N15: the linear phage-plasmid

The lambdoid phage N15 of Escherichia coli is very unusual among temperate phages in that its prophage is not integrated into chromosome but is a linear plasmid molecule with covalently closed ends. Upon infection the phage DNA circularises via cohesive ends, then phage-encoded enzyme, protelomerase, cuts at an inverted repeat site and forms hairpin ends (telomeres) of the linear plasmid prophage. Replication of the N15 prophage is initiated at an internally located ori site and proceeds bidirectionally resulting in formation of duplicated telomeres. Then the N15 protelomerase cuts duplicated telomeres generating two linear plasmid molecules with hairpin telomeres. Stable inheritance of the plasmid prophage is ensured by partitioning operon similar to the F factor sop operon. Unlike F sop, the N15 centromere consists of four inverted repeats dispersed in the genome. The multiplicity and dispersion of centromeres are required for efficient partitioning of a linear plasmid. The centromeres are located in N15 genome regions involved in phage replication and control of lysogeny, and binding of partition proteins at these sites regulates these processes. Two N15-related lambdoid Siphoviridae phages, φKO2 in Klebsiella oxytoca and pY54 in Yersinia enterocolitica, also lysogenize their hosts as linear plasmids, as well as Myoviridae marine phages VP882 and VP58.5 in Vibrio parahaemolyticus and ΦHAP-1 in Halomonas aquamarina. The genomes of all these phages contain similar protelomerase genes, lysogeny modules and replication genes, as well as plasmid-partitioning genes, suggesting that these phages may belong to a group diverged from a common ancestor.     

The temperate marine phage PhiHAP-1 of Halomonas aquamarina possesses a linear plasmid-like prophage genome

A myovirus-like temperate phage, PhiHAP-1, was induced with mitomycin C from a Halomonas aquamarina strain isolated from surface waters in the Gulf of Mexico. The induced cultures produced significantly more virus-like particles (VLPs) (3.73 x 10(10) VLP ml(-1)) than control cultures (3.83 x 10(7) VLP ml(-1)) when observed with epifluorescence microscopy. The induced phage was sequenced by using linker-amplified shotgun libraries and contained a genome 39,245 nucleotides in length with a G+C content of 59%. The PhiHAP-1 genome contained 46 putative open reading frames (ORFs), with 76% sharing significant similarity (E value of <10(-3)) at the protein level with other sequences in GenBank. Putative functional gene assignments included small and large terminase subunits, capsid and tail genes, an N6-DNA adenine methyltransferase, and lysogeny-related genes. Although no integrase was found, the PhiHAP-1 genome contained ORFs similar to protelomerase and parA genes found in linear plasmid-like phages with telomeric ends. Southern probing and PCR analysis of host genomic, plasmid, and PhiHAP-1 DNA indicated a lack of integration of the prophage with the host chromosome and a difference in genome arrangement between the prophage and virion forms. The linear plasmid prophage form of PhiHAP-1 begins with the protelomerase gene, presumably due to the activity of the protelomerase, while the induced phage particle has a circularly permuted genome that begins with the terminase genes. The PhiHAP-1 genome shares synteny and gene similarity with coliphage N15 and vibriophages VP882 and VHML, suggesting an evolutionary heritage from an N15-like linear plasmid prophage ancestor.     

The plasmid prophage N15: a linear DNA with covalently closed ends

Coliphage N15 is a temperate bacteriophage whose prophage is a linear plasmid molecule with covalently closed ends (telomeres). The N15 prophage provided the first example of such DNA in prokaryotes and, up to now, it is the only known example of a linear plasmid in Escherichia coli. The linear N15 mature phage DNA has single-stranded cohesive ends. The phage and plasmid prophage DNAs are circularly permuted. The nucleotide structure of the telomere-forming site tel RL in phage DNA corresponds to the structures of the terminal hairpin loops. It suggests a unique mechanism for conversion of the circular phage DNA to the linear plasmid form, which is performed by the prokaryotic telomerase (protelomerase). The results of a comparison of the protelomerase with integrases lead us to suggest that these proteins may have evolved from a common ancestor. The mechanism of plasmid N15 replication is unknown. We propose that the protelomerase participates in linear plasmid replication, acting as a resolvase of replicative intermediates that are tail-to-tail linear dimers. The sequence analysis of the N15 DNA showed that it represents an evolutionary 'link' between plasmids F, P1, P4 and lambdoid bacteriophages.     

The Bacteriophage HK97 gp15 Moron Element Encodes a Novel Superinfection Exclusion Protein

A phage moron is a DNA element inserted between a pair of genes in one phage genome that are adjacent in other related phage genomes. Phage morons are commonly found within phage genomes, and in a number of cases, they have been shown to mediate phenotypic changes in the bacterial host. The temperate phage HK97 encodes a moron element, gp15, within its tail morphogenesis region that is absent in most closely related phages. We show that gp15 is actively expressed from the HK97 prophage and is responsible for providing the host cell with resistance to infection by phages HK97 and HK75, independent of repressor immunity. To identify the target(s) of this gp15-mediated resistance, we created a hybrid of HK97 and the related phage HK022. This hybrid phage revealed that the tail tube or tape measure proteins likely mediate the susceptibility of HK97 to inhibition by gp15. The N terminus of gp15 is predicted with high probability to contain a single membrane-spanning helix by several transmembrane prediction programs. Consistent with this putative membrane localization, gp15 acts to prevent the entry of phage DNA into the cytoplasm, acting in a manner reminiscent of those of several previously characterized superinfection exclusion proteins. The N terminus of gp15 and its phage homologues bear sequence similarity to YebO proteins, a family of proteins of unknown function found ubiquitously in enterobacteria. The divergence of their C termini suggests that phages have co-opted this bacterial protein and subverted its activity to their advantage.     

The antirepressor needed for induction of linear plasmid-prophage N15 belongs to the SOS regulon

The physiological conditions and molecular interactions that control phage production have been studied in only a few families of temperate phages. We investigated the mechanisms that regulate activation of lytic development in lysogens of coliphage N15, a prophage that is not integrated into the host chromosome but exists as a linear plasmid with covalently closed ends. We identified the N15 antirepressor gene, antC, and showed that its product binds to and acts against the main phage repressor, CB. LexA binds to and represses the promoter of antC. Mitomycin C-stimulated N15 induction required RecA-dependent autocleavage of LexA and expression of AntC protein. Thus, a cellular repressor whose activity is regulated by DNA damage controls N15 prophage induction.     

PY54, a linear plasmid prophage of Yersinia enterocolitica with covalently closed ends

PY54 is a temperate phage isolated from Yersinia enterocolitica. Lysogenic Yersinia strains harbour the PY54 prophage as a plasmid (pY54). The plasmid has the same size (46 kb) as the PY54 genome isolated from phage particles. By electron microscopy, restriction analysis and DNA sequencing, it was demonstrated that the phage and the plasmid DNAs are linear, circularly permuted molecules. Unusually for phages of Gram-negative bacteria, the phage genome has 3'-protruding ends. The linear plasmid pY54 has covalently closed ends forming telomere-like hairpins. The equivalent DNA sequence of the phage genome is a 42 bp perfect palindrome. Downstream from the palindrome, an open reading frame (ORF) was identified that revealed strong DNA homology to the telN gene of Escherichia coli phage N15 encoding a protelomerase. Similar to PY54, the N15 prophage is a linear plasmid with telomeres. The N15 protelomerase has cleaving/joining activity generating the telomeres by processing a 56 bp palindrome (telomere resolution site tel RL). To study the activity of the PY54 protein, the telN-like gene was cloned and expressed in E. coli. A 77 kDa protein was obtained and partially purified. The protein was found to process recombinant plasmids containing the 42 bp palindrome. Telomere resolution of plasmids under in vivo conditions was also investigated in Yersinia infected with PY54. Processing required a plasmid containing the palindrome as well as adjacent DNA sequences from the phage including an additional inverted repeat. Regions on the phage genome important for plasmid maintenance were defined by the construction of linear and circular miniplasmid derivatives of pY54, of which the smallest miniplasmid comprises a 4.5 kb DNA fragment of the plasmid prophage.     

Sop proteins can cause transcriptional silencing of genes located close to the centromere sites of linear plasmid N15

Stable inheritance of bacterial chromosomes and low copy number plasmids is ensured by accurate partitioning of replicated molecules between the daughter cells at division. Partitioning of the prophage of the temperate bacteriophage N15, which exists as a linear plasmid molecule with covalently closed ends, depends on the sop locus, comprising genes sopA and sopB, as well as four centromere sites in different regions of the N15 genome essential for replication and the control of lysogeny. We found that binding of SopB to the centromere could silence centromere-proximal promoters, presumably due to subsequent polymerization of SopB along the DNA. Close to the IR4 centromere site we identified a promoter, P59, which was able to drive the expression of phage late genes encoding structural proteins of virion. We found that, following binding to IR4, the N15 Sop proteins could induce repression of this promoter. The repression depended on SopB and was enhanced in the presence of SopA. Sop-dependent silencing of centromere-proximal promoters may control gene expression in phage N15, particularly preventing undesired expression of late genes in the N15 prophage. Thus, the phage N15 sop system not only ensures plasmid partitioning but is also involved in the genetic network controlling prophage replication and the maintenance of lysogeny.     

The protelomerase of the phage-plasmid N15 is responsible for its maintenance in linear form

The prophage of coliphage N15 is not integrated into the bacterial chromosome but exists as a linear plasmid molecule with covalently closed ends. Upon infection of an Escherichia coli cell, the phage DNA circularises via cohesive ends. A phage-encoded enzyme, protelomerase, then cuts at another site, telRL, and forms hairpin ends (telomeres). We demonstrate that this enzyme acts in vivo on specific substrates, and show that it is necessary for replication of the linear prophage. We show that protelomerase is an end-resolving enzyme responsible for processing of replicative intermediates. Removal of protelomerase activity resulted in accumulation of replicative intermediates that were found to be circular head-to-head dimers. N15 protelomerase and its target site constitute a functional unit acting on other replicons independently of other phage genes; a mini-F or mini-P1 plasmid carrying this unit replicates as a linear plasmid with covalently closed ends. Our results suggest the following model of N15 prophage DNA replication. Replication is initiated at an internal ori site located close to the left end of plasmid DNA and proceeds bidirectionally. After replication of the left telomere, protelomerase cuts this sequence and forms two hairpin loops telL. After duplication of the right telomere (telR) the same enzyme resolves this sequence producing two linear plasmids. Alternatively, full replication of the linear prophage to form a circular head-to-head dimer may precede protelomerase-mediated formation of hairpin ends.     

Expression regulation of the protelomerase gene of the bacteriophage N15

The N15 bacteriophage, when in the lysogenic state, does not integrate into the chromosome; in fact, it exists as a linear plasmid with the covalently closed ends. Upon infection, the phage DNA circularizes via its cohesive ends, after which a specific enzyme, the N15 protelomerase, cuts the circular molecule thus generating a linear plasmid with the covalently closed telomeres. Protelomerase generates, as the replication of plasmid prophage proceeds, the hairpin telomeres in replicated molecules. We identified the promoter of the protelomerase gene and demonstrated that it could be repressed presumably due to its binding with 3 tosL sites overlapping the promoter. We also found the transformation efficiency of E. coli cells of linear DNA with hairpin telomeres to be approximately 100-fold lower versus the circular DNA of the same size. At the same time, presence of the N15 prophage or of the protelomerase-expressing vector enhances, in a strain being transformed, the efficiency of its transformation by linear DNA up to a level ensured in transformation by circular plasmids. We believe that protelomerase, while binding with the hairpin telomeres, protects the latter from degradation by cellular nucleases.     

Bacteriophage Mu genome sequence: analysis and comparison with Mu-like prophages in Haemophilus, Neisseria and Deinococcus

We report the complete 36,717 bp genome sequence of bacteriophage Mu and provide an analysis of the sequence, both with regard to the new genes and other genetic features revealed by the sequence itself and by a comparison to eight complete or nearly complete Mu-like prophage genomes found in the genomes of a diverse group of bacteria. The comparative studies confirm that members of the Mu-related family of phage genomes are genetically mosaic with respect to each other, as seen in other groups of phages such as the phage lambda-related group of phages of enteric hosts and the phage L5-related group of mycobacteriophages. Mu also possesses segments of similarity, typically gene-sized, to genomes of otherwise non-Mu-like phages. The comparisons show that some well-known features of the Mu genome, including the invertible segment encoding tail fiber sequences, are not present in most members of the Mu genome sequence family examined here, suggesting that their presence may be relatively volatile over evolutionary time.The head and tail-encoding structural genes of Mu have only very weak similarity to the corresponding genes of other well-studied phage types. However, these weak similarities, and in some cases biochemical data, can be used to establish tentative functional assignments for 12 of the head and tail genes. These assignments are strongly supported by the fact that the order of gene functions assigned in this way conforms to the strongly conserved order of head and tail genes established in a wide variety of other phages. We show that the Mu head assembly scaffolding protein is encoded by a gene nested in-frame within the C-terminal half of another gene that encodes the putative head maturation protease. This is reminiscent of the arrangement established for phage lambda.     

Selection of lambda Spi- transducing phages using the P2 old gene cloned onto a plasmid

The old gene product of the P2 prophage interferes with plaque formation by lambda wild type phage but allows lambda phages whose red and gam genes have been deleted to form small, visible plaques (the lambda Spi- phenotype). The old gene product also kills Escherichia coli recB or recC mutants. We have cloned the old gene into the high-copy-number plasmid pBR322, where it prevents plaque formation by both lambda Spi+ and lambda Spi- phages. We transferred a DNA fragment that carries the old gene to the low-copy-number plasmid pSC101 and found that lambda Spi- phages can be selected on strains that carry this plasmid. The plasmid-borne old gene kills E. coli recB mutants, providing a selection for old- mutants.     

Mechanisms of replication and telomere resolution of the linear plasmid prophage N15

The prophage of coliphage N15 is not integrated into the bacterial chromosome but exists as a linear plasmid molecule with covalently closed ends. Upon infection of an Escherichia coli cell, the phage DNA circularizes via cohensive ends. A phage-encoded enzyme, protelomerase, then cuts at another site, telRL, and forms hairpin ends (telomeres). Purified protelomerase alone processes circular and linear plasmid DNA containing the target site telRL to produce linear double-stranded DNA with covalently closed ends in vitro. N15 protelomerase is necessary for replication of the linear prophage through its action as a telomere-resolving enzyme. Replication of circular N15-based miniplasmids requires the only gene repA that encodes multidomain protein homologous to replication proteins of bacterial plasmids replicated by theta-mechanism, particularly, phage P4 alpha-replication protein. Replication of the N15 prophage is initiated at an internal ori site located within repA. Bidirectional replication results in formation of the circular head-to-head, tail-to-tail dimer molecule. Then the N15 protelomerase cuts both duplicated telomeres generating two linear plasmid molecules with covalently closed ends. The N15 prophage replication thus appears to follow the mechanism distinct from that employed by poxviruses and could serve as a model for other prokaryotic replicons with hairpin ends, and particularly, for linear plasmids and chromosomes of Borrelia burgdorferi.     

Isolation, characterization and mapping of the N15 phasmid insertion mutations]

Prophage of N15 temperate bacteriophage is stably maintained in Escherichia coli lysogens as a 46.33 kb linear plasmid. Using different transposons we obtained 18 insertion mutants of the N15 plasmid prophage. They were analysed for plaque formation ability, stability of the plasmid state and lysogenic conversion. Restriction mapping of the insertions allowed us to localize on the map the regions necessary for lytic growth and to map the lysogenic conversion gene. A recombinant phage encoding two antibiotic resistance genes was obtained. The phage contains an additional 4.77 kb DNA fragment (over 10% of the N15 genome).     

Mapping the Tail Fiber as the Receptor Binding Protein Responsible for Differential Host Specificity of Pseudomonas aeruginosa Bacteriophages PaP1 and JG004

The first step in bacteriophage infection is recognition and binding to the host receptor, which is mediated by the phage receptor binding protein (RBP). Different RBPs can lead to differential host specificity. In many bacteriophages, such as Escherichia coli and Lactococcal phages, RBPs have been identified as the tail fiber or protruding baseplate proteins. However, the tail fiber-dependent host specificity in Pseudomonas aeruginosa phages has not been well studied. This study aimed to identify and investigate the binding specificity of the RBP of P. aeruginosa phages PaP1 and JG004. These two phages share high DNA sequence homology but exhibit different host specificities. A spontaneous mutant phage was isolated and exhibited broader host range compared with the parental phage JG004. Sequencing of its putative tail fiber and baseplate region indicated a single point mutation in ORF84 (a putative tail fiber gene), which resulted in the replacement of a positively charged lysine (K) by an uncharged asparagine (N). We further demonstrated that the replacement of the tail fiber gene (ORF69) of PaP1 with the corresponding gene from phage JG004 resulted in a recombinant phage that displayed altered host specificity. Our study revealed the tail fiber-dependent host specificity in P. aeruginosa phages and provided an effective tool for its alteration. These contributions may have potential value in phage therapy.     

The generalized transducing Salmonella bacteriophage ES18: complete genome sequence and DNA packaging strategy

The generalized transducing double-stranded DNA bacteriophage ES18 has an icosahedral head and a long noncontractile tail, and it infects both rough and smooth Salmonella enterica strains. We report here the complete 46,900-bp genome nucleotide sequence and provide an analysis of the sequence. Its 79 genes and their organization clearly show that ES18 is a member of the lambda-like (lambdoid) phage group; however, it contains a novel set of genes that program assembly of the virion head. Most of its integration-excision, immunity, Nin region, and lysis genes are nearly identical to those of the short-tailed Salmonella phage P22, while other early genes are nearly identical to Escherichia coli phages lambda and HK97, S. enterica phage ST64T, or a Shigella flexneri prophage. Some of the ES18 late genes are novel, while others are most closely related to phages HK97, lambda, or N15. Thus, the ES18 genome is mosaically related to other lambdoid phages, as is typical for all group members. Analysis of virion DNA showed that it is circularly permuted and about 10% terminally redundant and that initiation of DNA packaging series occurs across an approximately 1-kbp region rather than at a precise location on the genome. This supports a model in which ES18 terminase can move substantial distances along the DNA between recognition and cleavage of DNA destined to be packaged. Bioinformatic analysis of large terminase subunits shows that the different functional classes of phage-encoded terminases can usually be predicted from their amino acid sequence.     

Characterization of the primary immunity region of the Escherichia coli linear plasmid prophage N15.

N15 is the only bacteriophage of Escherichia coli known to lysogenize as a linear plasmid. Clear-plaque mutations lie in at least two regions of the 46-kb genome. We have cloned, sequenced, and characterized the primary immunity region, immB. This region contains a gene, cB, whose product shows homology to lambdoid phage repressors. The cB3 mutation confers thermoinducibility on N15 lysogens, consistent with CB being the primary repressor of N15. Downstream of cB lies the locus of N15 plasmid replication. Upstream of cB lies an operon predicted to encode two products: one homologous to the late repressor of P22 (Cro), the other homologous to the late antiterminator of phi 82 (Q). The Q-like protein is essential for phage development. We show that CB protein regulates the expression of genes that flank the cB gene by binding to DNA at symmetric 16-bp sites. Three sites are clustered upstream of cB and overlap a predicted promoter of the cro and Q-like genes as well as two predicted promoters of cB itself. Two sites downstream of cB overlap a predicted promoter of a plasmid replication gene, repA, consistent with the higher copy number of the mutant, N15cB3. The leader region of repA contains terminators in both orientations and a putative promoter. The organization of these regulatory elements suggests that N15 plasmid replication is controlled not only by CB but also by an antisense RNA and by a balance between termination and antitermination.