Yet another way that phage λ manipulates its Escherichia coli host: λrexB is involved in the lysogenic–lytic switch

The life cycle of phage λ has been studied extensively. Of particular interest has been the process leading to the decision of the phage to switch from lysogenic to lytic cycle. The principal participant in this process is the λcI repressor, which is cleaved under conditions of DNA damage. Cleaved λcI no longer acts as a repressor, allowing phage λ to switch from its lysogenic to lytic cycle. The well‐known mechanism responsible for λcI cleavage is the SOS response. We have recently reported that the Escherichia coli toxin‐antitoxin mazEF pathway inhibits the SOS response; in fact, the SOS response is permitted only in E. coli strains deficient in the expression of the mazEF pathway. Moreover, in strains lysogenic for prophage λ, the SOS response is enabled by the presence of λrexB. λRexB had previously been found to inhibit the degradation of the antitoxin MazE, thereby preventing the toxic action of MazF. Thus, phage λ rexB gene not only safeguards the prophage state by preventing death of its E. coli host but is also indirectly involved in the lysogenic–lytic switch.     

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.     

Salt-concentration dependence of melting profiles of lambda phage DNAs: evidence for long-range interactions and pronounced end effects.

Melting profiles of DNAs from wild-type λ phage and a deletion mutant phage λb2 were examined in a wide range of salt concentration. The fine structure of the melting profiles changed sharply with salt concentration, especially in the range [Na⁺] ? 10 mM. A comparison of the melting profiles between the wild-type and the deletion mutant DNAs provided good evidence for extremely high melting cooperativity under low salt conditions, which is clearly manifested as the long-range interactions and the pronounced end effects; a large melting peak appeared as a result of the b2 deletion without any inserted sequence in the salt range [Na⁺] ? 2.8 mM. It was also suggested that in the further reduced salt range [Na⁺] ? 2.0 mM, melting of a λ DNA molecule starts from its right end rather than the most (A + T)-rich central region. The molecular basis of the high melting cooperativity at low salt concentrations can be explained in terms of the increased free energy associated with loop formation in the double-helical structure of DNA.     

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.     

Synthesis of coliphage lambda proteins in minicells as a possible tool for the identification of lambda early gene products.

Chromosome-less minicells of Escherichia coli harboring the plasmid λdv, mini [λdv] synthesize several proteins specified by this fragment of the “early” λ DNA region, as shown by ¹⁴C-labeling, gel electrophoresis and autoradiography. Mini[λdv] infected with phage λ reveal a much more composite protein profile. This profile originating from the system composed entirely of λ genes is very similar to that produced by λ-infected mini[ColE1] indicating that the latter may be used for the identification of λ gene products.     

Cellular levels of the prophage lambda and 434 repressors.

As a prerequisite to a quantitative study of the inactivation of phage repressors in vivo (Bailone et al., 1979), the cellular concentrations of the bacteriophage λ and 434 repressors have been measured in bacteria with varying repressor levels.Using the DNA-binding assay we have determined the conditions for optimal repressor titration. The sensitivity of the λ repressor assay was increased by adding magnesium ions to the binding mixture; this procedure was without effect on the titration of the 434 repressor. The measures of the cellular repressor concentrations varied with the method of cell disruption.The cellular concentration of λ repressor, about 140 active repressor molecules per monolysogen, was relatively constant under specific cultural conditions. The repressor concentration increased with the number of cI gene copies but not in direct proportion.The 434 repressor concentration, hardly detectable in extracts of lysogens carrying an imm434 prophage, was greatly enhanced in bacteria carrying the newly constructed plasmid pGY101, that encodes the 434 cI gene.The cellular repressor level produced by 434 is lower than that produced by λ: this indicates that the maintenance of the prophage state is ensured by a relatively small number of repressor molecules binding tightly to the operator sites.     

The int genes of bacteriophages P22 and λ are regulated by different mechanisms

Bacteriophage P22 and λ are related bacteriophages with similar gene organizations. In λ the cII-dependent P_I promoter is responsible for λint gene expression. The only apparent counterpart to P_I in P22 is oriented in the opposite direction, and cannot transcribe the P22 int gene. We show that this promoter, called P_al, is active both in vivo and in vitro, and is dependent upon the P22 cII-like gene, called c1. We have also determined the DNA sequence of a 3.3 kb segment that closes the gap between previously reported sequences to give a continuous sequence between the P22 p_L promoter and the int gene. The newly determined sequence is densely packed with genes from the p_L direction, and the proteins predicted by the sequence show excellent correlation with the proteins mapped by Youderian and Susskind in 1980. However, the sequence contains no apparent genes in the opposite (p_al) direction, and no additional binding motifs for the P22 c1 protein. We conclude that int gene expression in P22 is regulated by a different mechanism than in λ.     

Distribution of SCEs in lymphocytes in persons with normal,slightly increased,and heavily increased SCEs

The distribution of SCEs in lymphocytes was examined for 165 healthy persons (58 non-smokers and 107 smokers with cigarette consumption ranging from 1 to > 20 per day), and for 1 patient treated with melphalan, a cytostatic drug.The data from the healthy persons did not follow a Poisson distribution. A mixed Poisson that allowed diferent λ values for the 30 cells scored from each person and postulated a gamma distribution for the λs within the 30 cells fitted all the data examined including those from the melphalan-treated patient. In the latter case the 7 samples taken at various times after the treatment could all be represented satisfactorily with a common parameter, c, in the gamma distribution for the λs, even though the mean SCEs/cell varied from 9.8 to 36.8. Because the c parameter determines the spread of λ values within the 30 cells, this suggested that the effect ofthe cytostatic drug was to increase all the σs by a constant amount.The sum of the SCEs taken over all 30 cells in a sample is a convenient summary statistic, and the transformation y = √s + √s + 1 behaves as a normal variate with a constant variance within a group.     

Organization of ribosomal protein genes in Escherichia coli: I. Physical structure of DNA from transducing λ phages carrying genes from the aroE-str region

The physical structures of the genomes of five transducing bacteriophages (λaroE, λtrkA, λspc1, λspc2, and λfus2) carrying various portions of the aroE-trkA-spc-str segment of the Escherichia coli chromosome have been determined. Two methods were used: (a) heteroduplex analysis of DNA molecules from these phages, and (b) analysis of fragments obtained from digestion of the DNA by restriction endonucleases EcoRI and HindIII. In λaroE, λtrkA, λspc1 and λspc2, whose genome lengths vary from about 75% to about 104% of the λpapa genome, the right arm of λ DNA is present, whereas various portions of the left arm have been replaced by E. coli DNA. In λfus2, however, about 93% of the λ DNA molecule is replaced by E. coli DNA, the resultant genome being 103.5 %λ units long (Figs 1 and 2). All five phages contain an identical λ-E. coli junction at 1.9 %λ units from the left λ terminus, and there is complete homology between the common portions of the inserted E. coli DNA. Since these phages were independently isolated, we believe that the genetic organization of the E. coli DNA carried by these phages probably reflects the organization of the relevant segments of the E. coli chromosome. Comparison of the physical and genetic maps of these transducing phages has allowed us to assign a physical position to the ribosomal and neighbouring genes, including those coding for the α subunit of RNA polymerase and the elongation factors G and Tu, on the bacterial DNA.     

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.     

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.     

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.     

Prophage lambda at unusual chromosomal locations. II. Mutations induced by bacteriophage lambda in Escherichia coli K12

An Escherichia coli strain deleted for the primary λ attachment site was lysogenized with λ at secondary sites. Some lysogens became mutants because of prophage insertion in the affected gene. Mutagenesis by phage λ is not random with respect to the gene affected: most mutants were pro, although certain other genes could be mutated at lower frequencies. In the case of several independent ilv and gal mutants, the sites of prophage insertion were in the same segment of the ilv region and galT gene respectively. The galT location may also be a preferred site for the insertion of DNAs other than prophage λ. Insertion of prophage λ within an operon can reduce the expression of operator-distal genes. A trpC λ insertion mutant expresses the operator-distal trpB function constitutively at a low level. This expression probably derives from a promoter located in the left arm of the prophage.     

Identification of Critical Residues for the Tight Binding of Both Correct and Incorrect Nucleotides to Human DNA Polymerase λ

DNA polymerase λ (Pol λ) is a novel X-family DNA polymerase that shares 34% sequence identity with DNA polymerase β. Pre-steady-state kinetic studies have shown that the Pol λ-DNA complex binds both correct and incorrect nucleotides 130-fold tighter, on average, than the DNA polymerase β-DNA complex, although the base substitution fidelity of both polymerases is 10^− 4 to 10^− 5. To better understand Pol λ's tight nucleotide binding affinity, we created single-substitution and double-substitution mutants of Pol λ to disrupt the interactions between active-site residues and an incoming nucleotide or a template base. Single-turnover kinetic assays showed that Pol λ binds to an incoming nucleotide via cooperative interactions with active-site residues (R386, R420, K422, Y505, F506, A510, and R514). Disrupting protein interactions with an incoming correct or incorrect nucleotide impacted binding to each of the common structural moieties in the following order: triphosphate ? base > ribose. In addition, the loss of Watson-Crick hydrogen bonding between the nucleotide and the template base led to a moderate increase in K_d. The fidelity of Pol λ was maintained predominantly by a single residue, R517, which has minor groove interactions with the DNA template.     

Bacteriophage host range evolution through engineered enrichment bias,exploiting heterologous surface receptor expression

Research on the initial phage–host interaction has been conducted on a limited repertoire of phages and their cognate receptors, such as phage λ and the Escherichia coli LamB (EcLamB) protein. Apart from phage λ, little is known about other phages that target EcLamB. Here, we developed a simple method for isolating novel environmental phages in a predictable way, i.e. isolating phages that target a particular receptor(s) of a bacterium, in this case, the EcLamB protein. A plasmid (pMUT13) encoding the EcLamB porin was transferred into three different enterobacterial genera. By enrichment with these engineered bacteria, a number of phages (ZZ phages) that targeted EcLamB were easily isolated from the environment. Interestingly, although EcLamB-dependent in their recombinant heterologous hosts, these newly isolated ZZ phages also targeted OmpC as an alternative receptor when infecting E. coli. Moreover, the phage host range was readily extended within three different bacterial genera with heterologously expressed EcLamB. Unlike phage λ, which is a member of the Siphoviridae family, these newly isolated EcLamB-dependent phages were more commonly members of the Myoviridae family, based on transmission electron microscopy and genomic sequences. Modifications of this convenient and efficient phage enrichment method could be useful for the discovery of novel phages.     

Kinetics of RecA protein-directed inactivation of repressors of phage lambda and phage P22

Escherichia coli recA protein directs the inactivation of the repressor of Salmonella typhimurium phage P22 in vitro. As is true for repressor of the E. coli phage λ, inactivation of P22 repressor is accompanied by proteolytic cleavage of the repressor into two detectable fragments.We have investigated the kinetics of inactivation of the λ and P22 repressors in vitro. The fraction of λ repressor inactivated per unit time decreases as its concentration in the reaction is increased. However, high concentrations of λ repressor do not inhibit the inactivation of P22 repressor. Thus, it does not appear that the inactivation system is saturated by λ repressor, but rather that λ repressor is a less efficient substrate at higher concentrations.     

Infection of Escherichia coli envelope-membrane complex with lambda phage: adsorption and penetration

Adsorption and penetration, the first two steps in the life cycle of bacteriophage λ, were examined in vitro. As hosts for λ infection, the envelope and the cytoplasmic membrane, isolated from Escherichia coli K12 bacteria, were used. Lambda phage was found to adsorb and to inject its genetic material into the envelope-membrane complex, provided the envelope had been isolated from λ-sensitive cells; for the cytoplasmic membrane it is irrelevant whether it originates from λ-sensitive or from λ-resistant bacteria. No adsorption was found if either the envelope or the cytoplasmic membrane was separately infected. Following adsorption, λ DNA is rendered accessible to the hydrolytic action of DNase during the first six minutes. After that lambda DNA becomes DNase resistant. In this state it is found associated with the envelope-membrane complex.     

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.