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.     

Ligase-Defective Bacteriophage T4 II. Physiological Studies

The timing of the suppression of gene 30 (deoxyribonucleic acid ligase) mutations by rII mutations was studied by temperature shift-down experiments with a temperature-sensitive rII mutation. The rII function must remain inactivated for about 5 to 8 min at 37 C for suppression to occur, thus making suppression an early function. This result is in agreement with the timing of expression of other rII functions. A gene 30 defect can also be overcome by replacing the Na(+) cation in the growth medium with the Mg(2+) cation, a result similar to the relief of the lethality of rII mutations in lambda lysogens. Prior infection with bacteriophages T3 or T7, which produce their own deoxyribonucleic acid ligases, can also partially overcome the lethality of gene 30 mutations.     

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.     

Bacteriophage Tail Components: II. Dihydrofolate Reductase in T4D Bacteriophage

The protein component of the T-even bacteriophage coat which binds the phage-specific dihydropteroyl polyglutamate has been identified as the phage-induced dihydrofolate reductase. Dihydrofolate reductase activity has been found in highly purified preparations of T-even phage ghosts and phage substructures after partial denaturation. The highest specific enzymatic activity was found in purified tail plate preparations, and it was concluded that this enzyme was a structural component of the phage tail plate. Phage viability was directly correlated with the enzymological properties of the phage tail plate dihydrofolate reductase. All reactions catalyzed by this enzyme which changed the oxidation state of the phage dihydrofolate also inactivated the phage. Properties of two T4D dihydrofolate reductase-negative mutants, wh1 and wh11, have been examined. Various lines of evidence support the view that the product of the wh locus of the phage genome is normally incorporated into the phage tail structure. The effects of various dihydrofolate reductase inhibitors on phage assembly in in vitro complementation experiments with various extracts of conditional lethal T4D mutants have been examined. These inhibitors were found to specifically block complementation when added to extracts which did not contain preformed tail plates. If tail plates were present, inhibitors such as aminopterin, did not affect further phage assembly. This specific inhibition of tail plate formation in vitro confirms the analytical and genetic evidence that this phage-induced "early" enzyme is a component of the phage coat.     

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.