Characteristics of hybrid plasmids carrying the genes of colicinogenic plasmid Collb-P9 responsible for colicin Ib synthesis and inhibition of phage T5 development

The EcoRI and HindII restriction endonucleases and pBR325 vector plasmid were used to obtain a set of hybrid plasmids containing ColIb-P9 fragments carrying the characters for colicin Ib synthesis and immunity and the ability to inhibit T5 phage growth. The genes responsible for colicin synthesis and immunity are closely linked and localized in the EcoRI fragment with a molecular weight of 1.85 MD (pIV41) or in the HindII fragment of 2.4 MD (pIV1). The clones containing these plasmids show an increased level of both spontaneous and mitomycin C-induced colicin synthesis and an increased level of immunity due to a larger dosage of the genes. The genes controlling T5 growth inhibition are localized in other restriction fragments of ColIb DNA: the EcoRI fragment of 1.45 MD (pIV7) and the HindII fragment of 4.3 MD (pIV5). We have demonstrated by means of hybrid plasmids that T5 growth inhibition is not connected with the colicin Ib synthesized in infected cells and is controlled by other specific product(s) of the ColIb plasmid genes. T5 phage growth was as efficient in clones containing plasmids with cloned colicin Ib genes as in a strain without plasmids. An investigation of the expression of the genes inhibiting T5 phage growth in an in vitro protein synthesis system has revealed a protein with a molecular weight of 36 000 which seems to take part in the process.     

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.     

Functional Interactions between the DNA Ligase of ESCHERICHIA COLI and Components of the DNA Metabolic Apparatus of T4 Bacteriophage

T4 phage completely defective in both gene 30 (DNA ligase) and the rII gene (function unknown) require at least normal levels of host-derived DNA ligase (E. coli lig gene) for growth. Viable E. coli mutant strains that harbor less than 5% of the wild-type level of bacterial ligase do not support growth of T4 doubly defective in genes 30 and rII (T4 30- rII- mutants). We describe here two classes of secondary phage mutations that permit the growth of T4 30- rII- phage on ligase-defective hosts. One class mapped in T4 gene su30 (Krylov 1972) and improved T4 30- rII- phage growth on all E. coli strains, but to varying degrees that depended on levels of residual host ligase. Another class mapped in T4 gene 32 (helix-destabilizing protein) and improved growth specifically on a host carrying the lig2 mutation, but not on a host carrying another lig- lesion (lig4). Two conclusions are drawn from the work: (1) the role of DNA ligase in essential DNA metabolic processes in T4-infected E. coli is catalytic rather than stoichiometric, and (2) the E. coli DNA ligase is capable of specific functional interactions with components of the T4 DNA replication and/or repair apparatus.     

Development of Coliphage T5: Ultrastructural and Biochemical Studies

Electron microscopic studies of Escherichia coli infected with bacteriophage T5(+) have revealed that host nuclear material disappeared before 9 min after infection. This disappearance seemed to correspond to the breakdown of host deoxyribonucleic acid (DNA) into acid-soluble fragments. Little or no host DNA thymidine was reincorporated into phage DNA, except in the presence of 5-fluorodeoxyuridine (FUdR). Progeny virus particles were observed in the cytoplasm 20 min postinfection. Most of these particles were in the form of hexagonal-shaped heads or capsids, which were filled with electron-dense material (presumably T5 DNA). A small percentage (3 to 4%) of the phage heads appeared empty. On rare occasions, crystalline arrays of empty heads were observed. Nalidixic acid, hydroxyurea, and FUdR substantially inhibited replication of T5 DNA. However, these agents did not prevent virus-induced degradation of E. coli DNA. Most of the phage-specified structures seen in T5(+)-infected cells treated with FUdR or with nalidixic were in the form of empty capsids. Infected cells treated with hydroxyurea did not contain empty capsids. When E. coli F was infected with the DO mutant T5 amH18a (restrictive conditions), there was a small amount of DNA synthesis. Such cells contained only empty capsids, but their numbers were few in comparison to those in cells infected under permissive conditions or infected with T5(+). The cells also failed to lyse. These results confirm other reports which suggest that DNA replication is not required for the synthesis of late proteins. The data also indicate that DNA replication influences the quantity of viral structures being produced.     

Identification of the gene controlling the synthesis of the major bacteriophage T5 membrane protein.

After infection of Escherichia coli B by bacteriophage T5, a major new protein species, as indicated by polyacrylamide gel electrophoresis, appears in the cells' membranes. Phage mutants with amber mutations in the first-step-transfer portion of their DNA have been tested for their ability to induce membrane protein synthesis after they infect E. coli B. We have found that phage with mutations in the Al gene of T5 do not induce the synthesis of the T5-specific major membrane protein, whereas phage that are mutant in the A2 gene do induce its synthesis. We conclude that gene Al must function normally for T5-specific membrane protein biosynthesis to occur and that only the first 8% (first-step-transfer piece) of the DNA need be present in the cell for synthesis to occur.     

Mutations in the gene 5 DNA polymerase of bacteriophage T7 suppress the dominant lethal phenotype of gene 2.5 ssDNA binding protein lacking the C-terminal phenylalanine

Gene 2.5 of bacteriophage T7 encodes a ssDNA binding protein (gp2.5) essential for DNA replication. The C-terminal phenylalanine of gp2.5 is critical for function and mutations in that position are dominant lethal. In order to identify gp2.5 interactions we designed a screen for suppressors of gp2.5 lacking the C-terminal phenylalanine. Screening for suppressors of dominant lethal mutations of essential genes is challenging as the phenotype prevents propagation. We select for phage encoding a dominant lethal version of gene 2.5, whose viability is recovered via second-site suppressor mutation(s). Functional gp2.5 is expressed in trans for propagation of the unviable phage and allows suppression to occur via natural selection. The isolated intragenic suppressors support the critical role of the C-terminal phenylalanine. Extragenic suppressor mutations occur in several genes encoding enzymes of DNA metabolism. We have focused on the suppressor mutations in gene 5 encoding the T7 DNA polymerase (gp5) as the gp5/gp2.5 interaction is well documented. The suppressor mutations in gene 5 are necessary and sufficient to suppress the lethal phenotype of gp2.5 lacking the C-terminal phenylalanine. The affected residues map in proximity to aromatic residues and to residues in contact with DNA in the crystal structure of T7 DNA polymerase-thioredoxin.     

Synthesis of Bacteriophage and Host DNA in Toluene-Treated Cells Prepared from T4-Infected Escherichia coli: Role of Bacteriophage Gene D2a

We investigated the synthesis of DNA in toluene-treated cells prepared from Escherichia coli infected with bacteriophage T4. If the phage carry certain rII deletion mutations, those which extend into the nearby D2a region, the following results are obtained: (i) phage DNA synthesis occurs unless the phage carries certain DNA-negative mutations; and (ii) host DNA synthesis occurs even though the phage infection has already resulted in the cessation of host DNA synthesis in vivo. The latter result indicates that the phage-induced cessation of host DNA synthesis is not due to an irreversible inactivation of an essential component of the replication apparatus. If the phage are D2a(+), host DNA synthesis in toluene-treated infected cells is markedly reduced; phage DNA synthesis is probably also reduced somewhat. These D2a effects, considered along with our earlier work, suggest that a D2a-controlled nuclease, specific for cytosine-containing DNA, is active in toluene-treated cells.     

Identification and preliminary characterization of a mutant defective in the bacteriophage T4-induced unfolding of the Escherichia coli nucleoid.

The nucleoids of Escherichia coli S/6/5 cells are rapidly unfolded at about 3 min after infection with wild-type T4 bacteriophage or with nuclear disruption deficient, host DNA degradation-deficient multiple mutants of phage T4. Unfolding does not occur after infection with T4 phage ghosts. Experiments using chloramphenicol to inhibit protein synthesis indicate that the T4-induced unfolding of the E. coli chromosomes is dependent on the presence of one or more protein synthesized between 2 and 3 min after infection. A mutant of phage T4 has been isolated which fails to induce this early unfolding of the host nucleoids. This mutant has been termed "unfoldase deficient" (unf-) despite the fact that the function of the gene product defective in this strain is not yet known. Mapping experiments indicate that the unf- mutation is located near gene 63 between genes 31 and 63. The folded genomes of E. coli S/6/5 cells remain essentially intact (2,000-3,000S) at 5 min after infection with unfoldase-, nuclear disruption-, and host DNA degradation-deficient T4 phage. Nuclear disruption occurs normally after infection with unfoldase- and host DNA degradation-deficient but nuclear disruption-proficient (ndd+), T4 phage. The host chromosomes remain partially folded (1,200-1,800S) at 5 min after infection with the unfoldase single mutant unf39 x 5 or an unfoldase- and host DNA degradation-deficient, but nuclear disruption-proficient, T4 strain. The presence of the unfoldase mutation causes a slight delay in host DNA degradation in the presence of nuclear disruption but has no effect on the rate of host DNA degradation in the absence of nuclear disruption. Its presence in nuclear disruption- and host DNA degradation-deficient multiple mutants does not alter the shutoff to host DNA or protein synthesis.     

Involvement of bacteriophage T4 genes in radiation repair

One interpretation of Ebisuzaki's (1966) observation that the functional survival of certain early phage T4 genes is identical in v⁺ and v -infected cells is that the product of the early gene being studied is essential for the successful completion of excision repair (which is known to be mediated by the v gene). An experiment designed to test this hypothesis is described, with results which fully support the idea. Assuming then that this interpretation is valid, it became possible to determine the involvement in excision repair of a much wider range of early genes by establishing whether or not the v allele affects their functional survival. In addition a comparable series of experiments was performed with phages carrying the u.v.-sensitive y mutation which is known to mediate a quite different type of repair in T4-infected cells.The results indicate that genes 1, 30, 42, 43 and 56 are involved in excision repair, but not genes 32, 41, 43 or 44. All these genes are however involved in y-mediated repair. It appears therefore that this latter repair system (which bears some resemblance to that controlled by the rec genes in bacteria) depends on normal phage DNA synthesis for its completion. However the repair synthesis following the excision of pyrimidine dimers in u.v.-irradiated T4 DNA seems distinct from normal DNA synthesis in that it does not involve certain of the early phage genes, and in particular does not utilize the DNA polymerase coded by gene 43. It is suggested that the polymerase activity associated with this repair synthesis is provided by the bacterial Kornberg polymerase pol I.     

Transfection of Escherichia coli spheroplasts. VI. Transfection of nonpermissive spheroplasts by T5 and BF23 bacteriophage DNA carrying amber mutations in DNA transfer genes.

DNA was extracted from T5 and BF23 phage carrying amber mutations in genes A2, A1, or D9 and tested for its ability to transfect su minus spheroplasts. DNA from T5 am231, defective in gene A2, transfects Escherichia coli su minus recB minus spheroplasts with an efficiency of 16% of that of wild-type T5 DNA, whereas DNA from T5 am16d or BF23 am57, both defective in gene A1 or its equivalent, transfects E. coli su minus recB minus spheroplasts with an efficiency of 1.4% of that of wild-type T5 DNA, provided E. coli su+ bacteria is used as the indicator in all cases. More than 95% of the progeny from the am231, am16d, and am57 DNA that transfects su minus recB minus spheroplasts is still amber mutant. From these efficiencies of transfection we conclude that the product of gene A2 functions mainly in the mechanism of transfer of phage DNA to intact host cells, and that this function is not essential for transfection of spheroplasts. We also conclude that gene A1 controls functions in addition to DNA transfer, in agreement with previous studies which show that mutations in gene A1 have a pleiotropic effect. Apparently, the absence of these additional functions controlled by gene A1 leads to a high frequency of abortive infection. DNA from amber mutants defective in either gene A1 or A2 does not appreciably transfect su minus rec+ spheroplasts, indicating that the products of these two genes may both be needed to protect T5 DNA from the very active rec BC nuclease in spheroplasts.     

Various characteristics of the anti-restriction mechanism in bacteriophage T5

Bacteriophage T5 is not confined by the restriction systems of the second type EcoRII and EcoRV. Bacteriophage T5 DNA is not modified by EcoRII and EcoRV methylases in vivo. The sites of recognition for restriction endonuclease EcoRV are mapped at 24.4; 57.6; 68.5; 70.2% of T5 DNA, while the sites at 5.1; 7.6% are recognized by EcoRII, the sites at 5.75; 6.0 and 6.5% are recognized by HpaI in FST. A high activity of restriction endonucleases EcoRI and EcoRV is demonstrated in crude extracts of E. coli B834 (RI) and E. coli B834 (RV) cells infected by bacteriophage T5. The simultaneous infection of E. coli B834 (RI) or E. coli B834 (RV) cells by the amber mutants of bacteriophage T5 and the suppressing phage lambda NM761 does not result in the protection of lambda DNA by the T5 anti-restriction mechanism. The presented data support the hypothesis that the anti-restriction mechanism of bacteriophage T5 is based on prevention of T5 DNA contacts with restriction enzymes by a specific phage protein.     

Essential lysine residues in the RNA polymerase domain of the gene 4 primase-helicase of bacteriophage T7.

At a replication fork DNA primase synthesizes oligoribonucleotides that serve as primers for the lagging strand DNA polymerase. In the bacteriophage T7 replication system, DNA primase is encoded by gene 4 of the phage. The 63-kDa gene 4 protein is composed of two major domains, a helicase domain and a primase domain located in the C- and N-terminal halves of the protein, respectively. T7 DNA primase recognizes the sequence 5'-NNGTC-3' via a zinc motif and catalyzes the template-directed synthesis of tetraribonucleotides pppACNN. T7 DNA primase, like other primases, shares limited homology with DNA-dependent RNA polymerases. To identify the catalytic core of the T7 DNA primase, single-point mutations were introduced into a basic region that shares sequence homology with RNA polymerases. The genetically altered gene 4 proteins were examined for their ability to support phage growth, to synthesize functional primers, and to recognize primase recognition sites. Two lysine residues, Lys-122 and Lys-128, are essential for phage growth. The two residues play a key role in the synthesis of phosphodiester bonds but are not involved in other activities mediated by the protein. The altered primases are unable to either synthesize or extend an oligoribonucleotide. However, the altered primases do recognize the primase recognition sequence, anneal an exogenous primer 5'-ACCC-3' at the site, and transfer the primer to T7 DNA polymerase. Other lysines in the vicinity are not essential for the synthesis of primers.     

A coupled in vitro system for the formation and packaging of concatemeric phage T1 DNA

Summary Extracts derived from E. coli cells infected non-permissively with phage T1 amber mutants were used in an in vitro system to investigate the packaging of T1 DNA into phage heads. The standard extract used infections with amber mutants in genes 1 and 2 (g1^-g2^-) which are defective in T1 DNA synthesis but can synthesis the proteins required for particle morphogenesis. g1^-g2^- extracts packaged T1⁺ virion DNA molecules with an efficiency of 3×10⁵ pfu/g DNA. Extracts from cells infected with phage also defective in DNA synthesis but carrying additional mutations in genes 3.5 or 4 which are required for concatemer formation in vivo (g1^-g3.5^- and g1^-g4^- extracts) package T1 virion DNA at substantially lower efficiencies.Analysis of the DNA products from these in vitro reaction showed that concatemeric DNA is formed very efficiently by g1^-g2^- extracts but not by g1^-g3.5^- or g1^-g4^- extracts. These results are interpreted as evidence that the T1 in vitro DNA packaging system primarily operates in a similar manner to the in vivo headful mechanism. This is achieved in vitro by the highly efficient conversion of T1 virion DNA into concatemers which are then packaged with a much lower efficiency into heads to form infectious particles. A secondary pathway for packaging T1 DNA into heads and unrelated to the headful mechanism may also exist.     

Fate of cloned bacteriophage T4 DNA after phage T4 infection of clone-bearing cells

Plasmid pBR322 replication is inhibited after bacteriophage T4 infection. If no T4 DNA had been cloned into this plasmid vector, the kinetics of inhibition are similar to those observed for the inhibition of Escherichia coli chromosomal DNA. However, if T4 DNA has been cloned into pBR322, plasmid DNA synthesis is initially inhibited but then resumes approximately at the time that phage DNA replication begins. The T4 insert-dependent synthesis of pBR322 DNA is not observed if the infecting phage are deleted for the T4 DNA cloned in the plasmid. Thus, this T4 homology-dependent synthesis of plasmid DNA probably reflects recombination between plasmids and infecting phage genomes. However, this recombination-dependent synthesis of pBR322 DNA does not require the T4 gene 46 product, which is essential for T4 generalized recombination. The effect of T4 infection on the degradation of plasmid DNA is also examined. Plasmid DNA degradation, like E. coli chromosomal DNA degradation, occurs in wild-type and denB mutant infections. However, neither plasmid or chromosomal degradation can be detected in denA mutant infections by the method of DNA--DNA hybridization on nitrocellulose filters.     

Involvement of phage T5 tail proteins and contact sites between the outer and inner membrane of Escherichia coli in phage T5 DNA injection.

The penetration of phage T5 DNA into the Escherichia coli envelope takes place through ion channels (Boulanger, P., and Letellier, L. (1992) J. Biol. Chem. 267, 3168-3172). To identify putative phage protein(s) involved in the formation of these channels, E. coli cells were infected at 37 degrees C with radioactively labeled phage and their envelopes were fractionated. After a flotation gradient, proteins belonging to the phage tail were recovered both in fractions containing the contact sites between the inner and outer membranes and in the outer membrane. The electrophoretic banding pattern of phage proteins indicates that the contact sites were enriched in the protein pb2. Moreover, infected cells were significantly enriched in contact sites as compared to intact cells. There was no enrichment of contact sites and very little radioactivity was found in this fraction and in the outer membrane when the cells were infected at 4 degrees C (i.e. under conditions where the phage does not inject its DNA). These results suggest that both contact sites and pb2 may play a central role in the translocation of phage T5 DNA.