Protein synthesis induced by infection with packaged lambda dv plasmid

Plasmid λdv or imm²¹dv DNA was joined to a λ arm having a cos site. This recombinant plasmid can be packaged in a λ head, and used to infect Escherichia coli K12 cells. The injected DNA molecules become plasmids in cells. By adding these particles to uv-irradiated uvrA cells, the packageable λdv or imm²¹dv plasmids can be induced to synthesize proteins coded by genes on the plasmid genome. The packageable plasmid system is thus suitable for studying on synthesis and regulation of plasmid-coded biopolymers. Analyses of the dv-coded proteins in gel electrophoreses revealed that among several genes carried on the dv plasmid genome, only those genes that are members of the pRoR-tof-cII-O-P operon can be expressed. Evidence has been presented to show that expression of this operon, which is directly correlated with replication of the genome, is only partially allowed in cells perpetuating the dv plasmid. These observations are discussed in connection with the autorepressor model (D. E. Berg, 1974, Virology62, 224–233; K. Matsubara, 1976, J. Mol. Biol.102, 427–439) that genetically accounts for the control mechanism of plasmid replication.     

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.     

Tn903 induces inverted duplications in the chromosome of bacteriophage lambda

Specialized transducing strains of bacteriophage lambda have been isolated that carry the transposable kanamycin resistance element, Tn903. Tn903 carries an inverted duplication of 1130 base-pairs flanking the kanamycin resistance gene. Often, when λ::Tn903 particles are infected into bacterial cells, the lambda chromosome is rearranged into a defective lambda plasmid which replicates with the bacterial cell. The formation of the defective plasmids (called Tn903λdv) is most likely induced by the Tn903 insertion itself. This follows from the fact that the novel DNA sequence found in these plasmids, with respect to the ancestral λTn903 chromosome, is always adjacent to the Tn903 element. Physical chromosomal mapping of these plasmids shows that they contain large inverted duplications of lambda sequences situated about the Tn903 insertion. The formation of the Tn903λdv plasmids from the ancestral λTn903 is not dependent on the recombination functions provided through the phage red gene or the host recA gene.     

Mutations in the right operator of bacteriophage lambda: physiological effects

The right operator in bacteriophage lambda vs326 has one-twentieth the in vitro binding affinity for repressor as λv⁺; for comparison λv3 has one-quarter the affinity of λv⁺. In vivo, both mutants constitutively express genes in the right operon. Both λv3 and λvs326 express gene O constitutively because they complement λimm434Oam^? in a λ lysogen, vs, more efficiently than v3. The v3 allele in cis (but not in trans) to vs326 gives significantly greater phage yields in a λ lysogen than λvs326 alone, cro gene function, measured by arrest of exonuclease synthesis, suggested the following series of increasing degree of conatitutivity: v3, vs326, v3 vs326. λv2 vs326 forms plaques on lysogens that carry λcI857, but λv2 v3 does not. These results indicate that vs326, like v3, is an operator constitutive mutation but stronger in its effects. These mutants exemplify a uniform correlation between relative weakness of repressor binding and degree of constitutive gene expression.     

Altered arrangement of the DNA in injection-defective lambda bacteriophage.

We have characterized two variant bacteriophage λ particles, λZ^? and λdocL, that have low infectivity but normal morphology. The low infectivity is due, at least in part, to a defect in DNA injection. This defect is probably the result of an altered location of the right end of the chromosome with respect to the phage tail: the right end of λZ^? and λdocL DNA, in contrast to that of wild-type λ, cannot be cross-linked to the tail. The cross-linking experiments were greatly facilitated by a new technique that allows routine spreading of DNA for electron microscopy without the use of a protein film.We propose that the Z gene product, a tail protein, acts by recognizing a specific feature near the right terminus of the DNA and promoting its insertion into the tail. This feature is presumably missing in most λdocL particles.     

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.     

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.     

Mechanism of potent mutagenic action of N-methyl-N'-nitro-N-nitrosoguanidine on intracellular phage lambda.

N-Methyl-N′-nitro-N-nitrosoguanidine efficiently induces mutations from “clear” to “virulent” in phage λ only during the intracellular growth phase. Lambda DNA extracted from infected bacteria after treatment with MNNG³ produced a mutant yield about 100-fold higher than the spontaneous level upon transfection of MNNG-treated spheroplast cells, whereas the yield diminished an order of magnitude when assayed on untreated spheroplasts. As measured by ¹⁴C incorporation after treatment with [methyl-¹⁴C]MNNG, λ DNA packed in head protein was methylated to about 3% by an MNNG dose of 0.6 mg/ml but was barely mutagenised; whereas intracellular λ DNA was methylated to no more than 0.6% by an MNNG dose of 0.09 mg/ml and was highly mutagenised. Lambda phages treated in vitro with ethyl methanesulfonate produced a rather low mutant yield on untreated cells but the yield increased about tenfold on MNNG-treated cells. Mutability of untreated λ on cells having received an F′ factor was enhanced efficiently by ultraviolet light, but not so by MNNG, previously applied to the F′. Surprisingly similar MNNG dose-effect curves exist for enhancing spontaneous, mispairing (MNNG or EMS induced) and misrepair (ultraviolet light induced) mutagenesis of λ. From these and other data we conclude that MNNG hypermutagenesis results from a synergistic increase in mispairing probability of appropriately methylated bases (by action of MNNG in vivo) in the target gene within an MNNG-induced intracellular environment that has an enhanced mutagenic capacity.     

Mutations in the right operator of bacteriophage lambda: evidence for operator-promoter interpenetration

A set of virulent mutants of bacteriophage lambda have been selected from λv2 v3. The sites of mutation form two microclusters, both close to v3. Some of the mutants, selected for their ability to grow on a λ-lysogen, can also grow on a λdv carrier strain. They are called “supervirulent” and a mutation conferring super-virulence is called vs. The sites of mutation to vs lie between the presumed promoter mutants (x3, x7) and x13, implying that the operator and promoter interpenetrate each other. The relative affinities of λ repressor for binding, in vitro, to λv⁺, λv3, λvs326, and λv3 vs327 DNA were 1, $\text{1}\text{4}$, $\text{1}\text{20}$, and $\text{1}\text{4000}$, respectively. We suggest that two separate mutations in the right operator are needed to confer virulence because promoter sites lie within the operator.     

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.     

Synthesis and decay of lambda DNA replication proteins in minicells

The coliphage λ DNA replication proteins, the $\text{O}$- and $\text{P}$-gene products, have been identified by infection of nonpermissive $\text{Escherichia coli}$ minicells with the appropriate λ amber mutants as proteins of a molecular weight of about 34000 and 23000, respectively. Proteins of exactly the same size were found in minicells harbouring the plasmid $\text{λ}\text{dv}$. Both proteins seem to be synthesized at the same rate. In λ-infected minicells, as well as in $\text{lambda;}\text{dv}$-harbouring minicells the pulse-and-chase experiments have shown an exceptionally rapid decay of the O-protein.     

Bacteriophage lambda DNA maturation. The functional relationships among the products of genes Nul, A and FI

The FI gene of bacteriophage λ functions in head assembly, but its exact role is not well understood. FI mutants are leaky, producing between 0.1 and 0.5 viable particles per infected cell. In order to investigate the function of the FI product (gpFI) in vivo, mutants of λ were isolated that are able to grow in the absence of gpFI. These mutants, called fin (for FI independence) map in the region of gene Nul and the beginning of gene A.Proteins made in cells infected with the fin mutants were labelled with [³⁵S]methionine and analysed by polyacrylamide gel electrophoresis. In addition, the levels of activity of the A product were measured in the in vitro DNA packaging assay. As a result of these experiments, the fin mutants can be classified in two groups. Upon infection, fin mutants of one group selectively produce three to fivefold more gpA than do wild-type phage fin mutants of the second group do not overproduce any λ late gene product detectable by the autoradiographic technique.gpA overproducers can also be isolated by selecting for λAam Wam phages that can plate on a weak suII cell strain. The mutation responsible for this pseudoreversion is called Aop and maps in the Nu1-A region. Aop is also a fin mutation, since its presence in λFI^? enables it to plate on non-permissive hosts.Therefore, it seems that one condition sufficient for normal growth of FI^? phage is the overproduction of gpA. The nature of the fin mutations that do not result in gpA overproduction is discussed.     

Characterization of the deoxyribonuclease determined by lambda reverse as exonuclease VIII of Escherichia coli.

Gottesman et al. (1974) detected a new DNAase in Escherichia coli infected with λ reverse, a recombination-proficient substitution mutant of phage λ which is deleted for the λ recombination genes. We have purified this enzyme, using the procedure developed for the purification of exonuclease VIII (Kushner et al., 1974), a DNAase produced by E. coli K-12 strains carrying sbcA^? mutations. The λ reverse exonuclease (Exoλrev) is identical to exonuclease VIII by several criteria. The two enzymes elute at similar salt concentrations from DEAE-cellulose and DNA-cellulose; sediment at the same velocity in glycerol gradients, corresponding to a molecular weight of about 1.4 × 10⁵; migrate at the same R_F in sodium dodecyl sulfate/polyacrylamide gels, indicating a polypeptide molecular weight of 1.4 × 10⁵; exhibit maximum activity at 20 mm-Mg²⁺ and pH 8 to 9; and are much more active on double-stranded DNA than on heat-denatured DNA. Both enzymes are rendered sedimentable by antiserum against Exoλrev. This evidence supports the hypothesis that the non-λ DNA substitution in λ reverse includes recE, the structural gene for exonuclease VIII.     

Construction of various bacteriophage λ mutants for stable and efficient production of recombinant protein in Escherichia coli

Three λ mutants were constructed based on the Q⁻ mutant in order to enhance their productivity and stability in an Escherichia coli/bacteriophage λ system. The newly constructed bacteriophage mutants named λSNU1, λSNU2, and λSNU3 were Q⁻S⁻, Q⁻W⁻E⁻, and Q⁻S⁻W⁻E⁻ mutants, respectively. Compared to all of the mutants, λSNU1 turned out to be the best with regards to higher protein expression and better genetic stability. Mechanisms by which these attributes are achieved have been discussed. The high productivity of P90c/λSNU1 for the recombinant protein was due to the high copy number of λ DNA and high translational efficiency. This mutant phage λSNU1 can be used to provide a high level of stability and productivity of the cloned gene particularly for long-term continuous operation.     

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.