: This work is the first study to characterize Argentinean L. lactis bacteriophages.     

Lysogenization by bacteriophage lambda: II. - Identification of genes involved in the multiplicity dependent processes

We previously showed that, under conditions of rapid exponential growth, lysogenization of E. coli cells by phage λ requires that the cell is infected by at least 2 phages able to replicate their DNA, or 3 or 4 phages unable to replicate their DNA [ref. 4]. Since genes dealing with prophage integration appear not to be involved in these multiplicity dependent processes, a determination was made as to whether more than one copy of the genes involved in repressor synthesis or its activation are needed for lysogenization. The complementation patterns which we obtained indicate multiplicity effects involving gene cII (and, perhaps, cIII) in lysogenization by both phage able or unable to replicate. In the former case, we propose that cII protein (and, perhaps, cIII) both induces repressor synthesis and inhibits phage DNA replication. In lysogenization by phage unable to replicate, the data suggest that the expression of early phage genes and repressor synthesis in the course of lysogenization are mutually exclusive processes which do not take place on the same phage chromosome.     

An evaluation of the rate constants for the adsorption of the defective phage PBS Z to Bacillus subtilis

The adsorption of the defective phage PBS Z of Bacillus subtilis has previously been assumed to proceed in two steps, a reversible adsorption of extended phages followed by contraction of the adsorbed particles (Steensma, 1981a). This model, also used for other phages, explained the biphasic character of the adsorption curve, but a discrepancy was found between the calculated and observed concentrations of adsorbed, extended phages. Computer simulations indicated that this might be caused by inhomogeneity of the phage preparations with respect to their adsorption properties and that in that case other models would also fit the experimental data. Discrimination between the models was not possible on the basis of the available information on PBS Z and it was therefore concluded that the values reported previously for the rate constants (Steensma, 1981a) should be used with caution.     

Relationship between phage resistance and emulsan production,interaction of phages with the cell-surface of Acinetobacter calcoaceticus RAG-1

The hydrocarbon-degrading strain Acinetobacter calcoaceticus RAG-1 produces an extracellular emulsifying agent capable of forming stable oil-in-water emulsions. The bioemulsifier, termed emulsan, is a polyanionic heteropolysaccharide (M.W. 10⁶) composed mainly of N-acyl D-galactosamine and an N-acyl hexosamine uronic acid. In order to probe the interaction of emulsan with the cell surface prior to its release into the growth medium, two new virulent bacteriophages for A. calcoaceticus RAG-1 were isolated from sewage and the properties of phage resistant mutants were studied. The two phages, ap-2 and ap-3, were differentiated on the basis of plaque morphology, electron microscopy and buoyant density. Isolated mutants of A. calcoaceticus RAG-1 which were resistant to one of the two phages retained sensitivity to the other phage. Resistance to phage ap-3 was accompanied by a severe drop in emulsan production. Independently isolated derivatives of A. calcoaceticus RAG-1 with a defect in emulsan production also turned out to be resistant towards phage ap-3. Antibodies prepared against purified emulsan specifically inhibited phage ap-3 adsorption to the cell surface of the parental strain.     

Possible Origin of a Minor Virus Specific Protein (A<Subscript>1</Subscript>) in Qβ Particles

RNA phages such as R17, MS2 and f2 (group I of Watanabe¹) consist of a single-stranded RNA, about 180 molecules of coat protein and one of A (or maturation) protein, a component required for the functional integrity of the viral particle, possibly for its adsorption to the host^2–4. The phage genome comprises three cistrons, accounting for the two proteins mentioned above as well as for a component of the viral RNA replicase^5,6.     

Adsorption of temperate phages of Lactobacillus delbrueckii strains and phage resistance linked to their cell diversity

Aims: The aim of this work was to study the adsorption step of two new temperate bacteriophages (Cb1/204 and Cb1/342) of Lactobacillus delbrueckii and to isolate phage‐resistant derivatives with interesting technological properties. Methods and Results: The effect of divalent cations, pH, temperature and cell viability on adsorption step was analysed. The Ca²⁺ presence was necessary for the phage Cb1/342 but not for the phage Cb1/204. Both phages showed to be stable at pH values between 3 and 8. Their adsorption rates decreased considerably at pH 8 but remained high at acid pH values. The optimum temperatures for the adsorption step were between 30 and 40°C. For the phage Cb1/342, nonviable cells adsorbed a lower quantity of phage particles in comparison with the viable ones, a fact that could be linked to disorganization of phage receptor sites and/or to the physiological cellular state. The isolation of phage‐resistant derivatives with good technological properties from the sensitive strains and their relationship with the cell heterogeneity of the strains were also made. Conclusions: Characterization of the adsorption step for the first temperate Lact. delbrueckii phages isolated in Argentina was made, and phage‐resistant derivatives of their host strains were obtained. Significance and Impact of the Study: Some phage‐resistant derivatives isolated exhibited good technological properties with the prospective to be used at industrial level.     

Phages of Pseudomonas aeruginosa: response to environmental factors and in vitro ability to inhibit bacterial growth and biofilm formation

Aims: To examine effects of various environmental factors on adsorption and inactivation of Pseudomonas aeruginosa‐specific phages: δ (family Podoviridae), J‐1, σ‐1 and 001A (family Siphoviridae) and their ability to inhibit bacterial growth and biofilm formation. Methods and Results: The phages examined in the study were clonally different, as revealed by RFLP. The temperature in the range 7–44°C had no influence on the adsorption of Podoviridae, but did affect Siphoviridae adsorption, particularly 001A. All phages were significantly stable at pH 5–9, and phages δ and 001A even at pH 3. Most of the examined carbohydrates and exopolysaccharides of the original host efficiently inactivated phage δ, while phages σ‐1 and J‐1 were inactivated considerably only by the amino acid alanine. Silver nitrate efficiently inactivated all the phages, while Siphoviridae were more resistant to povidone‐iodine. Serum of nonimmunized rats had no influence on phage inactivation and adsorption. Only phage δ showed ability to effectively inhibit in vitro bacterial growth and biofilm formation. Conclusions: The examined environmental parameters can significantly influence the adsorption and viability of Ps. aeruginosa‐specific phages. The phage δ is a good candidate for biocontrol of Ps. aeruginosa. Significance and Impact of the Study: The study provides important data on Ps. aeruginosa‐specific phage adsorption, inactivation and in vitro lytic efficacy.     

Cell division in Escherichia coli septation during synchronous growth

Summary The capacity of E. coli B/r to support recombination and complementation between T4am phages during its life cycle has been analyzed in order to get information on the mechanism of cell division. It was found that a decrease in recombinants and complementation events, which is expected at the time of cell compartmentalization coincides with physical cell separation. Therefore, we conclude that the two halves of a dividing cell remain connected until a very late stage of the division period, thus allowing exchange of DNA and protein molecules.When a synchronized culture of E. coli B/r is infected at different cell age with phage T4, the number of surviving cells increases 10 min prior to cell division. At this time the cells are separated into two independent targets for killing by the phage, although there is still free exchange of DNA and proteins within the whole cell. The localized action of murein metabolizing enzymes at the site of subsequent cell division is likely to create a barriere within the cell envelope that prevents the propagation of the phage killing signal.     

Inhibition of β-galactosidase synthesis inEscherichia coli after infection with different DNA and RNA phages

Infection ofEscherichia coli with T1, T2r⁺, T3 and T4 phages leads to an immediate inhibition of β-galactosidase synthesis. Similar results were obtained with the virulent mutant of phage lambda. The degree of inhibition of β-galactosidase synthesis depends on the time delay between the addition of the inducer and the phage particles, and on the amount of phage DNA, which has penetrated into the host cell. RNA phage MS2 exhibited no inhibitory effect on enzyme synthesis.     

The role of the HCR system in the repair of lethal lesions ofBacillus subtilis phages and their transfecting DNA damaged by radiation and alkylating agents

The role of the HCR system in the repair of prelethal lesions induced by UV-light, γ-rays and alkylating agents was studied in theBacillus subtilis SPP1 phage, its thermosensitive mutants (N3, N73 endts ₁) and corresponding infectious DNA. The survival of phages and their transfecting DNA after treatment with UV light is substantially higher inhcr ⁺ cells than inhcr cells, the differences being more striking in intact phages than in their transfecting DNA’s. Repair inhibitors reduce the survival inhcr ⁺ cells: caffeine lowers the survival of UV-irradiated phage SPP1 in exponentially growinghcr ⁺ cells but has no effect on its survival in competenthcr ⁺ cells; acriflavin and ethidium bromide decrease the survival of UV-irradiated SPP1 phage in both exponentially growing and competenthcr ⁺ cells to the level of survival observed inhcr cells; moreover, ethidium bromide lowers the number of infective centres inhcr ⁺ cells of UV-irradiated DNA of the SPP1 phage. Repair inhibitors do not lower the survival of UV-irradiated phages or their DNA inhcr cells. The repair mechanism under study repairs effectively also lesions induced by polyfunctional alkylating agents in transfecting DNA’s ofB. subtilis phages but is not functional with lesions induced by these agents in free phages and lesions caused in phages and their DNA by ethyl methanesulphonate or γ-rays.