T4 phage and T4 ghosts inhibit f2 phage replication by different mechanisms

Both T4 phage and DNA-free ghosts inhibit replication of RNA phage f2. Most but not all of the effects by T4 upon f2 growth can be blocked by the addition of rifampicin prior to T4 superinfection; by contrast, the inhibition of f2 synthesis by T4 ghosts cannot be blocked by rifampicin. This indicates that inhibition by intact T4 requires gene function, while inhibition by ghosts does not. There is a small, multiplicity-dependent inhibition by viable T4 on f2 growth in the presence of rifampicin which may be similar to the gene function-independent inhibition by T4 ghosts. With one viable T4 per cell, there appears to be no effect by viable T4 upon f2 growth which does not require T4 gene action. Moreover, increasing multiplicities of viable T4 appear to inhibit T4 replication as well.In the absence of rifampicin, pre-existing f2 single and double-stranded RNA are degraded after superinfection by viable T4, but remain stable after superinfection by ghosts. However, no new f2 RNA is synthesized after superinfection with either. In the presence of rifampicin, f2-specific protein synthesis is largely unaffected by viable T4, but is completely inhibited by ghosts. Both Escherichia coli, as well as f2-speciflc polysomes disappear in the presence of ghosts.We conclude that, at low multiplicities, T4 phage and T4 ghosts inhibit replication of f2 phage, and presumably host syntheses, by different mechanisms.     

Analyses of spontaneous mutations of cloned gene 49 of phage T4

Holliday structure resolving enzyme endonuclease VII (endo VII) of phage T4 is highly toxic for E. coli when expressed outside of the phage infection environment. As a consequence, plasmids with a mutated gene 49, the gene which encodes for endo VII, can be easily isolated and characterised. We have isolated and characterised 400 survivors from independent transformations with a plasmid carrying gene 49 under the control of the T7 promoter. The majority had mutated gene 49 by IS10 insertions which almost exclusively mapped to a distinct site. When this site was mutated other insertion sites were observed as well as an increase in other mutational events including large deletions. Neither of the observed insertion sites mapped matched the consensus IS10 sequence completely. Additionally when the level of expression of gene 49 was altered the distribution of mutations was changed suggesting that other elements apart from the target sequence are necessary for determining IS10 insertion. The expression of gene 49 in E. coli provides a particularly useful tool for the analysis of mutational events.     

Transmission of amber mutants in phage T4. V. Positive effect of heat shock proteins on the replication of amber mutants in gene 31

The effect of growth of Escherichia coli BE, prior to infection, on multiplication of double amber mutant amN54-amNG71 in gene 31, mutant amN131-amNG114 in gene 26 and T4D wild-type at different temperatures has been studied. In the case of gene 31 mutant the increase in phage burst size, along with increase in growth temperature, was only observed. And this dependence seems to have the same character as the known dependence of growth temperature on cellular levels of heat shock proteins. Possibly, the product of gene 31 might be substituted to some extent by some heat shock protein. An antiserum against gene 31 protein immunoprecipitates heat shock protein, the molecular weight of which is close to the molecular weight of gene 31 protein. So, it seems likely that, in addition to supposed ability of this heat shock protein for functional substitution of gene 31 protein, these proteins might have some structural homology as well.     

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

The rates of DNA elongation by wild-type phage T4 and a gene 52 DNA-delay am mutant were estimated by pulse-labeling infected cells with tritiated thymidine and visualizing the gently extracted DNA by autoradiography. The estimated rate of chain elongation of wild-type DNA was 749 nucleotides/second early in synthesis and 516 to 581 nucleotides/second at a later time. The rate of DNA elongation by the am mutant was measured to be 693, 758 and 829 nucleotides/second during successive stages of synthesis, indicating that elongation was not slower than in wild-type. The kinetics of DNA increase after infection of host cells by wild-type phage T4 or by the gene 52 DNA-delay am mutant was followed using [methyl-³H]thymidine uptake into acid-insoluble material. It was found that DNA increase in both wild-type and am infections could be represented as exponential during early times and linear during late times of DNA synthesis. From the rates of DNA increase and the rates of DNA elongation we were able to estimate the number of growing points per chromosome equivalent of template DNA during the exponential and linear phases. Our estimates for wild-type phage were 0.55 and 0.71 to 0.80 growing points per chromosome equivalent of template DNA in the exponential and linear phases, respectively. For the am mutant we found 0.14 and 0.12 to 0.13 growing points per chromosome equivalent of template DNA during the exponential and linear phases, respectively. The apparent lower incidence of growing points in the am mutant infections suggests that the mutant may be defective in the initiation of growing points.