Genetic structure of the bacteriophage P22 PL operon

The arms race between bacteria and their phage foes

Bacteria are under immense evolutionary pressure from their viral invaders-bacteriophages. Bacteria have evolved numerous immune mechanisms, both innate and adaptive, to cope with this pressure. The discovery and exploitation of CRISPR-Cas systems have stimulated a resurgence in the identification and characterization of anti-phage mechanisms. Bacteriophages use an extensive battery of counter-defence strategies to co-exist in the presence of these diverse phage defence mechanisms. Understanding the dynamics of the interactions between these microorganisms has implications for phage-based therapies, microbial ecology and evolution, and the development of new biotechnological tools. Here we review the spectrum of anti-phage systems and highlight their evasion by bacteriophages.

Complete Genome Sequence of Salmonella enterica Serovar Typhimurium Myophage Mutine

Mutine is a myophage of Salmonella enterica serovar Typhimurium. Here, we present the complete genome of Mutine (161,502 bp) and show that it is similar to that of phage Vi01.

Complete Genome Sequence of Salmonella enterica Serovar Enteritidis Myophage Mooltan

Salmonella enterica serovar Enteritidis is a Gram-negative bacterium and one of the most common foodborne pathogens. Biocontrol using bacteriophage in food products or animals is one possible means by which pathogenic salmonellosis infection could be inhibited.

Salmonella enterica serovar Enteritidis is a Gram-negative bacterium and one of the most common foodborne pathogens. Biocontrol using bacteriophage in food products or animals is one possible means by which pathogenic salmonellosis infection could be inhibited. Here, we report the complete genome sequence of the T4-like Salmonella Enteritidis myophage Mooltan.

Complete Genome Sequence of Klebsiella pneumoniae Myophage Menlow

Klebsiella pneumoniae is an opportunistic pathogen that has become an increasing problem in nosocomial infections. Studying phages that infect K. pneumoniae may lead to improvements in phage therapeutics for treating these infections. Here, the full genome sequence of Menlow, a Vi01-like phage, is introduced and described.

High coverage metabolomics analysis reveals phage-specific alterations to Pseudomonas aeruginosa physiology during infection

Phage-mediated metabolic changes in bacteria are hypothesized to markedly alter global nutrient and biogeochemical cycles. Despite their theoretic importance, experimental data on the net metabolic impact of phage infection on the bacterial metabolism remains scarce. In this study, we tracked the dynamics of intracellular metabolites using untargeted high coverage metabolomics in Pseudomonas aeruginosa cells infected with lytic bacteriophages from six distinct phage genera. Analysis of the metabolomics data indicates an active interference in the host metabolism. In general, phages elicit an increase in pyrimidine and nucleotide sugar metabolism. Furthermore, clear phage-specific and infection stage-specific responses are observed, ranging from extreme metabolite depletion (for example, phage YuA) to complete reorganization of the metabolism (for example, phage phiKZ). As expected, pathways targeted by the phage-encoded auxiliary metabolic genes (AMGs) were enriched among the metabolites changing during infection. The effect on pyrimidine metabolism of phages encoding AMGs capable of host genome degradation (for example, YuA and LUZ19) was distinct from those lacking nuclease-encoding genes (for example, phiKZ), which demonstrates the link between the encoded set of AMGs of a phage and its impact on host physiology. However, a large fraction of the profound effect on host metabolism could not be attributed to the phage-encoded AMGs. We suggest a potentially crucial role for small, 'non-enzymatic' peptides in metabolism take-over and hypothesize on potential biotechnical applications for such peptides. The highly phage-specific nature of the metabolic impact emphasizes the potential importance of the 'phage diversity' parameter when studying metabolic interactions in complex communities.

The Kil peptide of bacteriophage λ blocks Escherichia coli cytokinesis via ZipA-dependent inhibition of FtsZ assembly

Assembly of the essential, tubulin-like FtsZ protein into a ring-shaped structure at the nascent division site determines the timing and position of cytokinesis in most bacteria and serves as a scaffold for recruitment of the cell division machinery. Here we report that expression of bacteriophage λ kil, either from a resident phage or from a plasmid, induces filamentation of Escherichia coli cells by rapid inhibition of FtsZ ring formation. Mutant alleles of ftsZ resistant to the Kil protein map to the FtsZ polymer subunit interface, stabilize FtsZ ring assembly, and confer increased resistance to endogenous FtsZ inhibitors, consistent with Kil inhibiting FtsZ assembly. Cells with the normally essential cell division gene zipA deleted (in a modified background) display normal FtsZ rings after kil expression, suggesting that ZipA is required for Kil-mediated inhibition of FtsZ rings in vivo. In support of this model, point mutations in the C-terminal FtsZ-interaction domain of ZipA abrogate Kil activity without discernibly altering FtsZ-ZipA interactions. An affinity-tagged-Kil derivative interacts with both FtsZ and ZipA, and inhibits sedimentation of FtsZ filament bundles in vitro. Together, these data inspire a model in which Kil interacts with FtsZ and ZipA in the cell to prevent FtsZ assembly into a coherent, division-competent ring structure. Phage growth assays show that kil+ phage lyse ∼30% later than kil mutant phage, suggesting that Kil delays lysis, perhaps via its interaction with FtsZ and ZipA.

The product of SPO1 gene 56 inhibits host cell division during infection of Bacillus subtilis by bacteriophage SPO1

Although cells of Bacillus subtilis continue to grow after being infected by bacteriophage SPO1, they do not undergo cell division. The product of SPO1 gene 56 is necessary and sufficient for this inhibition of cell division. GP56 inhibits cell division when expressed in uninfected B. subtilis, without preventing cell growth, DNA synthesis or chromosome segregation, ultimately causing filamentation and loss of viability. During infection, a gene 56 mutation prevents the inhibition of cell division that occurs in wild-type infection. Under the laboratory conditions used, the gene 56 mutation did not affect burst size, latent period, or other components of the host-takeover process.

Learning from bacteriophages - advantages and limitations of phage and phage-encoded protein applications

The emergence of bacteria resistance to most of the currently available antibiotics has become a critical therapeutic problem. The bacteria causing both hospital and community-acquired infections are most often multidrug resistant. In view of the alarming level of antibiotic resistance between bacterial species and difficulties with treatment, alternative or supportive antibacterial cure has to be developed. The presented review focuses on the major characteristics of bacteriophages and phage-encoded proteins affecting their usefulness as antimicrobial agents. We discuss several issues such as mode of action, pharmacodynamics, pharmacokinetics, resistance and manufacturing aspects of bacteriophages and phage-encoded proteins application.

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.

Bacteriophage protein-protein interactions

Bacteriophages T7, λ, P22, and P2/P4 (from Escherichia coli), as well as ϕ29 (from Bacillus subtilis), are among the best-studied bacterial viruses. This chapter summarizes published protein interaction data of intraviral protein interactions, as well as known phage-host protein interactions of these phages retrieved from the literature. We also review the published results of comprehensive protein interaction analyses of Pneumococcus phages Dp-1 and Cp-1, as well as coliphages λ and T7. For example, the ≈55 proteins encoded by the T7 genome are connected by ≈43 interactions with another ≈15 between the phage and its host. The chapter compiles published interactions for the well-studied phages λ (33 intra-phage/22 phage-host), P22 (38/9), P2/P4 (14/3), and ϕ29 (20/2). We discuss whether different interaction patterns reflect different phage lifestyles or whether they may be artifacts of sampling. Phages that infect the same host can interact with different host target proteins, as exemplified by E. coli phage λ and T7. Despite decades of intensive investigation, only a fraction of these phage interactomes are known. Technical limitations and a lack of depth in many studies explain the gaps in our knowledge. Strategies to complete current interactome maps are described. Although limited space precludes detailed overviews of phage molecular biology, this compilation will allow future studies to put interaction data into the context of phage biology.

Induction of the SOS response by bacteriophage lytic development in Salmonella enterica

Infection of Salmonella enterica with lytic mutants of either P22 or SE1 bacteriophages triggers the expression of its DNA damage-inducible SOS response through a lexA-dependent pathway. This induction of the SOS system strictly requires the presence of the bacteriophage kil gene. Accordingly, plasmid overexpression of the kil gene also promotes the S. enterica SOS network induction. Furthermore, S. enterica Gifsy prophages are induced following the infection with SE1 and P22 lytic derivatives. The observed data reveal a hitherto unknown SOS system-mediated fail-safe mechanism of resident prophages against infection with heteroimmune lytic bacteriophages and suggest a novel role for the kil family of proteins.

Analysis of the lambdoid prophage element e14 in the E. coli K-12 genome

BACKGROUND

Many sequenced bacterial genomes harbor phage-like elements or cryptic prophages. These elements have been implicated in pathogenesis, serotype conversion and phage immunity. The e14 element is a defective lambdoid prophage element present at 25 min in the E. coli K-12 genome. This prophage encodes important functional genes such as lit (T4 exclusion), mcrA (modified cytosine restriction activity) and pin (recombinase).

RESULTS

Bioinformatic analysis of the e14 prophage sequence shows the modular nature of the e14 element which shares a large part of its sequence with the Shigella flexneri phage SfV. Based on this similarity, the regulatory region including the repressor and Cro proteins and their binding sites were identified. The protein product of b1149 was found to be a fusion of a replication protein and a terminase. The genes b1143, b1151 and b1152 were identified as putative pseudogenes. A number of duplications of the stfE tail fibre gene of the e14 are seen in plasmid p15B. A protein based comparative approach using the COG database as a starting point helped detect lambdoid prophage like elements in a representative set of completely sequenced genomes.

CONCLUSIONS

The e14 element was characterized for the function of its encoded genes, the regulatory regions, replication origin and homology with other phage and bacterial sequences. Comparative analysis at nucleotide and protein levels suggest that a number of important phage related functions are missing in the e14 genome including parts of the early left operon, early right operon and late operon. The loss of these genes is the result of at least three major deletions that have occurred on e14 since its integration. A comparative protein level approach using the COG database can be effectively used to detect defective lambdoid prophage like elements in bacterial genomes.

Lambda Red-mediated recombinogenic engineering of enterohemorrhagic and enteropathogenic E. coli

Background

The λ Red recombineering technology has been used extensively in Escherichia coli and Salmonella typhimurium for easy PCR-mediated generation of deletion mutants, but less so in pathogenic species of E. coli such as EHEC and EPEC. Our early experiments with the use of λ Red in EHEC and EPEC have led to sporadic results, leading to the present study to identify factors that might improve the efficiency of Red recombineering in these pathogenic strains of E. coli.

Results

In this report, we have identified conditions that optimize the use of λ Red for recombineering in EHEC and EPEC. Using plasmids that contain a P_tac-red-gam operon and a temperature-sensitive origin of replication, we have generated multiple mutations (both marked and unmarked) in known virulence genes. In addition, we have easily deleted five O157-specific islands (O-islands) of EHEC suspected of containing virulence factors. We have examined the use of both PCR-generated substrates (40 bp of flanking homology) and plasmid-derived substrates (~1 kb of flanking homology); both work well and each have their own advantages. The establishment of the hyper-rec phenotype requires only a 20 minute IPTG induction period of red and gam. This recombinogenic window is important as constitutive expression of red and gam induces a 10-fold increase in spontaneous resistance to rifampicin. Other factors such as the orientation of the drug marker in recombination substrates and heat shock effects also play roles in the success of Red-mediated recombination in EHEC and EPEC.

Conclusions

The λ Red recombineering technology has been optimized for use in pathogenic species of E. coli, namely EHEC and EPEC. As demonstration of this technology, five O-islands of EHEC were easily and precisely deleted from the chromosome by electroporation with PCR-generated substrates containing drug markers flanked with 40 bp of target DNA. These results should encourage the use of λ Red recombineering in these and other strains of pathogenic bacteria for faster identification of virulence factors and the speedy generation of bacterial mutants for vaccine development.

Corrected sequence of the bacteriophage p22 genome

We report the first accurate genome sequence for bacteriophage P22, correcting a 0.14% error rate in previously determined sequences. DNA sequencing technology is now good enough that genomes of important model systems like P22 can be sequenced with essentially 100% accuracy with minimal investment of time and resources.

Analysis of the role of trans-translation in the requirement of tmRNA for lambdaimmP22 growth in Escherichia coli

The small, stable RNA molecule encoded by ssrA, known as tmRNA or 10Sa RNA, is required for the growth of certain hybrid lambdaimmP22 phages in Escherichia coli. tmRNA has been shown to tag partially synthesized proteins for degradation in vivo by attaching a short peptide sequence, encoded by tmRNA, to the carboxyl termini of these proteins. This tag sequence contains, at its C terminus, an amino acid sequence that is recognized by cellular proteases and leads to degradation of tagged proteins. A model describing this function of tmRNA, the trans-translation model (K. C. Keiler, P. R. Waller, and R. T. Sauer, Science 271:990-993, 1996), proposes that tmRNA acts first as a tRNA and then as a mRNA, resulting in release of the original mRNA template from the ribosome and translocation of the nascent peptide to tmRNA. Previous work from this laboratory suggested that tmRNA may also interact specifically with DNA-binding proteins, modulating their activity. However, more recent results indicate that interactions between tmRNA and DNA-binding proteins are likely nonspecific. In light of this new information, we examine the effects on lambdaimmP22 growth of mutations eliminating activities postulated to be important for two different steps in the trans-translation model, alanine charging of tmRNA and degradation of tagged proteins. This mutational analysis suggests that, while charging of tmRNA with alanine is essential for lambdaimmP22 growth in E. coli, degradation of proteins tagged by tmRNA is required only to achieve optimal levels of phage growth. Based on these results, we propose that trans-translation may have two roles, the primary role being the release of stalled ribosomes from their mRNA template and the secondary role being the tagging of truncated proteins for degradation.

Arrangement and functional identification of genes in the regulatory region of lambdoid phage H-19B, a carrier of a Shiga-like toxin

H-19B is a lambdoid phage that carries the genes (stx-I) encoding the two toxin subunits of a Shiga-like toxin; Escherichia coli lysogens of H-19B are converted to toxin producers. Based on the determination of a 17-kb region of the H-19B genome and functional studies, we have identified the early regulatory region and associated genes of H-19B, as well as the location of the late regulatory region and the toxin and lysis genes. A comparative analysis of the sequence of the H-19B genome reveals the presence of ORFs and genes found in analogous positions on the genomes of a number of other lambdoid phages. A cloned genomic fragment that confers immunity to an infecting H-19B phage contains an ORF of an analogous size and genomic location for a repressor gene, adjacent to a putative operator region. The lambda replication genes, O and P, are conserved in H-19B except for a 39-bp insert in the O gene creating two new O protein-binding sites in the origin of replication (ori), giving H-19B six binding sites as opposed to the four sites found in lambda. We identify ORFs and sequences involved in transcriptional regulation encoding N-like antitermination systems like those found in other lambdoid phages and nearly identical to sequences found in phage HK97. Our functional studies show that these sequences support antitermination even though they contain significant differences from those of other lambdoid phages. We also identify ORFs and sequences analogous to the Q-p'R late antiterminators-promoters found in other lambdoid phages. The Shiga-like stx-I genes are located directly downstream of the promoter, p'R, for the late genes, and upstream of the lysis genes.

Modification enhancement and restriction alleviation by bacteriophage lambda

The activity of EcoKI, and related restriction and modification (R-M) systems, is modulated by the bacteriophage lambda ral gene product. We have identified the coding sequence for an analogous function in the Rac prophage of E. coli K-12.

Restriction alleviation and modification enhancement by the Rac prophage of Escherichia coli K-12

Bacteriophage lambda encodes an antirestriction function, RaI, which is able to modulate the activity of the Escherichia coli K-12 restriction and modification system, EcoKI. Here we report the characterization of an analogous function, Lar, expressed by E. coli sbcA mutants and the hybrid phage lambda reverse. E. coli sbcA mutants and lambda reverse both express genes of the Rac prophage, and we have located the lar gene immediately downstream of recT in this element. The lar gene has been cloned in an expression plasmid, and a combination of site-directed mutagenesis and labelling of plasmid-encoded proteins has enabled us to identify a number of translational products of lar, the smallest of which is sufficient for restriction alleviation. Lar, like RaI, is able both to alleviate restriction and to enhance modification by EcoKI. Lar, therefore, is functionally similar to RaI and the nucleotide sequences of their genes share 47% identity, indicating a common origin. A comparison of the predicted amino acid sequences of Lar and RaI shows only a 25% identity, but a few short regions do align and may indicate residues important for structure and/or function.

A switch in translation mediated by an antisense RNA

Antisense RNAs regulate expression of target genes in a variety of ways--transcription termination, translation initiation, and mRNA stability. We describe a case in which the target gene encodes two polypeptides, and antisense RNA causes a switch in its translation by selectively inhibiting synthesis of one of the polypeptides. Bacteriophage P22 is a temperate Salmonella phage; in the prophage state it expresses only a handful of its genes. One of these genes, sieB, aborts the lytic development of some phages. P22 itself is insensitive to the lethal effect of SieB because it harbors a determinant called esc. We show that the sieB gene encodes two polypeptides--SieB, which is the exclusion protein, and Esc, which is a truncated version of SieB that inhibits its action. Superinfecting P22 synthesizes an antisense RNA, sas, that inhibits synthesis of SieB but allows continued synthesis of Esc, thus allowing P22 to bypass SieB-mediated exclusion. This translational switch induced by sas RNA is essential to vegetatively developing P22; a mutation that prevents this switch causes P22 to commit SieB-mediated suicide. Finally, we show that P22's Esc allows it to circumvent the SieB-mediated exclusion system of bacteriophage lambda.

Superinfection exclusion (sieB) genes of bacteriophages P22 and lambda

The superinfection exclusion gene (sieB) of Salmonella phage P22 was mapped with phage deletion mutants. The DNA sequence in the region was reexamined in order to find an open reading frame consistent with the deletion mapping. Several discrepancies with the previously published sequence were discovered. The revised sequence revealed a single open reading frame of 242 codons with six likely translation initiation codons. On the basis of deletion and amber mutant phenotypes, the second of these six sites was inferred to be the translation initiation site of the sieB gene. The sieB gene encodes a polypeptide with 192 amino acid residues with a calculated molecular weight of 22,442, which is in reasonable agreement with that estimated from polyacrylamide gels. The transcription start site of sieB was identified by the use of an RNase protection assay. The sieB promoter thus identified was inactivated by a 2-base substitution in its -10 hexamer. The sieB gene of coliphage lambda was also identified. The promoter for lambda sieB was identified by homology to that of P22 sieB.

The int genes of bacteriophages P22 and lambda are regulated by different mechanisms

Bacteriophage P22 and lambda are related bacteriophages with similar gene organizations. In lambda the cll-dependent Pl promoter is responsible for lambda int gene expression. The only apparent counterpart to pl in P22 is oriented in the opposite direction, and cannot transcribe the P22 int gene. We show that this promoter, called P(al), is active both in vivo and in vitro, and is dependent upon the P22 cll-like gene, called c1. We have also determined the DNA sequence of a 3.3 kb segment that closes the gap between previously reported sequences to give a continuous sequence between the P22 pL promoter and the int gene. The newly determined sequence is densely packed with genes from the pL direction, and the proteins predicted by the sequence show excellent correlation with the proteins mapped by Youderian and Susskind in 1980. However, the sequence contains no apparent genes in the opposite (p(al)) direction, and no additional binding motifs for the P22 c1 protein. We conclude that int gene expression in P22 is regulated by a different mechanism than in lambda.

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-).

The activity of the CIII regulator of lambdoid bacteriophages resides within a 24-amino acid protein domain

The CIII protein of lambdoid bacteriophages promotes lysogeny by stabilizing the phage-encoded CII protein, a transcriptional activator of the repressor and integrase genes. We have isolated a set of missense mutations in the cIII gene of phage lambda and of phage HK022 that yield inactive CIII proteins. All the mutations are located in the relatively conserved central region of the protein. A comparative analysis of the CIII protein sequence in lambda, HK022, and the lambdoid bacteriophage P22 leads us to suggest that this central region assumes an amphipathic alpha-helical structure. This part of the lambda cIII gene was cloned within a fragment of the lacZ gene (the alpha-complementing fragment). The resulting fusion protein displays CIII activity. Mutations that yield a nonfunctional fusion protein map within its CIII moiety. These results indicate that the central portion of the CIII protein is both necessary and sufficient for CIII activity.

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.