Skip to main content

Salmonella Typhimurium-specific bacteriophage ΦSH19 and the origins of species specificity in the Vi01-like phage family

Abstract

Background

Whole genome sequencing of bacteriophages suitable for biocontrol of pathogens in food products is a pre-requisite to any phage-based intervention procedure. Trials involving the biosanitization of Salmonella Typhimurium in the pig production environment identified one such candidate, ΦSH19.

Results

This phage was sequenced and analysis of its 157,785 bp circular dsDNA genome revealed a number of interesting features. ΦSH19 constitutes another member of the recently-proposed Myoviridae Vi01-like family of phages, containing S. Typhi-specific Vi01 and Shigella-specific SboM-AG3. At the nucleotide level ΦSH19 is highly similar to phage Vi01 (80-98% pairwise identity over the length of the genome), with the major differences lying in the region associated with host-range determination. Analyses of the proteins encoded within this region by ΦSH19 revealed a cluster of three putative tail spikes. Of the three tail spikes, two have protein domains associated with the pectate lyase family of proteins (Tsp2) and P22 tail spike family (Tsp3) with the prospect that these enable Salmonella O antigen degradation. Tail spike proteins of Vi01 and SboM-AG3 are predicted to contain conserved right-handed parallel β-helical structures but the internal protein domains are varied allowing different host specificities.

Conclusions

The addition or exchange of tail spike protein modules is a major contributor to host range determination in the Vi01-like phage family.

Background

The use of virulent bacteriophages (phages) as biological control (biocontrol) agents against bacterial pathogens is an expanding field of research aimed at producing sustainable solutions for the control of these pathogens, and to circumvent problems such as those associated with the development of multidrug-resistant bacteria [1]. The antimicrobial activities of phages committed to the cellular lysis of a range of bacterial pathogens have been reported, which include food pathogens such as Campylobacter jejuni [25], Escherichia coli [68], and various Salmonella enterica serovars [4, 9, 10]. However, despite the wealth of data regarding the efficacy of phages during intervention studies, relatively few phage-derived products have been developed sufficiently for commercial application. Only in the last few years has there been an extension of lab-based trials into the food production environment, where perhaps the best example is the recognition of the efficacy and the granting of 'generally recognized as safe' (GRAS) status to bacteriophages targeting Listeria monocytogenes by the United States Food and Drug Administration [11]. There are two products of note now available commercially-ListShield™ (Intralytix Inc., USA) a phage cocktail comprising virulent phages with broad activity against L. Monocytogenes, and Listex P100™ (EBI Food Safety, Netherlands). Following GRAS classification both ListShield™ and Listex P100™ are now viewed as safe to be applied as food biopreservatives on ready-to-eat foods in the USA. Phage P100 (the active component of Listex P100) was initially characterized at the genetic level and in oral toxicity studies by Carlton et al [12]. These studies showed that P100 had no undesirable genes within its genome, and caused no ill effects when administered to rats. Many studies reporting the efficacy of Listex P100 against L. monocytogenes in various food production settings are now available in the literature [1315].

If more phage-based applications are to reach standards where they are deemed fit for human/animal consumption then certain matters pertaining to safety must be taken into consideration. For instance, phages that show potential during preliminary studies must adhere to strict criteria if they are to be developed further as antimicrobial agents [16]. Most importantly, the selected phages must not possess genes associated with virulence, or those that may enhance the pathogenic profile of its target [17]. Many examples of phages that are recognized as being involved in such processes are known, for example, the Shiga toxin-encoding (Stx) phages-a key virulence factor of Shiga-toxigenic E. coli (STEC)-are the causative agents of haemolytic uraemic syndrome (HUS), a major contributor to disease associated with STEC infection [18, 19]. Also, temperate phages that have the potential to form lysogens with their host need to be eliminated from trials at the earliest opportunity. Integration into, and excision out of the host genome, can lead to the transfer of genes between the phage and bacterium potentially altering the genetic profile of both [20]. These undesirable traits are most often associated with phages belonging to the Podoviridae (icosahedral head with a short non-contractile tail e.g. Salmonella phage P22) or Siphoviridae (icosahedral head with a flexible non-contractile tail e.g. phage λ) families. However, members of the Myoviridae (icosahedral head and contractile tail e.g. phage T4) are more often associated with an obligately lytic lifecycle. All of these morphological characteristics can be easily discerned when phages are viewed under a transmission electron microscope, although assumptions as to the genetic nature of a phage cannot be made on morphological characteristics alone. Whole genome sequencing of phage isolates intended for use as biocontrol agents is now considered to be the 'gold standard' in terms of transferring phage-based applications from the laboratory to everyday use.

Here we report the complete genome sequence of ΦSH19, a lytic bacteriophage adapted to infecting a number of different S. Typhimurium serovars. ΦSH19 has shown great potential as a biocontrol agent against S. Typhimurium U288, the most prevalent serovar found in UK pig production premises [21]. S. Typhi phage Vi01 was the first of a recently-proposed new lineage of Myoviridae to be described. Genetic analyses of the ΦSH19 genome reveal that it is a close relative of phage Vi01, in terms of both DNA and protein sequences. However, phage Vi01 appears to be restricted to infecting S. Typhi, possibly due to the presence of a virulence (Vi) capsule antigen-degrading acetyl esterase domain incorporated into one of its three tail spikes [22]. The other completely sequenced member of the Vi01-like phage lineage is SboM-AG3 that is restricted to the infection of Shigella spp. [23]. No genes associated with either toxicity or lysogeny have been found within the ΦSH19 157,785 bp circular dsDNA genome, nor in any of the Vi01 family of phages. A lack of virulence associated genes in ΦSH19 will allow its use as a biocontrol agent, aimed at reducing S. Typhimurium entering the food chain, and in particular S. Typhimurium U288 from pork production.

Results

Bacteriophage ΦSH19 characterization

Bacteriophage ΦSH19 was originally isolated from pig intestinal contents and has specific activity against S. Typhimurium serovars [24]. Morphologically the phage has an icosahedral head with a contractile tail indicating it to be a member of the Myoviridae (Figure 1). A comparison of the lytic profiles of phages ΦSH19 and Vi01 against a panel of S. enterica Serovars is given in Table 1. The data shows that as expected all the S. Typhimurium strains tested are refractory to infection by Vi01, whereas S. Typhi BRD948 likewise displays immunity towards infection by ΦSH19 but susceptibility to Vi01.

Figure 1
figure 1

TEM image of ΦSH19. The presence of an icosahedral head and contractile tail indicate that ΦSH19 is a member of the Myoviridae. Magnification × 43,000. Bar 250 nm.

Table 1 Host range assays of ΦSH19 and Vi01 (+ = lysis and-= no lysis).

Genome analysis

The ΦSH19 genome was sequenced from sonicated DNA fragments using the Roche 454 GS FLX platform (17,796 reads), from which a single contig of 157,785 bp was generated. BlastN analysis of the ΦSH19 genome revealed two related genome sequences in the database-phages Vi01 (Genbank Acc. No. FQ312032) and SboM-AG3 (Genbank Acc. No. FJ373894). The ΦSH19 genome was ordered such that it could be directly aligned with the existing genomes of Vi01 and SboM-AG3 commencing with the rIIA gene. The GC-content of the ΦSH19 genome was determined to be 44.68%, which is slightly lower than Vi01 (45.22% GC), and considerably lower than SboM-AG3 (50.39% GC). Alignment of the nucleotide sequences of ΦSH19 and Vi01 indicate that they are highly similar over a large proportion of the genome (between 80-98% pairwise identity). However, for a region located between 120-130 Kb on the genome map this homology breaks down to approximately 70% identity (and in some instances the conservation is lost completely). This region contains a cluster of three putative tail spike reading frames in all of the Vi01-like phages sequenced to date. At the nucleotide level ΦSH19 is somewhat less similar when compared to SboM-AG3, with homologies ranging from 74-100% identity over approximately 60% of the genome. Comparison of the varying degrees of homology between ΦSH19, Vi01, and SboM-AG3 are represented in Figure 2. Otherwise highly similar nucleotide matches were restricted to components of Escherichia phage PhaxI (Genbank Acc. No. HQ259289), Serratia phage KSP90 (Genbank Acc. No. AB452990) and Salmonella phage Det7 (Genbank Acc. No. AM765843).

Figure 2
figure 2

Artemis Comparison Tool (ACT) analysis of the genomes of SboM-AG3 (top), ΦSH19 (middle), and Vi01 (bottom).

Initial analysis of the ΦSH19 genome identified 339 potential open reading frames (ORFs). Following BlastP and Pfam domain analyses of each potential ORF, the candidate ORFs were reduced to 166. Each ORF was then annotated using Vi01 and SboM-AG3 phages as reference sequences, and categorised as follows: Hypothetical phage proteins (81), Conserved hypothetical phage proteins (23), DNA replication (24), Tail morphogenesis (16), Capsid/DNA packaging (7), DNA maintenance/circularization (6), Putative uncharacterized proteins (3), Regulators (2), Lysis (2), and Putative homing endonucleases (2). A comparison of the major proteins of ΦSH19 with their homologues in Vi01 and SboM-AG3 is presented in Table 2. Figure 3 shows the fully annotated ΦSH19 genome as a circular genetic map. Using tRNAscan-SE, five tRNA genes were also identified in a 5 Kb non-coding region of the ΦSH19 genome at the following nucleotide positions: Methionine tRNA (CAT) 137,703-137,735; Asparagine tRNA (GTT) 137,806-137,878; Tyrosine tRNA (GTA) 138,497-138,577; Serine tRNA (GCT) 138,657-138,742; and an undetermined tRNA 138,749-138,834. For phages ΦSH19, Vi01, and SboM-AG3 there exists a set of tRNA genes located at similar positions in their respective genomes, some of which display a high degree of conservation. For example, BlastN analysis of the coding sequence for tRNA-Serine that is present in all three phages indicates 100% identity at the nucleotide level. Two other tRNAs (tRNA-Asparagine and tRNA-Tyrosine) are also shared between the group. For ΦSH19 tRNA-Asparagine, the gene is 100% identical with its homologue in Vi01 and 95% identical to that of SboM-AG3, whilst the ΦSH19 tRNA-Tyrosine shows more conservation with that of SboM-AG3 (99% identical) than Vi01 (84% identical). ΦSH19 also shares a tRNA-Methionine gene (88% identity) and a tRNA of undetermined specificity (99% identity) with Vi01 that are absent in SboM-AG3. Phire analysis for phage regulatory elements identified a number of sites in the ΦSH19 genome (Table 3). All of the putative regulatory elements are found on the non-coding strand (relative to the transcribed sequences within that region) however they appear to be associated with ORFs on the opposite strand. It is quite possible that these elements play a role in regulating ΦSH19 gene expression, in an as yet undetermined manner, but perhaps by the production of small RNA molecules.

Table 2 Comparison of ΦSH19 proteins with those of Vi01 and SboM-AG3
Figure 3
figure 3

A schematic circular map of the ΦSH19 genome.

Table 3 Putative phage regulatory elements identified by Phire analysis.

ΦSH19 tail spikes

Three tail spike genes-tsp1 (bases 120,710-122,641c), tsp2 (122,702-124,876c), and tsp3 (124,992-127,088c) were identified during the annotation of ΦSH19. BlastN analysis of the tsp1 gene (1932 bp) shows that the nucleotide sequence has 94% identity with that of Vi01 orf 170c (Vi01 Tsp1) over the first 263 bases, but beyond this conservation breaks down and no further nucleotide identities are observed between the two genes. A similar sequence to tsp1 is present at orf 00207 (SboM-AG3 Tsp1) of SboM-AG3 (64% identity over the first 390 bases), and a shorter stretch of homology (78% identity over the first 54 bases) is located within orf 00212 (SboM-AG3 Tsp3). As with Vi01, no further identity can be observed with tsp1 following these short stretches of conservation. Other nucleotide alignments of tsp1 include identities with the Salmonella phage Det7 tail spike gene (86% identity from bases 360-460), and an endo-α-sialidase gene of coliphage K1F (76% identical from bases 351-485). Aside from these alignments, which all span a region covering the first 485 bases of tsp1, no homologies were found in the database for the region covering bases 485-1932. Alignment of the tsp2 gene (2175 bp) reveals that only Vi01 and SboM-AG3 have similar sequences within the database. As with tsp1, the homologies all span the start of the gene: 85% identity (bases 1-723) with Vi01 orf 171c (Vi01 Tsp2-maturation/adhesion protein) and 70% identity (bases 1-360) with SboM-AG3 orf 00210 (SboM-AG3 Tsp2). The latter portion of the tsp2 gene does not align with any sequences in the database. BlastN searches involving the tsp3 gene (2097 bp) show that the sequence is highly similar to the Det7 tail spike gene (85% identity from bases 1-782). To a lesser extent, tsp3 shares sequence homology (84% identity between bases 1-461) with Vi01 orf 172c (Vi01 Tsp3) and orf 170c (69% identity between bases 1-179). Apart from these short regions of homology, there are no further identities between tsp3 and Vi01. Interestingly, no nucleotide sequence homology was found between tsp3 and SboM-AG3. Bases 481-667 show a conserved sequence that is shared between several phage genomes in the database. Sequence alignments over this region indicate 74-77% shared identities between various Salmonella phages including P22, ST104, ST64T, ST160, SE1, and some of the S. Enteritidis typing phages (SETP) [25]. Interestingly, the sequence is also present in prophage tail spikes of S. Typhimurium D23580, S. Typhimurium T000240, S. Heidelberg SL476, and S. Paratyphi A (strain AKU 12601). As was the case for tsp1 and tsp2 no homologous sequences are found to match the latter region of the tsp3 gene.

Translation of the tsp gene sequences indicate that Tsp1 is a 643 amino acid protein (predicted MW ~ 68.9 kDa), Tsp2 is comprised of 724 amino acids (predicted MW ~ 78.2 kDa), and Tsp3 698 amino acids (predicted MW ~ 75.8 kDa). Pfam domain searches for each tail spike indicated significant domain matches for Tsp2 (Pectate lyase domain-family 3 CL0268) and Tsp3 (P22 tail spike family); however no significant domain similarities were identified for Tsp1. Betawrap analyses of the amino acid sequences of each tail spike from ΦSH19, Vi01, and SboM-AG3 shows that each of these proteins potentially have the ability to form right-handed parallel β-helical structures. A comparison of each ΦSH19 tail spike protein sequence with those of Vi01 and SboM-AG3, and other homologous proteins in the database revealed the N-terminal residues (1-130) of ΦSH19 Tsp1 are highly conserved with the corresponding regions in Vi01 Tsp1 (78% ID), SboM-AG3 Tsp1 (75% ID), and to a lesser degree in Vi01 Tsp3 (56% ID). This N-terminal homology is also shared with the Salmonella phage Det7 tail spike (56% ID), and a tail fibre protein from Enterobacter phage Ecp1 (42% ID). A sequence motif present in ΦSH19 Tsp1 G-G-V-G-L-G-A-W (beginning at residue 143) possibly signifies the boundary at which the catalytic domain of the tail spike begins. No such sequence motif is present in Vi01 Tsp1, however similar sequence motifs are present at analogous positions within SboM-AG3 Tsp1 (G-G-L-S-S-S-N-W) and Vi01 Tsp3 (G-G-V-G-T-G-A-W). ClustalW2 alignments of phage tail-associated proteins containing derivatives of these motifs at their N-terminal boundaries are shown in Figure 4A. The C-terminus of ΦSH19 Tsp1 (residues 300-643) produced no significant alignments with any known proteins. BlastP analyses of Vi01 Tsp1 and SboM-AG3 Tsp1 was performed to identify any functionally-related proteins. However, as with ΦSH19 Tsp1, Vi01 Tsp1 produced no significant alignments over the C-terminal region with any protein sequences in the database.

Figure 4
figure 4

A-C ClustalW2 alignments of sequence motifs in tail-associated proteins (4A), the active site of P22-like tail spikes (4B), and the C-terminal region of P22-like tail spikes-yellow-sequence motif (residues 585-596 in P22) associated with intertwined region, green-five-stranded β-sheet and three-stranded β-sheet (residues 601-664 in P22), and red-regions lacking homology in ΦSH19 Tsp3 (4C).

Alignment of ΦSH19 Tsp2 with Vi01 Tsp2 (maturation/adhesion protein) and SboM-AG3 Tsp2 shows a high degree of conservation from residues 1-160. At this point SboM-AG3 sequence homology (73% ID over residues 1-162) breaks down with no further identity to either Vi01 or ΦSH19 Tsp2. Residues 100-403 in ΦSH19 Tsp2 show a weak but significant relationship with a phage structural protein/putative tail fibre (orf 00213) present in SboM-AG3. For ΦSH19 Tsp2 and Vi01 Tsp2, homology continues over the first 276 residues (86% ID) at which point the two sequences completely diverge from each other. Another region of low homology (residues 100-316) is also found with a putative tail fibre protein encoded in the Vi01 genome (Vi01 orf 173c). A pectate lyase protein family domain (family 3-CL0268) spanning residues 291-549 was identified during Pfam analysis of ΦSH19 Tsp2. The presence of this motif was further confirmed during BlastP analysis, with a number of alignments being made with various glycoside degrading enzymes from a wide range of microorganisms. No significant alignments with the C-terminus of ΦSH19 Tsp2 were identified (residues 557-724).

ΦSH19 Tsp3 alignment with Vi01 Tsp3 shows a high degree of sequence conservation between their N-terminal residues 1-154 (86% ID). However, the corresponding sequence in SboM-AG3 Tsp3 shows similarity over the first 19 residues before a deletion of 63 amino acids, after which the homology is restored between the three tail spike sequences. Interestingly, SboM-AG3 Tsp1 shows a higher degree of conservation with ΦSH19 Tsp3 over residues 1-139 (46% ID) than does SboM-AG3 Tsp3. The boundary motif G-G-V-G-L-G-A-W appears in ΦSH19 Tsp3 at residues 143-150 with analogous sequences in Vi01 (G-G-V-G-T-G-A-W) and SboM-AG3 (G-G-V-S-S-S-A-W), after which the sequence homologies between all three tail spikes break down. Pfam domain analysis of ΦSH19 Tsp3 identified a protein domain (residues 159-698) with significant homology to the P22 tail spike family (PF09251). BlastP analysis produced alignments with Det7 (the first reported Myovirus with a podoviral tail spike), P22, and a number of P22-like phages. The highest degree of homology was found for the tail spike of Det7 (77% ID over the first 300 residues). The sequence motif marking the domain boundary in ΦSH19 Tsp3 (G-G-V-G-L-G-A-W) is conserved in Det7. P22 tail spike-like sequences feature three conserved residues that function as catalytic components of the endo-rhamnosidase activity associated with P22 tail spike protein [26, 27]. These residues are located in the substrate binding cleft of the P22 tail spike and are conserved in ΦSH19 Tsp3 (Figure 4B: Glu-359, Asp-392 and Asp-395).

Discussion

Bacteriophage ΦSH19, a candidate for use as a biocontrol agent against Salmonella Typhimurium, was subjected to whole genome sequencing. This process is now viewed as a pre-requisite to using phages as therapeutic agents, especially if they are to be introduced into a food production environment. The presence or absence of genes associated with toxicity or lysogeny will ultimately govern whether or not a potential phage candidate is safe for commercial use. ΦSH19 was found to contain no undesirable genes in its 157,785 bp genome making it an excellent candidate for such applications. Also, ΦSH19 constitutes a new addition to the Vi01-like phage family (along with S. Typhi phage Vi01 and Shigella phage SboM-AG3). In many respects ΦSH19 is quite similar to Vi01 with the addition of a putative homing endonuclease and a putative uncharacterized protein. Structural genes and those associated with morphology of the phage particle are highly conserved between ΦSH19 and Vi01, and to a lesser degree with SboM-AG3. Analysis of the tRNA genes encoded by all three phages, and their location within each genome indicates that some of them are possibly derived from a common ancestor. Transmission electron microscope images of ΦSH19 (Figure 1), Vi01 and SboM-AG3 indicate that their morphologies are quite similar. The intricate 'chandelier-like' arrangements of tail spikes attached to the baseplate are visible for all three phages [22, 23]. It seems likely that there are more Vi01-like phages (such as Escherichia phage PhaxI) capable of infecting a diverse range of bacterial pathogens to be discovered for which there are commercial applications.

The modular structure of the three tail spikes found in ΦSH19 is potentially the main driving factor behind host-range determination for this phage. Although no function can at present be assigned to Tsp1, the other two tail spikes contain defined protein domains that provide evidence as to their mode of action. For Tsp2, the pectate lyase domain indicates that this protein may well function to modify or cleave glycoside bonds. The pectate lyase family domain (CL0268) notably contains proteins with pectate/pectin lyase and pectin methylesterase activities. The pectate/pectin lyases are a well-characterized family of proteins principally involved in microbial plant pathogenesis. Their primary mode of action involves the eliminative cleavage of α-1,4 linked galacturonosyl residues of pectins that are components of the middle lamella of plant cell walls. The three dimensional structure of Erwinia chrysanthemi EC16 pectate lyase C (PelC) was first solved by Yoder et al. [28] and is representative of a family of proteins containing right-handed parallel β-helical structures with the flexibility to allow protein loops from the stacked coils to add functionality, for example the formation of the active site clefts that support enzyme catalysis [29, 30]. Using a similar base architecture pectin methylesterase acts to de-esterify pectin to pectate. Members of the pectinolytic protein family are represented in prokaryotic and eukaryotic microorganisms, and also function in plants to remodel cell walls [29]. Divergence from the ancestral sequence over time has allowed different microorganisms to target a range of pectin-like substrates, while the overall structure has been maintained [30]. It is of little surprise that phages have evolved the ability to acquire these proteins and utilize their polysaccharide modifying properties. In the case of ΦSH19 Tsp2 it could be postulated that the target is the α-D-galactose (1-4) α-D-mannose linkage found in the S. Typhimurium O-antigen trisaccharide repeat. Many phage tail-associated proteins have been found to contain right-handed parallel β-helical structural domains, for example phages P22 [31], Sf6 [32], HK620 [33] and Det7 [27]. Moreover the presence of a pectate lyase-type structure in a phage tail spike protein has previously been reported for K5 lyase (KflA) of coliphages K5A and K1-5. KflA targets and degrades the capsular polysaccharide of E. coli K5, thus allowing the phage access to outer membrane receptors [34]. Whilst the precise identity of the polysaccharide target of ΦSH19 Tsp2 is at present unknown, it is possible that this tail spike plays a major role in host-range determination. Plaque assays using phages Vi01 and ΦSH19 against a panel of S. Typhimurium and S. Typhi BRD948 indicate that these phages are specific for their host (Table 1). This is perhaps not surprising since Vi01 orf 171c (Vi01 Tsp2) possesses a 9-0-acetyl esterase/acetylxylan esterase domain (residues 343-445; DUF303) that targets the acetyl-modification of the S. Typhi Vi capsule [22]. The pectate lyase domain found in ΦSH19 Tsp2 is more than likely involved in the degradation of a polysaccharide present on the surface of S. Typhimurium U288. Anany et al. [23] also report that SboM-AG3 is Shigella-specific and is unable to form plaques on lawns of any of the Salmonella, Escherichia, and Listeria strains tested.

A protein domain composed of parallel right-handed β-helices is also found in ΦSH19 Tsp3-the P22 tail spike domain. Many tail spike proteins possess an N-terminal binding domain involved in attaching the protein to the virion head/tail structure (the sequence of which is often highly conserved between phages with similar morphologies), a central catalytic domain (containing the trimeric parallel right-handed β-helices), and a C-terminal trimerization domain (involved in stabilization of the trimeric tail spike). The trimeric β-helices that form the catalytic domain bind and cleave polysaccharides present in bacterial lipopolysaccharide (LPS). P22 tail spike (Gp9) utilizes this endo-rhamnosidase activity to degrade the Salmonella O antigen [35]. Cleavage of α-L-rhamnose (1-3) α-D-galactose found in the trisaccharide-repeats of S. Typhimurium LPS takes place on the external surface of the tail spike. The structure and arrangement of the parallel β-helix tail spike domains result in a solvent-exposed exterior that features the proposed catalytic residues Glu-359, Asp-392, and Asp-395 [27, 36]. The active site residues and their sequence environments are conserved in ΦSH19 Tsp3, and therefore can be postulated to operate in a manner akin to the P22 tail spike and its relatives. Thus, there is a possibility that ΦSH19 Tsp3 acts in two distinct ways. Firstly, ΦSH19 Tsp3 may function as an initial step towards irreversible adsorption of the phage particle to its host, hydrolyzing the outer S. Typhimurium LPS layer in order to provide access to a previously inaccessible outer membrane receptor. Secondly, the endo-rhamnosidase activity associated with P22-like tail spikes may aid phage progeny in freeing themselves from cellular debris encountered during host lysis [37].

Tsp3 of ΦSH19 has an N-terminal sequence similar to Vi01 orf 172c (Vi01 Tsp3), SboM-AG3 orf 00207 (SboM-AG3 Tsp1) and Det7 tail spike. These phages are all Myoviridae of similar morphologies. Therefore the requirements of having to attach the tail spike to similar base plate structures more than likely places constraints on sequence divergence. Likewise, the alignments for the Podoviridae tail spikes show N-terminal conservation between related phage, followed by conserved catalytic and C-terminal domains that are shared between Myoviridae, Podoviridae and Siphoviridae. Interestingly, P22, ST64T, and ST104 as members of the Podoviridae are 98-99% identical over their 667 amino acid tail spike proteins, and similarly Siphoviridae members SETP12 and SETP13 also have almost identical tail spike sequences. Despite that the SETP 12 and 13 phage sequences are markedly different from P22, ST64T, and ST104 over the N-terminal regions; however, they become conserved between residues 140 to 684. As noted above, there appears to be sequence divergence constraints placed on conserved N-terminal regions associated with the myoviruses ΦSH19, Vi01, SboM-AG3 and Det7. Similarly it appears there are structural restrictions imposed on the Podoviridae and Siphoviridae N-terminal tail spike sequences. Similarities between ΦSH19 Tsp3, Det7 and the P22-like sequences begin ten amino acids after the boundary motif G-G-V-G-L-G-A-W that appears in ΦSH19 Tsp3 and Det7 (this motif also signals the divergence of the tail spike sequences of phages Vi01 and SboM-AG3 from ΦSH19 and Det7). ΦSH19 Tsp3 and Det7 Tsp show striking conservation with the P22-like sequences over the catalytic domain, up to and including the active site residues Glu-359, Asp-392 and Asp-395. However, immediately after the active site in ΦSH19 Tsp3 (residues 440-698) sequence conservation breaks down.

For P22-like tail spike proteins, the C-terminal residues 585-596 form an intertwined region that allows extensive hydrogen bonding between subunits, whilst residues 606-664 form a five-stranded and a three-stranded β-sheet region [27]. ClustalW2 alignment of these regions show that all the aligned P22-like tail spikes contain conserved residues at these locations (including the Myovirus Det7), that set them apart from ΦSH19 Tsp3 (Figure 4C). The eight amino acids spanning residues 585-592 (V/G-G-P/A-G-S/T-G-S-A-W) retain a sequence motif similar to that found at the N-terminal boundary of ΦSH19 Tsp3, and the tail-associated proteins aligned in Figure 4A. However, this motif is absent at the C-terminal end of ΦSH19 Tsp3. P22-like tail spike modules may well have descended from a common ancestor with the flexibility to diverge their protein sequences whilst retaining the topology of the right-handed parallel β-helices. It has been proposed that this flexibility has allowed the protein domain to become widespread amongst bacteriophages [33], with the possibility of later domain interchange creating further diversity [38].

In summary, we have sequenced the genome of ΦSH19, a promising candidate for phage biosanitization of S. Typhimurium in the food production environment. The 157,785 bp circular dsDNA genome was found to contain no genes associated with toxicity or lysogeny, which is a pre-requisite for such applications. Analysis of the nucleotide sequence of ΦSH19 revealed only two close relatives in the database: S. Typhi-specific Vi01 and Shigella-specific SboM-AG3 that collectively form the Vi01-like phage family. Major differences were evident between ΦSH19 and Vi01 in three different tail spike proteins. Two tail spikes from ΦSH19 contain protein domains associated with the degradation of polysaccharides common to Salmonella LPS, namely the pectate lyase (Tsp2) and P22 tail spike-like (Tsp3) families of proteins. The acquisition of these domains is the most obvious reason to explain the different host specificities of ΦSH19, Vi01 (seemingly host-restricted due to the presence of a Vi antigen-degrading tail spike protein domain) and SboM-AG3 (whose tail spikes are as yet undefined). Based on amino acid sequence analysis the tail spikes from all three phages appear to form right-handed parallel β-helical structures. This appears to be an evolutionarily-conserved structure for all three tail spikes found in the Vi01-like phage. However, this conservation is coupled to the exchange of individual protein domains within these structures that may ultimately determine host range.

Materials and methods

Isolation of ΦSH19

For phage isolation, sewage effluent was filtered through 0.2 μm Minisart filters (Sartorius Biotech. Cat. No. 16534) and the filtrate collected in sterile universals and stored at 4°C until required. For S. Typhimurium lawn preparation NZCYM broth (Difco Cat. No. 240410) cultures were prepared and incubated overnight at 37°C with shaking. Following this, the overnight culture was used to seed fresh NZCYM broth containing 10 mM MgSO4 (Sigma Aldrich Chemicals Cat. No. M2643) which was then incubated for 2 hours at 37°C with shaking. To molten (tempered to ~ 50°C) NZCYM top agar containing 0.6% Bacteriological Agar No.1 (Oxoid Cat No. LP0011) 500 μL of the required Salmonella was added, followed by 500 μL filtrate, and the mixture was poured onto NZCYM agar plates. The plates were left to set on the bench for 20 minutes before being inverted then incubated overnight at 37°C. Any plaques identified were picked using sterile pipette tips and resuspended in 500 μL SM buffer (50 mM Tris-HCl [pH7.5], 100 mM NaCl, 8 mM MgSO4:7H2O, 0.01% gelatin, pH 7.5), incubated at 37°C for 1 hour, then serial diluted in SM buffer. A 25 μL volume of each dilution was then added to Salmonella/NZCYM top agar, and lawns were prepared as described above. This process was repeated three times in order to obtain a single clonal isolate of ΦSH19.

Phage host range assays

The ability of phages ΦSH19 and Vi01 to lyse various S. Typhimurium serovars and S. Typhi BRD948 (kindly provided by D. Pickard Wellcome Trust Sanger Centre, UK) was determined as follows. S. Typhimurium and S. Typhi BRD948 top agar lawns were prepared as described above, with the exception of the latter being grown on supplemented minimal media as described by Tacket et al. [39]. To each bacterial lawn triplicate 20 μL volumes of log107 PFU mL-1 dilutions of the required phage were applied. Following a sufficient drying period, plates were inverted and incubated overnight at 37°C. The following day, each plate was observed for lysis and the results are shown in Table 1.

Transmission electron microscopy

A freshly-prepared high titre phage suspension of ΦSH19 was sedimented at 34,900 × g for 2 hours (4°C). Following centrifugation, the supernatant was decanted and each phage pellet was washed twice with 0.1 M ammonium acetate for 1 hour at 25,000 × g. The wash solution was discarded and 2 mL SM buffer added to each centrifuge tube. Phage pellets were recovered following overnight incubation at 4°C with gentle shaking. A small drop of washed phage suspension was spotted onto a carbon-coated copper mesh grid and allowed to sit for 3 minutes. Excess phage suspension was then removed with filter paper. For negative staining one drop of phosphotungstic acid [pH 7.4] was added to each grid, and excess stain was removed one minute later with filter paper. Each grid was then covered and allowed to dry for 15 minutes. Images were taken with a Fei Tecnai Biotwin TEM (Fei Company, USA).

ΦSH19 DNA extraction and sequencing

A high titre suspension of ΦSH19 (~ 1010 PFU mL-1) was subjected to a single-step caesium chloride (CsCl) purification procedure as follows. CsCl (Melfords Cat. No. MB1006) was added to the high titre phage suspension to a final concentration of 0.75 g mL-1. Samples were then subjected to ultracentrifugation at 264,000 × g for 24 hours in a Beckman TL100 ultracentrifuge (15°C). Extraction of the band containing purified highly-concentrated ΦSH19 was then performed with a sterile 20-gauge hypodermic needle, and the band was subsequently collected in a sterile tube. Residual CsCl was removed from the sample using an Amicon® Ultra-0.5 30 kDa MWCO centrifugal filter device (Millipore Cat. No. UFC 503008) as follows. Briefly, phage-CsCl solution was added to the column, which was then spun at 17,900 × g in a benchtop centrifuge for 30 mins. The column was then washed twice with SM buffer at 17,900 × g for 2 minutes. To elute the retained phage, SM buffer was added to the column which was then inverted and placed in a fresh collection tube. The column was then centrifuged at 17,900 × g for 10 minutes to recover the phage. ΦSH19 DNA was isolated from the purified stock using the phenol-chloroform extraction method with slight modifications as follows. An equal volume of 10 mg mL-1 Proteinase K (Fisher Scientific Cat No. BPE 1700-500) was added to the CsCl-purified sample, followed by detergent solution (10 ng mL-1 Proteinase K in 50 mM EDTA, 50 mM Tris-HCl [pH 8], 1% N-lauroyl sarcosine (Sigma Aldrich Chemicals, Cat No. L9150)). The solution was then incubated overnight at 55°C. Following this, phage DNA was extracted using phenol: chloroform and ethanol precipitation [5]. The extracted ΦSH19 DNA was purified using a DNA wizard purification kit (Promega, Cat No. A1120) then subjected to whole genome amplification using a Repli-G kit (Qiagen, UK Cat. No. 150023). Genomic DNA was fragmented to 500 bp using a Covaris S2 sonicator (Covaris Inc., USA) and libraries constructed using a NEBNext DNA Sample Prep Master Mix Set 2 (New England Biolabs Cat. No. E6070S). The libraries were subsequently sequenced using the Roche 454 GS FLX system (Roche Diagnostics, USA).

The fully sequenced ΦSH19 genome was annotated using a combination of CLC Genomics Workbench (CLC Bio, Denmark) and Artemis software [40]. For comparisons between the genomes of ΦSH19, Vi01, and SboM-AG3, ACT software was used [41], and comparison files were generated using the web-based programme DoubleACT http://www.hpa-bioinfotools.org.uk/pise/double_act.html. Nucleotide and protein searches were performed using the Blast search algorithm [42]. For the identification of protein domains of known function, searches of the Pfam database were made [43], whilst protein alignments were generated using ClustalW2 [44]. Betawrap was used to identify potential right-handed parallel β-helices in the tail spike proteins encoded by ΦSH19, Vi01, and SboM-AG3 [45]. For the identification of phage regulatory elements Phire analysis of the ΦSH19 genome was performed [46], and tRNAscan-SE 1.21 was used to identify tRNA genes [47]. The complete annotated ΦSH19 genome sequence has been deposited in the NCBI database (Genbank Acc. No. JN126049).

Abbreviations

gp:

gene product, used in the context of functional homologues to coliphage T4 proteins.

References

  1. Mahony J, McAuliffe O, Ross RP, van Sinderen D: Bacteriophages as biocontrol agents of food pathogens. Curr Opin Biotechnol 2011, 22: 157-163.

    Article  CAS  PubMed  Google Scholar 

  2. Atterbury RJ, Connerton PL, Dodd CE, Rees CE, Connerton IF: Application of host-specific bacteriophages to the surface of chicken skin leads to a reduction in recovery of Campylobacter jejuni. Appl Environ Microbiol 2003, 69: 6302-6306.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

  3. Wagenaar JA, Van Bergen MA, Mueller MA, Wassenaar TM, Carlton RM: Phage therapy reduces Campylobacter jejuni colonization in broilers. Vet Microbiol 2005, 109: 275-283.

    Article  PubMed  Google Scholar 

  4. Goode D, Allen VM, Barrow PA: Reduction of experimental Salmonella and Campylobacter contamination of chicken skin by application of lytic bacteriophages. Appl Environ Microbiol 2003, 69: 5032-5036.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

  5. Loc Carrillo C, Atterbury RJ, el-Shibiny A, Connerton PL, Dillon E, Scott A, Connerton IF: Bacteriophage therapy to reduce Campylobacter jejuni colonization of broiler chickens. Appl Environ Microbiol 2005, 71: 6554-6563.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

  6. O'Flynn G, Ross RP, Fitzgerald GF, Coffey A: Evaluation of a cocktail of three bacteriophages for biocontrol of Escherichia coli O157:H7. Appl Environ Microbiol 2004, 70: 3417-3424.

    Article  PubMed Central  PubMed  Google Scholar 

  7. Abuladze T, Li M, Menetrez MY, Dean T, Senecal A, Sulakvelidze A: Bacteriophages reduce experimental contamination of hard surfaces, tomato, spinach, broccoli, and ground beef by Escherichia coli O157:H7. Appl Environ Microbiol 2008, 74: 6230-6238.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

  8. Jamalludeen N, Johnson RP, Shewen PE, Gyles CL: Evaluation of bacteriophages for prevention and treatment of diarrhea due to experimental enterotoxigenic Escherichia coli O149 infection of pigs. Vet Microbiol 2009, 136: 135-141.

    Article  PubMed  Google Scholar 

  9. Atterbury RJ, Van Bergen MA, Ortiz F, Lovell MA, Harris JA, De Boer A, Wagenaar JA, Allen VM, Barrow PA: Bacteriophage therapy to reduce salmonella colonization of broiler chickens. Appl Environ Microbiol 2007, 73: 4543-4549.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

  10. Wall SK, Zhang J, Rostagno MH, Ebner PD: Phage therapy to reduce preprocessing Salmonella infections in market-weight swine. Appl Environ Microbiol 2010, 76: 48-53.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

  11. United States Food and Drug Administration[http://www.fda.gov/OHRMS/DOCKETS/98fr/cf0559.pdf]

  12. Carlton RM, Noordman WH, Biswas B, de Meester ED, Loessner MJ: Bacteriophage P100 for control of Listeria monocytogenes in foods: genome sequence, bioinformatic analyses, oral toxicity study, and application. Regul Toxicol Pharmacol 2005, 43: 301-312.

    Article  CAS  PubMed  Google Scholar 

  13. Guenther S, Huwyler D, Richard S, Loessner MJ: Virulent bacteriophage for efficient biocontrol of Listeria monocytogenes in ready-to-eat foods. Appl Environ Microbiol 2009, 75: 93-100.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

  14. Soni KA, Nannapaneni R: Removal of Listeria monocytogenes biofilms with bacteriophage P100. J Food Prot 2010, 73: 1519-1524.

    PubMed  Google Scholar 

  15. Soni KA, Nannapaneni R, Hagens S: Reduction of Listeria monocytogenes on the surface of fresh channel catfish fillets by bacteriophage Listex P100. Foodborne Pathog Dis 2010, 7: 427-434.

    Article  CAS  PubMed  Google Scholar 

  16. Merabishvili M, Pirnay JP, Verbeken G, Chanishvili N, Tediashvili M, Lashkhi N, Glonti T, Krylov V, Mast J, Van Parys L, Lavigne R, Volckaert G, Matthews W, Verween G, De Corte P, Rose T, Jennes S, Zizi M, De Vos D, Vaneechoute M: Quality-controlled small-scale production of a well-defined bacteriophage cocktail for use in human clinical trials. PLoS One 2009, 4: e4944.

    Article  PubMed Central  PubMed  Google Scholar 

  17. Gill JJ, Hyman P: Phage choice, isolation, and preparation for phage therapy. Curr Pharm Biotechnol 2010, 11: 2-14.

    Article  CAS  PubMed  Google Scholar 

  18. Herold S, Karch H, Schmidt H: Shiga toxin-encoding bacteriophages--genomes in motion. Int J Med Microbiol 2004, 294: 115-121.

    Article  CAS  PubMed  Google Scholar 

  19. Allison HE: Stx-phages: drivers and mediators of the evolution of STEC and STEC-like pathogens. Future Microbiol 2007, 2: 165-174.

    Article  CAS  PubMed  Google Scholar 

  20. Wagner PL, Waldor MK: Bacteriophage control of bacterial virulence. Infect Immun 2002, 70: 3985-3993.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

  21. Salmonella in livestock production in GB 2009[http://vla.defra.gov.uk/reports/docs/rep_salm09_chp4.pdf]

  22. Pickard D, Toribio AL, Petty NK, van Tonder A, Yu L, Goulding D, Barrell B, Rance R, Harris D, Wetter M, Wain J, Choudhary J, Thomson N, Dougan G: A conserved acetyl esterase domain targets diverse bacteriophages to the Vi capsular receptor of Salmonella enterica serovar Typhi. J Bacteriol 2010, 192: 5746-5754.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

  23. Anany H, Lingohr EJ, Villegas A, Ackermann HW, She YM, Griffiths MW, Kropinski AM: A Shigella boydii bacteriophage which resembles Salmonella phage ViI. Virol J 2011, 8: 242.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

  24. Hooton SP, Atterbury RJ, Connerton IF: Application of a bacteriophage cocktail to reduce Salmonella Typhimurium U288 contamination on pig skin. Int J Food Microbiol, in press.

  25. De Lappe N, Doran G, O'Connor J, O'Hare C, Cormican M: Characterization of bacteriophages used in the Salmonella enterica serovar Enteritidis phage-typing scheme. J Med Microbiol 2009, 58: 86-93.

    Article  CAS  PubMed  Google Scholar 

  26. Steinbacher S, Baxa U, Miller S, Weintraub A, Seckler R, Huber R: Crystal structure of phage P22 tailspike protein complexed with Salmonella sp. O-antigen receptors. Proc Natl Acad Sci USA 1996, 93: 10584-10588.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

  27. Walter M, Fiedler C, Grassl R, Biebl M, Rachel R, Hermo-Parrado XL, Llamas-Saiz AL, Seckler R, Miller S, van Raaij MJ: Structure of the receptor-binding protein of bacteriophage det7: a podoviral tail spike in a myovirus. J Virol 2008, 82: 2265-2273.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

  28. Yoder MD, Keen NT, Jurnak F: New domain motif: the structure of pectate lyase C, a secreted plant virulence factor. Science 1993, 260: 1503-1507.

    Article  CAS  PubMed  Google Scholar 

  29. Mayans O, Scott M, Connerton I, Gravesen T, Benen J, Visser J, Pickersgill R, Jenkins J: Two crystal structures of pectin lyase A from Aspergillus reveal a pH driven conformational change and striking divergence in the substrate-binding clefts of pectin and pectate lyases. Structure 1997, 5: 677-689.

    Article  CAS  PubMed  Google Scholar 

  30. Jenkins J, Mayans O, Pickersgill R: Structure and evolution of parallel beta-helix proteins. J Struct Biol 1998, 122: 236-246.

    Article  CAS  PubMed  Google Scholar 

  31. Steinbacher S, Seckler R, Miller S, Steipe B, Huber R, Reinemer P: Crystal structure of P22 tailspike protein: interdigitated subunits in a thermostable trimer. Science 1994, 265: 383-386.

    Article  CAS  PubMed  Google Scholar 

  32. Muller JJ, Barbirz S, Heinle K, Freiberg A, Seckler R, Heinemann U: An intersubunit active site between supercoiled parallel beta helices in the trimeric tailspike endorhamnosidase of Shigella flexneri Phage Sf6. Structure 2008, 16: 766-775.

    Article  PubMed  Google Scholar 

  33. Barbirz S, Muller JJ, Uetrecht C, Clark AJ, Heinemann U, Seckler R: Crystal structure of Escherichia coli phage HK620 tailspike: podoviral tailspike endoglycosidase modules are evolutionarily related. Mol Microbiol 2008, 69: 303-316.

    Article  CAS  PubMed  Google Scholar 

  34. Thompson JE, Pourhossein M, Waterhouse A, Hudson T, Goldrick M, Derrick JP, Roberts IS: The K5 lyase KflA combines a viral tail spike structure with a bacterial polysaccharide lyase mechanism. J Biol Chem 2010, 285: 23963-23969.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

  35. Wollin R, Eriksson U, Lindberg AA: Salmonella bacteriophage glycanases: endorhamnosidase activity of bacteriophages P27, 9NA, and KB1. J Virol 1981, 38: 1025-1033.

    PubMed Central  CAS  PubMed  Google Scholar 

  36. Weigele PR, Scanlon E, King J: Homotrimeric, beta-stranded viral adhesins and tail proteins. J Bacteriol 2003, 185: 4022-4030.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

  37. Andres D, Baxa U, Hanke C, Seckler R, Barbirz S: Carbohydrate binding of Salmonella phage P22 tailspike protein and its role during host cell infection. Biochem Soc Trans 2010, 38: 1386-1389.

    Article  CAS  PubMed  Google Scholar 

  38. Casjens SR, Thuman-Commike PA: Evolution of mosaically related tailed bacteriophage genomes seen through the lens of phage P22 virion assembly. Virology 2011, 411: 393-415.

    Article  CAS  PubMed  Google Scholar 

  39. Tacket CO, Sztein MB, Losonsky GA, Wasserman SS, Nataro JP, Edelman R, Pickard D, Dougan G, Chatfield SN, Levine MM: Safety of live oral Salmonella typhi vaccine strains with deletions in htrA and aroC aroD and immune response in humans. Infect Immun 1997, 65: 452-456.

    PubMed Central  CAS  PubMed  Google Scholar 

  40. Rutherford K, Parkhill J, Crook J, Horsnell T, Rice P, Rajandream MA, Barrell B: Artemis: sequence visualization and annotation. Bioinformatics 2000, 16: 944-945.

    Article  CAS  PubMed  Google Scholar 

  41. Carver TJ, Rutherford KM, Berriman M, Rajandream MA, Barrell BG, Parkhill J: ACT: the Artemis Comparison Tool. Bioinformatics 2005, 21: 3422-3423.

    Article  CAS  PubMed  Google Scholar 

  42. Altschul SF, Gish W, Miller W, Myers EW, Lipman DJ: Basic local alignment search tool. J Mol Biol 1990, 215: 403-410.

    Article  CAS  PubMed  Google Scholar 

  43. Bateman A, Coin L, Durbin R, Finn RD, Hollich V, Griffiths-Jones S, Khanna A, Marshall M, Moxon S, Sonnhammer EL, Studholme DJ, Yeats C, Eddy SR: The Pfam protein families database. Nucleic Acids Res 2004, 32: D138-141.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

  44. Larkin MA, Blackshields G, Brown NP, Chenna R, McGettigan PA, McWilliam H, Valentin F, Wallace IM, Wilm A, Lopez R, Thompson JD, Gibson TJ, Higgins DC: Clustal W and Clustal × version 2.0. Bioinformatics 2007, 23: 2947-2948.

    Article  CAS  PubMed  Google Scholar 

  45. Bradley P, Cowen L, Menke M, King J, Berger B: BETAWRAP: successful prediction of parallel beta -helices from primary sequence reveals an association with many microbial pathogens. Proc Natl Acad Sci USA 2001, 98: 14819-14824.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

  46. Lavigne R, Sun WD, Volckaert G: PHIRE, a deterministic approach to reveal regulatory elements in bacteriophage genomes. Bioinformatics 2004, 20: 629-635.

    Article  CAS  PubMed  Google Scholar 

  47. Schattner P, Brooks AN, Lowe TM: The tRNAscan-SE, snoscan and snoGPS web servers for the detection of tRNAs and snoRNAs. Nucleic Acids Res 2005, 33: W686-689.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

Download references

Acknowledgements

SPTH is the recipient of a UK Food Standards Agency post-graduate research award.

Author information

Authors and Affiliations

Authors

Corresponding author

Correspondence to Ian F Connerton.

Additional information

Competing interests

The authors declare that they have no competing interests.

Authors' contributions

SPTH and IFC contributed to the writing of this manuscript. SPTH contributed to all the experimental work reported here. ART contributed to the assembly and DNA sequence interpretation. JR and RW performed DNA sequencing. IFC was the principal investigator and provided all facilitates to complete this work. All authors approved the final manuscript.

Authors’ original submitted files for images

Rights and permissions

Open Access This article is published under license to BioMed Central Ltd. This is an Open Access article is distributed under the terms of the Creative Commons Attribution License ( https://creativecommons.org/licenses/by/2.0 ), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Reprints and permissions

About this article

Cite this article

Hooton, S.P., Timms, A.R., Rowsell, J. et al. Salmonella Typhimurium-specific bacteriophage ΦSH19 and the origins of species specificity in the Vi01-like phage family. Virol J 8, 498 (2011). https://doi.org/10.1186/1743-422X-8-498

Download citation

  • Received:

  • Accepted:

  • Published:

  • DOI: https://doi.org/10.1186/1743-422X-8-498

Keywords