ENZYMATIC SYNTHESIS OF DEOXYRIBONUCLEIC ACID. INFLUENCE OF BACTERIOPHAGE T2 ON THE SYNTHETIC PATHWAY IN HOST CELLS

DNase Specific for Uracil-Containing Bacteriophage DNA

A DNase from Bacillus subtilis which specifically hydrolyzes native DNA of phage PBS 1 has been purified and characterized. The mode of action of the enzyme is endonucleolytic, yielding deoxyuridine and oliogonucleotides of various sizes. The primary site of enzymatic attack is deoxyuridylic acid in the DNA. A mild nitrous acid treatment of thymine-containing thymus DNA, which deaminates 30% of the cytosine residues, renders the DNA susceptible to the DNase. Nicked DNA from coli phage T5 and hydroxymethyluracil-containing DNA from phage PBS 15 are not sensitive to this DNase.

Gamma-ray-induced thymine damage in the DNA in coliphage phi chi 174 and in E. coli

The radiation chemical reactivity of thymine residues has been compared for single-stranded phi chi 174 DNA free in solution and in the intact bacteriophage, as well as for native E. coli DNA in solution and inside the cell. The gamma-ray-induced release of [3H]H2O from thymine-methyl[3H] was measured to assess the reactivity of the thymine methyl group. Formation of ring-saturated products of the 5,6-dihydroxy-dihydrothymine type (see article) was determined by an alkali-acid degradation assay. It was observed that the formation of that the formation of [3H]H2O was suppressed by a factor of 9 in intact phi chi 174 bacteriophage compared to phi chi 174 DNA, whereas the formation of (see article) was only slightly suppressed in the phage. For E. coli cells the formation of [3H]H29 was reduced 790-fold compared with free E. coli DNA, and (see article) formation was reduced 140-fold. The extents of survival after gamma-irradiation of phi chi 174 phage plaque-forming ability and E. coli colony-forming ability were also determined. Under the conditions used in these experiments, a linear relationship was observed between the loss of biological activity and the formation of thymine damage for both phi chi 174 phage and E. coli cells.

Conjugal transfer of plasmid-borne multiple antibiotic resistance in Streptococcus faecalis var. zymogenes

A strain of Streptococcus faecalis var. zymogenes, designated JH1, had high-level resistance to the antibiotics streptomycin, kanamycin, neomycin, erythromycin, and tetracycline. These resistances were lost en bloc from approximately 0.1% of cells grown in nutrient broth at 45 C. The frequency of resistance loss was not increased by growth in the presence of the "curing" agents acriflavine or acridine orange, but after prolonged storage in nutrient agar 17% of cells became antibiotic sensitive. Covalently closed circular deoxyribonucleic acid (DNA) molecules were isolated from the parental strain and from antibiotic-sensitive segregants by using cesium chloride-ethidium bromide gradients. DNA molecular species were identified by using neutral sucrose gradients. Strain JH1 contained two covalently closed circular DNA species of molecular weights 50 x 10(6) and 38 x 10(6). An antibiotic-sensitive segregant, strain JH1-9, had lost the larger molecular species. A second sensitive segregant, strain JH1-5, had also lost the larger molecular species but a new molecular species of approximate molecular weight 6 x 10(6) was present. The antibiotic resistances that were curable from the parental strain were transferred to antibiotic-sensitive strains of S. faecalis and to strain JH1-9, during mixed incubation in nutrient broth at 37 C. Data to be described are interpreted to suggest that the transfer is by a conjugal mechanism. Analysis of the plasmid species in recipient clones showed that all had received the plasmid of molecular weight 50 x 10(6). Strain JH1-5 was not a good recipient. Analysis of one successful recipient clone of JH1-5 revealed that it had gained the 50 x 10(6) molecular weight plasmid but lost the 6 x 10(6) molecular weight species. These data are interpreted to mean that the multiple antibiotic resistance is borne by a transferable plasmid of 50 x 10(6) molecular weight, and that in clone JH1-5 this plasmid suffered a large deletion leaving only a 6 x 10(6) remnant which was incompatible with the complete replicon.

Relationship between Escherichia coli B titer and the level of deoxycytidylate deaminase activity induced on bacteriophage T2r + infection

The activities of six bacteriophage T2r(+)-induced enzymes (thymidylate synthetase, deoxycytidylate deaminase, thymidylate kinase, deoxycytidylate hydroxymethylase, deoxycytidine pyrophosphatase, and dihydrofolate reductase) were measured after dilution of phage-infected Escherichia coli B from 8 x 10(8) to 2 x 10(8) cells per ml. The only enzyme activity altered was that of deoxycytidylate deaminase, which increased three- to fourfold. Conversely, the rapid concentration of cells from 2 x 10(8) to 8 x 10(8) per ml did not result in a reduction in deaminase activity. Although an enhancement in aeration reduced the response of deoxycytidylate deaminase to cellular dilution, the influence of potential metabolic inhibitors or activators could not be shown. The change in deoxycytidylate deaminase activity appeared to be associated with an altered translational event, since the increase could not be prevented by rifampin but was blocked effectively by chloramphenicol and hydroxylamine. In addition, antibody to the T2 phage-induced deoxycytidylate deaminase demonstrated that the increase in enzyme activity was associated with a corresponding increase in radioactive leucine incorporated into the enzyme antigen.

Deoxyribonucleic acid synthesis in bacteriophage SPO1-infected Bacillus subtilis. I. Bacteriophage deoxyribonucleic acid synthesis and fate of host deoxyribonucleic acid in normal and polymerase-deficient strains

The effect of bacteriophage SPO1 infection of Bacillus subtilis and a deoxyribonucleic acid (DNA) polymerase-deficient (pol(-)) mutant of this microorganism on the synthesis of DNA has been examined. Soon after infection, the incorporation of deoxyribonucleoside triphosphates into acid-insoluble material by cell lysates was greatly reduced. This inhibition of host DNA synthesis was not a result of host chromosome degradation nor did it appear to be due to the induction of thymidine triphosphate nucleotidohydrolase. Examination of the host chromosome for genetic linkage throughout the lytic cycle indicated that no extensive degradation occurred. After the inhibition of host DNA synthesis, a new polymerase activity arose which directed the synthesis of phage DNA. This new activity required deoxyribonucleoside triphosphates as substrates, Mg(2+) ions, and a sulfhydryl reducing agent, and it was stimulated in the presence of adenosine triphosphate. The phage DNA polymerase, like that of its host, was associated with a fast-sedimenting cell membrane complex. The pol(-) mutation had no effect on the synthesis of phage DNA or production of mature phage particles.

Genetic control of the secondary modification of deoxyribonucleic acid in Escherichia coli

The wild-type restriction and modification alleles of Escherichia coli K-12 and B were found to have no measurable effect on the patterns of methylated bases in the deoxyribonucleic acid (DNA) of these strains. The genetic region controlling the methylation of cytosine in E. coli K-12 was mapped close to his, and the presence or absence of this gene in E. coli B or E. coli K had no effect on the restriction and modification properties of these strains. Thus, only a few of the methylated bases in the DNA of these strains are involved in host modification, and the biological role of the remainder remains obscure.

Biological effects of substituting cytosine for 5-hydroxymethylcytosine in the deoxyribonucleic acid of bacteriophage T4

Previous work from this laboratory has shown that the cytosine-containing T4 deoxyribonucleic acid (DNA) made by deoxycytidine triphosphatase (dCTPase) amber mutants is extensively degraded, and that nucleases controlled by genes 46 and 47 participate in this process. In this paper, we examine other consequences of a defective dCTPase. Included are studies of DNA synthesis and phage production, and of the control of both early and late protein synthesis after infection of Escherichia coli B with various T4 mutants defective in genes 56 (dCTPase), 42 (dCMP hydroxymethylase), 1 (deoxynucleotide kinase), 43 (DNA polymerase), 30 (polynucleotide ligase), 46 and 47 (DNA breakdown) or e(lysozyme). By varying the temperature of infection with a temperature-sensitive dCTPase mutant, we have been able to control intracellular dCTPase activity, and thus vary the cytosine content of the phage DNA. We have produced and characterized viable T4 phage in which cytosine replaces 20% of the 5-hydroxymethylcytosine (HMC) in the DNA. We present evidence which suggests that intact, cytosine-containing T4 DNA is much less efficient than is normal T4 DNA in directing the synthesis of tail-fiber antigen. Lysozyme production is much less affected by progressively decreasing dCTPase activity; however, complete substitution of cytosine is correlated with a depression of lysozyme synthesis greater than expected from the defective synthesis of DNA. Low but significant lysozyme synthesis is observed late after infection of E. coli B with T4 amber mutants defective in a number of genes controlling DNA synthesis. The "20% cytosine" T4 phage, once produced, can initiate an apparently normal infection at permissive temperatures; the synthesis of early enzymes, DNA, and phage does not appear to be impaired. Two roles for HMC in T4 DNA have been indicated previously: (i) involvement in host-controlled restriction of the phage, in which glucosylation of the hydroxymethyl group plays a crucial role (16, 29, 53, 58), and (ii) protection of vegetative DNA against phage-controlled nucleases, a protection not dependent on glucosylation (41, 66, 67). A third role is suggested by our present results: transcription of at least some late genes can occur only from HMC-containing DNA and not from cytosine-containing DNA.

Pyrimidine nucleotide metabolism and pathways of thymidine triphosphate biosynthesis in Salmonella typhimurium

The nucleoside triphosphate pools of two cytidine auxotrophic mutants of Salmonella typhimurium LT-2 were studied under different conditions of pyrimidine starvation. Both mutants, DP-45 and DP-55, are defective in cytidine deaminase and cytidine triphosphate (CTP) synthase. In addition, DP-55 has a requirement for uracil (uridine). Cytidine starvation of the mutants results in accumulation of high concentrations of uridine triphosphate (UTP) in the cells, while the pools of CTP and deoxy-CTP drop to undetectable levels within a few minutes. Addition of deoxycytidine to such cells does not restore the dCTP pool, indicating that S. typhimurium has no deoxycytidine kinase. From the kinetics of UTP accumulation during cytidine starvation, it is concluded that only cytidine nucleotides participate in the feedback regulation of de novo synthesis of UTP; both uridine and cytidine nucleotides participate in the regulation of UTP synthesis from exogenously supplied uracil or uridine. Uracil starvation of DP-55 in presence of cytidine results in extensive accumulation of CTP, suggesting that CTP does not regulate its own synthesis from exogenous cytidine. Analysis of the thymidine triphosphate (dTTP) pool of DP-55 labeled for several generations with (32)P-orthophosphate and (3)H-uracil in presence of (12)C-cytidine shows that only 20% of the dTTP pool is derived from uracil (via the methylation of deoxyuridine monophosphate); 80% is apparently synthesized from a cytidine nucleotide.

First-step-transfer deoxyribonucleic acid of bacteriophage T5

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T2 DNA-dependent synthesis of bacteriophage-related proteins

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Chronology of viral functions in bacteriophage alpha

Temperature-sensitive mutants of phage alpha were subjected to short pulses of permissive temperature at various times during the lytic cycle. All the mutants showed an optimal response to the permissive pulse at a specific time after infection. The optimal responses of the mutants belonging to the same complementation group fell close together in the same time interval; the optimal responses of mutants contained in 20 different complementation groups were more or less uniformly scattered throughout the lytic cycle. Temperature sensitivity, therefore, seems to afford, at least in the case of phage alpha, an independent way of grouping the genes in an ordered sequence with respect to the steps they control.

Differential effect of polyamines on T4 morphogenesis

The 5-fluorouracil (5 FU) technique for the phenotypic reversion of amber mutants was used to demonstrate that under certain circumstances, in the presence of putrescine or spermidine, early mutants have an enhanced response to 5 FU, whereas late mutants have a delayed response. Bacteria infected by T4D wild-type bacteriophage did not produce phage in the presence of high putrescine concentrations. Pulse treatments with putrescine showed that the production of lysozyme depends on a putrescine-sensitive process that begins immediately after infection at 26 C and ends at 36 min or even later. The addition of putrescine at any time during the critical period between 0 and 36 min led to a corresponding delay in lysozyme synthesis after the inhibitor was removed. Intracellular phage maturation was delayed by the addition of 100 mumoles of putrescine per ml. Early enzymes were not affected by the diamine, but the level of phage deoxyribonucleic acid was considerably decreased by the inhibitor. The putrescine-sensitive process that affects the timing of maturation is suggested to be the natural process controlling the T4 "clock."

Deoxyribonucleic acid replication and expression of early and late bacteriophage functions in Bacillus subtilis

The role of deoxyribonucleic acid (DNA) replication in the control of the synthesis of deoxycytidylate (dCMP) deaminase and lysozyme in Bacillus subtilis infected with bacteriophage 2C has been studied. These phage-induced enzymes are synthesized at different times during the latent period. It was shown by actinomycin inhibition that the formation of the late enzyme (lysozyme) required messenger ribonucleic acid (mRNA) synthesized de novo after the initiation of translation of mRNA which specifies the early function (dCMP deaminase). The inhibition of phage DNA synthesis by mitomycin C prevented the synthesis of lysozyme only when added before the onset of phage DNA replication, but it did not affect the synthesis or action of dCMP deaminase when added at any time during the latent period. Treatment of infected cells with mitomycin C after phage DNA synthesis had reached 8 to 10% of its maximal rate resulted in the production of normal amounts of lysozyme. These observations suggest that mRNA specifying early enzymes can be transcribed from parental (and probably also from progeny) DNA, whereas late functional messengers can be transcribed only after the formation of progeny DNA.

Ribonuclease induction in cells transformed by Agrobacterium tumefaciens

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