Localization of a DNA-binding determinant in the bacteriophage P22 Erf protein

λ Recombination and Recombineering

The bacteriophage λ Red homologous recombination system has been studied over the past 50 years as a model system to define the mechanistic details of how organisms exchange DNA segments that share extended regions of homology. The λ Red system proved useful as a system to study because recombinants could be easily generated by co-infection of genetically marked phages. What emerged from these studies was the recognition that replication of phage DNA was required for substantial Red-promoted recombination in vivo, and the critical role that double-stranded DNA ends play in allowing the Red proteins access to the phage DNA chromosomes. In the past 16 years, however, the λ Red recombination system has gained a new notoriety. When expressed independently of other λ functions, the Red system is able to promote recombination of linear DNA containing limited regions of homology (∼50 bp) with the Escherichia coli chromosome, a process known as recombineering. This review explains how the Red system works during a phage infection, and how it is utilized to make chromosomal modifications of E. coli with such efficiency that it changed the nature and number of genetic manipulations possible, leading to advances in bacterial genomics, metabolic engineering, and eukaryotic genetics.

Domain Structure of the Redβ Single-Strand Annealing Protein: the C-terminal Domain is Required for Fine-Tuning DNA-binding Properties, Interaction with the Exonuclease Partner, and Recombination in vivo

Redβ is a component of the Red recombination system of bacteriophage λ that promotes a single strand annealing (SSA) reaction to generate end-to-end concatemers of the phage genome for packaging. Redβ interacts with λ exonuclease (λexo), the other component of the Red system, to form a "synaptosome" complex that somehow integrates the end resection and annealing steps of the reaction. Previous work using limited proteolysis and chemical modification revealed that Redβ consists of an N-terminal DNA binding domain, residues 1-177, and a flexible C-terminal "tail", residues 178-261. Here, we quantitatively compare the binding of the full-length protein (Redβ(FL)) and the N-terminal domain (Redβ(177)) to different lengths of ssDNA substrate and annealed duplex product. We find that in general, Redβ(FL) binds more tightly to annealed duplex product than to ssDNA substrate, while Redβ(177) binds more tightly to ssDNA. In addition, the C-terminal region of Redβ corresponding to residues 182-261 was purified and found to fold into an α-helical domain that is required for the interaction with λexo to form the synaptosome complex. Deletion analysis of Redβ revealed that removal of just eleven residues from the C-terminus disrupts the interaction with λexo as well as ssDNA and dsDNA recombination in vivo. By contrast, the determinants for self-oligomerization of Redβ appear to reside solely within the N-terminal domain. The subtle but significant differences in the relative binding of Redβ(FL) and Redβ(177) to ssDNA substrate and annealed duplex product may be important for Redβ to function as a SSA protein in vivo.

Phage recombinases and their applications

The homologous recombination systems of linear double-stranded (ds)DNA bacteriophages are required for the generation of genetic diversity, the repair of dsDNA breaks, and the formation of concatemeric chromosomes, the immediate precursor to packaging. These systems have been studied for decades as a means to understand the basic principles of homologous recombination. From the beginning, it was recognized that these recombinases are linked intimately to the mechanisms of phage DNA replication. In the last decade, however, investigators have exploited these recombination systems as tools for genetic engineering of bacterial chromosomes, bacterial artificial chromosomes, and plasmids. This recombinational engineering technology has been termed "recombineering" and offers a new paradigm for the genetic manipulation of bacterial chromosomes, which is far more efficient than the classical use of nonreplicating integration vectors for gene replacement. The phage λ Red recombination system, in particular, has been used to construct gene replacements, deletions, insertions, inversions, duplications, and single base pair changes in the Escherichia coli chromosome. This chapter discusses the components of the recombination systems of λ, rac prophage, and phage P22 and properties of single-stranded DNA annealing proteins from these and other phage that have been instrumental for the development of this technology. The types of genetic manipulations that can be made are described, along with proposed mechanisms for both double-stranded DNA- and oligonucleotide-mediated recombineering events. Finally, the impact of this technology to such diverse fields as bacterial pathogenesis, metabolic engineering, and mouse genomics is discussed.

Isolation of lactococcal prolate phage-phage recombinants by an enrichment strategy reveals two novel host range determinants

Virulent lactococcal prolate (or c2-like) phages are the second most common phage group that causes fermentation failure in the dairy industry. We have mapped two host range determinants in two lactococcal prolate phages, c2 and 923, for the host strains MG1363 and 112. Each phage replicates on only one of the two host strains: c2 on MG1363 and 923 on 112. Phage-phage recombinants that replicated on both strains were isolated by a new method that does not require direct selection but rather employs an enrichment protocol. After initial mixed infection of strain 112, two rotations, the first of which was carried out on strain MG1363 and the second on 112, permitted continuous amplification of double-plating recombinants while rendering one of the parent phages unamplified in each of the two rotations. Mapping of the recombination endpoints showed that the presence of the N-terminal two-thirds of the tail protein L10 of phage c2 and a 1,562-bp cosR-terminal fragment of phage 923 genome overcame blocks of infection in strains MG1363 and 112, respectively. Both infection inhibition mechanisms act at the stage of DNA entry; in strain MG1363, the infection block acts early, before phage DNA enters the cytoplasm, and in strain 112, it acts late, after most of the DNA has entered the cell but before it undergoes cos-end ligation. These are the first reported host range determinants in bacteriophage of lactic acid bacteria required for overcoming inhibition of infection at the stage of DNA entry and cos-end ligation.

Lactococcal phage genes involved in sensitivity to AbiK and their relation to single-strand annealing proteins

Lactococcal phage mutants insensitive to the antiviral abortive infection mechanism AbiK are divided into two classes. One comprises virulent phages that result from DNA exchanges between a virulent phage and the host chromosome. Here, we report the analysis of the second class of phage mutants, which are insensitive to AbiK as a result of a single nucleotide change causing an amino acid substitution. The mutated genes occupy the same position in the various lactococcal phage genomes, but the deduced proteins do not share amino acid sequence similarity. Four nonsimilar proteins involved in the sensitivity to AbiK (Sak) were identified. Two of these Sak proteins are related to Erf and RAD52, single-strand annealing proteins involved in homologous recombination.

Phage conversion of Panton-Valentine leukocidin in Staphylococcus aureus : molecular analysis of a PVL-converting phage, φSLT

Staphylococcal Panton-Valentine leukocidin (PVL) is an important virulence factor, which causes leukocytolysis and tissue necrosis. Our previous report on the existence of the PVL genes (lukS-PV and lukF-PV) on the genome of prophage phiPVL in the Staphylococcus aureus strain V8 suggested the horizontal transmission of PVL genes by temperate bacteriophage among S. aureus (Kaneko, et al., 1998. Gene 215, 57-67). Here, we demonstrated the phage conversion of S. aureus leading to the production of PVL by discovery of a novel PVL-carrying phage, phiSLT (Staphylococcal Leukocytolytic Toxin) from a clinical isolate of S. aureus. phiSLT was able to lysogenize several clinical isolates of PVL-negative S. aureus strains as well as strain RN4220 at the conserved 29-bp sequence (attB) and all the lysogenized S. aureus strains had the ability to produce PVL. phiSLT had an elongated head of about 100x50 nm and a flexible tail of 400 nm long, that was quite different from phiPVL which had an isometric hexagonal head of about 60 nm diameter. The linear double-stranded phiSLT genome comprised 42,942 bp with 29-bp attachment core sequences and contained 62 open reading frames. Only 6.4 kbp region containing lysis cassette, PVL genes, attP, integrase, and orf204 of phiSLT was identical to that of phiPVL, while other regions were different from those of phiPVL. Thus, it can be concluded that PVL genes are carried by different temperate phages, which have the same attachment site.

Prophage, phiPV83-pro, carrying panton-valentine leukocidin genes, on the Staphylococcus aureus P83 chromosome: comparative analysis of the genome structures of phiPV83-pro, phiPVL, phi11, and other phages

Staphylococcus aureus P83 has Panton-Valentine leukocidin (PVL)-like genes, lukM and lukF-PV. Here, lukM and lukF-PV genes were found on the genome of a prophage, which was designated as phiPV83-pro. The precise genome size was 45,636 bp with att core sequences of 10 base pairs. Sixty-four ORFs were identified on the phiPV83-pro genome, including two extra operons, lukM-lukF-PV and orfs63-64. The lukM-lukF-PV cluster was located 2.1 kb upstream of the attL site. The most striking feature of the phiPV83-pro genome was a constituent of at least 4 regions from phi11, phiPVL, and other phages, i.e., (i) att sites identical with those of phi11, (ii) a cos sequence and the genes encoding packaging and head proteins of phiPVL (occupied half region of phiPV83-pro), and (iii) the other two regions which showed no significant similarity with known phages (occupied about 40% of phiPV83-pro). Furthermore, two insertion sequences, ISSA1 and ISSA2 were integrated into attL site and orf44, respectively. PhiPV83-pro was not induced as phage particles from S. aureus P83 regardless of its treatment with mitomycin C. The insertion of ISSA1 into the attL site was one of the reasons of the failure of the induction of the phage particles by mitomycin C treatment of the strain P83.

Genomic sequences of bacteriophages HK97 and HK022: pervasive genetic mosaicism in the lambdoid bacteriophages

We report the complete genome DNA sequences of HK97 (39,732 bp) and HK022 (40,751 bp), double-stranded DNA bacteriophages of Escherichia coli and members of the lambdoid or lambda-like group of phages. We provide a comparative analysis of these sequences with each other and with two previously determined lambdoid family genome sequences, those of E. coli phage lambda and Salmonella typhimurium phage P22. The comparisons confirm that these phages are genetic mosaics, with mosaic segments separated by sharp transitions in the sequence. The mosaicism provides clear evidence that horizontal exchange of genetic material is a major component of evolution for these viruses. The data suggest a model for evolution in which diversity is generated by a combination of illegitimate and homologous recombination and mutational drift, and selection for function produces a population in which most of the surviving mosaic boundaries are located at gene boundaries or, in some cases, at protein domain boundaries within genes. Comparisons of these genomes highlight a number of differences that allow plausible inferences of specific evolutionary scenarios for some parts of the genome. The comparative analysis also allows some inferences about function of genes or other genetic elements. We give examples for the generalized recombination genes of HK97, HK022 and P22, and for a putative headtail adaptor protein of HK97 and HK022. We also use the comparative approach to identify a new class of genetic elements, the morons, which consist of a protein-coding region flanked by a putative delta 70 promoter and a putative factor-independent transcription terminator, all located between two genes that may be adjacent in a different phage. We argue that morons are autonomous genetic modules that are expressed from the repressed prophage. Sequence composition of the morons implies that they have entered the phages' genomes by horizontal transfer in relatively recent evolutionary time.

Bacteriophage P22 Abc2 protein binds to RecC increases the 5' strand nicking activity of RecBCD and together with lambda bet, promotes Chi-independent recombination

Bacteriophage P22 Abc2 protein binds to the RecBCD enzyme from Escherichia coli to promote phage growth and recombination. Overproduction of the RecC subunit in vivo, but not RecB or RecD, interfered with Abc2-induced UV sensitization, revealing that RecC is the target for Abc2 in vivo. UV-induced ATP crosslinking experiments revealed that Abc2 protein does not interfere with the binding of ATP to either the RecB or RecD subunits in the absence of DNA, though it partially inhibits RecBCD ATPase activity. Productive growth of phage P22 in wild-type Salmonella typhimurium correlates with the presence of Abc2, but is independent of the absolute level of ATP-dependent nuclease activity, suggesting a qualitative change in the nature of Abc2-modified RecBCD nuclease activity relative to the native enzyme. In lambda phage crosses, Abc2-modified RecBCD could substitute for lambda exonuclease in Red-promoted recombination; lambda Gam could not. In exonuclease assays designed to examine the polarity of digestion, Abc2 protein qualitatively changes the nature of RecBCD double-stranded DNA exonuclease by increasing the rate of digestion of the 5' strand. In this respect, Abc2-modified RecBCD resembles a RecBCD molecule that has encountered the recombination hotspot Chi. However, unlike Chi-modified RecBCD, Abc2-modified RecBCD still possesses 3' exonuclease activity. These results are discussed in terms of a model in which Abc2 converts the RecBCD exonuclease for use in the P22 phage recombination pathway. This mechanism of P22-mediated recombination distinguishes it from phage lambda recombination, in which the phage recombination system (Red) and its anti-RecBCD function (Gam) work independently.

Properties of Escherichia coli expressing bacteriophage P22 Abc (anti-RecBCD) proteins, including inhibition of Chi activity

Escherichia coli strains bearing plasmids expressing phage P22 anti-RecBCD functions abc1 and abc2 were tested for the presence of recBC-like phenotypes. Abc2 induces moderate sensitivity to UV light in wild-type and recD mutant strains but severely sensitizes both recF and recJ mutants. Abc1 has little effect on UV sensitivity in wild-type or recF or recJ mutant hosts but increases the sensitivity of recD mutants to a UV dose of 20 J/m2 about 10-fold. Abc2 induces E. coli to segregate inviable cells during growth, interferes with the growth of lambda red gam chi+ and chi 0 phage (the effect is greater with chi+ phage), inhibits Chi and Chi-like activity as measured by lambda red gam crosses, and prevents SOS induction in response to nalidixic acid; Abc1 has no effect in these tests. Abc2, alone or with Abc1, does not allow the growth of lambda red gam in the presence of a P2 prophage but does not kill the P2 lysogenic host (as lambda Gam does). Finally, Abc2 inhibits conjugational recombination in wild-type cells to the level seen in recBC mutants. These data suggest that Abc2 inhibits the recombination-promoting ability of RecBCD but leaves the exonuclease functions intact.

Lambda Gam protein inhibits the helicase and chi-stimulated recombination activities of Escherichia coli RecBCD enzyme

The lambda Gam protein was isolated from cells containing a Gam-producing plasmid. The purified Gam protein was found to bind to RecBCD without displacing any of its subunits. Gam was shown to inhibit all known enzymatic activities of RecBCD: ATP-dependent single- and double-stranded DNA exonucleases, ATP-independent single-stranded endonuclease, and the ATP-dependent helicase. When produced in vivo, Gam inhibited chi-activated recombination in lambda red gam crosses but had little effect on the host's ability to act as a recipient in conjugational recombination. These experiments suggest that RecBCD possesses an additional "unknown" activity that is resistant to or induced by Gam. Additionally, the expression of Gam in recD mutants sensitizes the host to UV irradiation, indicating that Gam alters one or more of the in vivo activities of RecBC(D-).

Bacteriophage P22 accessory recombination function

The accessory recombination function (arf) gene of bacteriophage P22 is located immediately upstream of the essential recombination function (erf) gene. Three mutant alleles of arf were constructed and installed in P22 in place of the wild-type allele: an out-of-frame internal deletion, an in-frame internal deletion, and an amber mutation. The deletion mutant phages are partially defective in homologous recombination and plaque formation in wild-type and recA hosts; their defects are more severe in recB and recA recB hosts. The amber mutant phage exhibits the same growth phenotypes in nonsuppressing hosts, but not in an amber-suppressor host. Plasmids that express arf complement the growth defect of arf- phages. These plasmids stimulate erf-mediated recombination; they were also found to cause a small stimulation of recA-recBCD-mediated homologous recombination of phage lambda.

Sequence of the bacteriophage P22 anti-recBCD (abc) genes and properties of P22 abc region deletion mutants

The nucleotide sequence of a segment of the bacteriophage P22 chromosome to the left (downstream in the PL operon) of the erf gene was determined. Previous studies (A. C. Fenton and A. R. Poteete, 1984, Virology 134, 148-160) have shown that this region encodes a function that is required for efficient growth of P22 in wild-type, but not in recB- Salmonella. The gene or genes encoding this function were designated abc (anti-recBCD). The DNA sequence reveals three open reading frames that potentially encode polypeptides with molecular weights of 10,900, 11,600, and 6600 (in order of transcription). P22 deletion mutants lacking each of the open reading frames were constructed. In addition, plasmids were constructed placing each of the open reading frames under control of the lac UV5 promoter. The phenotypes of the deletion mutants, and the results of plasmid-phage complementation tests, indicate that Abc activity depends primarily on sequences that encode the 11.6-kDa polypeptide; the 10.9-kDa polypeptide-encoding sequence makes a minor contribution to Abc activity as well. These sequences have been designated abc2 and abc1, respectively. The 6.6-kDa polypeptide is apparently uninvolved.