Interaction with the recombination hot spot chi in vivo converts the RecBCD enzyme of Escherichia coli into a chi-independent recombinase by inactivation of the RecD subunit.

The RecBCD enzyme of Escherichia coli promotes recombination preferentially at chi nucleotide sequences and has in vivo helicase and strong duplex DNA exonuclease (exoV) activities. The enzyme without the RecD subunit, as in a recD null mutant, promotes recombination efficiently but independently of chi and has no nucleolytic activity. Employing phage lambda red gam crosses, phage T4 2- survival measurements, and exoV assays, it is shown that E. coli cells in which RecBCD has extensive opportunity to interact with linear chi-containing DNA (produced by rolling circle replication of a plasmid with chi or by bleomycin-induced fragmentation of the cellular chromosome) acquire the phenotype of a recD mutant and maintain this for approximately 2 h. It is concluded that RecBCD is converted into RecBC during interaction with chi by irreversible inactivation of RecD. After conversion, the enzyme is released and initiates recombination on other DNA molecules in a chi-independent fashion. Overexpression of recD+ (from a plasmid) prevented the phenotypic change and providing RecD after the change restored chi-stimulated recombination. The observed recA+ dependence of the downregulation of exoV could explain the previously noted "reckless" DNA degradation of recA mutants. It is proposed that chi sites are regulatory elements for the RecBCD to RecBC switch and thereby function as cis- and trans-acting stimulators of RecBC-dependent recombination.     

Cis-Limited Action of the Gene-A Product of Bacteriophage ϕX174 and the Essential Bacterial Site

Parental replicative-form (RF(*)) DNA of bacteriophage varphiX174 in a replication-deficient host cell (rep(3) (-)) exhibits two characteristic features that correlate the function of viral gene A with the initiation of viral DNA replication: a specific discontinuity in the viral strand of a constant number of RF molecules and elongation of the viral strand to yield replicative-intermediate DNA forms with single-stranded tails. At high multiplicities of infection, these initiation events are limited to an average of four specifically nicked RFII molecules per cell. The limiting factor from the host cell may be related (or identical) to the essential bacterial sites known to limit the participation of parental genomes in RF replication. Double-infection experiments with wild-type phage and phage carrying an amber mutation in gene A show that the formation of gene A-specific RFII and RI is cis-limited to only the wild-type DNA. These results provide a basis at the DNA level for the known asymmetric complementation of gene A.     

The recombination hot spot chi activates RecBCD recombination by converting Escherichia coli to a recD mutant phenocopy.

The products of the recB and recC genes are necessary for conjugal recombination and for repair of chromosomal double-chain breaks in Escherichia coli. The recD gene product combines with the RecB and RecC proteins to comprise RecBCD enzyme but is required for neither recombination nor repair. On the contrary, RecBCD enzyme is an exonuclease that inhibits recombination by destroying linear DNA. The RecD ejection model proposes that RecBCD enzyme enters a DNA duplex at a double-chain end and travels destructively until it encounters the recombination hot spot sequence chi. Chi then alters the RecBCD enzyme by weakening the affinity of the RecD subunit for the RecBC heterodimer. With the loss of the RecD subunit, the resulting protein, RecBC(D-), becomes deficient for exonuclease activity and proficient as a recombinagenic helicase. To test the model, genetic crosses between lambda phage were conducted in cells containing chi on a nonhomologous plasmid. Upon delivering a double-chain break to the plasmid, lambda recombined as if the cells had become recD mutants. The ability of chi to alter lambda recombination in trans was reversed by overproducing the RecD subunit. These results indicate that chi can influence a recombination act without directly participating in it.     

BtuB-Dependent Infection of the T5-like Yersinia Phage ϕR2-01

Yersinia enterocolitica is a food-borne Gram-negative pathogen responsible for several gastrointestinal disorders. Host-specific lytic bacteriophages have been increasingly used recently as an alternative or complementary treatment to combat bacterial infections, especially when antibiotics fail. Here, we describe the proteogenomic characterization and host receptor identification of the siphovirus vB_YenS_ϕR2-01 (in short, ϕR2-01) that infects strains of several Yersinia enterocolitica serotypes. The ϕR2-01 genome contains 154 predicted genes, 117 of which encode products that are homologous to those of Escherichia bacteriophage T5. The ϕR2-01 and T5 genomes are largely syntenic, with the major differences residing in areas encoding hypothetical ϕR2-01 proteins. Label-free mass-spectrometry-based proteomics confirmed the expression of 90 of the ϕR2-01 genes, with 88 of these being either phage particle structural or phage-particle-associated proteins. In vitro transposon-based host mutagenesis and ϕR2-01 adsorption experiments identified the outer membrane vitamin B12 receptor BtuB as the host receptor. This study provides a proteogenomic characterization of a T5-type bacteriophage and identifies specific Y. enterocolitica strains sensitive to infection with possible future applications of ϕR2-01 as a food biocontrol or phage therapy agent.     

Nicking-closing activity associated with bacteriophage lambda int gene product.

Integrative recombination of bacteriophage lambda requires the action of the protein Int, the product of the phage int gene. In this paper we show that highly purified Int relaxes supercoiled DNA. The association of this nicking-closing activity with Int is shown by: (i) the cosedimentation of nicking-closing and recombination activities of purified Int, (ii) the parallel inactivation of the two activities in purified Int by both heat and a specific antiserum, and (iii) the alteration of both activities in crude extracts of a strain expressing a mutant int gene. The nicking-closing activity of Int functions in the absence of divalent cations and in the absence of an apparent source of chemical energy. The activity displays no obvious sequence specificity and is inhibited by Mg2+, spermidine, and single-stranded DNA. Int relaxes positive as well as negative supercoils. We present a model for the mechanism of strand exchange that describes how the nicking-closing activity of Int might be used during recombination.     

Regulation of Repressor Expression in λ

A new gene in bacteriophage lambda is described. The product of this gene cro prevents expression of immunity and regulates the expression of those genes to the left of the immunity region. cro(-) mutants have been isolated and characterized.     

ISOLATION OF A CHLORAMPHENICOL-RESISTANT PROTEIN FROM λ-INFECTED CELLS

During infection with bacteriophage varphiX174, a protein, made in the presence of 30 gamma chloramphenicol/ml but not made in the presence of concentrations greater than 100 gamma/ml, has been shown to be essential for viral DNA replication. A protein with similar chromatographic properties and "chloramphenicol resistance" has now been demonstrated in cells infected with lambda bacteriophage.     

Interaction of Bacterial and Lambda Phage Recombination Systems in the X-Ray Sensitivity of Escherichia coli K-12

E. coli cells lysogenic for the thermoinducible prophage lambdacI857 can be transiently induced by a brief heat treatment. Although this treatment does not kill the cells, some lambda products normally formed during vegetative phage development are made that can alter the response of host cells to x-irradiation by causing an increase in radioresistance. This increased resistance is particularly striking in the recombination-deficient recB-strain, which is normally much more radiosensitive than its recB(+) parent. After pulse-heating at 42 degrees , the survival curve of E. coli recB(-) lysogenized with lambdacI857 does not differ from that of the wild-type strain. Since lambda red mutants do not increase the radioresistance of recB(-) strains, both lambda red gene products, lambda exonuclease and beta-protein, are required to compensate for the missing recB product. Furthermore, phage-induced radioresistance also occurs in recB(+) lysogens even when they carry lambda red(-), but not when the lambda prophage is gam(-). Thus, in wild-type cells, phage-induced radioresistance requires some interaction between the bacterial recB gene product (exonuclease V) and the phage lambda-protein.     

Bacteriophage λ Having EcoRI Endonuclease Sites Only in the Nonessential Region of the Genome

A derivative of lambda b221 that has lost by mutation all EcoRI restriction sites has been isolated by alternative growth on restrictive and nonrestrictive strains. It has an efficiency of plating equal to 1 on the restrictive strain. Genetic cross of this bacteriophage with lambda plac5 imm21 gave rise to recombinants of intermediate restricting ratios. The analysis of the EcoRI endonuclease-cleaved DNA by polyacrylamide gel electrophoresis, compared with the genetic results, has permitted identification of EcoRI endonuclease cleavage sites in the recombinants. The genotypes are: lambda plac5 CI857 sRIlambda3(0)sRIlambda2(0)sRIlambda1(0) and lambda plac5 CI857 sRIlambda2(0)sRIlambda1(0). The remaining cleavage sites, respectively, sRIlac sRIlambda4 and sRIlac sRIlambda4 sRIlambda3, are all located in a region nonessential for bacteriophage multiplication. The involvement of these mutant bacteriophages as vector for foreign genes are discussed.     

Characterization of the integration protein of bacteriophage lambda as a site-specific DNA-binding protein.

The Int protein specified by bacteriophage lambda is required for the recombination event that integrates the viral DNA into the host genome at its specific attachment site. Using a DNA-binding assay, we have partially purified the Int protein and studied some of the features of its binding specificity and regulation. The DNA-binding activity is attributed to Int protein because the activity is eliminated by a nonsense mutation or a deletion in the int gene, and is rendered thermolabile by temperature-sensitive mutations in the int gene. The DNA-binding activity is specific for DNA carrying an appropriate attachment site, suggesting that Int protein directs the sequence-specific recognition essential for integrative recombination. The specific DNA-binding activity is also missing after infection by phage carrying mutations in the cII and cIII regulatory genes of lambda. This finding corroborates the conclusion from other types of experiments that regulation of the int and cI genes by cII/cIII provides for coordinate regulation of both major events of the lysogenic response, establishment of repression and insertion of viral DNA.     

Cloning and purification of a unique lysozyme produced by Bacillus phage phi 29.

A DNA fragment of the bacteriophage phi 29 chromosome, encoding the entire sequence of phi 29 gene 15, has been cloned into the Escherichia coli expression vector pPLc245 under the control of the phage lambda major leftward promoter, PL. Upon heat induction, a protein with an apparent molecular mass of 26 kDa was overproduced. The molecular mass of this protein corresponds to the 28 kDa predicted for the product of gene 15 from its nucleotide sequence. The overproduced protein has been purified to near homogeneity and confirmed to be the product of gene 15 by amino acid sequence analysis of its N terminus. The purified product of gene 15 has a lysozyme activity similar to other phage-type lysozymes: products of phage T4 gene e and of phage P22 gene 19. However, to our knowledge phi 29 lysozyme is structurally unique among the phage-type lysozymes.     

A new class of Escherichia coli recBC mutants: implications for the role of RecBC enzyme in homologous recombination.

Mutants of Escherichia coli sensitive to phage T4 gene 2 mutants were obtained following ethyl methanesulfonate mutagenesis. By mapping and complementation analysis, the mutations in each of the six mutants are in recB and recC. By both in vivo and in vitro analyses, the nuclease activity of RecBC enzyme is undetectable in these mutants. However, by several other criteria, such as proficiency in recombination, relative resistance to UV radiation, and viability of the cells in the culture, these mutants are almost identical to their recBC+ parent. The properties of these mutants indicate that the ATP-dependent double-stranded DNA exonuclease activity of RecBC enzyme is not required for recombination. Chi recombinational hotspots, which stimulate recombination by the RecBC pathway, have no detectable activity in the mutants. This result suggests that the nuclease activity of RecBC enzyme is required for Chi activity and is consistent with the hypothesis that Chi stimulates recombination by directing RecBC enzyme to cut DNA at or near Chi.     

Initiation of bacteriophage lambda DNA replication in vitro with purified lambda replication proteins.

We have developed a soluble enzyme system that replicates exogenously added plasmid DNA (lambda dv) bearing the replication origin of the bacteriophage lambda chromosome. The system contains pure phage lambda O and P replication proteins and a partially purified mixture of Escherichia coli replication proteins [the enzyme system of Fuller, R.S., Kaguni, J.M. & Kornberg, A. (1981) Proc. Natl. Acad. Sci. USA 78, 7370-7374). The features of lambda dv replication in this system closely resemble the known characteristics of phage lambda DNA replication in vivo. The system (i) depends completely on exogenously supplied DNA, (ii) specifically replicates supercoiled plasmid DNA that contains a lambda replication origin, (iii) depends on both the lambda O protein and the lambda P protein, (iv) depends on RNA polymerase, (v) depends on host replication proteins (e.g., primase, dnaB protein, and several others that function in the priming of DNA synthesis in E. coli) as judged by antibody inhibitions, and (vi) replicates as much as 32% of added lambda dv plasmid DNA through a single complete round to generate catenated daughter molecules. Furthermore, replication of lambda dv DNA in vitro requires DNA gyrase and an ATP-regenerating system. It is notable that addition of lambda O and P proteins to the mixture of E. coli replication proteins inhibits replication of plasmids bearing the origin of the E. coli chromosome. Exploitation of this enzyme system should allow a detailed investigation of the biochemical mechanisms involved in bacteriophage lambda DNA replication and its regulation.     

Novel bacteriophage lambda cloning vector.

A simple method for generating phage collections representing eukaryotic genomes has been developed by using a novel bacteriophage lambda vector, lambda 1059. The phage is a BamHI substitution vector that accommodates DNA fragments 6-24 kilobases long. Production of recombinants in lambda 1059 requires deletion of the lambda red and gamma genes. The recombinants are therefore spi- and may be separated from the spi+ vector phages by plating on strains lysogenic for bacteriophage P2. Random fragments suitable for insertion into lambda 1059 are obtained by partial digestion of high molecular weight eukaryotic DNA with Sau3a. This restriction enzyme cleaves at the sequence G-A-T-C and leaves a 5'-tetranucleotide "sticky end." Because G-A-T-C extensions are also produced by BamHI cleavage, these fragments may be annealed directly to BamHI-cleaved lambda 1059. By using these methods, a set of clones covering the entire Caenorhabditis elegans genome was constructed. DNA segments which include the unc-54 myosin heavy chain gene have been isolated from this collection.     

RNA Polymerase from Bacillus amyloliquefaciens Infected with ϕ29 Bacteriophage

DNA-dependent RNA polymerase was purified from uninfected and varphi29-infected Bacillus amyloliquefaciens. Differences were observed in the specific activities, template specificities, stability, and sedimentation properties of the two enzymes. A polypeptide of 30,000 molecular weight was found in association with the polymerase of high specific activity from phage-infected cells and was absent from polymerase isolated from uninfected cells. The change in polymerase properties and the appearance of the polypeptide occurred early in phage infection.     

A bacteriophage T7 RNA polymerase/promoter system for controlled exclusive expression of specific genes.

The RNA polymerase gene of bacteriophage T7 has been cloned into the plasmid pBR322 under the inducible control of the lambda PL promoter. After induction, T7 RNA polymerase constitutes 20% of the soluble protein of Escherichia coli, a 200-fold increase over levels found in T7-infected cells. The overproduced enzyme has been purified to homogeneity. During extraction the enzyme is sensitive to a specific proteolysis, a reaction that can be prevented by a modification of lysis conditions. The specificity of T7 RNA polymerase for its own promoters, combined with the ability to inhibit selectively the host RNA polymerase with rifampicin, permits the exclusive expression of genes under the control of a T7 RNA polymerase promoter. We describe such a coupled system and its use to express high levels of phage T7 gene 5 protein, a subunit of T7 DNA polymerase.     

Expression of the denV gene of bacteriophage T4 cloned in Escherichia coli

The denV gene of bacteriophage T4 has been cloned into Escherichia coli K-12 by inserting appropriate fragments of cytosine-containing T4 DNA into the Sal I site of the plasmid pBR322. The denV gene codes for an enzyme that initiates the excision repair of pyrimidine dimers produced in DNA by UV. In uvrA recA mutants, deficient in an early step in excision repair, the cloned DNA results in enhanced UV resistance that is more pronounced in stationary- than in exponential-phase cultures. The expression of the cloned DNA also results in the enhanced survival of UV-irradiated phage lambda or of a denV mutant of phage T4 and in removal of dimers from the DNA of UV-irradiated cells.