Cell wall receptor for bacteriophage Mu G(+).

The invertible G segment in phage Mu DNA controls the host range of the phage. Depending on the orientation of the G segment, two types of phage particles, G(+) and G(-), are produced which recognize different cell surface receptors. The receptor for Mu G(+) was located in the lipopolysaccharide (LPS) of gram-negative bacteria. The analysis of different LPS core types and of mutants that were made resistant to Mu G(+) shows that the primary receptor site on Escherichia coli K-12 lies in the GlcNAc beta 1 . . . 6Glc alpha 1-2Glc alpha 1-part at the outer end of the LPS. Mu shares this receptor site in E. coli K-12 with the unrelated single-stranded DNA phage St-1. Phage D108, which is related to Mu, and phages P1 and P7, which are unrelated to Mu but contain a homologous invertible DNA segment, have different receptor requirements. Since they also bind to terminal glucose in a different configuration, they adsorb to and infect E. coli K-12 strains with an incomplete LPS core.     

Effect of the polymerase activity of DNA polymerase I on the development of moderate bacteriophages Mu, lambda red- and lambda red-gam-. II. The effect of the polymerase activity of DNA polymerase I on the development of bacteriophage Mu

The paper reports on the influence of polymerizing activity of DNA-polymerase I on different developmental stages of temperate bacteriophage Mu in Escherichia coli K-12 cells. This activity is shown to be necessary for optimization of phage Mu primary integration into cell chromosomes. The relative frequency of Mu integration into bacterial chromosomes is 5-6 times lower in polA cells than in isogenic polA+ control strains, the phage yield from cells being delayed during the phage infectious development, but not in the course of induction from the prophage state. Data have been obtained that show the process of phage Mu DNA integration into the plasmid pRP1 .2 and the process of Mu transposition from the cell chromosome into the plasmid to be independent of the polymerizing activity of DNA-polymerase I.     

'Receptor-independent' infection of Mu G(−) phage in Escherichia coli K-12

Abstract Bacteriophage Mu with its invertible G segment in G(−) orientation does not make plaques on Escherichia coli K-12, due to the absence of a suitable lipopolysaccharide receptor. Plaques formed by Mu G(−) were found, however, when the infected E. coli K-12 strain harbours a plasmid with the cloned DNA inversion function Gin which converts the infecting G(−) phage to G(+). Under overproducing conditions, where Gin expression is placed under the control of the tac promoter, the infectivity of Mu G(−) can be estimated as approximately 1% of that in the presence of the receptor. Furthermore, interaction of Mu G(−) with the E. coli K-12 cell wall leads to interference with the plating of a Mu G(+) variant which has the new phenotype Pen⁻ (penetration-negative).     

Genetic mapping of mutation pfm::Tn5 affecting the penetration of bacteriophage Mu into Escherichia coli K-12 cells

Genetic mapping of pfm mutation affecting the stage of phage Mu DNA penetration into Escherichia coli K-12 cells was performed. Localization of the mutation under study was established by conjugational crossing methods and by transduction with the help of the T4GT7 phage.     

Adsorptive capacity of bacteriophage Mu on Escherichia coli K-12 strains with deletions in the attlambda region]

Escherichia coli strains with deletions in att lambda region were obtained. The comparison of the extent of deletions with the sensitivity of the corresponding mutant clones to phage Mu showed that the gene controlling the sensitivity of E. coli K-12 to the phage Mu is located in nad A-gal region of the bacterial chromosome. It is shown that the resistance of E. coli strains which had lost the region of bacterial chromosome between nad A gene and genes of gal-operon have adsorption character. Deletion of the nad A-gal region does not affect the adsorption of other phages (lambda, P1 and T4). Thus, the gene, located in this region, is responsible for the specific adsorption of the phage Mu.     

Effect of mutations of Escherichia coli K-12 chromosome on the integration of bacteriophage Mu introduced into cells by infection or conjugation

We present the detailed research on the previously described Escherichia coli K-12 Mud- mutants with impaired development of bacteriophage Mu. The ability of Mu phage DNA to penetrate into mutant cells on infection was shown. If introduced into the cells or combined with mud mutation by recombination, the prophage may be induced, which results in phage Mu lythic development and phage burst from mutant cells. In the course of conjugative transfer into the mutant cells, within a DNA fragment of the lysogenic donor chromosome, MupAp1 prophage is not inherited by recombinants. At the same time, Mu prophage deficient in genes A and B, whose products are required for transposition, is inherited by the mutant with the usual frequency. These data enable us to conclude that the mud mutations disturb the stage of conservative transposition which is connected with the insertion of the Mu prophage into the chromosome, after excision from the linear DNA introduced into the cells via infection or conjugation.     

A gene for DNA invertase and an invertible DNA in Escherichia coli K-12

An assay system for the pin gene function, which suppresses the vh2 mutation of Salmonella, was developed and used to show that most strains of Escherichia coli K-12 are Pin+, whereas all the strains of E. coli C examined are Pin-. An E. coli host strain was constructed and used for detection of DNA fragments carrying the E. coli K-12 pin gene cloned in the plasmid vector pBR322. Restriction analysis of the cloned fragments showed that the invertible DNA (designated P region) is adjacent to the pin gene and that its inversion is mediated by the pin gene product. The pin gene was found to be functionally homologous to the gin gene of Mu phage and the cin gene of P1 phage. The P region most probably resides within the cryptic prophage e14, and the Pin- phenotype is likely to be associated with the loss of e14.     

Cloning of genes from members of the family Enterobacteriaceae with mini-Mu bacteriophage containing plasmid replicons.

An in vivo cloning system that uses derivatives of the Escherichia coli bacteriophage Mu with plasmid replicons has been extended to five different species of the family Enterobacteriaceae. Mu and these mini-Mu replicon elements were introduced into strains of E. coli, Shigella flexneri, Salmonella typhimurium, Citrobacter freundii, and Proteus mirabilis by infection, by transformation, or by conjugation with newly constructed broad-host-range plasmids containing insertions of these elements. Lysates from these cells, lysogenic for Mu and mini-Mu elements, were used to infect sensitive recipient strains of E. coli, S. typhimurium, and C. freundii. Drug-resistant transductants had mini-Mu replicon elements with inserts of different DNA sequences. All of the lysogens made could be induced to yield high phage titers, including those coming from strains that were resistant to Mu and Mu derivatives. Clones of 10 particular genes were isolated by their ability to complement specific mutations in the recipient strains, even in the presence of the E. coli K-12 restriction system. Some of the mini-Mu replicon elements used contained lac gene fusing segments and resulted in fusions of the lac operon to control regions in the cloned sequences.     

Roles of cell surface components of Escherichia coli K-12 in bacteriophage T4 infection: interaction of tail core with phospholipids.

The cell surface of Escherichia coli K-12, reconstituted from the OmpC protein, lipopolysaccharide, and the peptidoglycan layer, was active as a receptor for phage T4, resulting in the contraction of the tail sheath and the penetration of the core through the cell surface (Furukawa et al., J. Bacteriol. 140:1071--1080, 1979). In the present work the process of DNA ejection from the contracted T4 phage particle was studied. Contracted phage particles were adsorbed to phospholipid liposomes by the core tip. This adsorption resulted in ejection of phage DNA. Either phosphatidylglycerol or cardiolipin was active for the DNA ejection. A proton motive force across the liposome membrane was not required for these processes. The process of DNA ejection, however, was temperature dependent, whereas the adsorption of the core tip to liposomes took place at 4 degrees C. Based on these observations together with those in the previous paper, the process of T4 infection of E. coli K-12 cells is discussed with special reference to the roles of cell surface components.     

Host-controlled Restriction of T-even Bacteriophages: Relation of Four Bacterial Deoxyribonucleases to Restriction

Escherichia coli strains B and K-12, which restrict growth of nonglucosylated T- even phage (T(*) phage), and nonrestricting strains (Shigella sonnei and mutants of E. coli B) were tested for levels of endonuclease I and exonucleases I, II, and III, by means of in vitro assyas. Cell-free extracts freed from deoxyribonucleic acid (DNA) were examined with three substrates: E. coli DNA, T(*)2 DNA, and T2 DNA. Both restricting and nonrestricting strains had comparable levels of the four nuclease activities and had similar patterns of preference for the three substrates. In addition, mutants of E. coli B and K-12 that lack endonuclease I were as effective as their respective wild types in restricting T(*) phage.     

Infection of Salmonella typhimurium with coliphage Mu d1 (Apr lac): construction of pyr::lac gene fusions.

A procedure was developed for introducing the coliphage Mu d1 (Apr lac) into Salmonella typhimurium in order to construct gene fusions that place the structural genes of the lac operon under the control of the promoter-regulatory region of other genes. To introduce Mu d1 from Escherichia coli K-12 into S. typhimurium, which is normally not a host for Mu, we first constructed an E. coli double lysogen carrying the defective Mu d1 phage and a Mu-P1 hybrid helper phage (MuhP1) that confers the P1 host range. A lysate prepared from this strain was used to infect a P1-sensitive (i.e., galE), restriction-deficient, modification-proficient strain of S. typhimurium, and a double lysogen carrying Mu d1 and MuhP1 was isolated. Induction of the latter strain produced lysates capable of infecting and generating gene fusions in P1-sensitive strains of S. typhimurium. In this paper we describe the construction of pyr::lac fusions by this technique.     

Escherichia coli K-12 mutants with an increased efficiency of plasmid transformation

Escherichia coli K-12 mutants with an enhanced efficiency of plasmid transformation were obtained. In all the mutants, the efficiency of transfection with lambda vir phage DNA was changed, in comparison to the parent strain. However, these changes did not always correlate strictly with plasmid transformation alterations. For instance, two mutants with an increased plasmid transformation efficiency demonstrated 50-fold decrease in the level of transfection with lambda phage DNA. Polyacrylamide gel electrophoresis points to both quantitative and qualitative differences in protein composition of the mutant cell envelopes, as compared with the parent strain.     

A new insertion sequence, IS121, is found on the Mu dI1 (Ap lac) bacteriophage and the Escherichia coli K-12 chromosome

We have discovered a new insertion sequence, now designated IS121, as a component of the Mu dI1 (Ap lac) phage. This sequence is 1.2 kilobases long and contains single recognition sites for the HincII, Bg1II, and HindIII restriction endonucleases. IS121 is present in at least three copies in the chromosome of several Escherichia coli K-12 strains. When present in the nonconjugative plasmid pBR322, IS121 can mediate cointegrate formation with an F' lac plasmid and transfer of pBR322 sequences to suitable recipients. IS121 is also capable of precise or nearly precise excision. As part of the study of IS121, we have determined the physical structure of the Mu dI1 (Ap lac) phage and established an extensive restriction endonuclease map of this phage. A revised schema for the formation of the Mu dI1 (Ap lac) phage is presented.     

Construction from Mu d1 (lac Apr) lysogens of lambda bacteriophage bearing promoter-lac fusions: isolation of lambda ppheA-lac.

Bacteriophage Mu d1 (lac Aprr) was used to obtain strains of Escherichia coli K-12 in which the lac genes are expressed from the promoter of pheA, the structural gene for the enzyme chorismate mutase P-prephenate-dehydratase. A derivative of bacteriophage lambda which carries the pheA-lac fusion was prepared; the method used is generally applicable for the construction, from Mu dl lysogens, of specialized transducing lambda phage carrying the promoter-lac fusions. A restriction enzyme cleavage map of lambda ppheA-lac for the enzymes HindIII and PstI is presented.     

Integration of phage Mu into the RP4::D3112A-plasmid in Escherichia coli cells

Hybrid plasmids obtained as a result of Mu phage insertions into the RP4::D3112 plasmid in Escherichia coli cells were studied. Stable maintenance of RP4::D3112 plasmid in E. coli cells was provided by using the D3112 phage genome with a point polar mutation in the A gene which prevented early genes' expression. The presence of D3112A- in the RP4 plasmid has been shown to have no effect on efficiency of phage Mu transposition into this plasmid. Moreover, RP4 and D3112 genomes were equivalent targets for Mu integration. The integration of transposable phage into genome of nonrelated phage can be used as one of the approaches to construct recombinant phage genomes in vivo in the absence of DNA homology.     

Use of deletion mutants of plasmid RP4::D3112 for the genetic analysis of Pseudomonas aeruginosa bacteriophage D3112

The hybrid plasmid RP4::D3112 becomes unstable in Escherichia coli K-12 cells under certain growth conditions. The deletion mutants of this plasmid are formed at a high frequency. All the deletions selected have a specific feature: they start in the left end, at the point of joining of plasmid and phage DNA, and remove different portions of the phage genome. The deletion mutants have been used for genetic mapping of D3112. We have localized the repressor gene cI (0-1.3 kb), 3 early genes (1.3-14.2 kb) and two groups of late genes (14.2-29.9 and 29.9-38 kb). Electron microscope studies of RP4::D3112 DNA and its deletion derivatives have shown that integration of D3112 genome in RP4 occurs through the ends of the genome, without permutations. It appears that bacterial nucleotide sequences joined to DNA from mature D3112 particles, to the right end of D3112 genome, are lost. Thus, transposable phages D3112 of Pseudomonas aeruginosa and E. coli Mu phage have some similarities in the genome organization and in the way of their integration into the host DNA.     

Genetic study of the effect of lambda phage on Mu phage production in Escherichia coli K-12 strains with Mu--lambda--Mu structures

The interaction of temperate bacteriophages Mu and lambda is studied during their simultaneous induction in specially constructed heterolysogenic strains of Escherichia coli bearing trimeric Mu--lambda--Mu structures. These strains were obtained by the MU-mediated integration of phage lambda circular genomes. Heterolysogenic strains of E. coli were used for studying phage lambda eliminating effect on Mu development with a simultaneous induction of prophages in the same cell. The results of the study allow the localization of the region of phage lambda genome incorporating gene (genes) lambda, which produces an eliminating effect on Mu development.     

Intergeneric conjugational hybridization of Escherichia coli and Salmonella typhimurium. 1. Obtaining a salmonella hybrid possessing greater recipient activity in crosses with Escherichia coli]

Intergeneric hybrids were selected from mating HfrH Escherichia coli with F- Salmonella typhimurium. The hybrid obtained from E. coli leu+ and pro+ genes possessed the increased recipient ability in the mating with E. coli HfrR1 (O--ilv--metE--ara). This hybrid lacked the ability to restrict the phage P1 DNA propagated on E. coli K-12. The replacement of mutated uvrA gene of Salmonella for uvrA+ gene of E. coli restore uvr+ phenotype of Salmonella mutant.     

Electron Microscopic Evidence for Linear Insertion of Bacteriophage MU-1 in Lysogenic Bacteria

Temperate bacteriophage Mu-1 was used to generate a lysogenic derivative of the F'lac episome of Escherichia coli. Intact, covalently circular molecules of F'lac and lysogenic F'lac Mu(+) deoxyribonucleic acid (DNA) were isolated and examined by electron microscopy. The mean contour lengths of F'lac and F'lac Mu(+) molecules were 37.6 +/- 0.4 mum and 53.2 +/- 0.4 mum, respectively. The mean difference, 15.6 mum, is similar to the mean contour length of 12.9 +/- 0.1 mum obtained for linear DNA molecules released by osmotic shock from mature phage Mu-1 virions. These results provide direct physical evidence that phage Mu-1 integrates by linear insertion of its genome into the DNA of lysogenic host bacteria. Chemical and physical analyses of phage Mu-1 DNA indicate that it is similar to E. coli DNA in respect of gross base composition, buoyant density, and melting temperature.     

Sensitivity of Intracellular Bacteriophage λ to Colicin CA42-E2

Treatment of Escherichia coli K-12 infected by lambda CIts857 with colicin CA42-E2 resulted in partial inhibition of the infectious process. Uninfected bacteria were killed by colicin with a probability of about five times that with which similarly treated lambda-infected bacteria lose plaque-forming ability. The lambda deoxyribonucleic acid (DNA), when present in a bacterial cell either as the replicating DNA of infectious phage or as the nonreplicating DNA of superinfecting phage, was degraded to acid-soluble material after colicin treatment. Analysis of the intermediates of DNA breakdown has revealed that degradation of the DNA to acid-soluble material is preceded by endonucleolytic fragmentation of the chromosome at a limited number of sites. This is the same mechanism of degradation previously observed for E. coli DNA after colicin treatment.