Properties of a mutant of Escherichia coli defective in bacteriophage lambda head formation (groE). II. The propagation of phage lambda

In the accompanying paper (Sternberg, 1973) the properties of three independently isolated strains of Escherichia coli with groE mutations (NS-1, NS-2 and NS-3) have been characterized. In this report the ability of these strains to propagate phage λ is examined in greater detail. In the temperature -sensitive groE strain NS-1, all early phage functions tested (curing, infective center formation, DNA synthesis and early messenger RNA synthesis) are expressed normally. In addition, two late phage functions (late mRNA synthesis and tail formation) are also expressed normally, and a third, phage-induced cell lysis, is expressed with only a slight delay. Based upon head-tail in vitro complementation assays, however, λ fails to make any functional heads at elevated temperatures (41 °C) in this host. Electron microscopic studies of strain NS-1 defective lysates indicate that aberrant head-like forms, including tubular forms and “monsters,” are made.Mutants of λ, designated λEP, which are able to grow in the three groE strains, have been isolated. An analysis of these mutants indicates that at least some carry a mutation in λ head gene E and these make reduced levels of active gene E protein in groE hosts.A further study of all known λ head genes indicates that it is the interaction between the gene E protein and the proteins specified by head genes B and C that is adversely affected by the groE mutation. Presumably, the relative level of gene E protein is too high in groE strains for proper head formation. The λEP mutation compensates for this effect by reducing the level of this protein, and so restoring a balance.     

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.     

Evidence for sequence preferences in the intercalative binding of ethidium bromide to dinucleoside monophosphates.

The rate of production of tandem duplications in phage λ has been measured in the presence and absence of known recombination systems. Two deletion phages have been used: tdel33, a deletion derivative of a φ80-λ hybrid phage, and λb221, which carries a large deletion of the central portion of the λ chromosome. Both phages are int⁻, and tdel33 is also red⁻, by virtue of their deletions. Stocks of these phages can be prepared free of long tandem duplication derivatives by CsCl density gradient purification. After a single cycle of lytic growth, lysates from these purified phage stocks contain tandem duplications at a frequency of 10⁻³ in the case of tdel33 and 10⁻⁵ in the case of λb221. These frequencies are unaffected by the presence of mutations in the host Rec system or the phage Red system. To investigate the difference in duplication frequency between tdel33 and λb221, the phages were grown in mixed infection. The result indicates that a trans-active product of tdel33 is responsible for its high frequency of duplication production.Tandem duplications have been detected by banding the phage lysates in CsCl density gradients. Long DNA addition mutants can be detected in this way if they arise with a frequency of at least 10⁻⁵ and if the duplication length is at least 0.14 λ lengths. To accomplish this it is necessary to distinguish them from contaminating parental phage and from dense phages with aberrant structures which arise at roughly comparable frequencies. The former can be done by rebanding and the latter by growth and rebanding. To distinguish these types we have also made use of a new mutant of Escherichia coli which does not plate λ deletion phages. All of the DNA addition mutants we have detected in this way are tandem duplications; evidently mutants with long insertions arise more rarely.     

A novel assay for illegitimate recombination in Escherichia coli: Stimulation of λbio transducing phage formation by ultra-violet light and its independence from RecA function

We developed a novel assay system for illegitimate recombination, in which the frequency of the formation of λ Spi⁻ phages formed during prophage induction was measured with an E. coli P2 lysogen as the indicator bacteria. Since almost all of the λ Spi⁻ phages thus detected contain attR, they have essentially the same structures as λbio transducing phages, indicating that this assay system enables us to detect specialized transducing phages that produce heterogenote transductants, thus ignoring the occurrences of docL and docR particles which carry only one cohesive end. The following results on the formation of specialized transducing phages have been obtained by this assay system to date. (1) Irradiation with UV light greatly enhanced the formation of λ Spi⁻ phages. (2) Treatments with other DNA-damaging agents also enhanced the formation of λ Spi⁻ phages. (3) Illegitimate recombination during prophage induction does not require the RecA function, indicating that enhancement of λ Spi⁻ phage formation is not controlled by the SOS regulatory system. (4) Preliminary results suggested that DNA gyrase is involved in the formation of λ Spi⁻ phage during prophage induction. Since the above results were consistent with most of the previous observations on the illegitimate recombination in other systems, the Spi⁻ assay system can provide important clues to the mechanism of illegitimate recombination.     

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.     

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.     

Expression of the phage λ recombination genes exo and bet under lacPO control on a multi-copy plasmid

The bacteriophage λ genes exo and bet, whose products (λ exonuclease and β protein, respectively; Red phenotype) mediate homologous recombination of λ phages, have been cloned under lacPOlacI^q control on multi-copy plasmids. Induction of recA3 cells harboring these plasmids with isopropylthiogalactoside (IPTG) resulted in λ exonuclease levels (assayed in vitro) that were proportional to the time of induction (for at least 4 h); recombination of λ Red^? phages in vivo was similarly inducible. Only one out of 25 bet^Δ plasmids (constructed by a variety of in vitro techniques) expressed λ exonuclease, a result consistent with the polarity of several known phage bet mutations. A general method for transferring phage exo and bet mutations to plasmids was devised and plasmids bearing polar (bet3) and nonpolar (bet113) mutations were constructed. Mutant derivatives of the plasmid showed the same complementation pattern as analogous phage red mutants. When λbet3 phages (Exo^?Bet^?) infected IPTG-induced recA3 bacteria containing exo⁺bet⁺ plasmids, recombination frequencies were no more than twice those typical for infection of plasmid-free recA3 cells with exo⁺bet⁺ phages, even in the case of IPTG induction sufficient to elevate the production of λ exonuclease about 100-fold. Even when plasmid induction was delayed till as late as 50 min after infection, recombination was significant. Preliminary experiments suggest that these plasmids encode a polypeptide with Gam activity that corresponds to the 98-amino acid “shorter” open reading frame assigned to gam by Sanger et al.     

Streptomyces lividans 66 contains a gene for phage resistance which is similar to the phage λea59 endonuclease gene

The DNA of wild-type Streptomyces lividans 66 is degraded during electrophoresis in buffers containing traces of ferrous iron. S. lividans ZX1, a mutant selected for resistance to DNA degradation, simuiltaneously became sensitive to φHAU3, a wide-host-range temperate bacteriophage. A DNA fragment conferring φHAU3 resistance was cloned; it contains a phage resistance gene whose deduced amino acid sequence is similar to the phage λ Ea59 endonuclease. The S. lividansφHAU3 resistance does not seem to be a classical restriction-modification system, because no host-modified phages able to propagate on the wild-type strain could be isolated. The cloned fragment did not make the host DNA prone to degradation during electrophoresis, indicating that the two phenotypes are controlled by different genes which were deleted together from the chromosome of ZX1.     

Repression by the cI protein of phage λ: in vitro inhibition of RNA synthesis

We have studied the in vitro repression of RNA synthesis by the cI protein of phage λ. We find that highly purified cI protein is an effective and specific repressor of RNA synthesis from the early gene region of λ DNA. Under optimal conditions at least 95% of the early gene RNA synthesis is repressed and this repression is eliminated or severely impaired by the use of λ DNA-carrying operator-type mutations which reduce the binding affinity of the cI protein. Highly effective repression can be demonstrated only through the use of the initiation-inhibitor rifampicin, which presumably, selects “properly” initiated RNA chains; thus we can by-pass in vitro but not yet solve the problem of how the host polymerase initiates specifically in vivo from the immediate-early promoter sites.     

Isolation and Properties of Escherichia coli Mutants Which Are Nonpermissive for the Growth of Phage Lambda

By selecting survivors of λ phage infection, mutants of Escherichia coli K12 that block reproduction cycle of the phage have been isolated. Fourteen of these phage-tolerant mutants (lam mutants) were chosen and characterized biochemically and genetically. It was shown that these mutants were tolerant to infection by all the lambdoid phages, except for few cases, but they were susceptible to infection by a non-lambdoid temperate phage (φ299), P1 or T phages. The mutants can be divided into at least three groups: (1) A mutant (lam 16) strain that seems to block normal penetration of phage DNA: (2) Three mutant (lam 64, lam 67 and lam 71) strains that block an “early” step(s) of phage growth, including phage DNA synthesis: (3) Six mutant (lam 24, lam 25, lam 26, lam 27, lam 646 and lam 6) strains that block normal functioning of the gene E products and produce unusual head structures. Some lambdoid phages and λ mutants that overcome the interference by the lam mutations have been obtained, and were used as tools for characterizing the host mutations. Two (lam 12 and lam 13) mutant strains and one (lam 1) mutant were inferred as affecting the expression of “late” genes, and early gene, respectively, by this test.     

Expression of ultraviolet-induced restriction alleviation in Escherichia coli K-12. Detection of a λ phage fraction with a retarded mode of DNA injection

Ultraviolet-induced restriction alleviation is an SOS function which partially relieves the K-12-specific DNA restriction in Escherichia coli. Restriction alleviation is determined by observing elevated survival of unmodified phage λ in cells irradiated with ultraviolet prior to infection. We demonstrate that restriction of λ is also relieved when log-phase cells are irradiated as late as 50 min after adsorption of λ. At this time more than 60% of the λ DNA is already released as acid-soluble material from the cells. Experiments involving reextraction of λ DNA from infected cells and a mild detergent treatment removing adsorbed phages from the cellular surface showed that only a small specific fraction of all λ infections is destined to escape restriction due to restriction alleviation. This fraction (10–20%) has a retarded mode of DNA injection (60 min or longer) after adsorption which allows the expression of the restriction alleviation function before the phage DNA is exposed to restriction endonucleases. This behaviour of a fraction of λ phages explains why the SOS function restriction alleviation could initially be discovered. We show that the retarded mode of DNA injection is not required for another SOS function acting on λ DNA, the increased repair of ultraviolet-irradiated DNA (Weigle reactivation).     

Analysis of the dnaB function of Escherichia coli K12 and the dnaB-like function of P1 prophage

The dnaB function of Escherichia coli K12 was studied with a series of isogenic strains differing from each other only by a mutation in the dnaB gene. The strains showed different phenotypes depending on the particular dnaB mutation they carry. A clear example is provided by a strain carrying dnaB266 mutation which turned out to be an amber mutation. When the mutation was suppressed by different suppressors, the strains showed different phenotypes. Thus, dnaB proteins which differ from each other by only one amino acid at the mutation site give different phenotypes. Mutation dnaB266 is lethal to the host when not suppressed. Hence the dnaB protein is essential for bacterial growth.Three P1 mutants, P1mcb-4, P1mcb-5 and P1mcb-8, were isolated which converted the temperature-sensitive bacterial growth of dnaB266-supE to resistant growth. Lysogenization with P1mcb allowed growth of dnaB266su⁻ strain which was absolutely defective in the bacterial dnaB function, indicating that the dnaB-like function of P1 prophage can substitute for the bacterial dnaB function. However, lysogenization by P1mcb did not support the growth of λ and λπ phages on dnaB 266su⁻. While P1mcb-4 and P1mcb-5 prophages altered the phenotypes of other dnaB strains to permit the growth of bacterial and λ phage at 32 °C and 42 °C, P1mcb-8 prophage supports the growth of λ phages and bacteria at 42 °C but not λ phage growth on groP-bacteria at 32 °C. The alteration of phenotypes of the P1mcb lysogens varied depending on the dnaB mutations they carried. Mutual interaction between the bacterial dnaB protein and the phage dnaB-like protein which results in different phenotypes of lysogens is suggested.     

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.     

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.     

Lactococcal Bacteriophages Require a Host Cell Wall Carbohydrate and a Plasma Membrane Protein for Adsorption and Ejection of DNA

The mechanism of the initial steps of bacteriophage infection in Lactococcus lactis subsp. lactis C2 was investigated by using phages c2, ml3, kh, l, h, 5, and 13. All seven phages adsorbed to the same sites on the host cell wall that are composed, in part, of rhamnose. This was suggested by rhamnose inhibition of phage adsorption to cells, competition between phage c2 and the other phages for adsorption to cells, and rhamnose inhibition of lysis of phage-inoculated cultures. The adsorption to the cell wall was found to be reversible upon dilution of the cell wall-adsorbed phage. In a reaction step that apparently follows adsorption to the cell wall, all seven phages adsorbed to a host membrane protein named PIP. This was indicated by the inability of all seven phages to infect a strain selected for resistance to phage c2 and known to have a defective PIP protein. All seven phages were inactivated in vitro by membranes from wild-type cells but not by membranes from the PIP-defective, phage c2-resistant strain. The mechanism of membrane inactivation was an irreversible adsorption of the phage to PIP, as indicated by adsorption of [³⁵S] methionine-labeled phage c2 to purified membranes from phage-sensitive cells but not to membranes from the resistant strain, elimination of adsorption by pretreatment of the membranes with proteinase K, and lack of dissociation of ³⁵S from the membranes upon dilution. Following membrane adsorption, ejection of phage DNA occurred rapidly at 30°C but not at 4°C. These results suggest that many lactococcal phages adsorb initially to the cell wall and subsequently to host cell membrane protein PIP, which leads to ejection of the phage genome.     

Intercrossing of phage genomes in a phage cocktail and stable coexistence with Escherichia coli O157:H7 in anaerobic continuous culture

The emergence of phage-resistant cells is the most serious problem for realizing phage therapy and is observed frequently if only one phage strain is used against a particular bacterium. By contrast, using multiple phages (phage cocktail) can delay or control the appearance of phage-resistant cells. Anaerobic continuous culturing of Escherichia coli O157:H7 and a cocktail of EP16, PP17, and SP22 phages were conducted. Comparison of the restriction fragment length polymorphism (RFLP) pattern of each phage genome showed a pattern different from wild type. Furthermore, the RFLP pattern of mutant phages consisted of fragments of PP17 and SP22 genome, suggesting both phages had infected the same host simultaneously (superinfection) and exchanged genomic DNA. Through observation of the binding of SYBR Gold-stained mutant phage to individual phage-resistant cells (RC), we found that clonal RC cultures were heterogeneous in their ability to bind mutant phage. The ratio of susceptibility was a few percent, which suggested that a minority of the RC population was susceptible to phage, and this heterogeneity contributes to the stable coexistence of RC and chimeric phages. The ratio of susceptible cells did not change appreciably from bacterial generation to generation.     

Classification of Lytic Bacteriophages Attacking Dairy Leuconostoc Starter Strains

A set of 83 lytic dairy bacteriophages (phages) infecting flavor-producing mesophilic starter strains of the Leuconostoc genus was characterized, and the first in-depth taxonomic scheme was established for this phage group. Phages were obtained from different sources, i.e., from dairy samples originating from 11 German dairies (50 Leuconostoc pseudomesenteroides [Ln. pseudomesenteroides] phages, 4 Ln. mesenteroides phages) and from 3 external phage collections (17 Ln. pseudomesenteroides phages, 12 Ln. mesenteroides phages). All phages belonged to the Siphoviridae family of phages with isometric heads (diameter, 55 nm) and noncontractile tails (length, 140 nm). With the exception of one phage (i.e., phage ΦLN25), all Ln. mesenteroides phages lysed the same host strains and revealed characteristic globular baseplate appendages. Phage ΦLN25, with different Y-shaped appendages, had a unique host range. Apart from two phages (i.e., phages P792 and P793), all Ln. pseudomesenteroides phages shared the same host range and had plain baseplates without distinguishable appendages. They were further characterized by the presence or absence of a collar below the phage head or by unique tails with straight striations. Phages P792 and P793 with characteristic fluffy baseplate appendages could propagate only on other specific hosts. All Ln. mesenteroides and all Ln. pseudomesenteroides phages were members of two (host species-specific) distinct genotypes but shared a limited conserved DNA region specifying their structural genes. A PCR detection system was established and was shown to be reliable for the detection of all Leuconostoc phage types.     

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.     

Ambivalent bacteriophages of different species active on Escherichia coli K12 and Salmonella sp. strains

A study was made of several bacteriophages (including phages U2 and LB related to T-even phages of Escherichia coli) that grow both on E. coli K12 and on some Salmonella strains. Such phages were termed ambivalent. T-even ambivalent phages (U2 and LB) are rare and have a limited number of hosts among Salmonella strains. U2 and LB are similar to canonical E. coli-specific T-even phages in morphological type and size of the phage particle and in reaction with specific anti-T4 serum. Phages U2 and LB have identical sets of structural proteins, some of which are similar in size to structural proteins of phages T2 and T4. DNA restriction patterns of phages U2 and LB differ from each other and from those of T2 and T4. Still, DNAs of all four phages have considerable homology. Unexpectedly, phages U2 and LB grown on Salmonella bongori were unstable during centrifugation in a CsCl gradient. Ambivalent bacteriophages were found in species other than T-even phages and were similar in morphotype to lambdoid and other E. coli phages. One of the ambivalent phages was highly similar to well-known Felix01, which is specific for Salmonella. Ambivalent phages can be used to develop a new set for phage typing in Salmonella. An obvious advantage is that ambivalent phages can be reproduced in the E. coli K12 laboratory strain, which does not produce active temperature phages. Consequently, the resulting typing phage preparation is devoid of an admixture of temperate phages, which are common in Salmonella. The presence of temperate phages in phage-typing preparations may cause false-positive results in identifying specific Salmonella strains isolated from the environment or salmonellosis patients. Ambivalent phages are potentially useful for phage therapy and prevention of salmonellosis in humans and animals.