DNA elongation rates and growing point distributions of wild-type phage T4 and a DNA-delay amber mutant

T4 DNA topoisomerase: a new ATP-dependent enzyme essential for initiation of T4 bacteriophage DNA replication

A novel ATP-dependent DNA topoisomerase which makes reversible double-strand breaks in the DNA double helix has been purified to near homogeneity from T4 bacteriophage-infected Escherichia coli cells. Genetic data suggest that this activity is essential for initiating T4 DNA replication forks in vivo.

Recombinational repair of alkylation lesions in phage T4. II. Ethyl methanesulfonate

Treatment of bacteriophage T4 by ethyl methanesulfonate (EMS) caused more than a doubling in recombination between two rII markers. The functions of genes 47, 46, 32, 30, uvsX and y are known to be required for genetic recombination, and mutants defective in these genes were found to be more sensitive to inactivation by EMS than wild-type phage. This suggests that a recombinational pathway involving the products of these genes may be employed in repairing EMS induced lethal lesions. Genes 45 and denV are apparently not involved in recombination, and mutants defective in these genes were not EMS-sensitive. Gene 47, 46 and y mutants which were defective in the repair of EMS induced lethal lesions had no detectable deficiency in their ability to undergo EMS-induced mutation. This implies that recombinational repair of EMS lesions does not contribute substantially to EMS mutagenesis. The results obtained here with EMS are general similar to the results reported in the preceding paper with MNNG, suggesting that the lesions caused by both of these monofunctional alkylating agents may be eliminated by similar recombinational repair processes.

Properties of the nonlethal recombinational repair x and y mutants of bacteriophage T4. II. DNA synthesis

The bacteriophage T4 recombination-deficient mutants x and y exhibited decreased rates of DNA synthesis as compared to wild-type T4. Mutant-induced DNA synthesis was more sensitive to mitomycin C than was wild-type synthesis. However, DNA synthesis in mutant- and wild-type-infected cells exhibited the same sensitivity to UV light and X-irradiation. When high-specific-activity label was administered at various times postinfection, mutant DNA synthesis resembled that of wild type for 12 min. after which time mutant-induced incorporation was greatly decreased and sensitive to mitomycin C as compared to that of the wild type. Rifampin and chloramphenicol studies indicated that the gene products necessary for synthesis measured at 15 min postinfection, including those of x+ and y+ were transcribed within 2 min and translated within 8 min postinfection. Administration of chloramphenicol to mutant x- or mutant y-infected cells exactly 8 min postinfection, however, allowed for increased synthesis at 15 min that was sensitive to mitomycin C. Cells coinfected with T4+ and T4x or T4x and T4y retained a reduced mutant-type synthesis, whereas cells coinfected with T4+ and T4y exhibited a synthesis more closely resembling that of wild type.