Lateral transduction is inherent to the life cycle of the archetypical Salmonella phage P22

Lysogenic induction ends the stable association between a bacteriophage and its host, and the transition to the lytic cycle begins with early prophage excision followed by DNA replication and packaging (ERP). This temporal program is considered universal for P22-like temperate phages, though there is no direct evidence to support the timing and sequence of these events. Here we report that the long-standing ERP program is an observation of the experimentally favored Salmonella phage P22 tsc229 heat-inducible mutant, and that wild-type P22 actually follows the replication-packaging-excision (RPE) program. We find that P22 tsc229 excises early after induction, but P22 delays excision to just before it is detrimental to phage production. This allows P22 to engage in lateral transduction. Thus, at minimal expense to itself, P22 has tuned the timing of excision to balance propagation with lateral transduction, powering the evolution of its host through gene transfer in the interest of self-preservation.

The secret life (cycle) of temperate bacteriophages

Lysogenic induction ends the stable association between a bacteriophage and its host, and the transition to the lytic cycle begins with prophage excision followed by DNA replication and packaging (ERP) – a temporal program that is considered universal for most temperate phages. Here we report that the long-standing ERP program is an artefact of the experimentally favoured Salmonella phage P22 tsc229 heat-inducible mutant, and that wildtype P22 actually follows a replication-packaging-excision (RPE) program. We found that unlike P22 tsc229, P22 delayed excision to just before it was detrimental to phage production. Thus, at minimal expense to itself, P22 has tuned the timing of excision to balance propagation with lateral transduction, powering the evolution of its host through gene transfer in the interest of self-preservation.One Sentence SummaryGenetic analyses propose a new life cycle for temperate bacteriophages.

Intravirion DNA Can Access the Space Occupied by the Bacteriophage P22 Ejection Proteins

Tailed double-stranded DNA bacteriophages inject some proteins with their dsDNA during infection. Phage P22 injects about 12, 12, and 30 molecules of the proteins encoded by genes 7, 16 and 20, respectively. After their ejection from the virion, they assemble into a trans-periplasmic conduit through which the DNA passes to enter the cytoplasm. The location of these proteins in the virion before injection is not well understood, although we recently showed they reside near the portal protein barrel in DNA-filled heads. In this report we show that when these proteins are missing from the virion, a longer than normal DNA molecule is encapsidated by the P22 headful DNA packaging machinery. Thus, the ejection proteins occupy positions within the virion that can be occupied by packaged DNA when they are absent.

Equine intestinal O-seroconverting temperate coliphage Hf4s: genomic and biological characterization

Tailed bacteriophages constitute the bulk of the intestinal viromes of the vertebrate animals. However, the relationships between lytic and lysogenic lifestyles of the phages in these ecosystems are not always clear and may vary between the species or even between the individuals. The human intestinal (fecal) viromes are believed to be dominated by temperate phages, while in the horse feces the virulent phages are more prevalent. Almost all the isolates of horse fecal coliphages are virulent. Phage Hf4s is the first temperate equine intestinal coliphage characterized. It was isolated from the horse feces on the indigenous equine E. coli 4s strain. It is a podovirus, related to Lederbergvirus genus (including the well-characterized Salmonella phage P22). Hf4s recognizes the host O antigen as its primary receptor and possesses a functional O-antigen seroconversion cluster that renders the lysogens protected from the superinfection by the same phage and also abolishes the adsorption of some indigenous equine virulent coliphages, such as DT57C, while the other phages, such as G7C or phiKT retain the ability to infect E. coli 4s (Hf4s) lysogens.

Asparaginase-Phage P22 Nanoreactors: Toward a Biobetter Development for Acute Lymphoblastic Leukemia Treatment

Asparaginase (ASNase) is a biopharmaceutical for Acute Lymphoblastic Leukemia (ALL) treatment. However, it shows undesirable side effects such as short lifetimes, susceptibility to proteases, and immunogenicity. Here, ASNase encapsidation was genetically directed in bacteriophage P22-based virus-like particles (VLPs) (ASNase-P22 nanoreactors) as a strategy to overcome these challenges. ASNase-P22 was composed of 58.4 ± 7.9% of coat protein and 41.6 ± 8.1% of tetrameric ASNase. Km and Kcat values of ASNase-P22 were 15- and 2-fold higher than those obtained for the free enzyme, respectively. Resulting Kcat/Km value was 2.19 × 105 M−1 s−1. ASNase-P22 showed an aggregation of 60% of the volume sample when incubated at 37 °C for 12 days. In comparison, commercial asparaginase was completely aggregated under the same conditions. ASNase-P22 was stable for up to 24 h at 37 °C, independent of the presence of human blood serum (HBS) or whether ASNase-P22 nanoreactors were uncoated or PEGylated. Finally, we found that ASNase-P22 caused cytotoxicity in the leukemic cell line MOLT-4 in a concentration dependent manner. To our knowledge, this is the first work where ASNase is encapsulated inside of VLPs, as a promising alternative to fight ALL.

Assessment of phage-mediated inhibition of Salmonella Typhimurium treated with sublethal concentrations of ceftriaxone and ciprofloxacin

ABSTRACT This study was designed to evaluate the synergistic effect of phage (P22) and antibiotic on the inhibition of Salmonella Typhimurium exposed to ceftriaxone (CEF) and ciprofloxacin (CIP). The effect of phage and antibiotic treatments was evaluated by plaque size, disk diffusion, antibiotic susceptibility and phage multiplication assays. The sequential treatment effect of phage and antibiotic was carried out in different treatment order and time for 12 h at 37°C. P22 plaque sizes were increased by 28 and 71%, respectively, in the presence of CEF and CIP. The clear zone sizes in disk diffusion assay were significantly increased to >37 mm in the presence of CEF and CIP compared to the control (28–31 mm). Pre-treatment with P22 enhanced the antimicrobial effect of CIP, showing >2 log reduction after a 12 h incubation. Phage P22 combined with antibiotics (CEF and CIP) effectively inhibited the growth of S. Typhimurium depending on the treatment order and time. These results provide useful information for understanding the synergistic effect of phage and antibiotic treatment which can be an effective option to control antibiotic resistant pathogens.

Isolation and Characterization T4- and T7-Like Phages that Infect the Bacterial Plant Pathogen Agrobacterium tumefaciens

In the rhizosphere, bacteria–phage interactions are likely to have important impacts on the ecology of microbial communities and microbe–plant interactions. To better understand the dynamics of Agrobacteria–phage interactions, we have isolated diverse bacteriophages which infect the bacterial plant pathogen, Agrobacterium tumefaciens. Here, we complete the genomic characterization of Agrobacterium tumefaciens phages Atu_ph04 and Atu_ph08. Atu_ph04—a T4-like phage belonging to the Myoviridae family—was isolated from waste water and has a 143,349 bp genome that encodes 223 predicted open reading frames (ORFs). Based on phylogenetic analysis and whole-genome alignments, Atu_ph04 is a member of a newly described T4 superfamily that contains other Rhizobiales-infecting phages. Atu_ph08, a member of the Podoviridae T7-like family, was isolated from waste water, has a 59,034 bp genome, and encodes 75 ORFs. Based on phylogenetic analysis and whole-genome alignments, Atu_ph08 may form a new T7 superfamily which includes Sinorhizobium phage PCB5 and Ochrobactrum phage POI1126. Atu_ph08 is predicted to have lysogenic activity, as we found evidence of an integrase and several transcriptional repressors with similarity to proteins in transducing phage P22. Together, this data suggests that Agrobacterium phages are diverse in morphology, genomic content, and lifestyle.

A Hydrophobic Network: Intersubunit and Intercapsomer Interactions Stabilizing the Bacteriophage P22 Capsid

ABSTRACTDouble-stranded DNA (dsDNA) tailed phages and herpesviruses assemble their capsids using coat proteins that have the ubiquitous HK97 fold. Though this fold is common, we do not have a thorough understanding of the different ways viruses adapt it to maintain stability in various environments. The HK97-fold E-loop, which connects adjacent subunits at the outer periphery of capsomers, has been implicated in capsid stability. Here, we show that in bacteriophage P22, residue W61 at the tip of the E-loop plays a role in stabilizing procapsids and in maturation. We hypothesize that a hydrophobic pocket is formed by residues I366 and W410 in the P domain of a neighboring subunit within a capsomer, into which W61 fits like a peg. In addition, W61 likely bridges to residues A91 and L401 in P-domain loops of an adjacent capsomer, thereby linking the entire capsid together with a network of hydrophobic interactions. There is conservation of this hydrophobic network in the distantly related P22-like phages, indicating that this structural feature is likely important for stabilizing this family of phages. Thus, our data shed light on one of the varied elegant mechanisms used in nature to consistently build stable viral genome containers through subtle adaptation of the HK97 fold.IMPORTANCESimilarities in assembly reactions and coat protein structures of the dsDNA tailed phages and herpesviruses make phages ideal models to understand capsid assembly and identify potential targets for antiviral drug discovery. The coat protein E-loops of these viruses are involved in both intra- and intercapsomer interactions. In phage P22, hydrophobic interactions peg the coat protein subunits together within a capsomer, where the E-loop hydrophobic residue W61 of one subunit packs into a pocket of hydrophobic residues I366 and W410 of the adjacent subunit. W61 also makes hydrophobic interactions with A91 and L401 of a subunit in an adjacent capsomer. We show these intra- and intercapsomer hydrophobic interactions form a network crucial to capsid stability and proper assembly.

A hydrophobic network: Intersubunit and intercapsomer interactions stabilizing the bacteriophage P22 capsid

AbstractdsDNA tailed phages and herpesviruses assemble their capsids using coat proteins that have the ubiquitous HK97 fold. Though this fold is common, we do not have a thorough understanding of the different ways viruses adapt it to maintain stability in various environments. The HK97-fold E-loop, which connects adjacent subunits at the outer periphery of capsomers, has been implicated in capsid stability. Here we show that in bacteriophage P22, residue W61 at the tip of the E-loop plays a role in stabilizing procapsids and in maturation. We hypothesize that a hydrophobic pocket is formed by residues I366 and W410 in the P-domain of a neighboring subunit within a capsomer, into which W61 fits like a peg. In addition, W61 likely bridges to residues A91 and L401 in P-domain loops of an adjacent capsomer, thereby linking the entire capsid together with a network of hydrophobic interactions. There is conservation of this hydrophobic network in the distantly related P22-like phages, indicating that this structural feature is likely important for stabilizing this family of phages. Thus, our data shed light on one of the varied elegant mechanisms used in nature to consistently build stable viral genome containers through subtle adaptation of the HK97 fold.IMPORTANCESimilarities in assembly reactions and coat protein structures of the dsDNA tailed phages and herpesviruses make phages ideal models to understand capsid assembly and identify potential targets for antiviral drug discovery. The coat protein E-loops of these viruses are involved in both intra-and intercapsomer interactions. In phage P22, hydrophobic interactions peg the coat protein subunits together within a capsomer, where the E-loop hydrophobic residue W61 of one subunit packs into a pocket of hydrophobic residues I366 and W410 of the adjacent subunit. W61 also makes hydrophobic interactions with A91 and L401 of a subunit in an adjacent capsomer. We show these intra-and intercapsomer hydrophobic interactions form a network crucial to capsid stability and proper assembly.

NMR Mapping of Disordered Segments from a Viral Scaffolding Protein Encapsulated in a 23 MDa Procapsid Complex

SummaryScaffolding proteins are requisite for the capsid shell assembly of many tailed dsDNA bacteriophages, some archaeal viruses, herpesviruses, and adenoviruses. Despite their importance, no high-resolution structural information is available for scaffolding proteins within capsids. Here we use the inherent size limit of NMR to identify mobile segments of the phage P22 scaffolding protein in solution and when incorporated into a ~23 MDa procapsid complex. Free scaffolding protein gives NMR signals from both the N and C-terminus. When scaffolding protein is incorporated into P22 procapsids, NMR signals from the C-terminal helix-turn-helix (HTH) domain disappear due to binding to the procapsid interior. Signals from the N-terminal domain persist, indicating this segment retains flexibility when bound to procapsids. The unstructured character of the N-terminus coupled with its high content of negative charges, is likely important for the dissociation and release of scaffolding protein, during the genome packaging step accompanying phage maturation.Graphical AbstractScaffolding protein (SP) nucleates the assembly of phage P22 coat proteins into an icosahedral capsid structure that envelops the viral genome. NMR spectra of free SP show signals from the N-terminus (red) and a helix-turn-helix domain at the C-terminus (blue). When SP is incorporated into empty phage P22 procapsids to form a 23 MDa complex, the subset of signals from the N-terminal 40 residues persist indicating this segment is disordered. The unfolded nature of the N-terminus coupled with its negatively charged character, is important for the functional requirement of SP to exit the capsid as it becomes packaged with its genome.