Interaction between Phage T4 Protein RIII and Host Ribosomal Protein S1 Inhibits Endoribonuclease RegB Activation.

Lytic viruses of bacteria (bacteriophages, phages) are intracellular parasites that take over hosts' biosynthetic processes for their propagation. Most of the knowledge on the host hijacking mechanisms has come from the studies of the lytic phage T4, which infects Escherichia coli. The integrity of T4 development is achieved by strict control over the host and phage processes and by adjusting them to the changing infection conditions. In this study, using in vitro and in vivo biochemical methods, we detected the direct interaction between the T4 protein RIII and ribosomal protein S1 of the host. Protein RIII is known as a cytoplasmic antiholin, which plays a role in the lysis inhibition function of T4. However, our results show that RIII also acts as a viral effector protein mainly targeting S1 RNA-binding domains that are central for all the activities of this multifunctional protein. We confirm that the S1-RIII interaction prevents the S1-dependent activation of endoribonuclease RegB. In addition, we propose that by modulating the multiple processes mediated by S1, RIII could act as a regulator of all stages of T4 infection including the lysis inhibition state.

Pantoea Bacteriophage vB_PagS_MED16-A Siphovirus Containing a 2'-Deoxy-7-amido-7-deazaguanosine-Modified DNA.

A novel siphovirus, vB_PagS_MED16 (MED16) was isolated in Lithuania using Pantoea agglomerans strain BSL for the phage propagation. The double-stranded DNA genome of MED16 (46,103 bp) contains 73 predicted open reading frames (ORFs) encoding proteins, but no tRNA. Our comparative sequence analysis revealed that 26 of these ORFs code for unique proteins that have no reliable identity when compared to database entries. Based on phylogenetic analysis, MED16 represents a new genus with siphovirus morphology. In total, 35 MED16 ORFs were given a putative functional annotation, including those coding for the proteins responsible for virion morphogenesis, phage-host interactions, and DNA metabolism. In addition, a gene encoding a preQ0 DNA deoxyribosyltransferase (DpdA) is present in the genome of MED16 and the LC-MS/MS analysis indicates 2'-deoxy-7-amido-7-deazaguanosine (dADG)-modified phage DNA, which, to our knowledge, has never been experimentally validated in genomes of Pantoea phages. Thus, the data presented in this study provide new information on Pantoea-infecting viruses and offer novel insights into the diversity of DNA modifications in bacteriophages.

Escherichia coli trxAgene as a molecular marker for genome engineering of felixounoviruses

BACKGROUND: Bacterial viruses (bacteriophages or phages) have a lot of uncharacterized genes, which hinders the progress of their applied research. Functional characterization of these genes is often hampered by a lack of suitable methods for engineering of phage genomes. METHODS: Phages vB_EcoM_Alf5 (Alf5) and VB_EcoM_VpaE1 (VpaE1) were used as the model phages of Felixounovirus genus. The phage-coded properties were predicted by bioinformatics analysis. The 'pull-down' assay was used for detection of protein-protein interactions. Primer extension analysis was used for the DNA polymerase (DNAP) activity testing. Bacteriophage lambda Redγßα-assisted homologous recombination was used for construction of phage mutants. RESULTS: Bioinformatics analysis showed that felixounoviruses encode DNA polymerase, which is homologous to the T7 DNAP. We found that the Escherichia coli thioredoxin A (TrxA) in vitro interacts with the predicted DNAP of Alf5 phage (gp096) and enhances its activity. Phages Alf5 and VpaE1 do not grow on E. coli strains lacking trxA gene unless it is provided in trans. This feature was used for construction of the deletion/insertion mutants of non-essential genes of felixounoviruses. CONCLUSION: DNA replication of phages from Felixonuvirus genus depends on the host trxA, which therefore may be used as a molecular marker for their genome engineering. GENERAL SIGNIFICANCE: We present a proof-of-principle of a strategy for targeted engineering of bacteriophages of Felixounovirus genus. The method developed here will facilitate the basic and applied research of this unexplored phage group. Furthermore, detected functional interactions between the phage and host proteins will be significant for basic research of DNA replication.

Pantoea Bacteriophage vB_PagS_AAS23: A Singleton of the Genus Sauletekiovirus.

A cold-adapted siphovirus, vB_PagS_AAS23 (AAS23) was isolated in Lithuania using the Pantoea agglomerans strain AUR for the phage propagation. The double-stranded DNA genome of AAS23 (51,170 bp) contains 92 probable protein encoding genes, and no genes for tRNA. A comparative sequence analysis revealed that 25 of all AAS23 open reading frames (ORFs) code for unique proteins that have no reliable identity to database entries. Based on the phylogenetic analysis, AAS23 has no close relationship to other viruses publicly available to date and represents a single species of the genus Sauletekiovirus within the family Drexlerviridae. The phage is able to form plaques in bacterial lawns even at 4 °C and demonstrates a depolymerase activity. Thus, the data presented in this study not only provides the information on Pantoea-infecting bacteriophages, but also offers novel insights into the diversity of cold-adapted viruses and their potential to be used as biocontrol agents.

Complete genome analysis of Pantoea agglomerans-infecting bacteriophage vB_PagM_AAM22.

A novel myovirus, vB_PagM_AAM22 (AAM22), was isolated in Lithuania using Pantoea agglomerans as the host for phage propagation. The 49,744-bp genome of AAM22 has a G + C content of 48.4% and contains 96 probable protein-encoding genes and no genes for tRNA. In total, 34 ORFs were given a putative functional annotation, including genes associated with virion morphogenesis, DNA metabolism, and phage-host interactions. Based on comparative phylogenetic analysis, AAM22 cannot be assigned to any genus currently recognized by the ICTV and is a potential candidate to form a new genus within the family Myoviridae.

Pantoeaagglomerans-Infecting Bacteriophage vB_PagS_AAS21: A Cold-Adapted Virus Representing a Novel Genus within the Family Siphoviridae.

A novel cold-adapted siphovirus, vB_PagS_AAS21 (AAS21), was isolated in Lithuania using Pantoea agglomerans as the host for phage propagation. AAS21 has an isometric head (~85 nm in diameter) and a non-contractile flexible tail (~174 × 10 nm). With a genome size of 116,649 bp, bacteriophage AAS21 is the largest Pantoea-infecting siphovirus sequenced to date. The genome of AAS21 has a G+C content of 39.0% and contains 213 putative protein-encoding genes and 29 genes for tRNAs. A comparative sequence analysis revealed that 89 AAS21 open reading frames (ORFs) code for unique proteins that have no reliable identity to database entries. In total, 63 AAS21 ORFs were functionally annotated, including those coding for the proteins responsible for virion morphogenesis, phage-host interactions, and DNA metabolism. Proteomic analysis led to the experimental identification of 19 virion proteins, including 11 that were predicted by bioinformatics approaches. Based on comparative phylogenetic analysis, AAS21 cannot be assigned to any genus currently recognized by ICTV and may represents a new branch of viruses within the family Siphoviridae.

The Robust Self-Assembling Tubular Nanostructures Formed by gp053 from Phage vB_EcoM_FV3.

The recombinant phage tail sheath protein, gp053, from Escherichia coli infecting myovirus vB_EcoM_FV3 (FV3) was able to self-assemble into long, ordered and extremely stable tubular structures (polysheaths) in the absence of other viral proteins. TEM observations revealed that those protein nanotubes varied in length (~10⁻1000 nm). Meanwhile, the width of the polysheaths (~28 nm) corresponded to the width of the contracted tail sheath of phage FV3. The formed protein nanotubes could withstand various extreme treatments including heating up to 100 °C and high concentrations of urea. To determine the shortest variant of gp053 capable of forming protein nanotubes, a set of N- or/and C-truncated as well as poly-His-tagged variants of gp053 were constructed. The TEM analysis of these mutants showed that up to 25 and 100 amino acid residues could be removed from the N and C termini, respectively, without disturbing the process of self-assembly. In addition, two to six copies of the gp053 encoding gene were fused into one open reading frame. All the constructed oligomers of gp053 self-assembled in vitro forming structures of different regularity. By using the modification of cysteines with biotin, the polysheaths were tested for exposed thiol groups. Polysheaths formed by the wild-type gp053 or its mutants possess physicochemical properties, which are very attractive for the construction of self-assembling nanostructures with potential applications in different fields of nanosciences.

BREX system of Escherichia coli distinguishes self from non-self by methylation of a specific DNA site.

Prokaryotes evolved numerous systems that defend against predation by bacteriophages. In addition to well-known restriction-modification and CRISPR-Cas immunity systems, many poorly characterized systems exist. One class of such systems, named BREX, consists of a putative phosphatase, a methyltransferase and four other proteins. A Bacillus cereus BREX system provides resistance to several unrelated phages and leads to modification of specific motif in host DNA. Here, we study the action of BREX system from a natural Escherichia coli isolate. We show that while it makes cells resistant to phage λ infection, induction of λ prophage from cells carrying BREX leads to production of viruses that overcome the defense. The induced phage DNA contains a methylated adenine residue in a specific motif. The same modification is found in the genome of BREX-carrying cells. The results establish, for the first time, that immunity to BREX system defense is provided by an epigenetic modification.

Pantoea Bacteriophage vB_PagS_Vid5: A Low-Temperature Siphovirus That Harbors a Cluster of Genes Involved in the Biosynthesis of Archaeosine.

A novel low-temperature siphovirus, vB_PagS_Vid5 (Vid5), was isolated in Lithuania using Pantoea agglomerans isolate for the phage propagation. The 61,437 bp genome of Vid5 has a G⁻C content of 48.8% and contains 99 probable protein encoding genes and one gene for tRNASer. A comparative sequence analysis revealed that 46 out of 99 Vid5 open reading frames (ORFs) code for unique proteins that have no reliable identity to database entries. In total, 33 Vid5 ORFs were given a putative functional annotation, including those coding for the proteins responsible for virion morphogenesis, phage-host interactions, and DNA metabolism. In addition, a cluster of genes possibly involved in the biosynthesis of 7-deazaguanine derivatives was identified. Notably, one of these genes encodes a putative preQ0/preQ1 transporter, which has never been detected in bacteriophages to date. A proteomic analysis led to the experimental identification of 11 virion proteins, including nine that were predicted by bioinformatics approaches. Based on the phylogenetic analysis, Vid5 cannot be assigned to any genus currently recognized by ICTV, and may represent a new one within the family of Siphoviridae.

Molecular analysis of the low-temperature Escherichia coli phage vB_EcoS_NBD2.

A novel low-temperature Escherichia coli phage vB_EcoS_NBD2 was isolated in Lithuania from agricultural soil. With an optimum temperature for plating around 20 °C, vB_EcoS_NBD2 efficiently produced plaques on Escherichia coli NovaBlue (DE3) at a temperature range of 10-30 °C, yet failed to plate at temperatures above 35 °C. Phage vB_EcoS_NBD2 virions have a siphoviral morphology with an isometric head (65 nm in diameter), and a non-contractile flexible tail (170 nm). The 51,802-bp genome of vB_EcoS_NBD2 has a G + C content of 49.8%, and contains 87 probable protein-encoding genes as well as 1 gene for tRNASer. Comparative sequence analysis revealed that 22 vB_EcoS_NBD2 ORFs encode unique proteins that have no reliable identity to database entries. Based on homology to biologically defined proteins and/or proteomics analysis, 36 vB_EcoS_NBD2 ORFs were given a putative functional annotation, including 20 genes coding for morphogenesis-related proteins and 13 associated with DNA metabolism. Phylogenetic analysis revealed that vB_EcoS_NBD2 belongs to the subfamily Tunavirinae, but cannot be assigned to any genus currently recognized by ICTV.

Complete Genome Sequence of Escherichia coli Phage vB_EcoM_Alf5.

Here, we announce the complete genome sequence of the Escherichia coli myophage vB_EcoM_Alf5 belonging to the genus Felixo1virus, whose members have not been comprehensively studied at the molecular level. Phage vB_EcoM_Alf5 infects E. coli K-12-derived laboratory strains and therefore is well suited for functional studies.

Molecular Analysis of Arthrobacter Myovirus vB_ArtM-ArV1: We Blame It on the Tail.

This is the first report on a myophage that infects Arthrobacter A novel virus, vB_ArtM-ArV1 (ArV1), was isolated from soil using Arthrobacter sp. strain 68b for phage propagation. Transmission electron microscopy showed its resemblance to members of the family Myoviridae: ArV1 has an isometric head (∼74 nm in diameter) and a contractile, nonflexible tail (∼192 nm). Phylogenetic and comparative sequence analyses, however, revealed that ArV1 has more genes in common with phages from the family Siphoviridae than it does with any myovirus characterized to date. The genome of ArV1 is a linear, circularly permuted, double-stranded DNA molecule (71,200 bp) with a GC content of 61.6%. The genome includes 101 open reading frames (ORFs) yet contains no tRNA genes. More than 50% of ArV1 genes encode unique proteins that either have no reliable identity to database entries or have homologues only in Arthrobacter phages, both sipho- and myoviruses. Using bioinformatics approaches, 13 ArV1 structural genes were identified, including those coding for head, tail, tail fiber, and baseplate proteins. A further 6 ArV1 ORFs were annotated as encoding putative structural proteins based on the results of proteomic analysis. Phylogenetic analysis based on the alignment of four conserved virion proteins revealed that Arthrobacter myophages form a discrete clade that seems to occupy a position somewhat intermediate between myo- and siphoviruses. Thus, the data presented here will help to advance our understanding of genetic diversity and evolution of phages that constitute the order CaudoviralesIMPORTANCE Bacteriophages, which likely originated in the early Precambrian Era, represent the most numerous population on the planet. Approximately 95% of known phages are tailed viruses that comprise three families: Podoviridae (with short tails), Siphoviridae (with long noncontractile tails), and Myoviridae (with contractile tails). Based on the current hypothesis, myophages, which may have evolved from siphophages, are thought to have first emerged among Gram-negative bacteria, whereas they emerged only later among Gram-positive bacteria. The results of the molecular characterization of myophage vB_ArtM-ArV1 presented here conform to the aforementioned hypothesis, since, at a glance, bacteriophage vB_ArtM-ArV1 appears to be a siphovirus that possesses a seemingly functional contractile tail. Our work demonstrates that such "chimeric" myophages are of cosmopolitan nature and are likely characteristic of the ecologically important soil bacterial genus Arthrobacter.

Incomplete LPS Core-Specific Felix01-Like Virus vB_EcoM_VpaE1.

Bacteriophages represent a valuable source for studying the mechanisms underlying virus-host interactions. A better understanding of the host-specificity of viruses at the molecular level can promote various phage applications, including bacterial diagnostics, antimicrobial therapeutics, and improve methods in molecular biology. In this study, we describe the isolation and characterization of a novel coliphage, vB_EcoM_VpaE1, which has different host specificity than its relatives. Morphology studies, coupled with the results of genomic and proteomic analyses, indicate that vB_EcoM_VpaE1 belongs to the newly proposed genus Felix01likevirus in the family Myoviridae. The genus Felix01likevirus comprises a group of highly similar phages that infect O-antigen-expressing Salmonella and Escherichia coli (E. coli) strains. Phage vB_EcoM_VpaE1 differs from the rest of Felix01-like viruses, since it infects O-antigen-deficient E. coli strains with an incomplete core lipopolysaccharide (LPS). We show that vB_EcoM_VpaE1 can infect mutants of E. coli that contain various truncations in their LPS, and can even recognize LPS that is truncated down to the inner-core oligosaccharide, showing potential for the control of rough E. coli strains, which usually emerge as resistant mutants upon infection by O-Ag-specific phages. Furthermore, VpaE1 can replicate in a wide temperature range from 9 to 49 °C, suggesting that this virus is well adapted to harsh environmental conditions. Since the structural proteins of such phages tend to be rather robust, the receptor-recognizing proteins of VpaE1 are an attractive tool for application in glycan analysis, bacterial diagnostics and antimicrobial therapeutics.

Low-temperature bacterial viruses VR - a small but diverse group of E. coli phages.

The complete genome sequences of four low-temperature Escherichia coli-specific tevenviruses, vb_EcoM-VR5, vb_EcoM-VR20, vb_EcoM-VR25 and vb_EcoM-VR26, were determined. Genomic comparisons including recently described genomes of vb_EcoM-VR7 and JS98 as well as phage T4 allowed the identification of two genetic groups that were consistent with defined host-range phenotypes. Group A included the broad-host-range phages vb_EcoM-VR5 and JS98, while group B included vb_EcoM-VR7, vb_EcoM-VR20, vb_EcoM-VR25 and vb_EcoM-VR26, which all had somewhat limited host ranges. All four sequenced phages had genomes that were similar in length (~170 kb) and GC content (~40 %), and, with the exception of vb_EcoM-VR5, at the nucleotide level, they were much more closely related to each other than either was to any other tevenvirus currently characterized. Nevertheless, the overall genome organization of vb_EcoM-VR5, vb_EcoM-VR20, vb_EcoM-VR25 and vb_EcoM-VR26 was comparable to that seen in tevenviruses.

Isolation and characterization of vB_ArS-ArV2 - first Arthrobacter sp. infecting bacteriophage with completely sequenced genome.

This is the first report on a complete genome sequence and biological characterization of the phage that infects Arthrobacter. A novel virus vB_ArS-ArV2 (ArV2) was isolated from soil using Arthrobacter sp. 68b strain for phage propagation. Based on transmission electron microscopy, ArV2 belongs to the family Siphoviridae and has an isometric head (∼63 nm in diameter) with a non-contractile flexible tail (∼194×10 nm) and six short tail fibers. ArV2 possesses a linear, double-stranded DNA genome (37,372 bp) with a G+C content of 62.73%. The genome contains 68 ORFs yet encodes no tRNA genes. A total of 28 ArV2 ORFs have no known functions and lack any reliable database matches. Proteomic analysis led to the experimental identification of 14 virion proteins, including 9 that were predicted by bioinformatics approaches. Comparative phylogenetic analysis, based on the amino acid sequence alignment of conserved proteins, set ArV2 apart from other siphoviruses. The data presented here will help to advance our understanding of Arthrobacter phage population and will extend our knowledge about the interaction between this particular host and its phages.

A mutation in the gene for polynucleotide kinase of bacteriophage T4 K10 affects mRNA processing.

The bacteriophage T4 insertion-substitution (I/S) vector system has become one of the most important tools for the introduction of site-directed mutations into the T4 genome. In this study, we show that the I/S phage T4 K10 carries two point mutations within the gene for polynucleotide kinase pseT, resulting in amino acid substitutions G14D and R229H. The G14D mutation impairs 5'-kinase activity in vivo as well as in vitro and leads to diminished processing at secondary sites of several RegB-cleaved transcripts.

Klebsiella phage vB_KleM-RaK2 - a giant singleton virus of the family Myoviridae.

At 346 kbp in size, the genome of a jumbo bacteriophage vB_KleM-RaK2 (RaK2) is the largest Klebsiella infecting myovirus genome sequenced to date. In total, 272 out of 534 RaK2 ORFs lack detectable database homologues. Based on the similarity to biologically defined proteins and/or MS/MS analysis, 117 of RaK2 ORFs were given a functional annotation, including 28 RaK2 ORFs coding for structural proteins that have no reliable homologues to annotated structural proteins in other organisms. The electron micrographs revealed elaborate spike-like structures on the tail fibers of Rak2, suggesting that this phage is an atypical myovirus. While head and tail proteins of RaK2 are mostly myoviridae-related, the bioinformatics analysis indicate that tail fibers/spikes of this phage are formed from podovirus-like peptides predominantly. Overall, these results provide evidence that bacteriophage RaK2 differs profoundly from previously studied viruses of the Myoviridae family.

Bacteriophage vB_EcoM_FV3: a new member of "rV5-like viruses".

A proposed new genus of the family Myoviridae, "rV5-like viruses", includes two lytic bacteriophages: Escherichia coli O157: H7-specific bacteriophage rV5 and Salmonella phage PVP-SE1. Here, we present basic properties and genomic characterization of a novel rV5-like phage, vB_EcoM_FV3, which infects E. coli K-12-derived laboratory strains and replicates at high temperature (up to 47 °C). The 136,947-bp genome of vB_EcoM_FV3 contains 218 open reading frames and encodes 5 tRNAs. The genomic content and organization of vB_EcoM_FV3 is more similar to that of rV5 than to PVP-SE1, but all three phages share similar morphological characteristics and form a homogeneous phage group.

Genome of Klebsiella sp.-infecting bacteriophage vB_KleM_RaK2.

Despite the fact that multidrug-resistant Klebsiella sp. strains emerge rapidly (Xu J, et al., Adv. Mater. Res. 268-270:1954-1956, 2011) and bacteriophages have been reported to be useful in controlling these bacteria (Kumari S, Harjai K, Chhibber S, J. Med. Microbiol. 60:205-210, 2011), the complete genome sequences of only five Klebsiella phages (four siphoviruses and one myovirus) can be found in databases. In this paper, we report on the complete genome sequence of Klebsiella sp.-infecting bacteriophage vB_KleM_RaK2. With a genome size of 345,809 bp, this is the second largest myovirus and the largest Klebsiella phage sequenced to date. This phage differs substantially from other myoviruses since 411 out of 534 vB_KleM_RaK2 open reading frames have no known functions and lack any reliable database matches. Comparative analysis of the genome sequence of vB_KleM_RaK2 suggests that this phage forms a distinct phylogenetic branch within the family Myoviridae of tailed bacteriophages.

Genome of low-temperature T4-related bacteriophage vB_EcoM-VR7.

The complete genome sequence of the T4-related low-temperature Escherichia coli bacteriophage vB_EcoM-VR7 was determined. The genome sequence is 169,285 bp long, with a G+C content of 40.3%. Overall, 95% of the phage genome is coding. It encodes 293 putative protein-encoding open reading frames (ORFs) and tRNA(Met). More than half (59%) of the genomic DNA lacks significant homology with the DNA of T4, but once translated, 72% of the vB_EcoM-VR7 genome (211 ORFs) encodes protein homologues of T4 genes. Overall, 46 vB_EcoM-VR7 ORFs have no homologues in T4 but are derived from other T4-related phages, nine ORFs show similarities to bacterial or non-T4-related phage genes, and 27 ORFs are unique to vB_EcoM-VR7. This phage lacks several T4 enzymes involved in host DNA degradation; however, there is extensive representation of the DNA replication, recombination and repair enzymes as well as the viral capsid and tail structural genes.