Genes 1.2 and 10 of bacteriophages T3 and T7 determine the permeability lesions observed in infected cells of Escherichia coli expressing the F plasmid gene pifA.

Infections of F plasmid-containing strains of Escherichia coli by bacteriophage T7 result in membrane damage that allows nucleotides to exude from the infected cell into the culture medium. Only pifA of the F pif operon is necessary for "leakiness" of the T7-infected cell. Expression of either T7 gene 1.2 or gene 10 is sufficient to cause leakiness, since infections by phage containing null mutations in both of these genes do not result in permeability changes of the F-containing cell. Even in the absence of phage infection, expression from plasmids of either gene 1.2 or 10 can cause permeability changes, particularly of F plasmid-containing cells. In contrast, gene 1.2 of the related bacteriophage T3 prevents leakiness of the infected cell. In the absence of T3 gene 1.2 function, expression of gene 10 causes membrane damage that allows nucleotides to leak from the cell. Genes 1.2 and 10 of both T3 and T7 are the two genes involved in determining resistance or sensitivity to F exclusion; F exclusion and leakiness of the phage-infected cell are therefore closely related phenomena. However, since leakiness of the infected cell does not necessarily result in phage exclusion, it cannot be used as a predictor of an abortive infection.     

Synthesis of the capsid protein inhibits development of bacteriophage T3 mutants that abortively infect F plasmid-containing cells

Mutants of bacteriophage T3 that lack gene 1.2 resemble wild-type phage T7 in that they are unable productively to infect F plasmid-containing cells of Escherichia coli. Pseudorevertants of a T3 gene 1.2 deletion mutant that have regained the ability to plate efficiently on male cells have been isolated and characterized. At least two mutations in the gene for the major capsid protein are necessary for these phages to bypass F-mediated restriction. One mutation serves to reduce the rate of synthesis of the capsid protein; a second mutation apparently alters an unknown property that is intrinsic to the free, or unassembled form of the protein. During the abortive infection of an F-containing host, synthesis of the wild-type capsid protein directly inhibits further phage development.     

Defective DNA injection by alkylated and nonalkylated bacteriophage T7.

DNA injection by alkylated and nonalkylated bacteriophage T7 has been analyzed by a physical method which involved Southern hybridization to identify noninjected regions of DNA. Treatment of phage with methyl methanesulfonate reduced the amount of DNA injected into wild-type Escherichia coli cells. This reduction was correlated with a decreased injection of DNA segments located on the right-hand third of the T7 genome. An essentially identical injection defect was observed when alkylated phage infected E. coli mutant cells unable to repair 3-methyladenine. Furthermore, untreated phage particles were discovered to be naturally injection-defective. Some injected all their DNA except those segments located in the rightmost 15% of the T7 genome, while other injected no DNA at all. In the presence of rifampicin, untreated phages injected only segments from the left end of the genome. These results provide direct physical evidence that T7 DNA injection is strictly unidirectional, starting from the left end of the T7 genome. The injection defect quantified here for alkylated phage is probably partially, if not totally, responsible for phage inactivation, when that inactivation is measured in wild-type E. coli cells. Since alkylated phage injected the same DNA sequences into both wild-type and repair-deficient cells, we conclude that DNA injection is independent of the host-cell's capacity for repair of 3-methyladenine residues.     

Streptomycin- and rifampin-resistant mutants of Escherichia coli perturb F exclusion of bacteriophage T7 by affecting synthesis of the F plasmid protein PifA.

Certain alleles of rpsL that confer resistance to the antibiotic streptomycin almost completely relieve F exclusion of bacteriophage T7. Introduction of a specific rpoB allele conferring resistance to rifampin into the rpsL strain restores the ability of the F-containing strain to exclude T7. This variation in the severity of F exclusion is reflected in the levels of the F-encoded inhibitor protein PifA: F'-containing cells that harbor specific rpsL alleles are phenotypically Pif-, but become Pif+ by the further acquisition of a specific rpoB allele. F-containing cells harboring the gyrA43(Ts) mutation also appear phenotypically Pif-, possibly because repression of the pif operon is enhanced by an altered DNA conformation in the gyrase mutant strain.     

Recombinants between bacteriophages T7 and T3 which productively infect F-plasmid-containing strains of Escherichia coli

Recombinant phages between T7 and T3 have been isolated that grow well on strains of Escherichia coli that contain the F factor. One phage that has been characterized physically and genetically is predominately of the T7 genotype. Within this hybrid phage, two separate regions of T3 DNA have been located which are necessary for the phenotype of productive growth on F-containing strains. One of these, designated M1, contains the right part of gene 1 and continues through gene 1.3; the second, M2, appears to lie between gene 3 and gene 4.     

Rescue of abortive T7 gene 2 mutant phage infection by rifampin.

Infection of Escherichia coli with T7 gene 2 mutant phage was abortive; concatemeric phage DNA was synthesized but was not packaged into the phage head, resulting in an accumulation of DNA species shorter in size than the phage genome, concomitant with an accumulation of phage head-related structures. Appearance of concatemeric T7 DNA in gene 2 mutant phage infection during onset of T7 DNA replication indicates that the product of gene 2 was required for proper processing or packaging of concatemer DNA rather than for the synthesis of T7 progeny DNA or concatemer formation. This abortive infection by gene 2 mutant phage could be rescued by rifampin. If rifampin was added at the onset of T7 DNA replication, concatemeric DNA molecules were properly packaged into phage heads, as evidenced by the production of infectious progeny phage. Since the gene 2 product acts as a specific inhibitor of E. coli RNA polymerase by preventing the enzyme from binding T7 DNA, uninhibited E. coli RNA polymerase in gene 2 mutant phage-infected cells interacts with concatemeric T7 DNA and perturbs proper DNA processing unless another inhibitor of the enzyme (rifampin) was added. Therefore, the involvement of gene 2 protein in T7 DNA processing may be due to its single function as the specific inhibitor of the host E. coli RNA polymerase.     

In Vitro Packaging of UV Radiation-Damaged DNA from Bacteriophage T7

When DNA from bacteriophage T7 is irradiated with UV light, the efficiency with which this DNA can be packaged in vitro to form viable phage particles is reduced. A comparison between irradiated DNA packaged in vitro and irradiated intact phage particles shows almost identical survival as a function of UV dose when Escherichia coli wild type or polA or uvrA mutants are used as the host. Although uvrA mutants perform less host cell reactivation, the polA strains are identical with wild type in their ability to support the growth of irradiated T7 phage or irradiated T7 DNA packaged in vitro into complete phage. An examination of in vitro repair performed by extracts of T7-infected E.coli suggests that T7 DNA polymerase may substitute for E. coli DNA polymerase I in the resynthesis step of excision repair. Also tested was the ability of a similar in vitro repair system that used extracts from uninfected cells to restore biological activity of irradiated DNA. When T7 DNA damaged by UV irradiation was treated with an endonuclease from Micrococcus luteus that is specific for pyrimidine dimers and then was incubated with an extract of uninfected E. coli capable of removing pyrimidine dimers and restoring the DNA of its original (whole genome size) molecular weight, this DNA showed a higher packaging efficiency than untreated DNA, thus demonstrating that the in vitro repair system partially restored the biological activity of UV-damaged DNA.     

Role of F Pili in the Penetration of Bacteriophage fl

Early stages of infection of Escherichia coli with the filamentous bacteriophage f1 were examined in the electron microscope. Purified phage-bacteria complexes were prepared at various time intervals after the initiation of synchronous infection. Cells were scored for the total number of F pili, the number of F pili with f1 attached, the number of intact phage particles which occurred at the surface of the cell, and F pilus length. Electron microscope autoradiographs were also prepared at each time interval. The results showed that the average number of F pili with f1 attached decreased with time as phage deoxyribonucleic acid (DNA) entered the cell. Concomitant with this loss, the remaining F pili became shorter. The rate of entry of phage DNA into the cell followed, with a short lag, the rate of loss of F pili with f1 attached. During the lag period, intact phage particles accumulated at the surface of the cell. The results from radioautographs showed that no phage DNA could be located within the F pilus. These results suggest that F pili are resorbed by the cell during infection with the bacteriophage f1. Parallel experiments with noninfected cultures further suggest that pilus resorption may be a normal cellular phenomenon.     

Repair of benzo[a]pyrene diol epoxide damaged bacteriophage T7 DNA determined by survival of phage made by in vitro packaging

DNA from bacteriophage T7 was treated with benzo[a]pyrene diol epoxide (BPDE) and the number of covalently bound adducts per T7 genome was determined. BPDE treated T7 DNA was then incubated in an in vitro DNA packaging system so as to form infective T7 phage. The observed reduced survival of these phage measured with Escherichia coli uvrA- indicator bacteria showed that the BPDE treated DNA was in fact utilized by the in vitro packaging system and that the resulting phage contained DNA damage caused by in vitro exposure to BPDE. T7 DNA damage by BPDE was also incubated in an in vitro DNA repair system that used partially purified uvrABC proteins from E. coli. Alkaline sucrose gradient analysis demonstrated that nicks were introduced into the damaged DNA and that these incisions were repaired to yield nearly intact DNA molecules of about the size of a T7 genome. Encapsulation of the repaired DNA with the packaging system yielded phage that showed higher survival than the unrepaired control when plated on uvrA- indicator bacteria.     

Gene 1.2 protein of bacteriophage T7. Effect on deoxyribonucleotide pools

The gene 1.2 protein of bacteriophage T7, a protein required for phage T7 growth on Escherichia coli optA1 strains, has been purified to apparent homogeneity and shown to restore DNA packaging activity of extracts prepared from E. coli optA1 cells infected with T7 gene 1.2 mutants (Myers, J. A., Beauchamp, B. B., White, J. H., and Richardson, C. C. (1987) J. Biol. Chem. 262, 5280-5287). After infection of E. coli optA1 by T7 gene 1.2 mutant phage, under conditions where phage DNA synthesis is blocked, the intracellular pools of dATP, dTTP, and dCTP increase 10-40-fold, similar to the increase observed in an infection with wild-type T7. However, the pool of dGTP remains unchanged in the mutant-infected cells as opposed to a 200-fold increase in the wild-type phage-infected cells. Uninfected E. coli optA+ strains contain severalfold higher levels of dGTP compared to E. coli optA1 cells. In agreement with this observation, dGTP can fully substitute for purified gene 1.2 protein in restoring DNA packaging activity to extracts prepared from E. coli optA1 cells infected with T7 gene 1.2 mutants. dGMP or polymers containing deoxyguanosine can also restore packaging activity while dGDP is considerably less effective. dATP, dTTP, dCTP, and ribonucleotides have no significant effect. The addition of dGTP or dGMP to packaging extracts restores DNA synthesis. Gene 1.2 protein elevates the level of dGTP in these packaging extracts and restores DNA synthesis, thus suggesting that depletion of a guanine deoxynucleotide pool in E. coli optA1 cells infected with T7 gene 1.2 mutants may account for the observed defects.     

The small viral membrane-associated protein P32 is involved in bacteriophage PRD1 DNA entry

The lipid-containing bacteriophage PRD1 infects a variety of gram-negative cells by injecting its linear double-stranded DNA genome into the host cell cytoplasm, while the protein capsid is left outside. The virus membrane and several structural proteins are involved in phage DNA entry. In this work we identified a new infectivity protein of PRD1. Disruption of gene XXXII resulted in a mutant phenotype defective in phage reproduction. The absence of the protein P32 did not compromise the particle assembly but led to a defect in phage DNA injection. In P32-deficient particles the phage membrane is unable to undergo a structural transformation from a spherical to a tubular form. Since P32(-) particles are able to increase the permeability of the host cell envelope to a degree comparable to that found with wild-type particles, we suggest that the tail-tube formation is needed to eject the DNA from the phage particle rather than to reach the host cell interior.     

Isolation and characteristics of the bacteriophage from the vaccine strain Tohama phase I

Some properties of bacteriophage phi T isolated from the vaccine strain Bordetella pertussis Tohama phase I and propagated in Bordetella parapertussis 504 cells are presented. Phage phi T belongs to the IV group in accordance with Tikhonenko classification. The diameter of head and length of noncontractile tail sheath are 49.5 +/- 0.5 and 145 +/- 7 nm, respectively. Diameter of the tail sheath is 3.2 +/- 0.6 nm. Molecular mass of the phage DNA is 37 +/- 3 kb. Population of phi T phage is polymorphous and consists of particles the genomes or which vary from each other by the "insert" located 6.8 +/- 0.6 kb from the end of molecule. The blot hybridization has demonstrated that the bacteriophage genome is not inserted into the chromosome of the lysogenic strain. Autonomous location of the phage genome in the host cell is suggested. The temperature and hydrogen ions concentration effects on bacteriophage phi T stability were studied. The conditions for phage suspension storage are described.     

The role of ATP and membrane potential in the penetration of phage T17 DNA into the cell during infection

The role of ATP and membrane potential in phage T7 DNA injection into E. coli during infection has been studied. Entrance of phage T7 genes of class II and III was shown to be prevented by arsenate, indicating the requirement for phosphorylated macroergs in the phage DNA injection. The injection process was also inhibited by exposition of the cells to the uncoupler of oxidative phosphorylation. Dependence of the injection efficiency on the membrane-potential value has been shown to be sigmoidal, which suggests a regulatory role of the membrane potential in phage T7 DNA injection from the virion into the host cell.     

Inactivation of the T7 coliphage by monofunctional alkylating agents. Action of phage adsorption and injection of its DNA.

Alkylation by ethyl or methyl methanesulfonate to an extent that inactivates more than 99.5% of T7 coliphages has no effect on phage adsorption on Escherichia coli B cells, but decreases the amount of phage DNA injected into the host cells. Depurination interferes with the injection of the phage DNA. Failure to inject the whole phage genome thus appears to be a cause of the immediate as well as of the delayed inactivation of the T7 coliphage treated by monofunctional alkylating agents; the hypothesis that it is the only cause of inactivation, although not very likely, cannot be excluded at the present time.     

In vitro repair of double-strand breaks accompanied by recombination in bacteriophage T7 DNA.

A double-strand break in a bacteriophage T7 genome significantly reduced the ability of that DNA to produce viable phage when the DNA was incubated in an in vitro DNA replication and packaging system. When a homologous piece of T7 DNA (either a restriction fragment or T7 DNA cloned into a plasmid) that was by itself unable to form a complete phage was included in the reaction, the break was repaired to the extent that many more viable phage were produced. Moreover, repair could be completed even when a gap of about 900 nucleotides was put in the genome by two nearby restriction cuts. The repair was accompanied by acquisition of a genetic marker that was present only on the restriction fragment or on the T7 DNA cloned into a plasmid. These data are interpreted in light of the double-strand gap repair mode of recombination.