The effect of ultraviolet light on the production of bacterial virus protein

The amount of phage-specific protein in T2-infected bacteria growing in a medium containing radiosulfur, S³⁵, has been studied by measuring the radioactivity in specific antiphage serum precipitates of lysates. In the course of normal infection, non-infective phage antigen has been found to make its first intracellular appearance shortly before the end of the eclipse period, in agreement with the findings of Maaløe and Symonds with phage T4. No such phage antigen is produced either in bacteria infected with UV-inactivated T2 or in T2-infected bacteria whose survival as an infective center has been destroyed by UV irradiation during the early stages of the eclipse period. If the infected bacteria are UV-irradiated only at later stages of the eclipse period however, then phage antigenic protein continues to be synthesized in those infected cells in which DNA synthesis and, a fortiori, production of infective progeny have been almost completely suppressed. It is concluded from these results that once the mechanism for formation of phage-specific protein has been established within the infected cell under the influence of the parental DNA, synthesis of phage-specific protein can continue independently of the synthesis of phage DNA. The possibility that the phage DNA controls the specificity of the phage protein indirectly through substances other than DNA is discussed.     

Expression of bacteriophage M13 dna in vivo. I. Synthesis of phage-specific RNA and protein in minicells.

It is demonstrated that after infection of the appropriate minicell-producing strain of Escherichia coli with the filamentous bacteriophage M13, its replicative form DNA is segregated into minicells. Consequently these minicells have acquired the capability to direct the synthesis of phage-specific RNA and protein. Comparision of the electrophoretic mobilities of phage-specific RNA species made in vitro with those made in M13 replicative form DNA harbouring minicells, have indicated that almost all in vitro synthesized G-start RNAs have an equivalent among the in vivo synthesized RNA products. Furthermore it could be demonstrated that in M13 replicative form DNA harbouring minicells the phage-specific proteins encoded by genes III, IV, V and VIII are made. In addition the synthesis of a phage-specific polypeptide (molecular weight approx. 3000) co-migrating with the recently discovered capsid protein (designated C-protein) could be demonstrated. The meaning of these results for the resolution of the regulatory mechanisms operative during the life cycle of this phage will be discussed.     

Studies on the Biosynthesis of α-Putrescinylthymine in Bacteriophage φW-14-Infected Pseudomonas acidovorans

The alpha-putrescinylthymine (putThy) in bacteriophage phiW-14 DNA is synthesized at the mononucleotide level: it is labeled by uracil or deoxyuridine but not by thymidine, and it appears in the acid-soluble pool of infected cells before the onset of phage DNA synthesis. The methylene group at the C-5 position of the pyrimidine moiety of putThy is derived in vivo from a C(1) unit. Extracts of a phage infected thymidine auxotroph of the host, Pseudomonas acidovorans, apparently contain a phage-specific thymidylate synthetase and a phage-specific activity which forms 5-hydroxymethyl dUMP from N(5), N(10)-methylene-tetrahydrofolate and dUMP.     

Synthesis of phage-specific transfer RNA molecules by vibriophage phi 149

32P-Labelled tRNA was isolated from uninfected and phage phi 149-infected Vibrio cholerae cells. These tRNA preparations were then hybridised with DNA isolated from phage phi 149. Significant hybridisation was observed only with tRNA from phage phi 149-infected cells. This strongly suggests that infection of classical vibrio with phage phi 149 results in the synthesis of phage-specific tRNA molecules.     

Regulation of Bacteriophage T5 Development by ColI Factors

The I-type colicinogenic factor ColIb transforms Escherichia coli from a permissive to a nonpermissive host for bacteriophage T5 reproduction by preventing complete expression of the phage genome. T5-infected ColIb(+) cells synthesize only class I (early) phage protein and ribonucleic acid (RNA). Neither phage-specific class II proteins [associated with viral deoxyribonucleic acid (DNA) replication] nor class III proteins (phage structural components) are formed due to the failure of the infected ColIb(+) cells to synthesize class II or class III phage-specific messenger RNA. Comparable studies with T5-infected cells colicinogenic for the related ColIa factor revealed no decrease in the yield of progeny phage although the presence of the ColIa factor leads to a significant reduction in the amount of phage-directed class III protein synthesis.     

The replication of bacteriophage f1: Gene V protein regulates the synthesis of gene II protein

Two filamentous phage gene products are required for the replication of phage DNA. One of these, the gene II protein, is a site-specific endonuclease required for all phage-specific DNA synthesis. The other, the gene V protein, is a single-stranded DNA-binding protein required only for single-strand synthesis. Purified gene V protein, when added to an in vitro protein synthesizing system programmed by f1 DNA, specifically inhibits the synthesis of gene II protein. Inhibition seems to be translational, since synthesis of gene II protein from an RNA template is also inhibited by gene V protein. Gene V protein control of gene II expression can account for the regulation of the level of expression of the filamentous phage genome.     

Bacteriophage T4 transfer RNA : III. Clustering of the genes for the T4 transfer RNA's

Escherichia coli cells infected with phage strains carrying extensive deletions encompassing the gene for the phage Ser-tRNA are missing the phage tRNA's normally present in wild-type infected cells. By DNA-RNA hybridization we have demonstrated that the DNA complementary to the missing tRNA's is also absent in such deletion mutants. Thus the genes for these tRNA's must be clustered in the same region of the genome as the Ser-tRNA gene. Physical mapping of several deletions of the Ser-tRNA and lysozyme genes, by examination of heteroduplex DNA in the electron microscope, has enabled us to locate the cluster, to define its maximum size, and to order a few of the tRNA genes within it. That such deletions can be isolated indicates that the phage-specific tRNA's from this cluster are dispensable.     

Transcription After Bacteriophage SPP1 Infection in Bacillus subtilis

The role of the host polymerase in Bacillus subtilis infected with phage SPP1 was studied in vivo with regard to production of phage-specific and host-specific ribonucleic acid (RNA) and to phage yield. Evidence is presented that the subunit(s) of B. subtilis RNA polymerase which is sensitive to rifampin and streptolydigin is necessary at all times during infection for phage production. The synthesis of phage RNA and the phage yield in strains resistant to either antibiotic were unaffected by the drug. Host RNA synthesis continued throughout infection; phage-specific RNA never accounted for more than 20% of pulse-labeled RNA at any time during infection.     

Is the injection of DNA enough to cause bacteriophage P22-induced changes in the cellular transport process of Salmonella typhimurium?

It was demonstrated earlier in this laboratory that phage P22 induces a transient depression in the cellular transport processes of the host Salmonella typhimurium immediately after infection and that an effective injection process is enough to cause the depression. By using defective phage particles that contain host DNA instead of phage DNA for infection, it has been demonstrated that the injection of phage-specific DNA is essential for this. The defective particles adsorbed to the host and injected their DNA, but the cellular transport processes of the host were not altered. Thus, the injection of host DNA by the phage fails to affect the transport process. Insensitivity of the phage DNA-induced depression in transport to chloramphenicol rules out the involvement of newly synthesized protein in this change and indirectly suggests the possible role of phage DNA-associated internal proteins of P22.     

Infection by choleraphage phi 138: bacteriophage DNA and replicative intermediates.

Choleraphage phi 138 contains a linear, double-stranded, circularly permuted DNA molecule of 30 X 10(6) daltons or 45 kilobase pairs. Upon infection, the host DNA is degraded, and synthesis of phage-specific DNA is detectable 20 min after infection. The phage utilizes primarily the host DNA degradation products for its own DNA synthesis. A physical map of phi 138 DNA was constructed with the restriction endonucleases Bg/II, HindIII, and PstI. A concatemeric replicative DNA intermediate equivalent to eight mature genome lengths was identified. The concatemer was shown to be the precursor for the synthesis of mature bacteriophage DNA which is subsequently packaged by a headful mechanism.     

Genetic and Physiological Studies of Bacteriophage T5 III. Patterns of Deoxyribonucleic Acid Synthesis Induced by Mutants of T5 and the Identification of Genes Influencing the Appearance of Phage-Induced Dihydrofolate Reductase and Deoxyribonuclease

Patterns of deoxyribonucleic acid (DNA) metabolism in nonpermissive cells infected with amber mutants representing 29 genes of T5 are reported. A group of 7 contiguous genes are essential for the synthesis of phage DNA, whereas 20 other genes, when defective, permit varying degrees of phage DNA synthesis. Two further genes are essential for complete transfer of phage DNA to host cells, and therefore indirectly do not permit the synthesis of phage DNA. The structural genes for an early T5 deoxyribonuclease and for T5 DNA polymerase, as well as a gene that affects the synthesis of dihydrofolate reductase, have been identified in the genetic map of T5.     

Bacteriophage Tail Components: I. Pteroyl Polyglutamates in T-Even Bacteriophages

A pteroylpolyglutamate has been found to be a constituent of all Escherichia coli T-even bacteriophages and has been characterized with regard to its oxidation state, molecular weight, origin, and location on the phage particle. The phage compound has been shown to be a dihydropteroyl penta- or hexaglutamate on the basis of its chemical and physical properties. Analyses of extracts of uninfected and T2L-infected E. coli have indicated that the phage dihydropteroyl polyglutamate was present only in infected cells. Its synthesis was sensitive to the addition of chloramphenicol before infection, and the compound appeared to be specifically induced by phage infection. Analyses of isolated phage ghosts and tail substructures have shown that each phage particle contains between two and six phage-specific pteroyl derivatives and that the juncture of the phage tail plate with the tail tube is the most likely site of binding of the phage-induced pteroyl compound.     

A Bacteriophage of Bacillus subtilis Which Forms Plaques Only at Temperatures Above 50 C III. Inhibition of TSP-1-Specific Deoxyribonucleic Acid Synthesis at 37 C and 45 C

The effect of temperature on phage-specific deoxyribonucleic acid (DNA) synthesis was studied in TSP-1-infected Bacillus subtilis. This was facilitated by selectively inhibiting host DNA synthesis with 6-(p-hydroxyphenylazo)-uracil. The results indicated that TSP-1 DNA synthesis did not continue at 37 C and was immediately shut down after transfer to this temperature. Incubation at 45 C greatly reduced TSP-1 DNA synthesis. Phage-specific DNA synthesis could resume at 53 C, however, when the infected culture was returned to 53 C after a 2-min incubation period at 37 C. The results suggest that the inhibition of phage DNA synthesis at 37 C is reversible. Since infected cultures returned to 53 C after 2 min at 37 C could not complete the replicative cycle, the irreversible inhibition of yet another intermediate step was suggested.     

Regulation of bacteriophage f1 DNA replication. I. New functions for genes II and X

Gene II protein is required for all phases of filamentous phage DNA synthesis other than the conversion of the infecting single strand to the parental double-stranded molecule. It introduces a specific nick into the double-stranded replicative form DNA, is required for the initiation of (+) strand synthesis and is responsible for termination and ring closure of the (+) strand product. Here we show that the gene II protein also promotes minus strand synthesis later in infection. Over-expression of gene II protein can induce the conversion of all nascent single-stranded phage DNA to the double-stranded form, even in the presence of the single-stranded DNA-binding gene V protein that would normally sequester the newly synthesized single strands. We also present evidence that the gene X protein (separately translated from an initiator codon within gene II, and identical to the C-terminal one-third of the gene II protein) is a powerful inhibitor of phage-specific DNA synthesis in vivo.     

Alkylation of T7 bacteriophage blocks superinfection exclusion

Alkylation of T7 bacteriophage by methyl methane sulfonate blocked superinfection exclusion. This blockage could be correlated with a delay in the synthesis of phage-specific proteins. Therefore we conclude that protein synthesis directed by the primary infecting phage is required for efficient exclusion of superinfecting phage particles.     

Nucleic Acid Synthesis in Bacteriophage SPO2c1-Infected Bacillus subtilis

The synthesis of host macromolecules was shut off very slowly and incompletely by bacteriophage SPO2c(1). No change in the rate of incorporation of radioactive precursors into protein and ribonucleic acid (RNA) could be detected after infection, and the rate of incorporation of thymidine was increased only slightly. The relative proportions of phage and host species of nucleic acids at various intervals in the latent period were determined by means of nucleic acid hybridization. Phage-specific RNA populations synthesized early were different from those synthesized late in the latent period. Host deoxyribonucleic acid (DNA) replication continued until 8 to 10 min after SPO2c(1) infection and then decreased markedly as phage-specific DNA synthesis was initiated. Host DNA was not degraded to trichloroacetic acid-soluble fragments, and its nucleotides were not found in either newly synthesized intracellular phage DNA or in progeny phage particles. The average burst size of SPO2c(1) was approximately 200 plaque-forming units per cell.     

Bacteriophage SPO1-induced macromolecular synthesis in minicells of Bacillus subtilis.

SPO1 bacteriophage injects its DNA into minicells produced by Bacillus subtilis CU403 divIVB1. The injected DNA is partially degraded to small trichloracetic acid-precipitable material and trichloroacetic acid-soluble material. The injected DNA is not replicated; however, it serves as a template for RNA and protein synthesis. The RNA produced specifically hybridizes to SPO1 DNA, and the amount of RNA hybridized can be reduced by competition with RNA isolated at all stages of the phage cycle from infected nucleate cells of the B. subtilis CU403 divIVB1. An unrelated phage, SPP1, also induces phage-specific RNA in infected minicells. Translation occurs in SPO1-infected minicells resulting in at least eight proteins which have been separated by gel electrophoresis, and two of these proteins have mobilities similar to proteins found only in infected B. subtilis CU403 divIVB1 nucleate cells. A large proportion of the polypeptide material synthesized in infected minicells is very small and heterogeneous in size.