Mechanism of the Inactivation of the Bacteriophage T1 in Aerosols

The mechanism of inactivation of bacteriophage T(1) in aerosols was studied by using (32)P-labeled phage. During inactivation, viability decreased in parallel with the adsorption of (32)P to the host, showing either that inactivated phage does not adsorb or that the deoxyribonucleic acid (DNA) has left the coat. A (32)P band at the density of free DNA was found when inactivated phage was analyzed in a CsCl gradient.     

Inactivation of Bacteriophage Lambda Containing Semiconserved Alkylated Deoxyribonucleic Acid

Immediate and delayed inactivation of ethylmethane sulfonate (EMS)-treated lambda phage were studied. Phage particles with one alkylated and one intact deoxyribonucleic acid (DNA) strand were obtained by allowing host-modified, EMS-treated phage to undergo one growth cycle in a nonmodifying host and selecting the progeny with semiconserved parental DNA on a restricting host. The results indicate that particles with one alkylated DNA strand are more sensitive to a second treatment with the alkylating agent. When incubated at 37 C, they are subject to inactivation at a rate which is smaller than that of phages containing two alkylated DNA strands. It appears that depurination events in one of the DNA strands of a phage particle are sufficient to cause death.     

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.     

Isolation and characterization of plaque-forming lambdadnaZ+ transducing bacteriophages.

The Escherichia coli dnaZ gene, a deoxyribonucleic acid (DNA) polymerization gene, is located 1.2 min counterclockwise from purE, at approximately min 10.5 on the E. coli map. From a lysogen with lamdacI857 integrated at a secondary attachment site near purE, transducing phages (lambdadnaS+) that transduced a dnaZts (lambda+) recipient to temperature insensitivity (TS+) were discovered. Three different plaque-forming transducing phages were isolated from seven primary heterogenotes. Genetic tests and heteroduplex mapping were used to determine the length and position of E. coli DNA within the lambda DNA. Complementation tests demonstrated that the deletions in all three strains removed both att P and the int gene, i,e., DNA from both prophage ends. Heteroduplex mapping confirmed this result by demonstrating that all three strains had deletions of lambda DNA that covered the b2 to red region, thereby removing both prophage ends. Specifically, the deletions removed lambda DNA between the points 39.3 to 66.5% of lambda length (measured in percent length from the left and of lambda phage DNA) in all three strains. The three strains are distinct, however, because they had differing lengths of host DNA insertions. These phages must have been formed by an anomalous procedure, because standard lambda transducing phages are deleted for one prophage end only. In lambdagal and lambdabio strains, the deletions of lambda DNA begin at the union of prophage ends (i.e., position 57.3% of lambda length) and extend leftward or rightward, respectively (Davidson and Szybalski, in A, D. Hershey [ed.], The Bacteriophage Lambda, p. 45-82, 1971). Models for formation of the lambdadnaZ+ phages are discussed.     

Mutant of Escherichia coli that instantaneously loses the ability to adsorb lambda bacteriophage upon exposure to high temperature.

lad (lambda adsorption), an Escherichia coli mutant that loses the ability to adsorb lambda phage immediately after a shift to high temperature (e.g., 42 C), was isolated. This property for phage adsorption is irreversible and has been observed with phage lambda and 21 but not with phages 434, phi 170, and phi 80. A crude receptor preparation, extracted from lad cells will cholate-ethylenediaminetetraacetic acid by the procedure of Randall-Hazelbauer and Schwartz (1973), inactivated the phage lambda only at low temperature.     

Decay of incorporated radioactive phosphorus during reproduction of bacteriophage T2

The multiplication of vegetative T2 bacteriophage in B/r bacteria has been followed by studying the lethal effects of decay of incorporated radiophosphorus P³² at various stages of the eclipse period. Experiment I. Non-radioactive B/r bacteria were infected with highly radioactive (i.e. P³²-unstable) T2 and infection allowed to proceed at 37°C. for various numbers of minutes before freezing the infected cells and storing them in liquid nitrogen. The longer development had been allowed to proceed at 37°C. before freezing, the slower the inactivation of the frozen infective centers by P³² decay. Samples which were frozen after incubation for 9 minutes were completely stable. Experiment II. Radioactive B/r bacteria in radioactive growth medium were infected with non-radioactive (i.e. stable) T2 and incubated for various lengths of time before being frozen and stored in liquid nitrogen, like those of Experiment I. In this case, the infective centers were stable to P³² decay as long as they were frozen before the end of the eclipse period. The T2 progeny phages issuing from the infected bacteria were P³²-unstable. Experiment III. Radioactive B/r bacteria in radioactive medium were infected with radioactive (i.e. P³²-unstable) T2 and otherwise incubated and frozen like those of the first two experiments. In this case, the same progressive stabilization, of the infective centers towards inactivation by P³² decay was observed as that found in Experiment I. The ability to yield infective progeny of infected bacteria incubated for 10 minutes at 37°C. before freezing could no longer be destroyed by P³² decay. The progeny issuing from the infected cells were as unstable as the parental phage. These results could be explained by one of three general hypotheses. As vegetative phage begins to multiply, it is possible that: (a) there is a high probability that any part of the vegetative phage already duplicated can be saved after its destruction by P³² decay through a process analogous to multiplicity reactivation or, (b) there occurs a change in state of the deoxyribonucleic acid (DNA) preliminary to or in the course of its replication that renders it refractory to destruction by P³² decay, or, finally (c) there occurs a transfer of the genetic factors from the DNA of the infecting phage to another substance not sensitive to destruction by P³² decay.     

Luria effect in bacteriophages and the role of the products of recA+ and lexA+ genes in its induction

An analysis of UV-damages accumulation in the phages as revealed by delay of intracellular growth is represented using temperate lambda phage. The maximum of growth delay of phage lambda at given UV-dose was found with lambda red+, infecting Escherichia coli AB1886 uvrA strain. The growth delay was absent, when a strain RH-1 uvrA-recA- was infected with UV-irradiated phage lambda red3. A moderate growth delay was obtained with the phages lambda red+, infecting E. coli RH-1 uvrA-recA- or phage lambda red3, infecting E. coli AB1886 uvrA-. THe growth delay was also absent when wild type, recA- and uvrA mutants of E. coli were infected with phage lambda after 8-metnoxypsoralen + light (lambda > 310 nm) treatment. It is known that the crosslinks appear to be the DNA defects which give rise to the observed biological inactivation following psoralen + light treatment. However, a considerable growth delay of phage lambda, treated by 8-metnoxypsoralen + light, was only found under condition of crosslinks repair (W-reactivation and prophage-reactivation). The results obtained are best explained by the assumption that the growth delay reflects the time required for the postreplication repair (RecA, LexA, Red) of any lethal UV-lesion.     

Physical and genetical analysis of bacteriophage T4 generalized transduction

This report describes a comparison of the efficiency of transduction of genes in E. coli by the generalized transducing bacteriophages T4GT7 and P1CM. Both phages are capable of transducing many genetic markers in E. coli although the frequency of transduction for particular genes varies over a wide range. The frequency of transduction for most genes depends on which transducing phage is used as well as on the donor and recipient bacterial strains. Analysis of T4GT7 phage lysates by cesium chloride density gradient centrifugation shows that transducing phage particles contain primarily bacterial DNA and carry little, if any, phage DNA. In this regard transducing phages P1CM and T4GT7 are similar; both phages package either bacterial or phage DNA but not both DNAs into the same particle.     

Superinfection exclusion by heteroimmune corynebacteriophages.

Superinfection of Corynebacterium diphtheriae C7(beta) by heteroimmune phage gamma is productive, whereas superinfection by gamma-bin mutants is for the most part nonproductive. Exclusion of gamma-bin phage occurred after its DNA had penetrated and was partially expressed in the heteroimmune lysogen. All of the infected cells were killed, and lysis was observed. The beta inhibitor causing exclusion was produced during the prophage state and appeared to be distinct from immune repressor. The ability of gamma-bin phage to superinfect C7(beta) productively could be restored by recombination with beta phage, indicating that both beta and gamma phages contain either indentical or similar alleles of the bin gene. The bin gene was mapped by vegetative and prophage crosses and found to be located in the region of the phage genome concerned with regulation. Both beta and gamma wild-type phages induced the resident prophage in a significant fraction of superinfeted heteroimmune lysogens. This, coupled with the fact that induction of C7(beta) abolished exclusion, suggests that the bin gene product acts as antirepressor, i.e., it reduces the level of heteroimmune repressor either directly or indirectly. The gamma-bin mutants either failed to produce antirepressor or did so with reduced efficiency. Antirepressor activity was negatively controlled by homoimmune repressor. The isolation of beta mutants that appeared bin-like suggests that beta and gamma phages contain homologous systems of exclusion and antiexclusion. Exclusion of gamm-bin by beta phage in gram-positive C. diphtheriae exhibited striking parallels to the sieB exclusion described for phages P22 and lambda in gram-negative organisms. The extended similarities of these coryngephages to lambda bacteriophage is noted.     

Inactivation of coliphages by chitosan derivatives

The effect of chitosan fragments with different degrees of polymerization and the chemical derivatives of chitosan differing in the number of amino groups and total molecule charge on phages T2, T4, and T7 was studied. The interaction of chitosan with bacteriophage particles inactivated them to the extent dependent on the chemical properties of chitosan and its concentration. Phage T2 was found to be most susceptible to inactivation by chitosan. The polycationic nature of chitosan plays an important role in the inactivation of phages. It is assumed that the abnormal rearrangement of the basal plate of phages, the loss of long tail fibers, and, probably, modification of the receptor-recognizing phage proteins may be responsible for the inactivation of coliphages by chitosan.     

Morphological and genetic analysis of three bacteriophages of Serratia marcescens isolated from environmental water

Increases in multidrug-resistant strains of Serratia marcescens are of great concern in pediatrics, especially in neonatal intensive care units. In the search for bacteriophages to control infectious diseases caused by multidrug-resistant S. marcescens , three phages (KSP20, KSP90, and KSP100) were isolated from environmental water and were characterized morphologically and genetically. KSP20 and KSP90 belonged to morphotype A1 of the family Myoviridae , and KSP100 belonged to morphotype C3 of the family Podoviridae . Analysis of the DNA region coding virion proteins, together with their morphological features, indicated that KSP20, KSP90, and KSP100 were related to the P2-like phage (temperate), T4-type phage (virulent), and phiEco32 phage (virulent), respectively. Based on amino acid sequences of the major capsid protein, KSP90 formed a new branch with a Stenotrophomonas maltophilia phage, Smp14, in the T4-type phage phylogeny. Both Smp14 and phiEco32 have been reported as potential therapeutic phages. These results suggest that KSP90 and KSP100 may be candidate therapeutic phages to control S. marcescens infection.     

The influence of hydrostatic pressure and urethane on the thermal inactivation of bacteriophage

In Difco nutrient broth, containing 0.5 per cent NaCl, pH 6.6, Escherichia coli phages T1, T2, and T5 were inactivated at 66 degrees C., and T7 at 60 degrees C., at nearly the same rate. In each case the rate of destruction was not uniform but more or less decreased with time of heating. With T2 there was an initial increase in number of infective centers after heating for several minutes at 66 degrees C. Hydrostatic pressures up to 10,000 pounds per square inch retarded the thermal destruction of T1, T2, and T5, but accelerated that of T7, while small concentrations of urethane accelerated the rate of each. The rate of inactivation was increased by the addition of 0.005 M phosphate, and was decreased by 0.005 M MgCl(2) in all but T7, whose rate was unaffected by this amount of Mg. The influence of Ca was similar to that of Mg. The addition of 0.005 M MgCl(2) to the broth medium resulted in a first order rate of destruction of T5 at either normal or increased pressure, and with as well as without urethane. Analysis of data obtained under these conditions indicated that the thermal inactivation proceeds with a volume increase of activation of 113 cc. per mol, and with a heat and entropy of 170,000 calories and 425 E. U., respectively, in the rate-limiting reaction. In the presence of 0.1 M urethane the heat and volume change of activation are apparently slightly greater. The relation between concentration of urethane and the amount of acceleration in rate of destruction at normal pressure and 66 degrees C. indicated that the total rate involves at least two first order rate processes: the thermal inactivation itself and a urethane-catalyzed reaction, the latter involving the combination of an average of 2.3 molecules of urethane in the activated state of the bacteriophage molecule whose destruction results in loss of phage activity.     

Parent-to-Progeny Transfer and Recombination of T4rII Bacteriophage

Transfer of parental, light (not substituted with 5-bromodeoxyuridine) (32)P-deoxyribonucleic acid (DNA) from rII(-) mutants of T4 bacteriophage to heavy (5-bromodeoxyuridine-substituted) progeny in Escherichia coli B was less homogeneous than in wild phages. The net transfer was 5 to 20% of the value for wild T4 phage, and the parental contribution per progeny DNA molecule amounted to 7 to 100% of the genome. Three classes could be distinguished, based on the density distribution of parental label in CsCl analysis of the progeny phages. "Far recombined" phages contain parental material only in semiconservatively replicated subunits covalently attached to progeny DNA, amounting to 5 to 10% parental contribution per genome. "Intermediate recombinants" contain, aside from conventional recombinant DNA, parental DNA banding at the original, light density. This DNA may be unattached to heavy progeny DNA or attached by weak bonds which are very sensitive to shearing during the extraction procedure. The parental contribution is 10 to 50% per progeny DNA molecule in this class. "Conservative" phages band close to the parental, light density in CsCl; their DNA is purely light. When the parental phage is labeled with both (3)H-leucine (capsid) and (32)P (DNA), the specific activity of (3)H/(32)P in the "conservative progeny" is 10 to 40% of that in the parental, showing that at least some of the (32)P in this area belongs to phages with parental DNA as the sole DNA component inside an unlabeled capsid, i.e., parental DNA which has been injected into the host and matured in a new capsid without replication or recombination. This phenomenon occurs to about the same extent in both single and multiple infection.     

Coliphages inactivation using chitosan derivatives

The effect of chitosan fragments with different degrees of polymerization and the chemical derivatives of chitosan differing in the number of amino groups and total molecule charge on phages T2, T4, and T7 was studied. The interaction of chitosan with bacteriophage particles inactivated them to the extent dependent on the chemical properties of chitosan and its concentration. Phage T2 was found to be most susceptible to inactivation by chitosan. The polycationic nature of chitosan plays an important role in the inactivation of phages. It is assumed that the abnormal rearrangement of the basal plate of phages, the loss of long tail fibers, and probably, modification of the receptor-recognizing phage proteins may be responsible for the inactivation of coliphages by chitosan.     

Comparisons of the Distribution of Nucleotides and Common Sequences in Deoxyribonucleic Acid from Selected Bacteriophages

Results from comparisons of deoxyribonucleic acid (DNA) from several classes of bacteriophages suggest that most phage chromosomes contain either a homogeneous distribution of nucleotides or are made up of a few, rather large segments of different quanine plus cytosine (G + C) contents which are internally homogeneous. Among those temperate phages tested, most contained segmented DNA. Comparisons of sequence similarities among segments from lambdoid phage DNA species revealed the following order in relatedness to lambda: 82 (and 434) > 21 > 424 > phi80. Most common sequences are found in the highest G + C segments, which in lambda contain head and tail genes. Hybridization tests with lambda and 186 or P2 DNA species verified that the lambdoids and 186 and P2 belong to two distinct groups. There are fewer homologous sequences between the DNA species of coliphages lambda and P2 or 186 than there are between the DNA species of coliphage lambda and salmonella phage P22.     

Persistence of Infectious Shiga Toxin-Encoding Bacteriophages after Disinfection Treatments

In Shiga toxin-producing Escherichia coli (STEC), induction of Shiga toxin-encoding bacteriophages (Stx phages) causes the release of free phages that can later be found in the environment. The ability of Stx phages to survive different inactivation conditions determines their prevalence in the environment, the risk of stx transduction, and the generation of new STEC strains. We evaluated the infectivity and genomes of two Stx phages (Φ534 and Φ557) under different conditions. Infectious Stx phages were stable at 4, 22, and 37°C and at pH 7 and 9 after 1 month of storage but were completely inactivated at pH 3. Infective Stx phages decreased moderately when treated with UV (2.2-log₁₀ reduction for an estimated UV dose of 178.2 mJ/cm²) or after treatment at 60 and 68°C for 60 min (2.2- and 2.5-log₁₀ reductions, respectively) and were highly inactivated (3 log₁₀) by 10 ppm of chlorine in 1 min. Assays in a mesocosm showed lower inactivation of all microorganisms in winter than in summer. The number of Stx phage genomes did not decrease significantly in most cases, and STEC inactivation was higher than phage inactivation under all conditions. Moreover, Stx phages retained the ability to lysogenize E. coli after some of the treatments.     

Growth and DNA synthesis of bacteriophage phi x174 in a dnaP mutant of Escherichia coli.

phi X174am3trD, a temperature-resistant mutant of bacteriophage phi X174am3, exhibited a reduced ability to grow in a dnaP mutant, Escherichia coli KM107, at the restrictive temperature (43 degrees C). Under conditions at which the dnaP gene function was inactivated, the amount and the rate of phi X174am3trD DNA synthesis were reduced. The efficiency of phage attachment to E. coli KM107 at 43 degrees C was the same as to the parental strain, E. coli KD4301, but phage eclipse and phage DNA penetration were inhibited in E. coli KM107 at 43 degrees C. It is suggested that the dnaP gene product, which is necessary for the initiation of host DNA replication, participates in the conversion of attached phages to eclipsed particles and in phage DNA penetration in vivo in normal infection.     

Lethal modifications of DNA via the transmutation of32P and33P incorporated in the genome of the S13 bacteriophage

Summary When circular single-stranded DNA of phage S13 is labelled with³²P or³³P, the transmutations very efficiently bring about a loss of phage infectiousness (efficiency = 1 for³²P and 0.73 for³³P). For both radionuclides, the lethal efficiencies as well as the lethal events are different. In the case of³²P, the lethal event is the loss of the circular integrity of the DNA molecule, occurring as a consequence of a systematic single strand-break caused by each³²P decay (100%). Conversely, in the case of³³P, the lethal events are either a single strand-break (40%) or a local stereochemical modification (33%). The same primary event, the substitution at each³³P decay of a phosphate by a sulfate molecule, leads to one of these lethal events in relation to the decay site. Moreover, neither the phage adsorption nor its genome injection into bacteria depends on the physical state of the genome, and thus lethality is revealed at only the genetic level.