Comparison of new giant bacteriophages OBP and Lu11 of soil pseudomonads with bacteriophages of phiKZ-supergroup of Pseudomonas aeruginosa

Study of two recently isolated giant bacteriophages Lu11 and OBP that are active on Pseudomonas putida var. Manila and Pseudomonas fluorescens, respectively, demonstrated their similarity in morphology, genome size, and size of phage particles, with giant bacteriophages of Pseudomonas aeruginosa assigned to the supergroup of phiKZ-like phages of the family Myoviridae designated in this manner according to the best studied phage phiKZ that belongs to the species of this group widely distributed in nature. Comparison of major polypeptide sizes of mature particles suggests the similarity of certain proteins in the phages examined. In OBP particles visualized with an electron microscope, an "inner body" was detected, which points to the specific DNA package intrinsic to phages of phiKZ group. In the meantime, phages Lul11 and OBP do not exhibit resemblance among themselves or with any of earlier described phiKZ-like phages in respect to other traits; particularly, they have no detectable DNA homology. Note that phage Lu11 of P. putida var. Manila exhibits very slight homology with phage Lin68 of the family of P. aeruginosa phiKZ-like phages detected only in blot hybridization. This suggests the possible involvement of these phages in interspecies recombination ("gene shuffling") between phages of various bacterial species. Results of partial sequencing of phage genomes confirmed the phylogenetic relatedness of phage OBP to phages of the phiKZ-supergroup, whereas phage Lu11 most probably belongs to a novel species that is not a member of supergroup phiKZ composition. The results of the study are discussed in terms of the evolution of these phages.     

Amber mutants in gene 67 of phage T4. Effects on formation and shape determination of the head

Two amber mutations in gene 67 of bacteriophage T4 were constructed by oligonucleotide-directed mutagenesis and the resulting mutated genes were recombined back into the phage genome and their phenotype was studied. The 67amK1 mutation is close to the amino terminus of the gene, and phage carrying this mutation are unable to form plaques on suppressor-negative hosts. A second mutation, 67amK2, which lies in the middle of the gene, three codons N-terminal to a proteolytic cleavage site, produces a small number of viable phage particles. In suppressor-negative hosts, both mutants produce polyheads and proheads. 67amK1 assembles only few proheads that have a disorganized core structure, as judged from thin sections of infected cells. The proheads and the mature phages of both mutants are mainly isometric rather than having the usual prolate shape. Depending on the 67 mutant and the host, between 20% and 73% of the particles that are produced are isometric, and 1 to 10% are two-tailed biprolate particles. 67amK2 phages grown on a supD suppressor strain that inserts serine in place of the wild-type leucine do not contain gp67* derived from gene product 67 (gp67) by proteolytic cleavage. This demonstrates the importance of the correct amino acid at this position in the protein. Other abnormalities in these 67amK2 phages are the presence of uncleaved scaffolding core proteins (IPIII and gp68), indicating a structural alteration in the prohead scaffold, resulting in only partial cleavage. In wild-type phages these proteins are found in the head only in the cleaved form. With double-mutants of 67 with mutations in the major shell protein gp23 no naked scaffolding cores were found, confirming the necessity of gp67 for the assembly or persistence of a "normal" core.     

Influence of ionic strength on the stability of phage t2r to osmotic shock

The authors assume that an increase in the ionic strength of the medium results in dissociation of the DNA-polyamine complex in the phage head. The released polyamines and internal protein molecules are unable to permeate into the external environment. Their thermal movement causes constant pressure within the phage; this contributes to rupture of the head by osmotic shock and probably plays a decisive role in injection of the phage DNA into the bacterium. Study of osmotic shock by glycerol in media of different ionic strengths showed that, as the ionic strength increases, the bacteriophage is at first destabihized by the action of the released polyamines and that only when the ionic strength is raised still further, it is restabilized by the influence of the ionic strength on the resistance of the membrane. The osmotic prossures required to rupture the phage head are practically the same for NaCl and KCl solutions, while for shock by glycerol solutions, considerably lower values were measured in media of low ionic strengths. The authors attribute these differences to differences in the rate of permeation of the shocking substance across the phage membrane. The equilibrium for NaCl and KCl is established in less than one minute and for glycerol in 5–10 min.     

Phage-stable mutants of Pseudomonas putida: new types of stability

More than 170 phage-resistant mutants (PRM) of the first order of Pseudomonas putida strain PpG1 were obtained using newly isolated and previously described bacteriophages specific for this strain. According to the results of analysis of resistance of the mutants to each of 31 phages of PpG1 strain and 8 phages of the PpN strain, the PRM strains were distributed into 20 groups. In most cases, the reason for resistance is loss of absorption capacity of bacteria. However, no direct relation between the level of absorption and efficiency of phage plating was detected. It was shown that some of the PRM of P. putida PpG1 strains acquired the ability to maintain the growth of phages specific for the other P. putida strain, PpN. Frequencies of isolating mutants of various resistance types depend on the concrete phage used. In accordance with their absorption specificity, all phages were distributed into 23 groups, and a tridimensional formal scheme of receptor sites for these phages on the PpG1 strain was drawn. In the process of selection of the PpG1 clones resistant to non-lysogenizing mutant of temperate PP71 phage, a variant of this strain manifesting the phenomenon of "auto-plaquing" was found. These results support the mutational origin of this phenomenon in some cases.     

Characterisation of four Leuconostoc bacteriophages isolated from dairy fermentations

Abstract Four bacteriophages (phages) growing on the same Leuconostoc strain were characterised. Electron micrographs showed these phages to be similar in morphology to the commonly isolated lactococcal phages with head diameters ranging from 49–55 nm and tail lengths of 117–131 nm. A distinctive base plate and collar were also present. From restriction enzyme analysis of purified phage DNA, the genome sizes were 23–29 kb. All four phages showed one major structural protein (of approximately 24 kDa) on SDS polyacrylamide gels. Hybridization experiments confirmed that the phages belonged to the same homology group. There was no homology between DNA from these phages and DNA from a prolate or small isometric lactococcal phage.     

Viable transmembrane region mutants of bacteriophage M13 coat protein prepared by site-directed mutagenesis

Bacteriophage M13 coat protein - a 50-residue protein located at the E. coli host membrane during phage reproduction - is subjected to cytoplasmic, membrane-bound, and DNA-interactive environments during the phage life cycle. In research to examine the specific features of primary/secondary structure in the effective transmembrane (TM) region of the protein (residues 21-39: YIGYAWAMVVVIVGATIGI) which modulate its capacity to respond conformationally to the progressive influences of these varying environments, we have prepared over two dozen viable mutant phages with alterations in their coat protein TM regions. Mutants were obtained through use of site-directed mutagenesis techniques in combination with three "randomized" oligonucleotides which spanned the TM region. No subcloning was required. Among mutations observed were those in which each of the four TM Val residues was changed to Ala, and several with increased Ser or Thr content, including one double Ser mutant (G23S-A25S). Polar substitutions arising at Gly23 and Tyr24-including G23D, Y24H, Y24D and Y24N-suggested that this local segment resides external to the host membrane. Milligram quantities of mutant coat proteins are obtained by growing M13 mutant phages in liter preparations, with isotopic (e.g., 13C) labelling at desired sites, for subsequent characterization and conformational analysis in membrane-mimetic media.     

Isolation and characterization of lytic bacteriophages from sewage at an egyptian tertiary care hospital against methicillin-resistant Staphylococcus aureus clinical isolates

BackgroundMethicillin resistant Staphylococcus aureus (MRSA) is a pathogen to humans causing life-threatening infections. MRSA have the capability to grow resistance to many antibiotics, and phage therapy is one treatment option for this infection.ObjectivesThe aim of the present study was to isolate and characterize the lytic bacteriophages specific to MRSA from domestic sewage water at a tertiary care hospital in Egypt.MethodsThirty MRSA strains were isolated from different clinical samples admitted to the microbiology lab at Theodor Bilharz Research institute (TBRI) hospital, Giza, Egypt. They were confirmed to be MRSA through phenotypic detection and conventional PCR for mecA gene. They were used for the isolation of phages from sewage water of TBRI hospital. Plaque assay was applied to purify and quantify the titer of the isolated phages. The host range of the isolated phages was detected using the spot test assay. The morphology of phages was confirmed using transmission electron microscope (TEM). Digestion of DNA extracted from phages with endonuclease enzymes including EcoRI and SmaI was performed. SDS-PAGE was performed to analyze MRSA specific phage proteins. As a positive control prophages were isolated from a mitomycin C (MitC) treated culture of S. aureus strain ATCC25923. Further characterization using conventional polymerase chain reaction (PCR) was used to select three known Staphylophages by detecting the endolysin gene of phage K, the polymerase gene of phage 44AHJD, and the minor tail gene of phage P68.ResultsIsolated phages in this research displayed a wide host range against MRSA using the spot test, out of thirty tested MRSA isolates 24 were sensitive and got lysed (80%). The titer of the phages was estimated to be 1.04 × 10⁶ pfu/ml using plaque test. Identification of head and tail morphology of the phages was achieved using TEM and they were designated to tailed phages of order Caudovirales, they composed an icosahedral capsid. Prophages were isolated through MitC induction. DNA of phages was digested by endonuclease enzymes. Conventional PCR yielded 341 bp of phage K endolysin gene and phage P68 minor tail protein gene 501 bp. Protein analysis using SDS-PAGE showed 4 proteins of sizes between 42 kDa and 140 kDa.ConclusionPhages isolated here are alike to others mentioned in previous studies. The high broad host range of the isolated phages is promising to control MRSA and can be in the future commercially suitable for treatment as lysate preparations. Animal models of phage-bacterial interaction will be our next step that may help in resolving the multidrug resistant crisis of MRSA in Egypt.     

Some Properties of Five New Salmonella Bacteriophages

Five bacteriophages were isolated from lysogenic strains of Salmonella potdam. On the basis of plaque morphology, thermostability, serology, host range, one-step growth parameters, and phage morphology, they were divided into three groups: group A, phages P4 and P9c; group B, phages P3 and P9a; and group C, phage P10. Group A phages had a hexagonal head 55 nm in diameter with a short tail 15 nm long. These phages were particularly characterized by high thermostability, lack of serological relationship with any of the other phages, and restriction of lysis to other Salmonella strains of Kauffmann-White group C(1). Group B phages had a head identical in size and shape to that of the A phages, but they possessed a tail 118 nm long with a contractile sheath. A unique feature was the occurrence of tail fibers at the end of the core rather than at the base of the sheath. These phages were considerably less thermostable, had extended host ranges, and were serologically distinct from each other but unrelated to the A phages. The group C phage, P10, had a head identical to that of the A and B phages. It had a tail 95 nm in length, with tail fibers attached to a base plate at the end of a contractile sheath. P10 was highly sensitive to heat, lysed only smooth strains of Salmonella, and showed a degree of serological relationship to both B phages. The relationship of these phage groups to previous Salmonella phage grouping schemes is discussed.     

Effect of freezing modes on the survival of Escherichia coli bacteriophages

The object of this work was to study the effect of freezing down to--196 degrees C at different cooling and warming rates on the survival of T3, T4 and phiX174 phages. Phage particles survived when T3 phage was frozen at a rate of 20-400 degrees/min and phiX174 phage at a rate of 20-45 degrees/min. The survival rate of T4 phage was highest when it was frozen at a rate of 45 degrees/min. The survival of the phages depended also on the regime of warming. The susceptibility of the phages to freezing correlated with their sensitivity to osmotic shock in NaCl and sucrose solutions.     

Comparative Study of 35 Bacteriophages of Lactobacillus helveticus: Morphology and Host Range

This survey included 23 phages isolated from cheese whey and 12 temperate phages induced with mitomycin from their lysogenic host strains. All of the phages had an isometric head and a tail with a contractile sheath. In addition, short-tailed (160-nm-long) and long-tailed (260-nm-long) phages were distinguished. Short-tailed phages were by far the most widespread in French cheese factories (32 of the 35 phages studied). The study of phage relationships enabled two large groups of strains to be distinguished: those not or slightly sensitive to phages and those very sensitive to phages. There was an obvious relationship in the first group between phage sensitivity (or resistance) and the geographic origin of the strains. The second group contained primarily strains from large international collections and those isolated from commercial starters. The relationships among short-tailed phages, either temperate or isolated as lytic, suggest that lysogenic strains could be the major source of phages in French cheese factories.     

Localization of minor protein components of the head of bacteriophage T4.

The bacteriophage T4 capsid contains a number of minor proteins that are required for head assembly but whose detailed function and position in the head are unknown. We have found that by systematically varying the conditions of extraction, some of these minor proteins can be removed while the main capsid structure is left substantially intact. Electron microscopic examination of the residual capsids showed that the extraction of the product of gene 20 is correlated with the loss of a plug that distinguishes one vertex position (presumably the tail attachment site) from the others. Extraction of the product of gene 24 is correlated with the loss of the other 11 (nonproximal) vertexes of the capsid. We further show that antibody to P24 binds specifically to the nonproximal vertexes of both T4 preheads and T4 phages. On the basis of our findings, we suggest that P20 is located at or near the tail attachment site of the capsid, whereas P24 forms the 11 nonproximal vertexes of preheads and P24 forms the nonproximal vertexes of the mature head.     

In Vitro system for the study of bacteriophage phi chi 174 adsorption and eclipse.

An in vitro system was developed for the study of the initial stages of bacteriophage phi chi 174 infection. Escherichia coli C cells were incubated with 20% sucrose and then subjected to cold osmotic shock in 5 mM MgSO4. The concentrated supernatant shock fluid inactivated phi chi 174 with the same kinetics and requirements as for normal infection. Shock fluids prepared from phi chi 174-resistant strains of E. coli did not show this effect. The 114S phage were initially converted into 70S particles, the process termed "eclipse". These structurally altered phages then attached to a component of the shock fluid, producing fast-sedimenting complexes, and eventually released at least a part of their DNA into the medium. The fast-sedimenting complex could be radioactively labeled with oleic acid. Radioactivity was found to co-chromatograph with both biological activity and the majority of the high-molecular-weight carbohydrates present in the shock fluid. It is concluded that E. coli C osmotic shock fluid contains isolated phi chi 174-specific receptor sites composed of lipopolysaccharides. This system conveniently separates the early stages of phage phi chi 174 infection from the intracellular events.     

Classification of Lytic Bacteriophages Attacking Dairy Leuconostoc Starter Strains

A set of 83 lytic dairy bacteriophages (phages) infecting flavor-producing mesophilic starter strains of the Leuconostoc genus was characterized, and the first in-depth taxonomic scheme was established for this phage group. Phages were obtained from different sources, i.e., from dairy samples originating from 11 German dairies (50 Leuconostoc pseudomesenteroides [Ln. pseudomesenteroides] phages, 4 Ln. mesenteroides phages) and from 3 external phage collections (17 Ln. pseudomesenteroides phages, 12 Ln. mesenteroides phages). All phages belonged to the Siphoviridae family of phages with isometric heads (diameter, 55 nm) and noncontractile tails (length, 140 nm). With the exception of one phage (i.e., phage ΦLN25), all Ln. mesenteroides phages lysed the same host strains and revealed characteristic globular baseplate appendages. Phage ΦLN25, with different Y-shaped appendages, had a unique host range. Apart from two phages (i.e., phages P792 and P793), all Ln. pseudomesenteroides phages shared the same host range and had plain baseplates without distinguishable appendages. They were further characterized by the presence or absence of a collar below the phage head or by unique tails with straight striations. Phages P792 and P793 with characteristic fluffy baseplate appendages could propagate only on other specific hosts. All Ln. mesenteroides and all Ln. pseudomesenteroides phages were members of two (host species-specific) distinct genotypes but shared a limited conserved DNA region specifying their structural genes. A PCR detection system was established and was shown to be reliable for the detection of all Leuconostoc phage types.     

Genome Organization and Characterization of the Virulent Lactococcal Phage 1358 and Its Similarities to Listeria Phages

Virulent phage 1358 is the reference member of a rare group of phages infecting Lactococcus lactis. Electron microscopy revealed a typical icosahedral capsid connected to one of the smallest noncontractile tails found in a lactococcal phage of the Siphoviridae family. Microbiological characterization identified a burst size of 72 virions released per infected host cell and a latent period of 90 min. The host range of phage 1358 was limited to 3 out of the 60 lactococcal strains tested. Moreover, this phage was insensitive to four Abi systems (AbiK, AbiQ, AbiT, and AbiV). The genome of phage 1358 consisted of a linear, double-stranded, 36,892-bp DNA molecule containing 43 open reading frames (ORFs). At least 14 ORFs coded for structural proteins, as identified by SDS-PAGE coupled to liquid chromatography-tandem mass spectrometry (LC-MS/MS) analyses. The genomic organization was similar to those of other siphophages. All genes were on the same coding strand and in the same orientation. This lactococcal phage was unique, however, in its 51.4% GC content, much higher than those of other phages infecting this low-GC Gram-positive host. A bias for GC-rich codons was also observed. Comparative analyses showed that several phage 1358 structural proteins shared similarity with two Listeria monocytogenes phages, P35 and P40. The possible origin and evolution of lactococcal phage 1358 is discussed.The first sequenced genome of a phage infecting Lactococcus lactis (bIL67) was reported in 1994 (57). Its genomic characterization was performed with the prospect of a better understanding of lactococcal phage biology. L. lactis is a Gram-positive bacterium added to milk to produce an array of fermented dairy products. In this human-made environment, substantial amounts of lactococcal cells are cultivated on a daily basis in large fermentation vats, and these added cells randomly encounter virulent phages present in heat-treated but nonsterile milk. Moreover, it is widely acknowledged that the increased use of the same bacterial strains within existing dairy facilities inevitably leads to milk fermentation failures due to the multiplication of virulent phages. This biotechnological problem reduces yields and lowers the quality of fermented products (51).Over 700 lactococcal phage isolates have been reported in the literature (3). To date, more than 25 complete genome sequences of lactococcal phages are publicly available in the NCBI database, and the sequencing of others is under way. These numbers indicate that Lactococcus phages are among the most studied of the bacterial viruses. All lactococcal phages belong to the order Caudovirales and are included within two families according to their tail morphology: the Siphoviridae (long noncontractile tail [most lactococcal phages]) and the Podoviridae (short noncontractile tail [few lactococcal phages]) (14). Currently, phages infecting L. lactis strains have been divided into 10 genetically distinct groups (14). The complete genomic sequence is available for at least one representative of 8 of the groups.Early sequencing efforts concentrated on the genomes of lactococcal phages belonging to the 936, c2, and P335 groups (Siphoviridae), because members of these groups were regularly isolated in dairy plants (8, 36, 50). PCR-based methods were also devised to rapidly classify these phages (41). These Siphoviridae phages pose a significant risk to the dairy industry, and their characterization is important for developing adapted antiphage strategies to limit their propagation and evolution.In recent years, representatives of the less recognized lactococcal phage groups have been characterized, including phages Q54 (22), KSY1 (13), 1706 (23), asccφ28 of the P034 group (39), and P087 (63). Their molecular characterizations were aimed at understanding why some phage groups (936, c2, and P335) predominate while the others have remained marginal, at best. However, it was recently reported that P034-like phages may be emerging in certain regions (52). Genomic and microbiological analyses indicated that members of these rare phage groups were likely the result of recombination between different lactococcal phages and phages infecting other Gram-positive bacteria, and they may not be fit to multiply rapidly in milk. For example, lactococcal phage 1706 shares similarities with Ruminococcus and Clostridium prophages (23). Similarly, L. lactis phage P087 structural proteins share identity with gene products found in a prophage in the Enterococcus faecalis genome (63). It was also shown previously that lactococcal phage asccφ28 was related to Streptococcus pneumoniae phage Cp-1 and Bacillus subtilis φ29-like phages (39). It was suggested that phages 1706, asccφ28, and P087 acquired a receptor-binding protein complex from another lactococcal phage that enabled them to infect a L. lactis host.Here, we report the complete genome sequence and analysis of phage 1358, a virulent representative of the 9th lactococcal phage group.     

The CRISPR/Cas Adaptive Immune System of Pseudomonas aeruginosa Mediates Resistance to Naturally Occurring and Engineered Phages

Here we report the isolation of 6 temperate bacteriophages (phages) that are prevented from replicating within the laboratory strain Pseudomonas aeruginosa PA14 by the endogenous CRISPR/Cas system of this microbe. These phages are only the second identified group of naturally occurring phages demonstrated to be blocked for replication by a nonengineered CRISPR/Cas system, and our results provide the first evidence that the P. aeruginosa type I-F CRISPR/Cas system can function in phage resistance. Previous studies have highlighted the importance of the protospacer adjacent motif (PAM) and a proximal 8-nucleotide seed sequence in mediating CRISPR/Cas-based immunity. Through engineering of a protospacer region of phage DMS3 to make it a target of resistance by the CRISPR/Cas system and screening for mutants that escape CRISPR/Cas-mediated resistance, we show that nucleotides within the PAM and seed sequence and across the non-seed-sequence regions are critical for the functioning of this CRISPR/Cas system. We also demonstrate that P. aeruginosa can acquire spacer content in response to lytic phage challenge, illustrating the adaptive nature of this CRISPR/Cas system. Finally, we demonstrate that the P. aeruginosa CRISPR/Cas system mediates a gradient of resistance to a phage based on the level of complementarity between CRISPR spacer RNA and phage protospacer target. This work introduces a new in vivo system to study CRISPR/Cas-mediated resistance and an additional set of tools for the elucidation of CRISPR/Cas function.     

Location of DNA ends in P2, 186, P4 and lambda bacteriophage heads

When mature phage particles were suspended in a solution containing formaldehyde (0.07 m-Na⁺, pH 9.0, 10% HCHO for 10 min at 23 °C) and the mixture then spread for electron microscopy in the presence of 50% formamide and cytochrome c, the phage lysed and a high proportion of the DNA molecules were seen to be attached to phage tails. The phage tails were found to be attached at only one end of each DNA molecule and denaturation mapping showed that this end was unique for each of the phages P2, 186, P4 and λ. It is argued that in these mature phage particles one specific end of the DNA molecule is present at the head-tail attachment site.     

The transformation of τ-particles into T4 heads. I. Evidence for the conservative mode of this transformation.

Asynchroneous T4 phage head maturation includes the step of P23 cleavage: P23 of head-related τ-particles is cleaved into P23

1 This paper is part of the thesis of R. K. L. Bijlenga. It is number X of the series: “Studies on the morphopoieses of the head of phage T-even.”

of capsids with a conservative mode of transformation as evidenced by “heavy” labeling in temperature shift-down experiments with mutant 24 (tsL90). Assuming a subunit pool, data indicate in situ cleavage on individual precursor particles. The interpretation becomes less interesting when assuming a compartmentation of the membrane surface; this hypothesis is not ruled out.