Interactions between a genetically markedPseudomonas fluorescens strain and bacteriophage ΦR2f in soil: Effects of nutrients, alginate encapsulation, and the wheat rhizosphere

The introduction of bacteriophages could potentially be used as a control method to limit the population size of engineered bacteria that have been introduced into soil. Hence, the ability of a species-specific phage, R2f, to infect and lyse its host, a Pseudomonas fluorescens R2f transposon Tn5 derivative, in soil, was studied. Control experiments in liquid media revealed that productive lysis of host cells by phage R2f occurred when cells were freely suspended, whereas cells present in alginate beads resisted lysis. The presence of nutrients enhanced the degree of lysis as well as the production of phage progeny, both with the suspended cells and with cells escaped from the alginate beads. Experiments in which host cells and phage R2f were introduced into two soils of different texture revealed that host cells were primarily lysed in the presence of added nutrients, and phage reached highest titres in these nutrient-amended soils. Encapsulation of the host cells in alginate beads inhibited lysis by the phage in soil. Populations of free host cells introduced into soil that colonized the rhizosphere of wheat were not substantially lysed by phage R2f. However, P. fluorescens R2f populations colonizing the rhizosphere after introduction in alginate beads were reduced in size by a factor of 1,000. Cells migrating from the alginate beads towards the roots may have been in a state of enhanced metabolic activity, allowing for phage R2f infection and cell lysis. Correspondence to: J.D. van Elsas     

Restriction and modification of phage 47 and lambda by R factors

S. panama 47 (antibiotic-sensitive, phage pattern A) was infected with R factors from a number of field strains of Enterobacteriaceae (Salmonella, Escherichia coli, Citrobacter, Enterobacter, Klebsiella andProteus) isolated from human and animal sources. These R factors could be grouped into 11 types i.e. R1 R11 on the basis of induced changes in the phage type of the recipient.R8 and R11 renderS. panama resistant to the phages A H:S. panama 47 (R3) and 47 (R6) adsorb the phages A F, but there is no phage multiplication: phages G and H are considered to be restricted and modified in these strains. The R factors R5 and R7 also exert restriction and modification on a number of the typing phages A H. The nature of the changes in phage pattern brought about by R4, R9 and R10 is not understood. R2 does not exert restriction (i.e. no change in phage pattern). The R factors were also investigated for the fi (fertility inhibition) and spp (restriction of phage ) markers.The R factors R3 R11 readily segregate, in the sense that the restriction and modification loci, and occasionally the Resistance Transfer Factor as a whole was frequently lost after R transfer. These 9 types of R factors were encountered infrequently in the present material.Resistance to tetracycline inS.panama is nearly always due to R factors of type R1. In other members of Enterobacteriaceae, notably inE.coli, R1 is less frequently found than R2.     

Molecular cloning of menaquinone biosynthetic genes of Escherichia coli K12

Summary A tranducing phage carrying some of the genes (men) defining the early stages of menaquinone biosynthesis was isolated from a pool of recombinant lambda phages that had been constructed from R.HindIII digests of E. coli DNA and the corresponding insertion vector. The lesions of menB and menC mutants were complemented by the phage but menD mutants were transduced either at low frequencies or not at all. This indicates that the transducing phage contains functional menB and menC genes but that only part of the menD gene had been cloned. The phage (G68) was accordingly disignated menCB(D). Studies with the transducing phage enabled earlier mapping data (Guest 1979) to be reinterpreted in favour of the gene order nalA.... menC..menB..menD.... purF. Restriction analyses established the presence of a bacterial DNA fragment (11.5 kb) linked by a R.HindIII target to the right arm of the genome but fused to the left arm of the vector. Hybridization studies confirmed that the cloned DNA was derived from a larger R.HindIII fragment (21 kb). A physical map of the men region was constructed and some flanking and overlapping fragments were identified.     

R factor compatibility groups

Summary Eight R factors are described which fall into four compatibility groups, distinct from previously described F-like and I-like groups. E. coli K12 carrying one of these factors, TP114, supports multiplication of the I-specific phage If1. However, TP114 is fully compatible with the I-like factor T- and with all the other R factors described in this paper. Interactions between TP114 and T- are described. Another R factor, TP122, inhibits F-fertility and is therefore fi ⁺, although strains carrying it do not support multiplication of the F-specific phage 2. TP122 is compatible with the F-like R factor R1, but incompatible with three other factors, all of which fall into the N group. Two further factors, TP116 and TP117, are incompatible with each other and constitute a new group, designated Group H. The final factor, TP113, is compatible with all the R factors with which it has been tested, so that it represents yet a further group. A second member of this group has recently been identified.     

Virulence as a consequence of genome instability of a novel temperate bacteriophage, ΦRsG1, of Rhodobacter sphaeroides Y

A novel temperate bacteriophage, designated RsG1, was isolated from Rhodobacter sphaeroides Y (previously designated Rhodopseudomonas sphaeroides) following exposure to mitomycin C. The phage morphology, as revealed from electron microscopy, showed a hexagonal head (90 by 46.5 nm) connected with a tail (116 by 9.4 nm), to which a collar was proximally attached. A morphologically similar phage was also produced by spontaneous lysis of the cells. While RsG1 did not grow on any other bacterial strain tested, spontaneously produced phage particles propagated (and formed plaques) on R. sphaeroides Y still carrying RsG1 in the prophage state. The genome of RsG1 consisted of double stranded linear DNA with cohesive ends and a GC-content of 71.8 mol%. The DNA molecules formed circles in vitro with a mean contour length of 17.18±0.4 m, which corresponds to a size of 49 kbase pairs (kb). On the other hand, DNA extracted from the virulent phage particles was heterogeneous and consisted of two DNA species of different size, occurring in a ratio of about 1:1. These molecules also circularized having contour lengths of 17.18±0.4 m and 14.02±0.41 m corresponding to 49 and 40 kb, respectively. Restriction digest analysis of the two DNA species and DNA from RsG1 indicated that they are similar, and allowed the indentification of an 11.5 kb EcoRI fragment that carries the cohesive ends. Because DNA from RsG1 and the 49 kb DNA of the virulent phage particles were indistinguishable with the criteria applied, it is suggested that phage particles containing the 40 kb DNA represent the virulent type of phage, termed RsG1.1.     

In vitro insertion of the lambda attachment site into the plasmid RP4.

Summary The region of the phage lambda chromosome containing the attachment site (P · P) and the genes int and xis, excised by the action of endonuclease R.EcoRI, has been inserted into the unique site for that enzyme on the promiscuous conjugative plasmid, RP4, generating the recombinant plasmid RP4att. Transformants containing the hybrid plasmid were recognised by their ability to allow efficient lysogenization by phage b2 (Weil and Signer, 1968; Echols et al., 1968) containing the mutant attachment site · P. The construction and properties of the hybrid plasmid RP4att are described.     

Lambda transducing phages derived from a FinO- R100::lambda cointegrate plasmid: proteins encoded by the R100 replication/incompatibility region and the antibiotic resistance determinant.

Summary Three transducing phages have been isolated from pEDR20, an R100:: cointegrate plasmid in which the insertion inactivated the R100 finO gene. Physical analysis of the three phages showed that the is inserted at kilobase coordinate 81.3 of R100. All three phages carry different amounts of R100 DNA in the left arm of . Each phage contains IS1b, the mer genes and the region between coordinate 81.3 and 88.6; thus, all contain the genes necessary for R100 replication. One phage, VA73, contains the entire r-determinant of R100 in addition to the above DNA. Five proteins coded by the region between 81.3 and 88.6 were detected. These had subunit molecular weights of 10,400; 12,200; 16,200; 19,600; and 38,300. The first was made constitutively and the other four only from a promoter. Other constitutive proteins were one from the cml fus region with a molecular weight of 22,400 (cml) and two from the str sul region with molecular weights of 31,500 (str?) and 30,100 (sul?). Mercuric ion induced synthesis of at least 10 proteins. Six of these were known from earlier work. The total size of the proteins which appear to derive from the mer genes exceeds by a factor of 1.5, the coding capacity of this region without overlapping genes. Some, or all of these extra proteins may be chromosomal in origin, possibly derepressed in response to mercury gene products.     

Isolation and characterization of a recombination defective-dependent bacteriophage ofRhodobacter sphaeroides

A new virulent bacteriophage, designated RZ1, was isolated from a local pond on the facultative phototrophic bacteriumRhodobacter sphaeroides ZZ101. Electron microscopic studies revealed that, in general morphology, phage RZ1 resembles the bacteriophage ofEscherichia coli. The host range of phage RZ1 is limited to some strains ofR. sphaeroides. The phage genome consists of double-stranded DNA of about 44 kb lacking cohesive ends and seems to present terminal redundancy and cyclic permutation. RZ1 phage may carry out a lytic cycle only in recombination-defective mutants ofR. sphaeroides. Nevertheless, a derivative of the RZ1 phage, termed RW1, able to grow in recombination-proficient strains ofR. sphaeroides, has also been obtained. In vitro restriction analysis of both RZ1 and RW1 phages shows the presence of a rearrangement in their DNA. Generalized transduction of Str^r and Rif^r chromosomal markers has not been detected with either RZ1 or RW1 phages.     

Molecular cloning and nucleotide sequence of the Rhizobium phaseoli recA gene

Summary A recombinant phage carrying the recA gene of Rhizobium phaseoli was isolated from a R. phaseoli genomic library by complementation of the Fec^– phenotype of the recombinant phage in Escherichia coli. When expressed in E. coli, the cloned recA gene was shown to restore resistance to both UV irradiation and the DNA alkylating agent methyl methanesulphonate (MMS). The R. phaseoli recA gene also promoted homologous recombination in E. coli. The cloned recA gene was only weakly inducible in E. coli recA strains by DNA damaging agents. The DNA sequence of the R. phaseoli recA gene was determined and compared with published recA sequences. No LexA-binding site was detected in the R. phaseoli recA upstream region.     

Restriction and modification in Bacillus subtilis: identification of a gene in the temperate phage SP beta coding for a BsuR specific modification methyltransferase

Summary A gene coding for a modifying DNA-methyltransferase which methylates the central C in the BsuR recognition sequence 5GGCC was identified in the genome of the temperate Bacillus subtilis phage SP. This gene is expressed only after induction of the prophage by either mitomycin C or UV. The presence of active methyltransferase in induced cells leads to modification of BsuR recognition sites in SP DNA as well as in heterologous DNA.     

Requirement of the Escherichia coli dnaA gene function for integrative suppression of dnaA mutations by plasmid R100-1

Summary The phenotype of Escherichia coli dnaA missense and nonsense mutations was integratively suppressed by plasmid R100-1. The suppressed strains, however, could not survive when the dnaA function was totally inactivated. This was demonstrated by the inability of replacing the dnaA allele in the suppressed strain by a dnaA::Tn10 insertion using phage P1-mediated transduction. When the intact dnaA ⁺ allele was additionally supplied by a specialized transducing phage, imm ²¹ dnaA ⁺, which integrated at the att site on the E. coli chromosome, then the dnaA::Tn10 insertion, together with a oriC deletion, were able to be introduced into the suppressed strain. Thus, the mechanisms of dnaA function for oriC and for the replication origin of R100-1 may not be quite the same.     

Isolation and characterization of lambda b221poriCasnA, a plaque-forming specialized transducing phage carrying the origin of replication of the Escherichia coli chromosome

Summary A specialized transducing phage, b221poriCasnA has been isolated carrying oriC the origin of chromosomal replication of Escherichia coli. All phage genes required for lytic growth are retained, thus the phage is capable of lytic growth. The presence of the oriC locus confers upon infecting phage DNA the ability to replicate as a plasmid using only host DNA replication functions. The presence of both oriC and asnA markers has allowed the development of a plaque assay for origin function which can be used to identify mutants at these loci. Comparison of restriction endonuclease cleavage sites present on b221poriCasnA DNA to those on tis parent, b221 rex::Tn10 suggests the steps involved in the formation of the transducing phage.     

Circular structure of the genome of phage ?H in a lysogenic Halobacterium halobium

Summary Phage H is a temperate phage, i.e., it can establish lysogeny in the archaebacterium Halobacterium halobium. H-lysogens are immune to phage infection and phage production is spontaneously induced at a rate of about 10^-7. In the prophage state. H DNA exists as a covalently closed circle of 57 kb.The frequent occurrence of clones carrying the phage genome but unable to produce phage is another proof of the high variability of DNA in H. halobium. In one such strain, R₁-3, the phage genome has undergone a structural change which may have abolished an essential phage gene.     

Inhibition of modification and restriction for phages lambda and T-1 by co-infecting T3

Summary The host controlled modifications of phage -DNA byEscherichia coli B, K, and C (P1) can be suppressed by preinfecting the bacteria with UV-irradiated phage T3. Since UV-irradiated T3 induces an enzyme which cleaves S-adenosylmethionine into homoserine and thiomethyl adenosine, and since S-adenosylmethionine is the only methyl group donor for DNA methylation, we conclude that methylation is a required step in the host controlled modification of -DNA.T3 itself successfully infectsE. coli K and B with its nonmethylated DNA. Also, restricted phage or T1 will be accepted by the restrictive hostsE. coli B, K, and C(P1) if these are preinfected with UV-T3. It thus appears that T3 is capable of blocking the restriction mechanisms in these hosts.The inability of T3 to grow on C(P1) is not understood. Since T3-DNA is restricted but not degraded into nucleotides byE. coli C(P1) we presume that degradation is not the initial step in restriction.Supported by Grant No. GB 1033 R of the National Science Foundation.Postdoctoral fellow of the Deutsche Forschungsgemeinschaft.     

Non-random distribution of transduction termini in transductants from the integrated R plasmid, R100-1

Summary Tra ⁺and tra ^–derivatives of drug resistance plasmid, R100-1, were isolated by phage P1 from an Hfr donor with integrated R100-1 and then analyzed by complementation tests with tra ^–point mutants of Flac. Tra ⁺derivatives of R100-1 carrying tetracycline resistance alone and those carrying all six drug-resistance genes could support transfer of tra ^–point mutants of Flac except Flac traJ, whereas all of tra ^–derivatives of R100-1 failed to complement any one of tra ^–point mutants of Flac. This suggests that these tra ^–derivatives of R100-1 carrying tetracycline resistance gene are deleted for all the transfer genes impaired in the Flac point mutants tested. We assume a hot point, probably a specific base sequence similar to an IS element, at the left of the tetracycline gene (Fig. 1) becomes a transduction terminus in transduction of the integrated R100-1 by phage P1. Complementation analysis of tra ^–derivatives carrying five resistance genes except the tetracycline gene led us to a supposition that a gene(s), probably analogous to traJ of the F plasmid, is located on R100-1 near the tetracycline gene which plays an important regulatory role for self-transfer as well as for the complementation of tra ^–Flac mutants.     

Localization of the metJBLF gene cluster of Escherichia coli in lambda met transducing phage

Summary The position of the metJBLF gene cluster in the transducing phage dmet102 was determined by ligation of its leftmost EcoRI fragment (102-1) to the BCDEF (nin5) EcoRI fragment of gtl (BC) and characterization of the resultant recombinant phage. The new transducing phage carries about 6kb of bacterial DNA which contains the entire met gene cluster including the promoter of its rightmost member metF. Reasonable estimates of the coding capacity required for the four genes indicate that most of the bacterial DNA of the recombinant phage is occupied by the met gene cluster.     

Genetische und physiologische Beziehungen zwischen den Bakteriophagen T1 und D 20

Summary The close relationship between phages T 1 and D 20 was confirmed by genetical crosses. D 20 could be shown to differ from T 1 by at least two genes, both affecting the host range of the phage. The geneDs will render a phage capable of multiplying on the original host of D 20, SF;Ha will enable the phage to lyse B/1. D 20 may thus be formulated as T 1HaDs. Both genes could be localized within the T 1 linkage map, in the vicinity of the geneHr, which is known to control the host range specifity against B/1. The results of genetical, adsorption, and serological studies can be interpreted by the assumption that each gene controls the synthesis of a specific protein, responsible for the adsorption behaviour of the particular phage. A phage will adsorb to SF according to itsDs genotype, to B or its phage resistant mutants according to itsHa genotype. These proteins do not, however, exert their functions independently. Therates of adsorption and neutralization are influenced by the presence or absence of proteins not required for the particular reaction under investigation.

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