Packaging of coliphage lambda DNA. I. The role of the cohesive end site and the gene A protein

The cohesive ends of the DNA of bacteriophage λ particles are normally formed by the action of a nuclease on the cohesive end sites (cos) of concatemeric λ DNA (reviewed by Hohn et al., 1977). The nuclease also cuts the cos site of an integrated prophage, and DNA located to the right is preferentially packaged into phage particles. This process occurs with approximately the same efficiency and rate in a single lysogen as in a tandem polylysogen. Thus, the rate of cos cutting does not increase when the number of cos sites per molecule increases, an hypothesis that has been proposed to explain why cohesive ends are not formed in circular monomers of λ DNA. We propose instead that the interaction of Ter with cos is influenced by the configuration of the DNA outside of cos during packaging, and that this configuration is different for circular monomers than for other forms of λ DNA. A model that gives rise to such a difference is described.We also found that missense mutations in the λ A gene changed the efficiency of packaging of phage relative to host DNA. This was not the case for missense mutations in several phage genes required for capsid formation. Thus, the product of gene A plays a role in determining packaging specificity, as expected if it is or is part of the nuclease that cuts λ DNA at cos.     

Bacteriophage lambda derivatives carrying two copies of the cohesive end site

A spontaneously arising tandem duplication derivative of bacteriophage lambda has been isolated, which carries two copies of the site where the cohesive ends are formed (designated cos). Its structure has been determined by electron microscopy of DNA heteroduplexes. These heteroduplexes reveal that the duplication is usually, but not always, carried on the left end of the chromosome. A second duplication phage having two copies of cos, constructed by Feiss &; Campbell (1974), has also been studied by electron microscopy and is found to have a similar property.Unlike most tandem duplication derivatives of phage λ, the mutant studied here is not stable during growth in the absence of generalized recombination, but segregates both the triplication and the parental phage. This verifies that both cos sites are functional. The triplication does not arise as a result of end-to-end aggregation of phage chromosomes or site-specific recombination catalyzed by the chromosome maturation system at cos. It must therefore result from the cutting of mature ι chromosomes from concatemeric replication intermediates. The pattern of cutting observed shows that the λ cohesive ends are not created by a free nuclease acting on unpackaged DNA. The cutting appears to be influenced by the amount of DNA previously packaged into a phage head. A model for λ packaging is presented which explains the results.The duplication phage of Feiss &; Campbell (1974) carries a novel addition containing self-complementary sequences.     

Processing of bacteriophage lambda DNA during its assembly into heads

DNA purified from bacteriophage λ added to a cell-free extract derived from induced λ lysogens can be packaged into infectious phage particles (Kaiser & Masuda, 1973). In this paper the structure of the DNA which is the substrate for in vitro packaging and head assembly is described. The active precursor is a multichromosomal polymer that contains covalently closed cohesive end sites. Neither circular or linear DNA monomers nor polymers with unsealed cohesive ends are packaged efficiently into heads. The unit length monomer is packaged when it is either contained in the interior of a polymer (both of its ends are in cos sites) or when it has a free left end and a cos site on its right. The monomer unit with a free right end is not a substrate for packaging.A procedure is given for the purification of λ DNA fragments that contain either the left or the right cohesive end. The fragments are produced by digesting λ DNA with the site-specific Escherichia coli R₁ endonuclease; the left and right ends are separated by sedimentation through a sucrose gradient. These fragments are used to construct small polymers that have a unit length λ monomer with (1) a free left end and a closed right end, (2) a free right end and a closed left end, or (3) both ends closed in cos sites.     

Initial cos cleavage of bacteriophage lambda concatemers requires proheads and gpFI in vivo

The development of bacteriophage lambda and double-stranded DNA viruses in general involves the convergence of two separate pathways: DNA replication and head assembly. Clearly, packaging will proceed only if an empty capsid shell, the prohead, is present to receive the DNA, but genetic evidence suggests that proheads play another role in the packaging process. For example, lambda phages with an amber mutation in any head gene or in FI, the gene encoding the accessory packaging protein gpFI, are able to produce normal amounts of DNA concatemers but they are not cut, or matured, into unit length chromosomes for packaging. Similar observations have been made for herpes simplex 1 virus. In the case of lambda, a negative model proposes that in the amber phages, unassembled capsid components are inhibitory to maturation, and a positive model suggests that assembled proheads are required for cutting. We tested the negative model by using a deletion mutant devoid of all prohead genes and FI in an in vivo cos cleavage assay; in this deleted phage, the cohesive ends were not cut. When lambda proheads and gpFI were provided in vivo via a second prophage, cutting was restored, and gpFI was required, results that support the positive model. Phage 21 is a sister phage of lambda, and although its capsid proteins share approximately 60% residue identity with lambda's, phage 21 proheads did not restore cutting, even when provided with the accessory protein gpFI. Models for the role of proheads and gpFI in cos cutting are discussed.     

DNA Packaging Specificity of Bacteriophage N15 with an Excursion into the Genetics of a Cohesive End Mismatch

During DNA replication by the λ-like bacteriophages, immature concatemeric DNA is produced by rolling circle replication. The concatemers are processed into mature chromosomes with cohesive ends, and packaged into prohead shells, during virion assembly. Cohesive ends are generated by the viral enzyme terminase, which introduces staggered nicks at cos, an approx. 200 bp-long sequence containing subsites cosQ, cosN and cosB. Interactions of cos subsites of immature concatemeric DNA with terminase orchestrate DNA processing and packaging. To initiate DNA packaging, terminase interacts with cosB and nicks cosN. The cohesive ends of N15 DNA differ from those of λ at 2/12 positions. Genetic experiments show that phages with chromosomes containing mismatched cohesive ends are functional. In at least some infections, the cohesive end mismatch persists through cyclization and replication, so that progeny phages of both allelic types are produced in the infected cell. N15 possesses an asymmetric packaging specificity: N15 DNA is not packaged by phages λ or 21, but surprisingly, N15-specific terminase packages λ DNA. Implications for genetic interactions among λ-like bacteriophages are discussed.     

Electron microscopy study of viral DNA packaging with lambda head mutants

In a previous study, various intermediates in λ DNA packaging were visualized after lysis of λ-infected cells with osmotic shock and sedimentation through a sucrose formalin cushion onto electron microscope grids. Along this line, a systematic screening for intermediates accumulated in all head mutants available was performed. λA^?-infected cells accumulate only empty spherical protein shells (petit λ) bound at an intermediate point along the DNA thread. In situ digestion experiments with restriction endonuclease EcoRI show that the petit λ-DNA complexes are formed at a fixed point on the DNA concatemer. In $\text{λNu1}{}^{\mathrm{?}}\text{-}\text{infected}$ cells, however, most petit λ was not bound to DNA. In Fec^? cells, which are defective in formation of concatemers but normal in head protein synthesis, most petit λ did not sediment onto the carbon film of the grid. In $\text{D}{}^{\mathrm{?}}$ mutant, petit λ, partially full heads and empty heads with released DNA were observed. λFI^?-infected cells also accumulate petit λ and partially full heads. The present studies suggest that protein pNu1 is required for complex formation between head precursors and DNA concatemers, $\text{p}\text{A}$ for the initiation of DNA packaging, $\text{p}\text{D}$ and $\text{p}\text{F}$I for the promotion of DNA packaging, and $\text{p}\text{D}$ for stabilization of head structures. The results obtained with other head mutants involved in formation of mature proheads and head completion confirm earlier results obtained by different techniques.     

Polarized packaging of bacteriophage lambda chromosomes.

Packaging of chromosomes during lytic growth of cohesive end-site (cos site) duplication strains of phage lambda is strikingly asymmetric; the duplication segment is generally at the left chromosome end (Emmons, 1974). In the present study, the packaging of non-replicating cos duplication chromosomes is shown to be similarly asymmetric. It is, therefore, likely that the packaging process itself is polarized, in an A to R direction. This conclusion is based on the study of packaging of repressed prophage chromosomes of dilysogenic strains of Escherichia coli by a heteroimmune helper. In these strains one of the two prophages contains a cos duplication (see Fig. 2). The frequency with which helper-packaged chromosomes carry the cos duplication segment agrees well with expectations derived from lytically grown phage.Haploid segregants are produced from the cos duplication strain at a lower level (35%) during lytic growth than during packaging of repressed prophage chromosomes (50%). This is expected if chromosomes are packaged processively (in sequence) during lytic growth.Packaging of repressed cos triplication chromosomes by a heteroimmune helper also yields a distribution of haploid and duplication chromosomes that agrees with expectations from lytically grown cos duplication phage and the assumption that the initial cutting of a cos site to initiate a packaging sequence is made at random.Polarized, processive packaging and random initial cutting are elements of a model of lambda chromosome packaging proposed by Emmons (1974), for which our experiments provide support.     

Virus DNA packaging: the strategy used by phage λ

Phage λ, like a number of other large DNA bacterio-phages and the herpesviruses, produces concatemeric DNA during DNA replication. The concatemeric DNA is processed to produce unit-length, virion DNA by cutting at specific sites along the concatemer. DNA cutting is coordinated with DNA packaging, the process of translocation of the cut DNA into the preformed capsid precursor, the prohead. A key player in the λ DNA packaging process is the phage-encoded enzyme terminase, which is involved in (i) recognition of the concatemeric λ DNA; (ii) initiation of packaging, which includes the introduction of staggered nicks at cosN to generate the cohesive ends of virion DNA and the binding of the prohead; (iii) DNA packaging, possibly including the ATP-driven DNA translocation; and (iv) following translocation, the cutting of the terminal cosN lo complete DNA packaging. To one side of cosN is the site cosB, which plays a role in the initiation of packaging; along with ATP, cosB stimulates the efficiency and adds fidelity to the endo-nuclease activity of terminase in cutting cosN. cosB is essential for the formation of a post-cleavage complex with terminase, complex I, that binds the prohead, forming a ternary assembly, complex II. Terminase interacts with cosN through its large subunit, gpA, and the small terminase subunit, gpNul, interacts with cosB. Packaging follows complex II formation. cosN is flanked on the other side by the site cosQ, which is needed for termination, but not initiation, of DNA packaging. cosQ is required for cutting of the second cosN, i.e. the cosN at which termination occurs. DNA packaging in λ has aspects that differ from other λ DNA transactions. Unlike the site-specific recombination system of λ, for DNA packaging the initial site-specific protein assemblage gives way to a mobile, translocating complete, and unlike the DNA replication system of λ, the same protein machinery is used for both initiation and translocation during λ DNA packaging.     

The two-disulphide intermediates and the folding pathway of reduced pancreatic trypsin inhibitor.

We have studied bacteriophage λ head assembly under conditions in which the normal pathways for late phage DNA (concatemer) synthesis are blocked, and early (monomeric circular) DNA replication products accumulate. Our results show that under such conditions, the amount of late protein per amount of DNA is normal, but the amount of phage produced is not. Electron microscopic examination of thin sections of these bacteria shows that large numbers of “empty” head-shaped particles are produced. We conclude that the packaging of λ DNA depends on some structure (or property) possessed by DNA concatemers and absent in monomeric circular molecules and that the empty head-shaped particles which accumulate when concatemer production is blocked are head precursors which would normally accept concatemer DNA.These empty particles are the same size (approximately 550 Å vertex-to-vertex diameter) as the electron-dense, DNA-filled particles observed in similar sections of wild-type infected bacteria. In lysates the empty particles are approximately the same size as they are within the bacteria. However, filled heads observed in thin sections (or in negatively stained preparations) of lysates are larger than they are within the bacteria. This observation is contrary to what was previously suspected, since there seems to be little or no change in the size of intracellular λ capsids as a direct consequence of DNA packaging. Instead, an increase in the size of completed phage heads seems to take place as a consequence of cell lysis.     

DNA packaging steps in bacteriophage lambda head assembly

Petit λ is an empty spherical shell of protein which appears wherever λ grows. If phage DNA and petit λ are added to a cell-free extract of induced lysogenic bacteria, then phage particles are formed that contain the DNA and protein from the petit λ. Petit λ is transformed, without dissociation, into a phage head by addition of DNA and more phage proteins.The products of ten genes, nine phage and one host, are required for λ head assembly. Among these, the products of four phage genes, E, B, C, and Nu3 and of the host gene groE are involved in the synthesis of petit λ, consequently these proteins are dispensable for head assembly in extracts to which petit λ has been added. The products of genes A and D allow DNA to combine with petit λ to form a head that has normal morphology. In an extract, DNA can react with A product and petit λ to become partially DNAase-resistant, as if an unstable DNA-filled intermediate were formed. ATP and spermidine are needed at this stage. This intermediate is subsequently stabilized by addition of D product. The data suggest a pathway for head assembly.     

Genetic Variation of Lactobacillus delbrueckii subsp. lactis Bacteriophages Isolated from Cheese Processing Plants in Finland

The genomes of four Lactobacillus delbrueckii subsp. lactis bacteriophages were characterized by restriction endonuclease mapping, Southern hybridization, and heteroduplex analysis. The phages were isolated from different cheese processing plants in Finland between 1950 and 1972. All four phages had a small isometric head and a long noncontractile tail. Two different types of genome (double-stranded DNA) organization existed among the different phages, the pac type and the cos type, corresponding to alternative types of phage DNA packaging. Three phages belonged to the pac type, and a fourth was a cos-type phage. The pac-type phages were genetically closely related. In the genomes of the pac-type phages, three putative insertion/deletions (0.7 to 0.8 kb, 1.0 kb, and 1.5 kb) and one other region (0.9 kb) containing clustered base substitutions were discovered and localized. At the phenotype level, three main differences were observed among the pac-type phages. These concerned two minor structural proteins and the efficiency of phage DNA packaging. The genomes of the pac-type phages showed only weak homology with that of the cos-type phage. Phage-related DNA, probably a defective prophage, was located in the chromosome of the host strain sensitive to the cos-type phage. This DNA exhibited homology under stringent conditions to the pac-type phages.     

Maturation of the head of bacteriophage T4. I. DNA packaging events

Pulse-chase experiments in wild-type and mutant phage-infected cells provide evidence that the following particles called prohead I, II and III are successive precursors to the mature heads. The prohead I particles contain predominantly the precursor protein P23 and possibly P22 (mol. wt 31,000) and IP III (mol. wt 24,000) and have an s value of about 400 S. Concomitantly with the cleavage of most of P23 (mol. wt 55,000) to P231 (mol. wt 45,000), they are rapidly converted into prohead II particles which sediment with about 350 S. The prohead II particles contain, in addition to P231, the major constituents of the viral shella—a core consisting of proteins P22 and IP III. In cell lysates, prohead I and prohead II particles contain no DNA in a DNase-resistant form and are not bound to the replicative DNA. We cannot, however, positively rule out the possibility that these particles may have contained some DNA while in the cells.The prohead II particles are in turn converted into particles which sediment with about 550 S after DNase treatment (prohead III). During this conversion about 50% of normal DNA complement becomes packaged in a DNase-resistant form, and roughly 50% of the core proteins P22 and IP III are cleaved. In lysates the prohead III particles are attached to the replicative DNA. The prohead III particle appears to be the immediate precursor of the full mature head (1100 S). Cleavage of protein P22 to small polypeptides and conversion of IP III IP III1 are completed at this time. No precursor proteins are found in the full heads. Studies with various mutant phage showed that the prohead II to III conversion is blocked by mutations in genes 16 and 17 and that the conversion of the prohead III particles to the mature heads is blocked by mutations in gene 49. Cleavage of the head proteins, however, occurs normally in these mutant-infected cells. We conclude that the cleavage of the major component of the viral shell, P23, into P231 precedes the DNA packaging event, whereas cleavage of the core proteins P22 and IP III appears to be intimately linked to the DNA packaging event. Models relating the cleavage processes to DNA encapsulation are discussed.     

Flow dichroism of capsid DNA phages. II. Effect of DNA deletions and intercalating dyes

The flow linear dichroism of bacteriophage λ and its deletion mutants, λ b2 and λ b221, was determined. The hydrodynamic behavior of the three phages differed slightly, but the magnitude of the dichroism was substantially the same with 〈cos²θ_μp〉 = 0.364, 0.368, and 0.372, respectively. The dichroism of intercalating dyes combined with bacteriophage was used as a further probe of phage structure. The reduced dichroism from proflavin with T4 showed no change with time during the reaction, but the interpretation of the ligand dichroism is complicated by an alteration of the hydrodynamic behavior of the phage–dye complex relative to the phage alone. Ethidium with λ also produced a stable reduced dichroism, but the signal indicated an average orientation of intercalated dye that is different from the average base orientation. The reduced dichroism of ethidium changes with time as it penetrates λ b2, eventually approaching the dichroism of the nucleotide bases. The implication of these findings on the plausibility of various simple DNA packing models is discussed.     

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.     

A functional domain of bacteriophage lambda terminase for prohead binding

Terminase is a multifunctional protein complex involved in DNA packaging during bacteriophage lambda assembly. Terminase is made of gpNul and gpA, the products of the phage lambda Nu1 and A genes. Early during DNA packaging terminase binds to lambda DNA to form a complex called complex I. Terminase is required for the binding of proheads by complex I to form a DNA: terminase: prohead complex known as complex II. Terminase remains associated with the DNA during encapsidation. The other known role for terminase in packaging is the production of staggered nicks in the DNA thereby generating the cohesive ends. Lambdoid phage 21 has cohesive ends identical to those of lambda. The head genes of lambda and 21 show partial sequence homology and are analogous in structure, function and position. The terminases of lambda and 21 are not interchangeable. At least two actions of terminase are involved in this specificity: (1) DNA binding; (2) prohead binding. The 1 and 2 genes at the left end of the 21 chromosome were identified as coding for the 21 terminase. gp1 and gp2 are analogous to gpNu1 and gpA, respectively. We have isolated a phage, lambda-21 hybrid 33, which is the product of a crossover between lambda and 21 within the terminase genes. Lambda-21 hybrid 33 DNA and terminase have phage 21 packaging specificity, as determined by complementation and helper packaging studies. The terminase of lambda-21 hybrid 33 requires lambda proheads for packaging. We have determined the position at which the crossover between lambda DNA and 21 DNA occurred to produce the hybrid phage. Lambda-21 hybrid 33 carries the phage 21 1 gene and a hybrid phage 2/A gene. Sequencing of lambda-21 hybrid 33 DNA shows that it encodes a protein that is homologous at the carboxy terminus with the 38 amino acids of the carboxy terminus of lambda gpA; the remainder of the protein is homologous to gp2. The results of these studies define a specificity domain for prohead binding at the carboxy terminus of gpA.     

Synthesis of a trans-Acting Inhibitor of DNA Maturation by Prohead Mutants of Phage λ

Bacteriophage lambda with mutations in genes that control prohead assembly and other head precursors cannot mature their DNA. In this paper we present evidence that the failure of these phage mutants to mature DNA is a reflection of a mechanism that modulates terminase nicking activity during normal phage development. We have constructed plasmids that contain the lambda-cohesive end site (cos) and the genes that code for DNA terminase, the enzyme that matures DNA by cutting at cos. The DNA terminase genes are under control of a thermosensitive cI repressor. These plasmids lack most of the genes involved in prohead morphogenesis and other head precursors. However, when repression is lifted by destruction of the thermosensitive repressor, the terminase synthesized is able to cut almost 100% of the plasmids. Therefore, these plasmids can mature in the absence of proheads and other head gene products. The plasmids are also able to complement mutants of lambda deficient in terminase and DNA maturation. However, in these complementation experiments, if the phage carry mutations in prohead genes E or B, not only is phage DNA maturation blocked, but the plasmid also fails to mature. These experiments show that, in the absence of proheads, phage lambda produces a trans-acting inhibitor of maturation. The genetic determinant of this inhibitor maps in a region extending from the middle of gene B to the end of gene C. A model is proposed in which the nicking activity of DNA-bound terminase is inhibited by the trans-acting inhibitor. Prohead (and other factors) binding to this complex would release the block to allow DNA cleavage and packaging.     

Sequencing and analysis of the cos region of the lactococcal bacteriophage c2

The cohesive termini of the DNA genome of the lactococcal bacteriophage c2 were directly sequenced and appeared to be complementary, non-symmetrical, 9-nucleotide single-stranded, 3′ extended DNAs, with the following sequence: 5′-GTTAGGCTT-3′ 3′-CAATCCGAA-5′. DNA located on either side of the cohesive ends was sequenced and several repeats and a region with the potential for a DNA bend were found. Previously sequenced cos regions of 13 other bacteriophages were also examined for similar sequence features. All of the bacteriophages from gram-positive hosts had 3′ extended DNA termini, in contrast to the bacteriophages from gram-negative hosts, which had 5′ extended DNA termini. All bacteriophages had a region of dyad symmetry close to the cohesive termini. A 7.3 kb DNA fragment of the c2 genome containing the cos sequences was cloned; transduction experiments demonstrated that these cloned sequences could act as a substrate for packaging enzymes of phage c2.     

Isolation and structure of phage lambda head-mutant DNA

High molecular weight DNA accumulates in bacteria in which λ is multiplying but cannot complete the formation of new phage particles due to a defect in head assembly. Accumulated λ DNA has been isolated from induced mitomycin C-treated lysogens by means of a shift in buoyant density labels from heavy to light and fractionation by density-gradient sedimentation for completely light DNA. Head formation was blocked in these lysogens by amber mutations in genes D or E, which specify the two major head proteins. The purified DNA is at least 80% λ by DNA-DNA hybridization and some preparations are close to 100% λ by this test.     

Morphogenesis of bacteriophage lambda deletion mutants. I. Abnormal head-related structures produced in normal Escherichia coli.

Late in the morphogenesis of bacteriophage lambda, DNA condenses into the nascent head and is cut from a concatemeric replicative intermediate by a nucleolytic function, Ter, acting at specific sites, called cos. As a result of this process, heads of lambda deletion mutants contain less DNA than those of the wild-type phage. It has been reported that phage with very large deletions (22% of the genome or more) grow poorly but that normal growth can be restored by the non-specific addition of DNA to the genome. This finding implies that DNA content may exert a physical effect on some stage of head assembly.We have investigated the effects of two long deletions, b221 and tdel33, on head assembly. Bacteria infected with the mutants were lysed with non-ionic detergent under conditions favoring stabilization of labile structures containing condensed DNA. It has proved possible to isolate two aberrant head-related structures produced by the deletion mutants. One of these (“overfilled heads”) contains DNA which is longer than the deletion mutant genome and is about the same size as that found in wild-type heads. These structures appear to be unable to attach tails. The second type of structure (“incompletely filled heads”) contains a short piece of DNA, 40% of the length of the mutant genome. The incompletely filled heads are found both with and without attached tails. Both of these abnormal structures are initially attached to the replicating DNA but are released by treatment with DNAase. The nature of these abnormal structures indicates that very small genomes affect a late stage of head morphogenesis, after the DNA is complexed with a capsid of normal size. The results presented suggest that underfilling of the capsid interferes with the ability of the Ter function to properly cleave cos.     

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.