Specificity determinants for bacteriophage lambda DNA replication: I. A chain of interactions that controls the initiation of replication

The genetic elements which control autonomous DNA replication differ in functional specificity among coliphage λ, the coliphages φ80 and 82, and the Salmonella phage P22. Hybrid phages derived by genetic recombination between λ and each of these related phages have been used to define and to localize specificity determinants for DNA replication.In λ-P22 hybrid phages (Hilliker & Botstein, 1976) the replication control elements segregate as an intact unit. By contrast, some viable λ-φ80 and λ.82 hybrid phages arise by recombination within the replication control region, in a small interval inside structural gene O. From the properties of such hybrid phages, we infer that the O gene product of λ and the functionally equivalent proteins of φ80 and 82 each interact with a specific nucleotide sequence in the cognate ori site, the DNA target for control of the origin of replication. With respect to this interaction, both the O products and the receptor sequences within ori show stringent type specificity. The donor and receptor specificity determinants for the ori-O interaction lie within an interval of less than 400 base-pairs.The O gene product also interacts with the product of replication gene P (Tomizawa, 1971). The O-P interaction displays limited type specificity; the P-like protein of φ80 can function together with the O protein of λ, but the P protein of λ cannot function with the O-like protein of φ80. The specificity determinants for the O-P interaction can be separated from those for the ori-O interaction.We propose that a chain of interactions between ori, O product, P product, and replication functions of the bacterial host, Escherichia coli, controls specific template selection and the assembly of the essential replication apparatus in the initiation of λ DNA replication.     

Bacteriophage P2-lambda interference. III. Essential role of an early step in the initiation of lambda replication.

Induction of bacteriophage λ in the presence of a P2 prophage results in inactivation of cellular transfer RNA, inhibition of amino acid and uridine incorporation in the host, as well as inhibition of phage replication. A red gam double mutation allows λ to escape from interference, and a mutation in gene O or P abolishes the effects on the host.It is shown here that phage and plasmid DNA extracted from cells undergoing P2-λ interference are still active in a transfection assay. Mutations in bacterial gene dna B or in phage site ori suppress the inhibition of amino acid incorporation, whereas genes dnaE and dna G have no such effect. Derepression of bacterial exonuclease VIII totally suppresses the interference, and mutations in genes recA and lexA, which control the SOS functions, suppress it partially if the λ phage is red⁺. Our results suggest that P2-λ interference is due to the action of old at an early step of the initiation of λ replication.     

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.     

An analysis of repressor overproduction by the lambda cIIIs mutant.

Efficient lysogenization of Escherichia coli K12 by bacteriophage λ requires the high level of synthesis of the phage repressor shortly after infection. This high level of synthesis of repressor requires the action of the λ eII and cIII proteins. Certain mutants of λ (λcIIIs) appear to have excess $\text{c}\text{II}\text{c}\text{III}$ activity and can lysogenize more efficiently than λ⁺. The basis for the enhanced lysogenization is that, while two or more infecting phage are necessary for λ⁺ to lysogenize, a single infecting λcIIIs particle is sufficient for lysogenization. Also, repressor levels in cells infected with λcIIIs are higher than in those infected with λ⁺. I report here that repressor overproduction by λcIIIs (1) is due to a much higher rate of repressor synthesis than that of λ⁺; (2) is most marked at low multiplicities of infection, possibly because λcIIIs produces repressor much more efficiently than λ⁺ as a singly infecting phage.     

Number and size distribution of the DNA chains in Escherichia coli.

The essential replication protein encoded by gene O of bacteriophage λ (O-λ) is one of the major polypeptides produced in vitro in a DNA-dependent protein synthesizing system with λ DNA as template (Yates et al., 1977). We have used this system to identify the proteins encoded by lambdoid phages φ80 and 82 and equivalent in function to O-λ. The O protein of each phage type differs slightly in polypeptide molecular weight. Hybrid λ-φ80 and λ-82 phages derived by recombination within gene O direct synthesis of hybrid O proteins with the aminoterminal segment characteristic of one parent, and the carboxyl-terminal segment characteristic of the other. Differences in structure among O-λ, O-80 and O-λ82 segregate together with specificity determinants for interactions between the O protein and the control site ori, and between the O protein and the product of replication gene P. The coding region for the O protein includes ori.     

Replication of bacteriophage lambda DNA. Examination of variants containing double origins and observation of a bias in directionality

Bacteriophage λ variants have been constructed that possess two λ ori sites. Replicative intermediates resulting from infection with these phages have been investigated. We find that initiation of replication from the ori site on an EcoRI fragment (containing all the DNA sequences from within the red gene to the middle of gene O) cloned in the inverted orientation is predominantly bidirectional but occurs at a decreased frequency. Double initiations were observed at low frequency. However, a second cloned ori fragment (carrying two large deletions and a small insertion) cloned in the normal orientation demonstrated insignificant levels of replication from the cloned site unless the normal ori had already initiated.A bias in directionality of λ replication has been observed. Molecules that replicate unidirectionally propagate to the right more often than to the left. If the cloned ori-containing EcoRI fragment is inserted with reversed polarity, then the bias is towards the left. Bidirectional λ replicative intermediates also appear to show a similar bias but this is superimposed on a large, apparently random, effect that results in asymmetric growing-point propagation.     

Lack of a unique termination site for the first round of bacteriophage lambda DNA replication

From previous data on the first round of bacteriophage λcIIcIII DNA replication (Schnös & Inman, 1970) it is possible to estimate, by extrapolation, the position on circular λ DNA where bidirectional growing points meet. In the present study we have investigated whether this position occurs at a genetically defined site. To this end, replicative intermediates of λ mutants containing either deletions to the left of the replication origin, or one deletion plus a duplication to the right, were analyzed in the electron microscope. Our results indicate that: (i) leftward growing points can traverse the extrapolated termination point calculated from the λcIIcIII data, (ii) no discontinuity of either right or leftward growing fork position is observed, and (iii) the extrapolated termination points for these mutants are well removed from those calculated for λcIIcIII DNA. From these data we conclude that there is probably no unique termination site for the first round of λ DNA replication and that termination occurs simply by collision of the growing forks.     

Cloning of a functional replication origin of phage G4 into the genome of phage M13.

A chimeric single-stranded DNA phage, M13Gori1, has been formed as a result of the in vitro insertion of a 2216 base-pair HaeII fragment of bacteriophage G4 replicative form DNA into the replicative form DNA of bacteriophage M13. The inserted G4 DNA carries the dnaG-dependent origin for G4 complementary strand synthesis. The cloned G4 origin functions both in vivo and in vitro in the conversion of M13Gori1 single-stranded viral DNA to the duplex replicative form by a rifampicin-resistant mechanism. Labelling of the 3′ terminus of the single discontinuity in M13Gori1 replicative form II molecules synthesized in crude extracts and subsequent restriction analysis indicate that M13Gori1 complementary strand synthesis can be initiated at either the RNA polymeraseprimed M13 origin or at the dnaG-primed G4 origin. The M13Gori1 complementary strand initiated at the G4 origin terminates in the vicinity of the G4 origin after progressing around the circular template and traversing the M13 origin region, indicating the absence of a specific nucleotide sequence in the M13 origin for termination of the newly formed complementary strand. The ability of this chimeric phage to utilize the cloned G4 origin in vivo even in the presence of the presumed M13 pilot protein (gene 3 protein) indicate that the nucleotide sequence of the replication origin is sufficient for recognizing the appropriate initiation enzymes. Since decapsidation of M13 is tightly coupled to replicative form formation, initiation at the G4 origin, located over 1000 nucleotides from the M13 complementary strand origin, indicates that widely separated nucleotide sequences contained in the filamentous virion can be exposed to the cell cytoplasm during eclipse.