Isolation and Preliminary Characterization of Bacteriophages for Bdellovibrio bacteriovorus

Ten bacteriophages that attack and lyse saprophytic strains of Bdellovibrio bacteriovorus were isolated. Morphological, serological, and host-range studies revealed that there were four different bdellovibrio phages present among the isolates. One of the phages lysed a strain of B. bacteriovorus that requires the presence of a suitable bacterial host for growth. The phage attached to the bdellovibrio cells in the absence of the bacterial host cells; lysis occurred only in the presence of host cells. The 19 saprophytic bdellovibrio strains employed in the phage host-range studies were grouped on the basis of their susceptibility to phage lysis.     

Microviridae, a family divided: isolation, characterization, and genome sequence of phiMH2K, a bacteriophage of the obligate intracellular parasitic bacterium Bdellovibrio bacteriovorus.

A novel single-stranded DNA phage, phiMH2K, of Bdellovibrio bacteriovorus was isolated, characterized, and sequenced. This phage is a member of the Microviridae, a family typified by bacteriophage phiX174. Although B. bacteriovorus and Escherichia coli are both classified as proteobacteria, phiMH2K is only distantly related to phiX174. Instead, phiMH2K exhibits an extremely close relationship to the Microviridae of Chlamydia in both genome organization and encoded proteins. Unlike the double-stranded DNA bacteriophages, for which a wide spectrum of diversity has been observed, the single-stranded icosahedral bacteriophages appear to fall into two distinct subfamilies. These observations suggest that the mechanisms driving single-stranded DNA bacteriophage evolution are inherently different from those driving the evolution of the double-stranded bacteriophages.     

Transfection of Escherichia coli Spheroplasts I. General Facilitation of Double-Stranded Deoxyribonucleic Acid Infectivity by Protamine Sulfate

The addition of 25 mug of protamine sulfate per ml to lysozyme-ethylenediamine-tetraacetic acid spheroplasts of Escherichia coli stimulates transfection not only for T1 phage deoxyribonucleic acid (DNA; Hotz and Mauser, 1969) but also for the following phage DNA species: lambda, 10,000-fold to an efficiency of 10(-3) infective centers per DNA molecule; phiX174 replicative form, 300-fold to an efficiency of 5 x 10(-2); fd replicative form, 300-fold to 10(-6); T7, 300-fold to 3 x 10(-7). Three native phage DNA species were not infective at all in the absence of protamine sulfate but were infective in the presence of protamine sulfate with the following efficiencies: T4, 10(-5); T5, 3 x 10(-6); and P22, 3 x 10(-9). The effect of protamine sulfate is specific for double-stranded DNA. The application of infectivity assays to the study of phage DNA replication, recombination, prophage integration, prophage excision, and interspecies transfection are discussed.     

Pyrimidine metabolism of Bdellovibrio bacteriovorus grown intraperiplasmically and axenically.

Bdellovibrio bacteriovorus grown axenically or intraperiplasmically on Escherichia coli has pathways for the interconversion of pyrimidines and the synthesis of pyrimidine nucleoside 5'-triphosphates similar to those found in the enteric bacteria. Minimal differences in enzyme activities were observed for axenically and intraperiplasmically grown cells. As might be expected for an organism which takes up deoxyribonucleoside 5'-monophosphates per se, high levels of enzymes which catalyze the generation of deoxyribonucleoside triphosphates from monophosphates were found. In addition, all enzymes of the thymine salvage pathway, except for thymidine kinase, were directly demonstrated in wild-type strains. It was possible to demonstrate this activity only indirectly owing to an inhibitor in wild-type extracts. Investigations with inhibitors of pyrimidine interconversion reactions showed that essentially all B. bacteriovorus deoxyribonucleic acid not synthesized from units derived from E. coli deoxyribonucleic acid is made from components of the substrate organism's ribonucleic acid. Evidence for de novo pyrimidine synthesis from the amino acid level was not found for B. bacteriovorus grown on E. coli that had a high protein/deoxyribonucleic acid ratio or on normal E. coli. The potential for de novo pyrimidine synthesis by intraperiplasmically grown B. bacteriovorus, however, cannot be totally ruled out on the basis of these investigations.     

Phage display of catalytically active staphylococcal nuclease

Staphylococcal nuclease (SNase), a 14 kD enzyme that catalyzes the hydrolysis of single- and double-stranded nucleic acid, was fused to the N-terminus of the gene III (pIII) protein of filamentous phage fdtet. The SNase-pIII protein is infective and the catalyzes DNA hydrolysis, demonstrating that functional SNase can be displayed on the phage surface.     

Interaction of Bdellovibrio bacteriovorus and Host Bacteria II. Intracellular Growth and Development of Bdellovibrio bacteriovorus in Liquid Cultures

The intracellular life cycle of Bdellovibrio bacteriovorus 109 growing on Escherichia coli in a dilute nutrient medium exhibits a period of constant infective titer while the parasite grows and elongates inside the host cell. This period is terminated after 2 to 4 hr, and the number of the plaque-forming units in the culture rises rapidly to as much as six times the initial titer. The growth pattern of Bdellovibrio is similar with actively growing or resting host cells, or with host cells killed by ultraviolet irradiation or by heating at 70 C. The yield of B. bacteriovorus strain 109 in two-membered cultures with E. coli B depends on the host concentration and may reach 7.5 x 10(10) cells per ml. Penicillin, which has no effect on the attachment and penetration of Bdellovibrio, inhibits its multiplication.     

Bacteriophage SP82G Inhibition of an Intracellular Deoxyribonucleic Acid Inactivation Process in Bacillus subtilis

The stability of SP82G bacteriophage deoxyribonucleic acid (DNA) after its uptake by competent Bacillus subtilis was examined by determining the ability of superinfecting phage particles to rescue genetic markers carried by the infective DNA. These experiments show that a DNA inactivation process within the cell is inhibited after infection of the cell by intact phage particles. The inhibition is maximally expressed 6 min after phage infection and is completely prevented by the addition of chloramphenicol at the time of infection. The protective effect of this function extends even to infective DNA which was present in the cell before the addition of intact phage. Continued protein synthesis does not appear to be a requirement for the maintenance of the inhibition. In an analogous situation, if infectious centers resulting from singly infecting phage particles are exposed to chloramphenicol shortly after the time of infection, an exponential decrease in the survival of infectious centers with time held in chloramphenicol is observed. If the addition of chloramphenicol is delayed until 6 min after infection, the infectious centers are resistant to chloramphenicol. The sensitivity of infectious centers treated with chloramphenicol at early times after infection is strongly dependent upon the multiplicity of infection and is consistent with a model of multiplicity reactivation. These results indicate that injected DNA is also susceptible to the intracellular inactivation process and suggest that the inhibition of this system is necessary for the successful establishment of an infectious center.     

Adsorption of bacteriophage phi 29 to Bacillus subtilis through the neck appendages of the viral particle.

Phage phi 29 particles produced under restrictive conditions by mutants in gene 12 have normal amounts of all of the structural proteins except the appendage protein, p12*, which is missing. These particles are not infective and do not adsorb to Bacillus subtilis cells. By in vitro complementation of 12- particles with extracts containing protein p12* or with purified protein p12*, the defective particles could bind the appendage protein and become infective and able to adsorb to bacteria. Therefore, the neck appendages of phage phi 29, formed by protein p12*, are involved in the interaction of the phage with the cell wall receptors. Protein p12*, purified in its native state, competed with wild-type phage for adsorption to bacteria. Also, protein p12* could displace adsorbed phage from bacteria. Since the displaced phage was infective, protein p12* does not seem to be modified after phage adsorption.     

Inhibition of Bacteriophages of Amino Acid Producing Bacteria by N-Acylamino Acids

The screening of phage inhibitors from various N-acylamino acids in the industrial amino acid fermentation was carried out, using the Brevibacterium lactofermentum No. 2256–L₁ phage system. Of the seventy-six chemicals tested, the N-acyl derivative of glutamic acid having 16 or 18 carbon atoms in N-acyl residue showed the selective inhibition for phage infection at the concentration of 20 μg/ml without affecting bacterial growth and fermentation. They were effective also on the other kinds of bacterium-phage systems. With N-palmitoyl-l-glutamic acid, its inhibitory action for phage infection was investigated. The results indicated that the chemical at the concentration of 20 μg/ml did not inhibit the phage adsorption, but diminished the number of infective center at the latent period and suppressed the number of the released phage progenies.     

Acetobacter bacteriophage A-1

A bacteriophage ofAcetobacter suboxydans was isolated and found to correspond to type A phage according to Bradley's classification. The phage contains double stranded DNA. The length of the latency period and burst size could not be precisely determined because of apparent non-synchronous release of phage from single infective cycles. The host range was determined using 24 strains ofAcetobacter andGluconobacter species. Evidence for a probable occurence of host determined restriction and modification was obtained withAcetobacter suboxydans strain ATCC 621. The phage is designated A-1 and it is the first one to be reported forAcetobacter.Abbreviations pfu plaque forming units - PTA phosphotungstic acid - GC guanarine + cytosine     

Infection of Competent Mycobacterium smegmatis with Deoxyribonucleic Acid Extracted from Bacteriophage B1

A relatively competent state of Mycobacterium smegmatis for infection with deoxyribonucleic acid (DNA) extracted from phage B1 was found in the late log phase of bacterial growth. This state of the culture was used in quantitative studies on the infectivity of the DNA. The buoyant density of B1 DNA was 1.728 g/cc in CsCl, and 1 mug of the DNA produced 84 infective centers, the phage equivalent of which was 1.5 x 10(-8). The infectivity was destroyed by catalytic amounts of deoxyribonuclease but not by specific B1 antiserum. Tween 80, which prevents phage adsorption, did not prevent DNA infection. The response of plaque-forming ability to DNA concentration suggested that two or more molecules are required to initiate an infective center. The low efficiency of DNA infection in mycobacteria was considered to be caused by a limiting population of competent cells in the culture employed; in this experiment less than 10(-5) of the cells were infected with DNA. A typical cycle of infection was observed, although the latent period was prolonged and the burst size reduced after DNA infection. The transition of B1 DNA infection to deoxyribonuclease insensitivity had a lag period of about 10 min, and increased linearly with a velocity of about 0.24 infective centers per min per mug of DNA. Half of the infective titer was inactivated by heating at 92 C for 15 min. The melting temperature was about 96 C. Species barriers were not crossed by B1 DNA; however, the DNA was infectious for a B1-resistant mutant of the host.     

Utilization of nucleoside monophosphates per Se for intraperiplasmic growth of Bdellovibrio bacteriovorus.

During growth of Bdellovibrio bacteriovorus on Escherichia coli, there was a marked preferential use of E. coli phosphorus over exogenous orthophosphate even though the latter permeated into the intraperiplasmic space where the bdellovibrio was growing. This preferential use occurred to an equal extent for lipid phosphorus and nucleic acid phosphorus. Exogenous thymidine-5'-monophosphate competed effectively with [3H]thymine residues of E. coli as a precursor for bdellovibrio deoxyribonucleic acid; exogenous thymidine competed less effectively and thymine and uridine not at all. A mixture of exogenous nucleoside-5'-monophosphates equilibrated effectively with E. coli phosphorus as a phosphorus source for B. bacteriovorus; the nucleotide phosphorus entered preferentially into bdellovibrio nucleic acids. A comparable mixture of exogenous nucleosides plus orthophosphate had only a small effect on utilization of E. coli phosphorus by B. bacteriovorus, as did orthophosphate alone. A mixture of exogenous deoxyriboside monophosphates equilibrium effectively with E. coli phosphorus as a phosphorus source for bdellovibrio growth; the phosphorus from this source entered preferentially into deoxyribonucleic acid. These data show that nucleoside monophosphates derived from the substrate organism are utilized directly for n-cleic acid biosynthesis by B. bacteriovorus growing intraperiplasmically. As a consequence, the phosphate ester bonds preexisting in the nucleic acids of the substrate organism are conserved by the bdellovibrio, presumably lessening its energy requirement for intraperiplasmic growth. The data also suggest, but do not prove, that the phosphate ester bonds of phospholipids are also conserved.     

Penicillin-induced formation of osmotically stable spheroplasts in nongrowing Bdellovibrio bacteriovorus

Bdellovibrio peptidoglycan is of typical gram-negative composition. The molar ratios of alanine:glutamic acid:diaminopimelic acid:muramic acid:glucosamine were about 2:1:1:1:1. Nascent, nongrowing Bdellovibrio bacteriovorus 109J were converted from highly motile vibrios to highly motile spheres when shaken in dilute buffer plus penicillin, cephalothin, bacitracin, or D-cycloserine. The spherical forms contained essentially no sedimentable peptidoglycan; i.e., they were spheroplasts. Spheroplasts induced by penicillin, D-cycloserine, and lysozyme were stable in dilute buffer and did not lyse when subjected to osmotic shock. Normal Bdellovibrio suspended in buffer turned over their peptidoglycan at a rate of approximately 30% h during the initial 120 min of starvation. Chloramphenicol and sodium azide strongly inhibited Bdellovibrio peptidoglycan turnover and the induction of spheroplasts by penicillin. The data indicate that nongrowing B. bacteriovorus are sensitive to penicillin and other antibiotics affecting cell walls because of their high rate of peptidoglycan turnover. It is also concluded that an intact peptidoglycan layer is required for maintaining cell shape, but is not required for osmotic stability of B. bacteriovorus.     

Development of Bdellophage VL-1 in Parasitic and Saprophytic Bdellovibrios

Ultrastructure was correlated with growth kinetics of bdellophage VL-1 infecting host-dependent ("parasitic") Bdellovibrio bacteriovorus 109J in its Escherichia coli B host (the three-membered system), as well as in the host-independent ("saprophytic") derivative of the Bdellovibrio. Electron microscope observations showed the arrested growth of the phage-infected bdellovibrios, polar localization of the phage progeny, and stages in their release. Present evidence indicates that bdellophage DNA is derived from both the Bdellovibrio and its host cell.     

Evaluation of T3 Coliphage Injuries and Efficacy of Selected Materials in Preventing Them

A procedure was developed to analyze the inactivation of coliphage T3 during freeze-drying and subsequent rehydration. The amount of gross disruption of the phage as compared with the amount of phage remaining intact was evaluated by cesium chloride density gradient centrifugation. The amount of phage material able to adsorb to host cells and the residual infectivity after the drying were also evaluated. These analyses made it possible to determine the amount of phage material (i) degraded to protein and nucleic acid, (ii) intact or largely intact, (iii) capable of adsorption on host cells, and (iv) infective. The capacities of casein hydrolysate, ascorbic acid, thiourea, bovine albumin, polyethyleneglycol, raffinose, inositol, and lipoproteins to protect T3 bacteriophage from the stress of freeze-drying were investigated.     

Purification of B. megatherium Phage G and Evidence for a Muralytic Enzyme as an Integral Part of the Phage

The Purification Of B. megatherium G phage is described and it is shown that DEAE cellulose chromatography combined with conventional methods gave a phage preparation which was at least 95 per cent pure, and contained 2.16 µg nitrogen/10¹¹ infective particles. The phage particle weight in molecular weight units was 91 x 10⁶. The small amount of contaminating material appeared to represent phage "ghosts." An essentially 1:1 ratio of particles to infective units was found when data from electron microscopic counts or data from chemical analysis were related to phage infectivity. Comparison, by several methods, of the G phage and coliphage T2 shows that T2 is 2.6 times larger than G phage. The specific activity of the muralytic component obtained by disintegration of phage preparations with urea was unchanged by the purification indicating that the phage-"bound" muralytic activity is an integral part of the phage structure.     

Transfection of Escherichia coli Spheroplasts IV. Transfection of rec+ and rec? Spheroplasts by Native,Denatured, and Renatured T5 Bacteriophage DNA After Repair of Single-Strand Breaks by Polynucleotide Ligase

Transfection of Escherichia coli spheroplasts by native T5 phage DNA was not affected by treatment with polynucleotide ligase. Denatured T5 phage DNA infectivity, only 0.1% of the native DNA level, was increased slightly by polynucleotide ligase treatment. Renatured T5 phage DNA infectivity was also increased slightly by polynucleotide ligase treatment. To form an infective center with rec(+) spheroplasts, 1.6 to 2.1 native T5 phage DNA molecules were required; however, 1.4 T5 phage DNA molecules were required to form an infective center with recA(-)B(-) spheroplasts, and one molecule was sometimes sufficient for rec B(-) spheroplasts. Polynucleotide ligase treatment of T5 phage DNA had no effect on these parameters. Thus, the single-strand interruptions of T5 phage DNA are probably not essential to the survival of the parental T5 phage DNA, and T5 phage DNA, especially the denatured form, is highly sensitive to some nucleases in E. coli spheroplasts.     

The mortality of bacteriophage containing assimilated radioactive phosphorus

The bacteriophage T4 containing assimilated radioactive phosphorus is inactivated at a rate proportional to the specific radioactivity of the constituent phosphorus. The beta radiation from the phosphorus makes a negligible contribution to this effect. The inactivation is therefore a direct consequence of the nuclear reaction, which kills the phage with an efficiency of about 1/12. Several phages related to T4 behave similarly. When radioactive phage is grown from a seed of non-radioactive phage, all of the phage progeny are subject to killing by radioactive decay. The phage is killed by beta radiation from P³² with an efficiency of about 1/100 per ionization within the particle volume. Bacteriophage T4 and its relatives contain about 500,000 atoms of phosphorus per infective particle. Virtually all this phosphorus is adsorbed to bacteria with the specificity characteristic of the infective particles, and none of it can be removed from the particles by the enzyme desoxyribonuclease. The phosphorus content per particle, together with the published data on analytical composition, indicates a particle diameter close to 110 mµ for the varieties of phage studied.     

Comprehensive analysis of transport proteins encoded within the genome of Bdellovibrio bacteriovorus

Bdellovibrio bacteriovorus is a bacterial parasite with an unusual lifestyle. It grows and reproduces in the periplasm of a host prey bacterium. The complete genome sequence of B. bacteriovorus has recently been reported. We have reanalyzed the transport proteins encoded within the B. bacteriovorus genome according to the current content of the Transporter Classification Database. A comprehensive analysis is given on the types and numbers of transport systems that B. bacteriovorus has. In this regard, the potential protein secretory capabilities of at least four types of inner-membrane secretion systems and five types of outer-membrane secretion systems are described. Surprisingly, B. bacteriovorus has a disproportionate percentage of cytoplasmic membrane channels and outer-membrane porins. It has far more TonB/ExbBD-type systems and MotAB-type systems for energizing outer-membrane transport and motility than does Escherichia coli. Analysis of probable substrate specificities of its transporters provides clues to its metabolic preferences. Interesting examples of gene fusions and of potentially overlapping genes are also noted. Our analyses provide a comprehensive, detailed appreciation of the transport capabilities of B. bacteriovorus. They should serve as a guide for functional experimental analyses.     

Development of a novel genetic system to create markerless deletion mutants of Bdellovibrio bacteriovorus

Bdellovibrio bacteriovorus is a species of unique obligate predatory bacteria that utilize gram-negative bacteria as prey. Their life cycle alternates between a motile extracellular phase and a growth phase within the prey cell periplasm. The mechanism of prey cell invasion and the genetic networks and regulation during the life cycle have not been elucidated. The obligate predatory nature of the B. bacteriovorus life cycle suggests the use of this bacterium in potential applications involving pathogen control but adds complexity to the development of practical genetic systems that can be used to determine gene function. This work reports the development of a genetic technique for allelic exchange or gene inactivation by construction of in-frame markerless deletion mutants including the use of a counterselectable marker in B. bacteriovorus. A suicide plasmid carrying the sacB gene for counterselection was used to inactivate the strB gene in B. bacteriovorus HD100 by an in-frame deletion. Despite the inactivation of the strB gene, B. bacteriovorus was found to retain resistance to high concentrations of streptomycin. The stability of a plasmid for use in complementation experiments was also investigated, and it was determined that pMMB206 replicates autonomously in B. bacteriovorus. Development of this practical genetic system now facilitates the study of B. bacteriovorus at the molecular level and will aid in understanding the regulatory networks and gene function in this fascinating predatory bacterium.