Studies on Temperate Phages of Lactobacillus salivarius

Twenty-three temperate phages of Lactobacillus salivarius isolated from human feces were studied as to their morphological, biological, and serological properties. (1) Among 30 strains of L. salivarius tested, 23 strains were lysed by induction with mitomycin C (MC). In all these lysates, phage particles were detected by electron microscopic examination. (2) These phages were morphologically divided into three groups: particles with a regular hexagonal head and a long flexible tail; particles having a regular hexagonal head with or without a short tail-like structure; particles with an elongated head and a long noncontractile tail. (3) Only two, phage 223 having an elongated head and phage 227 with a regular hexagonal head and a long noncontractile tail, produced tiny and very turbid plaques on several host bacteria. Six phages could produce only inhibition zones, ranging from complete inhibition through partial inhibition to normal growth by a serial dilution spot test. (4) All these killer particles could also inhibit the growth of their producer cells. (5) A serological relationship was observed between temperate phages and killer particles, and this was somewhat consistent with the morphological groupings.     

Characteristics of five bacteriophages of yellow-pigmented enterobacteria

Four bacteriophages (C2, C2F, E3, and E16P) belonging to morphological group C3 and one belonging to morphological group A3 (E16B) were purified by deuterium oxide gradient centrifugation and cesium chloride gradient centrifugation. Morphological group C3 phages had a densityd=1.534–1.541 and group A3 phage (E16B) had a densityd=1.492 in CsCl. Phages of morphological group C3 isolated onEnterobacter sakazakii (C2, C2F) and onErwinia herbicola (E3, E16P) were compared withSalmonella newport phage 7-11 with respect to host-range, genome size, antigenic relatedness, and ultraviolet and heat susceptibility. Phages C2 and C2F could multiply inEnterobacter cloacae, E. sakazakii, Erwinia herbicola, E. rhapontici, andLevinea malonatica; whereas phages E3, E16P, and 7-11 could multiply on these same species and onEscherichia coli and severalSalmonella serotypes. Molecular weights of phage DNAs were determined to be 58×10⁶ (C2), 60×10⁶ (7-11), 67×10⁶ (E3), and 39×10⁶ (E16B).All studied phages of morphological group C3 (includingSalmonella newport phage 7-11) were neutralized by anti-phage C2 serum. Despite differences in neutralization kinetics and in ultraviolet and heat sensitivities, these phages of morphological group C3 constitute one phage species. Phage E16B (morphological group A3) had a host-range limited toEnterobacter cloacae, Erwinia herbicola, andE. rhapontici; it was antigenically unrelated to the preceding phage group C3, and showed ultraviolet and heat susceptibility close to that of coliphage T4.     

Isolation and characterization of a new ruminal bacteriophage lytic toStreptococcus bovis

A new bacteriophage, designated F4, was isolated from the ruminal fluid of a calf. The host range of F4 phage was limited to five strains ofStreptococcus bovis out of ten tested on which clear plaques 0.6–1.2 mm in diameter were found. Bacteriophage F4 had an elongated head 75 nm long and 33 nm wide with a noncontractile flexible tail 100 nm in length on average. This phage is defective in the generation of plaques at low multiplicities of infection. Its genome consists of double-stranded linear DNA of 60.38 kb lacking cohesive ends. The F4 DNA was analyzed with 13 restriction enzymes. The restriction enzymes that did not cleave it wereBamHI,EcoRI,PvuI, andSmaI. The circular restriction map was constructed with four restriction endonucleases (XbaI,EcoI,SalI, andBglI).     

Lysogeny among mycobacteria

Our investigations to detect naturally lysogenic strains of mycobacteria were limited to 1 strain ofMycobacterium smegmatis, 4 strains ofMycobacterium borstelense var.niacinogenes, and to 5 strains ofMycobacterium marinum (Syn:Mycobacterium balnei), all together 10 strains. They were chosen because as a sign of lysis they secrete a large quantity of cytoplasmatic components (nucleic acids proteins, amino acids etc.) into the fluid medium (for instance phosphate buffer), in which they are suspended. In a first series of experiments culture filtrates were tested on 84 strains of slowly and rapidly growingMycobacterium species as indicator strains. Using this method free phage particles were only found in the culture filtrate of 1 strain,Mycobacterium smegmatis SN 46, isolated from a patient with achalasia. Phage particles could not be found in the filtrates of the other 9 probably lysogenic strains. In a second series of experiments more closely related indicator strains were used. The 10 probably lysogenic strains were cultured in bovine serum or antiphage-antiserum containing medium and single selected colony cultures a small part of which showed sensitivity to the filtrates. The released and adapted phages, designated as B₂₄, B₃₀, B₃₂, B₃₃, B₃₄ and B₃₅ have a very narrow host range. The plaques are very small and turbid. On electron micrographs the temperate phages B₂₄, B₃₀ and B₃₅ exhibit the typical head-tail morphology. The head of the temperateborstelense var.niacinogenes phage B₃₀ is 45 nm in diameter, the tength of tail is about, 120nm. The average dimensions of the long head ofsmegmatis phage B₂₄ are 40 × 80 nm, the tail is about 160 nm long. The balnei phage B₃₅ is very similar morphologically to phage B₃₀. The head is about 50 nm in diameter, the length of tail about 160 nm. The phage sensitive variants are not “carrier” strains. Their phage sensitivity is not a stable property. After several culture passages in serum-free medium the variants regain their phage immunity completely and release phages like the lysogenic parent strains. The sensitive variants must therefore be considered to be also lysogenic. TheMycobacterium borstelense var.niacinogenes phages are serologically very related. Dedicated to Academician Ivan Málek on the occasion of his 60th birthday     

DNA relatedness among bacteriophages of the morphological group C3

Six bacteriophages with an elongated head and a short, noncontractile tail were compared by DNA-DNA hybridization, seroneutralization kinetics, mol% G+C and molecular weight of DNA, and host range. Three phage species could be identified. Phage species 1 containedEnterobacter sakazakii phage C2,Erwinia herbicola phages E3 and E16P, andSalmonella newport phage 7–11. These phages had a rather wide host range (4 to 13 bacterial species). DNA relatedness among species 1 phages was above 75% relative binding ratio (S1 nuclease method, 60°C) when labeled DNA from phage C2 was used, and above 41% when labeled DNA from phage E3 was used. Molecular weight of DNA was about 58×10⁶ (C2) to 67 ×10⁶ (E3). The mol% G+C of DNA was 43–45. Anti-C2 serum that neutralizes all phages of species 1 does not neutralize phages of the other two species. Species 2 contains only coliphage Esc-7-11, whose host range was only oneEscherichia coli strain out of 188 strains of Enterobacteriaceae studied; it was unrelated to the other two species by seroneutralization and DNA hybridization. DNA from phage Esc-7-11 had a base composition of 43 mol% G+C and a molecular weight of about 45×10⁶. Species 3 contains onlyProteus mirabilis phage 13/3a. Its host range was limited to swarmingProteus species. Species 3 was unrelated to the other two species by seroneutralization and DNA hybridization. DNA from phage 13/3a had a base composition of 35 mol% G+C and molecular weight of about 53×10⁶. It is proposed that phage species be defined as phage nucleic acid hybridization groups.     

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.     

BVPaP-3, a T7-Like Lytic Phage of <Emphasis Type="Italic">Pseudomonas aeruginosa</Emphasis>: Its Isolation and Characterisation

The increasing emergence of antibiotic-resistant bacteria has produced a growing interest among scientists in bacteriophages as alternative antimicrobial agents. This article reports a lytic phage against an antibiotic-resistant strain of Pseudomonas aeruginosa. Phage BVPaP-3 is a member of the Podoviridae family and morphologically similar to the T7-like phage gh-1. The phage has a hexagonal head of 58–59 nm in diameter and a short tail of 10 × 8 nm. It is stable at a wide range of pH (6–10) and temperatures (4–40°C). Its optimal growth temperature is 37°C and the adsorption rate constant is 1.19 × 10⁻⁹. Latent and eclipse periods are 20 and 15 min, respectively, and the burst size is 44 after 35 min at 37°C. The phage has a DNA size of 41.31 kb and a proteome of 11 proteins. The major protein is 33 kDa in size.     

Comparison of Vero-cytotoxin-encoding phages from Escherichia coli of human and bovine origin

Phages encoding production of Vero cytotoxins VT1 or VT2 were isolated from strains of Escherichia coli of human and bovine origin. Two human strains of serotype O157: H7 produced both VT1 and VT2 and each carried two separate phages encoding either VT1 or VT2. The phages were morphologically similar to each other and to a VT2 phage previously isolated from a strain of serotype O157: H-; all had regular hexagonal heads and short tails. The phages had similar genome sizes and DNA hybridization and restriction enzyme digestion showed that the DNAs were very closely related. This contrasts with another report that one of the strains tested (933) released two clearly distinguishable phages separately encoding VT1 and VT2. The O157 phages differed from a VT1 phage isolated from a bovine E. coli strain belonging to serotype O26: H11 and from the reference VT1 phage isolated previously from a human strain, H19, of serotype O26: H11. The two O26 phages were morphologically similar with elongated heads and long tails. They had similar genome sizes and DNA hybridization indicated a high level of homology between them. Hybridization of an O157 phage DNA probe to DNA of the O26 phages, and vice versa, showed there was some cross-hybridization between the two types of phage. A phage from a bovine strain of serotype O29: H34 had a regular hexagonal head and short tail resembling those of the O157 phages. The DNA was distinguishable from that of all the other phages tested in restriction digest patterns but hybridized significantly to that of an O157 phage. Hybridization of the phage genomes with VT1 and VT2 gene probes showed that sequences encoding these toxins were highly conserved in the different phages from strains belonging to the three serogroups.     

φ20, A Temperate Bacteriophage Isolated from Bacillus anthracis Exists as a Plasmidial Prophage

This study describes the isolation of temperate B. anthracis phages, from 4 out of 20 B. anthracis strains screened, by use of the inducing agents mitomycin C and UV light. Phage φ20 isolated from B. anthracis Sterne 34F₂ (pXO1⁺ pXO2⁻) was shown to have double-stranded DNA of size 48756 bp and a restriction site map showing nine sites for enzymes BamHI, BglII, and SstI is included. The φ20 genome was found to exist as a plasmidial prophage and the phage itself to have a polyhedral head of diameter 65 nm and tail 217 nm long and 15 nm wide.     

Characterization of <Emphasis Type="Italic">Bacillus</Emphasis> phage-K2 isolated from chungkookjang,a fermented soybean foodstuff

An investigation of a virulent Bacillus phage-K2 (named Bp-K2) isolated from chungkookjang (a fermented soybean foodstuff) was made. Bp-K2 differed in infectivity against a number of Bacillus subtilis strains including starter strains of chungkookjang and natto, being more infectious to Bacillus strains isolated from the chungkookjang, but much less active against a natto strain. Bp-K2 is a small DNA phage whose genome size is about 21 kb. Bp-K2 is a tailed bacteriophage with an isometric icosahedral head (50 nm long on the lateral side, 80 nm wide), a long contractile sheath (85–90 nm × 28 nm), a thin tail fiber (80–85 nm long, 10 nm wide), and a basal plate (29 nm long, 47 nm wide) with a number of spikes, but no collar. The details of the structures of Bp-K2 differ from natto phage ϕBN100 as well as other known Bacillus phages such as SPO1-like or ϕ 29-like viruses. These data suggest that Bp-K2 would be a new member of the Myoviridae family of Bacillus bacteriophages.     

Heterocyst division in two blue-green algae

Bacteriophage 16-6-12 of Rhizobium lupini has a long, non-contractile tail and a head which is hexagonal in outline. The tail is 140 nm in length, 11 nm in diameter, and carries a short terminal fiber. Analysis of the tail structure by optical diffraction indicates that it is of the helical “stacked disc” type. After phenol-extraction from purified particles, the DNA of phage 16-6-12 can circularize in vitro. No significant difference in contour length was observed between the linear (14.34±0.28 μm) and circular (14.44±0.24 μm) forms of molecules. After partial denaturation with alkali an AT-GC-map was constructed, which shows an asymmetric distribution of AT- and GC-rich regions. It is concluded that this phage DNA can circularize due to the presence of cohesive ends and that it is not circularly permuted.     

Coliphage HK243: Biological and Physicochemical Characteristics

Coliphage HK243 can form plaques on Escherichia coli C and K-12, but not B. The plaques are 1–2 mm in diameter and are opaque areas which clear upon exposure to chloroform vapor. During one-step growth, the eclipse and the latent periods are 20 and 30 min, respectively. Phage-infected cells continue to produce cell-free plaque-forming units for as long as 80 min after the end of the latent period, although at high multiplicities of infection (MOI) most cells lyse. No lysogenic bacteria have been found among survivors, so HK243 is considered a virulent phage. Some of the cells surviving a high MOI challenge are maltose negative and resistant to both HK243 and coliphage lambda. This fact has made possible the isolation of lambda-resistant mutants of lambda-lysogens. However, no serological cross-reaction between the phages lambda and HK243 has been detected. Genetic data involving three essential loci and a locus controlling plaque morphology suggest a circular linkage map. The virions are tadpole-shaped with an icosahedral head 68 nm long which is attached to a flexible tail 131 nm long. The phage has a linear, duplex DNA genome of molecular weight approximately 44 × 10⁶ and a base composition of 33% adenine, 31% thymine, 16% guanine, and 20% cytosine.     

Transient electric birefringence of the bacteriophages T3 and T7

Electric birefringence measurements of suspensions of T3 and T7 bacteriophages in 10^?2 M phosphate buffer, pH 6.9, show that there is a difference in their rotational diffusion coefficient. The values corrected to 25°C and water viscosity are D_25,w = 4630 ± 130 sec^?1 and D_25,w = 5290 ± 260 sec^?1 for T3 and T7, respectively. The value obtained from shell model calculations (according to Filson and Bloomfield) is D_25,w = 4500 ± 600 sec^?1. The apparent permanent dipole moments are 4.5 × 10^?26 C·m and 1.7 × 10^?26 C·m for T3 and T7, respectively. For both phage particles the intrinsic optical anisotropy is +7.2 × 10^?3. It is shown that this anisotropy is mainly due to the DNA molecule inside the head of the phage. Its positive value means that there exists an excess orientation of the DNA helix perpendicular to the symmetry axis of the particle. For T7 an unexpectedly large increase of Δn_s and K_sp occurs at a glycerol concentration of about 30% (v/v). This increase is interpreted as being caused by a change of the shape of the particle and/or a change in the secondary structure of the DNA inside the head of the bacteriophage.     

Two Novel Bacteriophages of Thermophilic Bacteria Isolated from Deep-Sea Hydrothermal Fields

Bacteriophages of thermophiles are of great interest due to their important roles in many biogeochemical and ecological processes. However, no virion has been isolated from deep-sea thermophilic bacteria to date. In this investigation, two lytic bacteriophages (termed Bacillus virus W1 and Geobacillus virus E1) of thermophilic bacteria were purified from deep-sea hydrothermal fields in the Pacific for the first time. Bacillus virus W1 (BVW1) obtained from Bacillus sp. w13, had a long tail (300nm in length and 15 nm in width) and a hexagonal head (70 nm in diameter). Another virus, Geobacillus virus E1 (GVE1) from Geobacillus sp. E26323, was a typical Siphoviridae phage with a hexagonal head (130 nm in diameter) and a tail (180 nm in length and 30 nm in width). The two phages contained double-stranded genomic DNAs. The genomic DNA sizes of BVW1 and GVE1 were estimated to be about 18 and 41 kb, respectively. Based on SDS-PAGE of purified virions, six major proteins were revealed for each of the two phages. The findings in our study will be very helpful to realize the effect of virus on thermophiles as well as the communities in deep-sea hydrothermal fields.     

Morphology and General Characteristics of Bacteriophages Infectious to Robinia pseudoacacia Mesorhizobia

Four phages infectious to Mesorhizobium strains were identified in soil samples taken from local Robinia pseudoacacia stands. Based on their polyhedral heads and short noncontractile tails, three of the phages, Mlo30, Mam12, and Mam20, were assigned to group C of Bradley’s classification, the Podoviridae family, while phage Mlo1, with its elongated hexagonal head and a long flexible tail represented subgroup B2 bacteriophages, the Siphoviridae family. The phages were homogeneous in respect of their virulence, as they only lysed Mesorhizobium strains, but did not affect strains of Rhizobium or Bradyrhizobium. On the basis of one-step growth experiments, the average virus yield was calculated as approximately 10–25 phage particles for phages Mlo30, Mam12 and Mam20, and as many as 100–120 for phage Mlo1. The rate of phage adsorption to heat-treated cells showed differences in the nature of their receptors, which seemed to be thermal sensitive, thermal resistant, or a combination of the two. Only the receptor for phage Mlo30 was likely to be an LPS molecule, which was supported by a neutralization test. The smooth LPS with O-antigenic chains of the phage-sensitive M. loti strain completely reduced the bactericidal activity of virions at a concentration of 1 μg/ml. The molecular weights of phage DNAs estimated from restriction endonuclease cleavage patterns were in the range from ~39 kb for group C phages to ~80 kb for B2.     

Bacteriophages of Clostridium saccharoperbutylacetonicum

The fine structure of phage HM 2 (group I) active on Clostridium saccharoperbutylacetonicum was studied by an electron microscopy with a negative-staining technique, and compared with those of more conventional types, phages HM 3 (group II) and HM 7 (group III), whose tails were clearly observed by a shadow-casting technique. This study revealed that phage HM 2 had an intricate tail which was not observed by a shadow-casting technique.

Phage HM 2 has an icosahedral head about 450 Å in diameter and a non-contractile tail about 300 Å long. The distal 130 Å of the tail axis has a width of 80 Å which is wider than the upper portion of the tail (50 to 60 Å). The distal enlargement is not seen in the hollow tail. Twelve fibrous-shaped appendages are attached symmetrically at the upper portion of tail axis and extend toward the distal base of the tail. Their length is a little shorter than 300 Å. They combine with divalent cations in the phage dilution medium, and also adsorb the host cell debris.

Phage HM 3 has an icosahedral head about 770 Å in diameter and a tail about 1000 Å long and 150 Å wide with contractile sheath. Phage HM 7 has an icosahedral head about 750 Å in diameter and a long non-contractile tail about 2000 Å long and about 120 Å wide with forked tip.

The structure of the tail of phage HM 2 is quite different from those of phages HM 3 and HM 7 hitherto described and those of the various phages of other bacteria.     

Electrogenic cyclic redox chain in bacterial photosynthesis: Two regimes of operation in intact cells of Rhodospirillum rubrum

Bacteriophage K7 is specific for Escherichia coli strains harbouring R factors of incompatability group W, including hybrid coliphage P1-Myxococcus virescens plasmids. The phage has an unusual morphology with an isometric head and long tail of variable length. The tail lengths appear to fall into classes corresponsing to simple multimers of a unit length. Partially purified lysates of the phage include material that may represent phage particles in the process of biogenesis and other material demonstrating attachment of phage to cell envelope. Newly released phage DNA contains single standed ends. In the course of work, E. coli strains that harbour R factor Sa were found to be apparently restrictive.     

Morphology and general characteristics of phages of chickpea rhizobia

Six rhizobiophages designated as RC1, RC2, RC3, RC4, RC5 and RC6, infective against six strains of chickpea Rhizobium were isolated from field soils. Seasonal incidence, morphology, host range and inactivation pattern of the phages to heat and UV-light were studied. Four investigated phages were differentiated into two morphological types; one with hexagonal head and a long flexible tail (RC1 and RC5), the other with hexagonal head and a very short tail (RC2 and RC3). Electron microscopic examination of phage RC1 infected cells revealed that phage multiplication occurred at one pole of the cell. Phage RC3 appeared to be more thermal sensitive than others and exhibited one component inactivation while relatively resistant phages (RC1 and RC2) revealed two component inactivation. The six phages could be grouped into two classes on the basis of UV sensitivity; relatively resistant (RC1, RC2 and RC5) and sensitive (RC3, RC4 and RC6).     

Bacteriophages of Clostridium saccharoperbutylacetonicum

The morphological properties of the twelve previously described HM-phages were examined by electron microscopy. Specimens were prepared by air-drying and shadow-casting method using purified phage suspensions. As a result, the HM-phages were classified into three morphologically distinct groups, 1, 11 and 111. Group 1 phages were HM 1, HM 2, HM 8, HM 9, HM 10, HM 11 and HM 12. These phages had a spherical head about 100 mμ in diameter and a rudimentary tail. Group 11 phages were HM 3, HM 4, HM 5 and HM 6. These phages had a spherical head about 100 mμ in diameter and a tail with contractile sheath, and the normal tail of these phages was about 100 mμ in length, and the contracted sheath was about 50 mμ in length, Group 111 phage was HM 7 alone. This phage had a spherical head about 120 mμ in diameter and a relatively long tail about 350 mμ in length.     

Temperate Bacteriophage ZF40 of Erwinia carotovora: Phage Particle Structure and DNA Restriction Analysis

Structural organization of the temperate bacteriophage ZF40 of Erwinia carotovora was studied. Phage ZF40 proved to be a typical member of the Myoviridae family (morphotype A1). Phage particles consist of an isometric head 58.3 nm in diameter and a contractile 86.3-nm-long tail with a complex basal plate and short tail fibers (31.5 nm). Phage tail sheath, a truncated cone in shape, is characterized by specific packaging of structural subunits. The ZF40 phage genome is 45.8 kb in size, as determined by restriction analysis, and contains DNA cohesive ends. The ZF40 phage ofErwinia carotovora is assumed to be a new species of bacteriophages specific for enterobacteria.