Initiation of synthesis of the structural proteins of Semliki Forest virus.

Insertion of phage λ DNA into the normal attachment site of the DNA of the host Escherichia coli has been studied by ultracentrifugation analysis of the conversion of covalent circles of F′450 (F′gal att^λ bio) to F′450(λ) circles. We have found that integration proceeds at the normal rate if, in addition to the int gene product and a proper combination of phage and bacterial attachment sites, a large pool of λ DNA and some activity of the excision gene xis are present. In addition, turnoff of both phage DNA synthesis and xis gene activity are required.     

Physical studies of RNA involvement in bacteriophage lambda DNA replication and prophage excision

Non-diffusible genetic elements in bacteriophage λ DNA replication and λ prophage excision have been analyzed by the DNA-cutting assay of Freifelder and Kirschner (1971) and Freifelder et al. (1972). The mutant ti12, which affects a unique site for replication in or near the origin of replication (Dove et al., 1971), makes λ DNA partially refractory to replicative DNA-cutting. RNA synthesis in the vicinity of the origin, of replication seems to control the susceptibility of λ DNA to replicative DNA-cutting (Dove et al., 1969). Analogously, RNA synthesis in the vicinity of the left-hand prophage terminus seems to control excisional DNA-cutting of derepressed λ DNA, as predicted by the studies of Davies et al. (1972). These physical studies confirm previous genetic analyses and imply that the elements involved act at a very early stage in replication and in excision.     

Dimers of escherichia coli F' factors

Covalently closed circular DNA dimers of several $\text{E.}$$\text{coli}$ sex factors have been isolated. One of these, F′451, a dimer of F′450, has a molecular weight of $\text{ca.}$ 230 × 10⁶ daltons. F′451 (λ) containing a λ prophage has a molecular weight of 260 × 10⁶ and is probably the largest covalent closed circle of DNA yet reported. These dimers arise spontaneously and are of unknown origin and significance.     

Lambda excision revisited: testing a model for synapsis of prophage ends

Excision of lambda prophage was reexamined to test a model for prophage end synapsis. The model proposes that, during in situ prophage replication, following induction, the diverging replication forks are held together. Consequently, prophage DNA is spooled through the replication machinery, drawing the prophage ends together and facilitating synapsis. The model predicts that excision will be slowed if in situ lambda replication is inhibited, and the predicted low rate of excision of a nonreplicating prophage was observed after thermoinduction. However, excision was rapid if additional Int protein was supplied or if the temperature was reduced after induction, showing that (i) Int is partially thermosensitive for excision at 42 degrees C and (ii) in situ replication is not required for rapid excision, a finding that is inconsistent with the model.     

Bidirectional replication from an internal ori site of the linear N15 plasmid prophage

The prophage of coliphage N15 is not integrated into the chromosome but exists as a linear plasmid molecule with covalently closed hairpin ends (telomeres). Upon infection the injected phage DNA circularizes via its cohesive ends. Then, a phage-encoded enzyme, protelomerase, cuts the circle and forms the hairpin telomeres. N15 protelomerase acts as a telomere-resolving enzyme during prophage DNA replication. We characterized the N15 replicon and found that replication of circular N15 miniplasmids requires only the repA gene, which encodes a multidomain protein homologous to replication proteins of bacterial plasmids replicated by a theta-mechanism. Replication of a linear N15 miniplasmid also requires the protelomerase gene and telomere regions. N15 prophage replication is initiated at an internal ori site located within repA and proceeds bidirectionally. Electron microscopy data suggest that after duplication of the left telomere, protelomerase cuts this site generating Y-shaped molecules. Full replication of the molecule and subsequent resolution of the right telomere then results in two linear plasmid molecules. N15 prophage replication thus appears to follow a mechanism that is distinct from that employed by eukaryotic replicons with this type of telomere and suggests the possibility of evolutionarily independent appearances of prokaryotic and eukaryotic replicons with covalently closed telomeres.     

Group Y incompatibility and copy control of P1 prophage

We have identified a restriction fragment (EcoRI-5) of bacteriophage P1 that, when cloned in a λ prophage, expresses incompatibility characteristic of the unit copy P1 plasmid prophage. Lysogens of λ-P1 chimeras in which the P1 fragment is EcoRI-5 fail to maintain P1 or P7 plasmids. In order to study the nature of this incompatibility, we isolated P1 mutants that overcome it. These mutants exhibit an elevated copy number. We provide evidence that the increased copy number results from a defect in a repressor of replication that can be furnished in trans by a chromosomally integrated P1, but not by EcoRI-5 itself. We, therefore, suggest that the incompatibility exerted by EcoRI-5 is not attributable to the represser of replication involved in the above copy control defect. Instead, it could be attributed to the presence of a DNA site required for proper plasmid partition at cell division. The elevated copy number of the P1 mutants would then enable them to compete favorably with the single copy of the cloned EcoRI fragment for a cellular component of the partition apparatus. Thus, incompatibility could be overcome.     

Chromosomal transfer promoted by the promiscuous plasmid RP4.

We have studied the properties of the recombinant plasmid RP4λatt. This plasmid possesses the EcoRI-generated fragment of phage λ containing the genes att-int-xis (srIλ2–3) inserted into the single EcoRI site of the promiscuous plasmid RP4. The insertion of this λ fragment has no detectable effect on normal plasmid functions. However, it confers the ability to promote low-frequency polarized chromosomal transfer by int-promoted integration into the host λ attachment site attλ. We have succeeded in isolating an Hfr derivative which has the plasmid stably integrated at attλ. The Hfr derivative is unusual in having both an integrated and an autonomous RP4λatt stably coexisting in the same cell.     

Regional replication of the bacterial chromosome induced by derepression of prophage lambda

Summary Derepression of prophage in E. coli strain K12 results in constitutive synthesis of the enzymes directed by the nearby bacterial operon, gal (escape synthesis). Phage 82 fails to cause escape synthesis despite that it lysogenizes the strain K12 at the site identical to that of on the host chromosome. The reason for the observed difference between 82 and is studied in the light of the recent finding that escape synthesis in -lysogen is closely associated to phage-promoted replication of bacterial chromosome contiguous to the prophage including gal operon (escape replication). Excision-defective mutants from 82, 82int or 82xis, do initiate escape synthesis, suggesting that the prophage 82 is normally excised too quickly after induction to allow sufficient escape replication. In support of this, much more DNA hybridizable to bacterial DNA contained in gal accumulates after induction of 82int than after induction of 82. Studies with various hybrid phages between 82 and have suggested: 1. The occurrence of gal escape synthesis depends on the nature of the region between b2 and N in the map. 2. Regions of the 82 genome on both sides of the attachment site contribute independently to prevent gal escape synthesis. Implications of these results are discussed with regard to the factors involved in the prophage excision.The IIIrd article of this series is in Molec. Gen. Genet. 159, 185–190 (1978)     

Initiation of recA+-dependent recombination in Escherichia coli (lambda). I. Undamaged covalent circular lambda DNA molecules in uvrA+ recA+ lysogenic host cells are cut following superinfection with psoralen-damaged lambda phages.

When λ bacteriophages were treated with a photosensitizing agent, psoralen or khellin, and 360 nm light, monoadducts and interstrand crosslinks were produced in the phage DNA. The DNA from the treated phages was injected normally into Escherichia coli uvrA^? (λ) cells and it was converted to the covalent circular form in yields similar to those obtained in experiments with undamaged λ phages. In excision-proficient host cells, however, there was a dose-dependent reduction in the yield of rapidly sedimenting molecules, and a corresponding increase in slow sedimenting material, the extent of this conversion corresponding to about one cut per two crosslinks. Presumably, the damaged λ DNA molecules were cut by the uvrA endonuclease of the host cell, but were not restored to the original covalent circular form.The presence of psoralen damage in λ phage DNA greatly increased the frequency of genetic exchanges in λ phage-prophage crosses in homoimmune lysogens (Lin et al., 1977). As genetic recombination is thought to depend on cutting and joining in DNA molecules, experiments were performed to test whether psoralen-damaged λ DNA would cause other λ DNA in the same cell to be cut. E. coli (λ) host cells were infected with ³²P-labeled λ phages and incubated to permit the labeled DNA to form covalent circles. When these host cells were superinfected with untreated λ phages, there was no effect upon the circular DNA. When superinfected with λ phages that had been treated with psoralen and light, however, many of the covalent circular molecules were cut. The cutting of undamaged molecules in response to the damaged DNA was referred to as “cutting in trans”. It required the uvrA⁺ and recA⁺ host gene functions, but neither recB⁺ nor any phage gene functions. It occurred normally in non-lysogenic hosts treated with chloramphenicol before infection. Cutting in trans may be one of the steps in recA-controlled recombination between psoralen crosslinked phage λ DNA and its homologs.     

Repair mechanisms involved in prophage reactivation and UV reactivation of UV-irradiated phage lambda

Survival of UV-irradiated phage λ is increased when the host is lysogenic for a homologous heteroimmune prophage such as λimm434 (prophage reactivation). Survival can also be increased by UV-irradiating slightly the non-lysogenic host (UV reactivation).Experiments on prophage reactivation were aimed at evaluating, in this recombination process, the respective roles of phage and bacterial genes as well as that of the extent of homology between phage and prophage.To test whether UV reactivation was dependent upon recombination between the UV-damaged phage and cellular DNAs, lysogenic host cells were employed. Such hosts had thus as much DNA homologous to the infecting phage as can be attained. Therefore, if recombination between phage and host DNAs was involved in this repair process, it could clearly be evidenced.By using unexposed or UV-exposed host cells of the same type, prophage reactivation and UV reactivation could be compared in the same genetic background.The following results were obtained: (1) Prophage reactivation is strongly decreased in a host carrying recA mutations but quite unaffected by mutation lex-I known to prevent UV reactivation; (2) In the absence of the recA⁺ function, the red⁺ but not the int⁺ function can substitute for recA⁺ to produce prophage reactivation, although less efficiently; (3) Prophage reactivation is dependent upon the number of prophages in the cell and upon their degree of homology to the infecting phage. The presence in a recA host of two prophages either in cis (on the chromosome) or in trans (on the chromosome and on an episome) increases the efficiency of prophage reactivation; (4) Upon prophage reactivation there is a high rate of recombination between phage and prophage but no phage mutagenesis; (5) The rate of recombination between phage and prophage decreases if the host has been UV-irradiated whereas the overall efficiency of repair is increased. Under these conditions UV reactivation of the phage occurs as in a non-lysogen, as attested by the high rate of mutagenesis of the restored phage.These results demonstrate that UV reactivation is certainty not dependent upon recombination between two pre-existing DNA duplexes. The hypothesis is offered that UV reactivation involves a repair mechanism different from excision and recombination repair processes.     

Initiation of recA+-dependent recombination in Escherichia coli (lambda). II. Specificity in the induction of recombination and strand cutting in undamaged covalent circular bacteriophage 186 and lambda DNA molecules in phage-infected cells.

Covalent circular λ DNA molecules produced in Escherichia coli (λ) host cells by infection with labeled λ bacteriophages are cut following superinfection with λ phages damaged by exposure to psoralen and 360 nm light. This cutting of undamaged covalent circular molecules is referred to as “cutting in trans”, and could be a step in damage-induced recombination (Ross &; Howard-Flanders, 1977). Similar experiments performed with the temperate phage 186, which is not homologous with phage λ, showed cutting in trans and damage-induced recombination to occur in homoimmune crosses with phage 186 also. Double lysogens carrying both λ and 186 prophages were used in a test for specificity in cutting in trans and in damage-induced recombination. The double lysogens were infected with ³H-labeled 186 and ³²P-labeled λ phages. When these doubly infected lysogens containing covalent circular phage DNA molecules of both types were superinfected with psoralen-damaged 186 phages and incubated, the covalent circular 186 DNA was cut, while λ DNA remained intact. Similarly, superinfection with damaged λ phages caused λ, but not 186, DNA to be cut. Evidently, cutting in trans was specific to the covalent circular DNA homologous to the DNA of the damaged phages. Homoimmune phage-prophage genetic crosses were performed in the double lysogenic host infected with genetically marked λ and 186 phages. Damage-induced recombination was observed in this system only between the damaged phage DNA and the homologous prophage, none being detected between other homolog pairs present in the same cell. This result makes it unlikely that the damaged phage DNA induces a general state of enhanced strand cutting and genetic recombination affecting all homolog pairs present in the host cell. The simplest interpretation of the specificity in cutting and in recombination is as follows. When they have been incised, the damaged phage DNA molecules are able to pair directly with their undamaged covalent circular homologs. The latter molecules are cut in a recA ⁺ -dependent reaction by a recombination endonuclease that cuts the intact member of the paired homologs.     

Early events in the replication of Mu prophage DNA.

To determine whether the early replication of Mu prophage DNA proceeds beyond the termini of the prophage into hose DNA, the amounts of both Mu DNA and the prophage-adjacent host DNA sequences were measured using a DNA-DNA annealing assay after induction of the Mu vegetative cycle. Whereas Mu-specific DNA synthesis began 6 to 8 min after induction, no amplification of the adjacent DNA sequences was observed. These data suggest that early Mu-induced DNA synthesis is constrained within the boundaries of the Mu prophage. Since prophage Mu DNA does not undergo a prophage lambda-like excision from its original site after induction (E. Ljungquist and A. I. Bukhari, Proc. Natl. Acad. Sci. U.S.A. 74:3143--3147, 1977), we propose the existence of a control mechanism which excludes prophage-adjacent sequences from the initial mu prophage replication. The frequencies of the Mu prophage-adjacent DNA sequences, relative to other Escherichia coli genes, were not observed to change after the onset of Mu-specific DNA replication. This suggests that these regions remain associated with the host chromosome and continue to be replicated by the chromosomal replication fork. Therefore, we conclude that both the Mu prophage and adjacent host sequences are maintained in the host chromosome, rather than on an extrachromosomal form containing Mu and host DNA.     

Genes from the exo–xis region of λ and Shiga toxin-converting bacteriophages influence lysogenization and prophage induction

The exo–xis region, present in genomes of lambdoid bacteriophages, contains highly conserved genes of largely unknown functions. In this report, using bacteriophage λ and Shiga toxin-converting bacteriophage ?24_Β, we demonstrate that the presence of this region on a multicopy plasmid results in impaired lysogenization of Escherichia coli and delayed, while more effective, induction of prophages following stimulation by various agents (mitomycin C, hydrogen peroxide, UV irradiation). Spontaneous induction of λ and ?24_Β prophages was also more efficient in bacteria carrying additional copies of the corresponding exo–xis region on plasmids. No significant effects of an increased copy number of genes located between exo and xis on both efficiency of adsorption on the host cells and lytic development inside the host cell of these bacteriophages were found. We conclude that genes from the exo–xis region of lambdoid bacteriophages participate in the regulation of lysogenization and prophage maintenance.     

The nucleotide sequences at the termini of adenovirus-2 DNA.

The nucleotide sequence of the first 156 residues from the left end and the first 134 residues from the right end of adenovirus-2 DNA have been determined by direct DNA sequencing techniques. The inverted terminal repetition is 102 nucleotide pairs long. The 5′-ends of the intact DNA are resistant to the action of T4 polynucleotide kinase and the 5′ → 3′ exonucleases from phages lambda and T7. This resistance is most likely due to the covalent attachment of the 5′-terminal C residue to the terminal protein. No significant self-complementarity exists within the inverted terminal repetition, making terminal initiation of DNA replication via a self-priming mechanism unlikely. However, the terminal A + T-rich region followed immediately by a very G + C-rich region is consistent with other schemes for adenovirus-2 DNA replication. The left end of adenovirus-2 DNA contains extensive sequence repetition.     

Evidence for circular permutation of the prophage genome of Bacillus subtilis bacteriophage phi 105.

Analysis of DNA extracted from Bacillus subtilis lysogenic for bacteriophage phi 105 was performed by restriction endonuclease digestion and Southern hybridization using mature phi 105 DNA as a probe. The data revealed that the phi 105 prophage is circularly permuted. Digests using the enzymes EcoRI, SmaI, PstI, and HindIII localized the bacteriophage attachment site (att) to a region 63.4 to 65.7% from the left end of the mature bacteriophage genome. The phi 105 att site-containing SmaI C, PstI J, and HindIII L fragments were not present in digests of phi 105 prophage DNA. phi 105-homologous "junction" fragments were visualized by probing digests of prophage DNA with the purified PstI J fragment isolated from the mature bacteriophage genome. The excision of the phi 105 prophage was detected by observing the appearance of the mature PstI J fragment and the concomitant disappearance of a junction fragment during the course of prophage induction.     

Inactivation of prophage lambda repressor in vivo.

Jacob &; Monod (1961) postulated that prophage A induction results from the inactivation of the λ repressor by a cellular inducer. Although it has been shown that the phage A repressor is inactivated by the recA gene product in vitro (Roberts et al., 1978), we wanted to determine the action of the “cellular inducer” in vivo. Our results have led to a new model, which defines the relationship between the “cellular inducer” and the recA gene product.In order to quantitate the action of the cellular inducer on the λ repressor, we made use of bacteria with elevated cellular levels of the λ repressor (hyperimmune lysogens). We determined the kinetics of repressor inactivation promoted by three representative inducing treatments: ultraviolet light irradiation, thymine deprivation and temperature shift-up of tif-1 mutants.The kinetics of repressor decay in wild-type monolysogens indicate that repressor inactivation is a relatively slow cellular process that takes a generation time to reach completion. Incomplete inactivation of the repressor without subsequent prophage development may occur in a cell. We call this phenomenon detected at the biochemical level “subinduction”. In hyperimmune lysogens. subinduction is always the case.A high cellular level of A repressor that prevents prophage λ induction does not prevent induction of a heteroimmune prophage such as 434 or 80. Although the cellular inducer does not seem specific for any inducible prophage, it does not inactivate two prophage repressors present in a cell in a random manner. We have called this finding “preferential repressor inactivation”. Preferential repressor inactivation may be accounted for by considering that the intracellular concentration of a repressor determines its susceptibility to the action of the inducer.In bacteria with varying repressor levels, a fixed amount of repressor molecules is inactivated per unit of time irrespective of the initial repressor concentration. The rate of repressor inactivation depends on the catalytic capacity of the cellular inducer that behaves as a saturated enzyme. In wild-type bacteria the cellular inducer seems to be produced in a limited amount, to have a weak catalytic capacity and a relatively short half-life. The amount of the inducer formed after tif-1 expression is increased in STS bacteria overproducing a tif-1-modified RecA protein. This result is an indication that a modified form of the RecA protein causes repressor inactivation in vivo.From the results obtained we propose a model concerning the formation of the cellular inducer. We postulate that the cellular inducer is formed in a two-step reaction. The is model visualises how the RecA protein can be induced to high cellular concentrations, even though the RecAp protease molecules remain at a low concentration. The latter accounts for the limited proteolytic activity found in vivo.