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).     

Reduced restriction of phage lambda in Escherichia coli K-12 cells after gamma-irradiation

In gamma-irradiated cells of Escherichia coli K-12 restriction alleviation of an unmodified phage lambda is only observed in AB1157 strain. No restriction alleviation by gamma-rays is registered in AB1157 mutants (rec A and ssb-1).     

Genetic requirements of phage lambda red-mediated gene replacement in Escherichia coli K-12

Recombination between short linear double-stranded DNA molecules and Escherichia coli chromosomes bearing the red genes of bacteriophage lambda in place of recBCD was tested in strains bearing mutations in genes known to affect recombination in other cellular pathways. The linear DNA was a 4-kb fragment containing the cat gene, with flanking lac sequences, released from an infecting phage chromosome by restriction enzyme cleavage in the cell; formation of Lac(-) chloramphenicol-resistant bacterial progeny was measured. Recombinant formation was found to be reduced in ruvAB and recQ strains. In this genetic background, mutations in recF, recO, and recR had large effects on both cell viability and on recombination. In these cases, deletion of the sulA gene improved viability and strain stability, without improving recombination ability. Expression of a gene(s) from the nin region of phage lambda partially complemented both the viability and recombination defects of the recF, recO, and recR mutants and the recombination defect of ruvC but not of ruvAB or recQ mutants.     

The transfer of bacterial biotin genes to Escherichia coli K-12 cells by transfection with lambda bio phage DNA.

The transfection of biotin genes to biotin negative Escherichia coli K-12 cells with donor DNA isolated from transducing lambda bio phages was examined. The transfection of the cells was performed in the presence of bovine serum albumin and sucrose (Osowiecki and Skalińska, 1974).     

Methyl-cytosine specific restriction in Escherichia coli K-12

Experiments on transformation of Escherichia coli K-12 cells by plasmids carrying RM systems with different recognition sites containing 5-methylcytosine have shown that the gene mcrB determines the function of restriction. The data obtained made it possible to believe that E. coli possesses no restriction system recognizing specifically cytosine methylated in position 4.     

W-reactivation of phage lambda in X-irradiated mutants ofEscherichia coli K-12

Summary The survival of UV irradiated phage lambda was increased on X-irradiatedE. coli K-12 host cells over that on unirradiated cells. The frequency of c mutants among the surviving phages was to a similar extent increased by the X-ray exposure of the host cells as by UV light. This W-reactivation of phage lambda occurred inuvrA, polA, andrecB mutants besides the wild type at about equal X-ray doses, however, at a reduced reactivation efficiency compared with the wild type. W-reactivation was undetectable inrecA mutants. While maximal UV induced W-reactivation occurred 30 min after irradiation, the maximal X-ray induced reactivation was found immediately after irradiation. Chloramphenicol (100 µg/ml) and nitrofurantoin (50 µg/ml) inhibited W-reactivation of phage lambda if added before irradiation of the host cells, indicating the necessity of protein synthesis for W-reactivation.     

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.     

Isolation of a recombinant lambda phage carrying nusA and surrounding region of the Escherichia coli K-12 chromosome

Summary A recombinant bacteriophage lambda, argG-6, has been isolated which carries the argG gene and neighbouring loci on an EcoRI-generated 15.5 Kb DNA fragment from the Escherichia coli chromosome. The locations of the argG, nusA and pnp genes on the 15.5 Kb DNA fragment have been determined. In the case of nusA, a Tn5 insertion and sub-cloning of restriction fragments were used to locate the gene. The gene products of nusA and pnp have been identified on one- and two-dimensional polyacrylamide gels. The clockwise gene order was found to be argG-nusA-pnp.     

Reactivation of ultraviolet-irradiated phage lambda and recombination in Escherichia coli K-12 cells containing plasmid ColIb-P9

It was shown that the presence of colicinogenis plasmid ColIb-P9 increased the survival of UV-irradiated bacteriophage lambda cI857 in non-irradiated cells of Escherichia coli K-12. The effect of this plasmid was retained in the polA and recB mutants, being sharply reduced in the uvrA and recB recC sbcB recF mutants. This effect strongly depended on recA+ and lexA+ genotype. The W-reactivation efficiency was slightly higher in the cells containing ColIb-P9 than in those lacking the plasmid. No significant effect of the plasmid on recombination during transduction, after conjugation under usual conditions and in the case when a conjugation mixture or recipient cells were irradiated, was observed. The data demonstrate that the effect of ColIb-P9 plasmid on DNA repair is not mediated by its influence on recombination.     

Mapping of ilvO loci of Escherichia coli K-12 with bacteriophage lambda dilv.

A set of lambda dilv phage have been used in a deletion mapping procedure to determine the location of two previously characterized ilvO alleles. In contrast to earlier conclusions derived from three-factor crosses and episome-shortening techniques with phage P1, the order found is ilvG-ilvO-ilvEDA. A three-factor cross with phage P1 is described that is not consistent with this location for an ilvO allele. Further analysis of this particular three-factor cross revealed than an artifact attributable to a mutual syntrophism had skewed the apparent frequency of inheritance of the ilvO locus. The role of mutual syntrophism is discussed as a source of mapping errors for the ilvO locus. The value of this set of lambda dilv phage and this mapping procedure for obtaining comparatively unambiguous data on the locations of the ilv structural and regulatory genes is demonstrated.     

Different mechanisms for SOS induced alleviation of DNA restriction in Escherichia coli.

The alleviation of DNA restriction during the SOS response in Escherichia coli has been further investigated. With the EcoK DNA restriction system UV irradiated wild-type cells show a 10(4)-fold increase in ability to plate non-modified lambda phage and a 3-4 fold increase in transformation by non-modified plasmid DNA. A role for the umuDC genes of E coli in the process of SOS-induced restriction alleviation was identified by showing that a umuC122::Tn5 mutant could alleviate EcoK restriction to only 5% that of wild-type levels. Although umuDC are better characterized for their pivotal role in SOS induced mutagenesis, it is demonstrated here that umu-dependent alleviation of EcoK restriction is a transient process in which umu-dependent mutagenesis plays little part. A second form of SOS induced alleviation of DNA restriction is described in this paper involving the McrA restriction system. The mcrA gene is shown to be encoded within a defective prophage called e14 situated at the 25 min region on the Escherichia coli genetic map. e14 is known to abortively excise from the chromosome after SOS induction and it is demonstrated in this report that mcrA is lost from the genome after SOS induction as part of e14. This results in co-ordinate decrease in the level of McrA restriction within a population of cells.     

Direction of bacteriophage lambda DNA replication in a thymine requiring Escherichia coli K-12 strain. Effect of thymidine concentration

The direction of replication was established for the first round of bacteriophage lambda DNA replication in thymine requiring E. coli K-12 cells exposed to different concentrations of thymidine. It was found that a dramatic decrease in the proportion of bidirectionally replicating molecules followed a decrease in the concentration of thymidine. Moreover, the rightward mode of replication appears to be exclusively favored in unidirectionally replicating molecules found at low concentrations of thymidine.     

The proteolytic control of restriction activity in Escherichia coli K-12

The endonuclease activity of EcoKI is regulated by the ClpXP-dependent degradation of the subunit that is essential for restriction, but not modification. We monitored proteolysis in mutants blocked at different steps in the restriction pathway. Mutations that prevent DNA translocation render EcoKI refractory to proteolysis, whereas those that permit DNA translocation, but block endonuclease activity, do not. Although proteolysis alleviates restriction in a mutant that lacks modification activity, some restriction activity remains; our evidence indicates residual EcoKI associated with the membrane fraction. ClpXP protects the bacterial chromosome, but little effect was detected on unmodified foreign DNA within the cytoplasm of a restriction-proficient cell. The molecular basis for the distinction between unmodified resident and foreign DNA remains to be determined.     

Bacteriophage lambda receptor site on the Escherichia coli K-12 LamB protein.

We have analyzed eight new phage-resistant missense mutations in lamB. These mutations identify five new amino acid residues essential for phage lambda adsorption. Two mutations at positions 245 and 382 affect residues which were previously identified, but lead to different amino acid changes. Three mutations at residues 163, 164, and 250 enlarge and confirm previously proposed phage receptor sites. Two different mutations at residue 259 and one at 18 alter residues previously suggested as facing the periplasmic face. The mutation at residue 18 implicates for the first time the amino-terminal region of the LamB protein in phage adsorption. The results are discussed in terms of the topology of the LamB protein.     

Localization of a genetic region involved in McrB restriction by Escherichia coli K-12.

A 5,500-base-pair BglII-EcoRI fragment proximal to the hsd genes of Escherichia coli K-12 has been cloned in the plasmid vector pUC9. The resultant hybrid plasmid was shown to complement the mcrB mutation of E. coli K802. The presence of the hybrid plasmid in strain K802 caused an 18.3-fold drop in transformation efficiency with AluI-methylated pACYC184 relative to unmethylated pACYC184. These results indicate that the cloned DNA is involved in the McrB system restriction of 5-methylcytosine DNA.     

Trans-dominant mutation affecting restriction and modification in Escherichia coli K-12

Summary We have analysed the mechanism of action of a ts mutation in E. coli, which has an effect on the expression of the restriction and modification phenotype. The frequencies of recombinants obtained in transduction experiments support the idea that the temperature sensitive mutation is located outside the hsd operon in the gene denoted hsd. X. Complementation experiments demonstrated the trans-dominant nature of the temperature sensitive mutation. The possible role of the hsd.X product in the formation of EcoR.K and EcoM.K complexes and their interaction with the recognition site on the DNA is discussed.     

A novel activity in Escherichia coli K-12 that directs restriction of DNA modified at CG dinucleotides.

The restriction systems McrA and McrB of Escherichia coli K-12 are known to attack DNA containing modified cytosine. In strains lacking both activities, however, we observed that DNA methylated at CG dinucleotides (as is mammalian DNA) was still significantly restricted. We show that this substantial barrier to the acceptance of 5-methylcytosine-containing DNA is attributable to a hitherto unknown activity of the Mrr restriction system. Strikingly, the multiple systems used by this gut inhabitant to determine the fate of invading DNA will all limit genetic exchange with its mammalian host(s), reinforcing the idea that one role of DNA methylation is to serve as a "molecular passport" (E. A. Raleigh, R. Trimarchi, and H. Revel, Genetics 122:279-296, 1989).