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.     

Surface Sampling of Spores in Dry-Deposition Aerosols

The ability to reliably and reproducibly sample surfaces contaminated with a biological agent is a critical step in measuring the extent of contamination and determining if decontamination steps have been successful. The recovery operations following the 2001 attacks with Bacillus anthracis spores were complicated by the fact that no standard sample collection format or decontamination procedures were established. Recovery efficiencies traditionally have been calculated based upon biological agents which were applied to test surfaces in a liquid format and then allowed to dry prior to sampling tests, which may not be best suited for a real-world event with aerosolized biological agents. In order to ascertain if differences existed between air-dried liquid deposition and biological spores which were allowed to settle on a surface in a dried format, a study was undertaken to determine if differences existed in surface sampling recovery efficiencies for four representative surfaces. Studies were then undertaken to compare sampling efficiencies between liquid spore deposition and aerosolized spores which were allowed to gradually settle under gravity on four different test coupon types. Tests with both types of deposition compared efficiencies of four unique swabbing materials applied to four surfaces with various surface properties. Our studies demonstrate that recovery of liquid-deposited spores differs significantly from recovery of dry aerosol-deposited spores in most instances. Whether the recovery of liquid-deposited spores is overexaggerated or underrepresented with respect to that of aerosol-deposited spores depends upon the surface material being tested.     

Induction of P1 Prophage and Superinfection by Bacteriophage T1

Induction of the resident prophage did not permit restricted phage T1 to replicate freely in P1-lysogenic hosts. A few induced cells did become infectible.     

Synthesis of Messenger Ribonucleic Acid After Bacteriophage T1 Infection

Synthesis of host-specific and phage-specific messenger ribonucleic acid (mRNA) was studied in bacteria infected by unmodified (T1 . B) or modified [T1 . B(P1)] bacteriophage T1. In a "standard" infection of Escherichia coli B by T1 . B (no host-controlled modification involved), the rate and amount of T1 mRNA synthesis was intermediate between those values reported for infections by a virulent phage such as T4 or a temperate phage such as lambda. The initial rate of mRNA synthesis was slightly increased after T1 . B(P1) infection of E. coli B in comparison with T1 . B infection of the same host. Little or no phage mRNA synthesis could be detected in T1 . B infection of E. coli B(P1). Phage mRNA synthesis in T1 . B(P1)-infected E. coli B(P1) cells was approximately the same in amount as that seen in T1 . B(P1) infection of E. coli B. Synthesis of host-specific mRNA continued throughout the latent period in all infections studied. However, the enzyme beta-galactosidase could not be induced, except after T1 . B infection of E. coli B(P1). In an attempt to understand the apparent differences in mRNA synthesis after infection of E. coli B by phages T1 . B or T1 . B(P1), the effect of altered T1 deoxyribonucleic acid (DNA) methylation on mRNA synthesis was studied. Methyl-deficient T1 DNA, made in cells infected with ultraviolet-irradiated phage T3, inhibited (14)C-uridine incorporation more strongly than normal T1. One passage of methyl-deficient T1 through E. coli B restored uracil incorporation rates to those seen with ordinary T1. This suggests that methylation of T1 DNA can influence the rate of phage mRNA synthesis. However, attempts to relate the difference in mRNA synthesis seen between T1 . B and T1 . B(P1) in E. coli B to the activity of the P1 modification gene were not conclusive.     

Physiological Study of Cooperative Infection by Restricted Bacteriophage T1

The ability of certain phages to successfully infect a restricting host at a high multiplicity of infection is known as cooperative infection or cooperation. We have examined the ability of unmodified T1 (T1.0) to participate in cooperative infection in cells possessing the P1 restriction system. We have found that cooperation is dependent upon protein synthesis during the first few minutes after phage infection. However, we have been unable to attribute the necessary protein to a known T1 cistron. Degradation of the restricted T1 genome is approximately equally extensive whether cooperative infection occurs or whether it is blocked by chloramphenicol. It is postulated that an inducible host repair mechanism may be responsible for the phenomenon of cooperative infection.     

Production of Bacteriophage T7

Bacteriophage T7 was grown with Escherichia coli B as the host organism in 3- and 20-liter vessels. Under the best growth conditions devised, the yields of T7 in the culture lysates averaged 1.33 x 10(12) and 0.95 x 10(12) plaque-forming units per ml, respectively, compared with the best previously reported yields of 10(11) to 3 x 10(11) plaque-forming units per ml in 1-liter batches grown in the presence of air, or double this in similar batches grown in the presence of oxygen. The bacteriophage was purified by a simple method which gave average yields of 143 mg/liter and 131 mg/liter from the 3- and 20-liter batches, respectively. The efficiency of plating of the final material ranged from 18 to 42%. The purified bacteriophage is a convenient source of monodisperse deoxyribonucleic acid, the molecular weight of which is about 25 x 10(6).     

Multiple-Tailed T4 Bacteriophage.

Smith, Kendall O. (Baylor University College of Medicine, Houston, Tex.), and Melvin Trousdale. Multiple-tailed T4 bacteriophage. J. Bacteriol. 90:796-802. 1965.-T4 phage particles which appeared to have multiple-tails were observed. Experiments were designed to minimize the possibility that superimposed particles might account for this appearance. Double-tailed particles occurred at a frequency as high as 10%. Triple- and quadruple-tailed particles were extremely rare. All attempts to isolate pure lines of multiple-tailed phage have failed. Multiple-tailed phage particles were produced in highest frequency by Escherichia coli cells in the logarithmic growth phase which had been inoculated at a multiplicity of about 2.     

Cadaverine in Bacteriophage T4

Cadaverine was found in bacteriophage T4 when the host cells of Escherichia coli K-12 were grown in complex media and aerated by agitation. Only traces of cadaverine were found if the host was grown and agitated in synthetic medium or was aerated by vigorous bubbling in a complex medium. When the host cells were grown anaerobically in a complex medium, cadaverine became the major polyamine in the progeny phage. The polyamine content comprised 80% cadaverine, 14% spermidine (or its recently discovered homologue, N-3-aminopropyl-1, 5-diaminopentane), and the remainder putrescine. The conditions that favored appearance of cadaverine are known to be required for induction of lysine decarboxylase. It was shown that lysine was the sole source of bacterial cadaverine.     

The Effect of Temperature on the Formation of T1 and T2r Bacteriophage

A very rapid variation of yield of T1 and T2r bacteriophage in E. coli at slightly higher than normal temperatures has been observed. T1 phage will develop at 41.2°C but not at 41.7°C. By infecting cells grown on lactose and, therefore, induced to contain beta galactosidase, a technique which indicates when cells have become leaky was worked out. This method shows that at elevated temperatures the enzymatic attack on the cell wall continues to go at a faster rate, while completion of the phage goes more slowly. Thermal constants are given for the processes. Cells at higher temperature, grown on P³² medium develop incomplete particles capable of combining with phage antibody. This suggests that the process affected by the early leakiness of the cells is the completion of the virus protein coat. Supplementing the medium with casamino acids, phosphate, and ATP causes the “rescue” of phage particles by aiding the formation of the coat. This can be achieved several minutes after the cells have become leaky and may form a useful system for the study of phage development in the presence of analogs.     

Gamma-Ray Mutagenesis in Bacteriophage T4

137Cs-gamma irradiation of bacteriophage T4 induces large deletions plus a variety of types of point mutations. All mutations arise with single-hit kinetics, and all by a misrepair process. The estimated point mutation rate is 1.5 X 10(-9) per locus per rad.     

Thymineless Mutagenesis in Bacteriophage T4

Thymine deprivation can be achieved in bacteriophage T4 either by the use of the thymidylate synthetase inhibitor FUdR, or by an appropriate combination of genetic blocks; both methods produce marked mutagenesis. Extensive tests of the specificity of thymineless mutagenesis reveal that only A:T base pairs are affected, and that transitions and possibly transversions are produced. This system therefore constitutes the first example of an A:T-specific mutagen. Thymineless mutagenesis in bacteriophage T4 exhibits a marked dependence upon the functional state of the DNA polymerase gene, but is largely independent of the px-y misrepair system.