Specialized transduction of colicin E1 DNA in Escherichia coli K-12

Pervasive prophage recombination occurs during evolution of spore-forming Bacilli

Phages are the main source of within-species bacterial diversity and drivers of horizontal gene transfer, but we know little about the mechanisms that drive genetic diversity of these mobile genetic elements (MGEs). Recently, we showed that a sporulation selection regime promotes evolutionary changes within SPβ prophage of Bacillus subtilis, leading to direct antagonistic interactions within the population. Herein, we reveal that under a sporulation selection regime, SPβ recombines with low copy number phi3Ts phage DNA present within the B. subtilis population. Recombination results in a new prophage occupying a different integration site, as well as the spontaneous release of virulent phage hybrids. Analysis of Bacillus sp. strains suggests that SPβ and phi3T belong to a distinct cluster of unusually large phages inserted into sporulation-related genes that are equipped with a spore-related genetic arsenal. Comparison of Bacillus sp. genomes indicates that similar diversification of SPβ-like phages takes place in nature. Our work is a stepping stone toward empirical studies on phage evolution, and understanding the eco-evolutionary relationships between bacteria and their phages. By capturing the first steps of new phage evolution, we reveal striking relationship between survival strategy of bacteria and evolution of their phages.

In vivo repackaging of recombinant cosmid molecules for analyses of Salmonella typhimurium, Streptococcus mutans, and mycobacterial genomic libraries

Strains of Escherichia coli K-12 were constructed that permitted the amplification of in vitro-packaged recombinant cosmid-transducing particles by in vivo repackaging of recombinant cosmid molecules. Thermal induction of these thermoinducible, excision-defective lysogens containing recombinant cosmid molecules yielded high titers of packaged recombinant cosmids and low levels of PFU. These strains were used to amplify packaged recombinant cosmid libraries of Mycobacterium leprae, Mycobacterium vaccae, Salmonella typhimurium, and Streptococcus mutans DNA. Contiguous and noncontiguous libraries were compared for the successful identification of cloned genes. Construction of noncontiguous libraries allowed the dissociation of desired genes from genes that were deleterious to the survival of a cosmid recombinant and permitted selection for unlinked traits that resulted in a selected phenotype. In vivo repackaging of recombinant cosmids permitted amplification of the original in vitro-packaged collection of transducing particles, storage of cosmid libraries as phage lysates, facilitation of complementation screening, expression analysis of repackaged recombinant cosmids after UV-irradiated cells were infected, in situ enzyme or immunological screening, and facilitation of recovery of recombinant cosmid molecules containing transposon inserts.

Blue ghosts: a new method for isolating amber mutants defective in essential genes of Escherichia coli

We describe a technique which permits an easy screening for amber mutants defective in essential genes of Escherichia coli. Using this approach, we have isolated three amber mutants defective in the rho gene. An extension of the technique allows the detection of ochre mutants and transposon insertions in essential genes.

Lambda bacteriophage-mediated transduction of ColE1 deoxyribonucleic acid having a lambda bacteriophage-cohesive end site: selection of packageable-length deoxyribonucleic acid

An in vitro recombinant ColE1-cos lambda deoxyribonucleic acid (DNA) molecule, pKY96, has 70% of the length of lambda phage DNA. The process of lambda phage-mediated transduction of pKY96 generated a small amount of transducing phage particles containing ColE1-cos lambda DNA molecules of 80 or 101% of the length of lambda phage DNA, in addition to those containing original pKY96 DNA molecules. The newly isolated larger plasmid DNAs were transduced 100 times more efficiently than pKY96 DNA. Their structures were compared with that of a prototype pKY96 DNA, and the mechanism of the formation of these molecules is discussed.

Construction and some properties of packageable plasmid F

A derivative of plasmid F which is packageable in lambda phage coat was constructed using techniques of in vitro recombination. This plasmid is composed of three DNA fragments generated by restriction enzyme EcoRI: a miniF fragment (fragment f5 of F'lac) which is able to replicate autonomously, a DNA fragment from Staphylococcus plasmid that carries the beta-lactamase gene, and a portion of guaA (B) transducing lambda phage DNA carrying lambda cohesive ends (cos site) along with almost all the late genes but devoid of all those genes and sites that are needed for replication, regulation, and recombination. The hybrid plasmid has a molecular weight of 2.7 x 10(7) daltons, about 84% size of lambda phage genome, and can be packaged in lambda coat when helper phage replicates in the plasmid-carrier cell. The packaged plasmid and the helper lambda phage particles are separated by CsCl density gradient centrifugation. The replication characteristics of the recombinant plasmid are all those of F including the copy number, incompatibility, and curing with acidine orange. The packaged plasmid is injected into an F- cell and establishes a plasmid state with normal efficiency. In F+ or Hfr cells, the resident F factor hinders this process.

Repair of ultraviolet-light damaged ColE1 factor carrying Escherichia coli genes for guanine synthesis

Hybrid ColE1 plasmids called ColE1-coslambda-qua A or ColE1-coslambda-gal can be efficiently tranduced into various E. coli K-12 cells through packaging into lambda phage particles. Using these plasmids, repair of ultraviolet-light (UV) damaged ColE1 DNAs was studied in various UV sensitive E. coli K-12 mutants. (1) The host mutations uvrA and uvrB markedly reduced host-cell reactivation of UV-irradiated ColE1-coslambda-guaA. (2) Pre-existing hybrid ColE1 plasmids had no effect on the frequency of lambda phage-mediated transduction of another differentially marked hybrid ColE1 DNAs. (3) ColE1-coslambda-guaA and ColE1-coslambda-gal DNAs could temporarily but not stably co-exist in E. coli K-12 recA cells. (4) The presence of ColE1-coslambda-gal in uvrB cells promoted the repair of super-infected UV-irradiated ColE1-coslambda-guaA about 7-fold. (5) The same ColE1-coslambda-gal plasmid in a uvrB recA double mutant did not have this promoting effect. These results indicate that the effect of resident hybrid ColE1 plasmids is manifested by the host recA+ gene function(s) and suggest that ColE1 plasmid itself provides norecA+-like functions.

DNA sequences of the integration sites and inverted repeated structure of transposon Tn3

The nucleotide sequence of the "inverted repeat" structure of the transposon Tn3 was determined by the DNA sequencing procedure developed by Maxam and Gilbert(1). The sequence, 38 base pairs long, is as follows: 5'-GGGGTCTGACGCTCAGTGGAACGAAAACTCACGTTAAG..(Tn3) 3'-CCCCAGACTGCGAGTCACCTTGCTTTTGAGTGCAATTC.. The integration of Tn3 is associated with a directly repeated sequence of 5 nucleotides appearing at each end of Tn3. The two directly repeated sequences so far determined are not the same. Furthermore, there is no homologous structure around the integration point of Tn3.

Isolation and characterization of a plaque-forming lambda bacteriophage carrying a ColE1 plasmid

A plaque-forming lambdaimm434 bacteriophage carrying the entire genome of colicinogenic factor E1 has been isolated and characterized. This phage, lambdaimm434ColE1, can lysogenize as a stable plasmid within a recombination-deficient Escherichia coli cell that lacks the normal attachment site for lambda phage. Furthermore, it has been found that lambdaimm434ColE1 phage carrying amber mutations in the O and P genes of the lambda genome, i.e., lambdaimm434OamPamColE1, behaves as a plaque-forming phage, and this finding suggests that the ColE1 factor DNA permits replication of the DNA of the plaque-forming phage.

Packaging of ColE1 DNA having a lambda phage cohesive end site

The mechanism of lambda phage-mediated transduction of hybrid colicin E1 DNAs of various lengths was studied, and factors influencing the formation of these transducing particles were investigated. The results were as follows: 1. The presence of a cohesive end site of lambda phage (coslambda) on colicin E1 DNA was essential for packaging of the DNA. 2. Packaging of colicin E1 DNAs, which carry coslambda with molecular sizes corresponding to 68% of that of lambda phage DNA, was observed in the absence of all known recombination functions of E. coli K-12 and of lambda phage. 3. Hybrid colicin E1 DNAs having coslambda with molecular sizes corresponding to 28% of that of lambda phage DNA were packaged within lambda phage particles as trimers; hybrid DNAs with coslambda of 40 and 47% of the length of lambda phage DNA were packaged as dimers; and those with molecular sizes of 68% of that of lambda phage DNA were packaged mostly as monomers. These results demonstrated that two factors are essential for the packaging of DNAs within lambda phage particles; the presence of coslambda on the DNA molecule and an appropriate size of DNA.