Bacteriophage SPP1 pac Cleavage: A Precise Cut without Sequence Specificity Requirement

DNA Packaging Specificity in the λ-Like Phages: Gifsy-1

DNA viruses recognize viral DNA and package it into virions. Specific recognition is needed to distinguish viral DNA from host cell DNA. The λ-like Escherichia coli phages are interesting and good models to examine genome packaging by large DNA viruses. Gifsy-1 is a λ-like Salmonella phage. Gifsy-1's DNA packaging specificity was compared with those of closely related phages λ, 21, and N15. In vivo packaging studies showed that a Gifsy-1-specific phage packaged λ DNA at ca. 50% efficiency and λ packages Gifsy-1-specific DNA at ~30% efficiency. The results indicate that Gifsy-1 and λ share the same DNA packaging specificity. N15 is also shown to package Gifsy-1 DNA. Phage 21 fails to package λ, N15, and Gifsy-1-specific DNAs; the efficiencies are 0.01%, 0.01%, and 1%, respectively. A known incompatibility between the 21 helix-turn-helix motif and cosBλ is proposed to account for the inability of 21 to package Gifsy-1 DNA. A model is proposed to explain the 100-fold difference in packaging efficiency between λ and Gifsy-1-specific DNAs by phage 21. Database sequences of enteric prophages indicate that phages with Gifsy-1's DNA packaging determinants are confined to Salmonella species. Similarly, prophages with λ DNA packaging specificity are rarely found in Salmonella. It is proposed that λ and Gifsy-1 have diverged from a common ancestor phage, and that the differences may reflect adaptation of their packaging systems to host cell differences.

Hijackers, hitchhikers, or co-drivers? The mysteries of mobilizable genetic elements

Mobile genetic elements shape microbial gene repertoires and populations. Recent results reveal that many, possibly most, microbial mobile genetic elements require helpers to transfer between genomes, which we refer to as Hitcher Genetic Elements (hitchers or HGEs). They may be a large fraction of pathogenicity and resistance genomic islands, whose mechanisms of transfer have remained enigmatic for decades. Together with their helper elements and their bacterial hosts, hitchers form tripartite networks of interactions that evolve rapidly within a parasitism-mutualism continuum. In this emerging view of microbial genomes as communities of mobile genetic elements many questions arise. Which elements are being moved, by whom, and how? How often are hitchers costly hyper-parasites or beneficial mutualists? What is the evolutionary origin of hitchers? Are there key advantages associated with hitchers' lifestyle that justify their unexpected abundance? And why are hitchers systematically smaller than their helpers? In this essay, we start answering these questions and point ways ahead for understanding the principles, origin, mechanisms, and impact of hitchers in bacterial ecology and evolution.

Prophage induction can facilitate the in vitro dispersal of multicellular Streptomyces structures

Streptomyces are renowned for their prolific production of specialized metabolites with applications in medicine and agriculture. These multicellular bacteria present a sophisticated developmental cycle and play a key role in soil ecology. Little is known about the impact of Streptomyces phage on bacterial physiology. In this study, we investigated the conditions governing the expression and production of "Samy", a prophage found in Streptomyces ambofaciens ATCC 23877. This siphoprophage is produced simultaneously with the activation of other mobile genetic elements. Remarkably, the presence and production of Samy increases bacterial dispersal under in vitro stress conditions. Altogether, this study unveiled a new property of a bacteriophage infection in the context of multicellular aggregate dynamics.

Viral genome packaging machines: Structure and enzymology

Although the process of genome encapsidation is highly conserved in tailed bacteriophages and eukaryotic double-stranded DNA viruses, there are two distinct packaging pathways that these viruses use to catalyze ATP-driven translocation of the viral genome into a preassembled procapsid shell. One pathway is used by ϕ29-like phages and adenoviruses, which replicate and subsequently package a monomeric, unit-length genome covalently attached to a virus/phage-encoded protein at each 5'-end of the dsDNA genome. In a second, more ubiquitous packaging pathway characterized by phage lambda and the herpesviruses, the viral DNA is replicated as multigenome concatemers linked in a head-to-tail fashion. Genome packaging in these viruses thus requires excision of individual genomes from the concatemer that are then translocated into a preassembled procapsid. Hence, the ATPases that power packaging in these viruses also possess nuclease activities that cut the genome from the concatemer at the beginning and end of packaging. This review focuses on proposed mechanisms of genome packaging in the dsDNA viruses using unit-length ϕ29 and concatemeric λ genome packaging motors as representative model systems.

The Yersinia Phage X1 Administered Orally Efficiently Protects a Murine Chronic Enteritis Model Against Yersinia enterocolitica Infection

Yersinia enterocolitica is generally considered an important food-borne pathogen worldwide, especially in the European Union. A lytic Yersinia phage X1 (Viruses; dsDNA viruses, no RNA stage; Caudovirales; and Myoviridae) was isolated. Phage X1 showed a broad host range and could effectively lyse 27/51 Y. enterocolitica strains covering various serotypes that cause yersiniosis in humans and animals (such as serotype O3 and serotype O8). The genome of this phage was sequenced and analyzed. No toxin, antibiotic-resistance or lysogeny related modules were found in the genome of phage X1. Studies of phage stability confirmed that X1 had a high tolerance toward a broad range of temperatures (4–60°C) and pH values (4–11) for 1 h. The ability to resist harsh acidic conditions and enzymatic degradation in vitro demonstrated that phage X1 is suitable for oral administration, and in particular, that this phage can pass the stomach barrier and efficiently reach the intestine in vivo without losing infectious ability. The potential of this phage against Y. enterocolitica infection in vitro was studied. In animal experiments, a single oral administration of phage X1 at 6 h post infection was sufficient to eliminate Y. enterocolitica in 33.3% of mice (15/45). In addition, the number of Y. enterocolitica strains in the mice was also dramatically reduced to approximately 10³ CFU/g after 18 h compared with 10⁷ CFU/g in the mice without phage treatment. Treatment with phage X1 showed significant improvement by intestinal histopathologic observations. Moreover, proinflammatory cytokine levels (IL-6, TNF-α, and IL-1β) were significantly reduced (P < 0.05). These results indicate that phage X1 is a promising candidate to control infection by Y. enterocolitica in vivo.

A viral small terminase subunit (TerS) twin ring pac synapsis DNA packaging model is supported by fluorescent fusion proteins

A bacteriophage T4 DNA "synapsis model" proposes that the bacteriophage T4 terminase small subunit (TerS) apposes two pac site containing dsDNA homologs to gauge concatemer maturation adequate for packaging initiation. N-terminus, C-terminus, or both ends modified fusion Ter S proteins retain function. Replacements of the TerS gene in the T4 genome with fusion genes encoding larger (18-45 kDa) TerS-eGFP and TerS-mCherry fluorescent fusion proteins function without significant change in phenotype. Co-infection and co-expression by T4 phages encoding TerS-eGFP and TerS-mCherry shows in vivo FRET in infected bacteria comparable to that of the purified, denatured and then renatured, mixed fusion proteins in vitro. FRET of purified, denatured-renatured, mixed temperature sensitive and native TerS fusion proteins at low and high temperature in vitro shows that TerS ring-like oligomer formation is essential for function in vivo. Super-resolution STORM and PALM microscopy of intercalating dye YOYO-1 DNA and photoactivatable TerS-PAmCherry-C1 fusions support accumulation of TerS dimeric or multiple ring-like oligomer structures containing DNA and gp16-mCherry in vivo as well as in vitro to regulate pac site cutting.

Acidic residues and a predicted, highly conserved α-helix are critical for the endonuclease/strand separation functions of bacteriophage λ's TerL

Complementation, endonuclease, strand separation, and packaging assays using mutant TerL^λ 's, coupled with bioinformatic information and modeling of its endonuclease, identified five residues, D401, E408, D465, E563, and E586, as critical acidic residues of TerL^λ 's endonuclease. Studies of phage and viral TerL nucleases indicate acidic residues participate in metal ion-binding, part of a two-ion metal catalysis mechanism, where metal ion A activates a water for DNA backbone hydrolysis. Modeling places D401, D465, and E586 in locations analogous to those of the metal-binding residues of many phage and viral TerLs. Our work leads to a model of TerL^λ 's endonuclease domain where at least three acidic residues from a ~185 residue segment (D401 to E586) are near each other in the structure, forming the endonuclease catalytic center at cosN, the nicking site. DNA interactions required to bring the rotationally symmetric cosN precisely to the catalytic center are proposed to rely on an ~60 residue region that includes a conserved α-helix for dimerization. Metal ion A, positioned by TerL^λ 's acidic D401 and E586, would be placed at cosN for water activation, ensuring high accuracy for DNA backbone hydrolysis.

The Revisited Genome of Bacillus subtilis Bacteriophage SPP1

Bacillus subtilis bacteriophage SPP1 is a lytic siphovirus first described 50 years ago [1]. Its complete DNA sequence was reported in 1997 [2]. Here we present an updated annotation of the 44,016 bp SPP1 genome and its correlation to different steps of the viral multiplication process. Five early polycistronic transcriptional units encode phage DNA replication proteins and lysis functions together with less characterized, mostly non-^{essential, functions. Late transcription drives synthesis of proteins necessary for SPP1 viral particles assembly and for cell lysis, together with a short set of proteins of unknown function. The extensive genetic, biochemical and structural biology studies on the molecular mechanisms of SPP1 DNA replication and phage particle assembly rendered it a model system for tailed phages research. We propose SPP1} as the reference species for a new SPP1-like viruses genus of the Siphoviridae family.

Packaging of Dinoroseobacter shibae DNA into Gene Transfer Agent Particles Is Not Random

Gene transfer agents (GTAs) are phage-like particles which contain a fragment of genomic DNA of the bacterial or archaeal producer and deliver this to a recipient cell. GTA gene clusters are present in the genomes of almost all marine Rhodobacteraceae (Roseobacters) and might be important contributors to horizontal gene transfer in the world’s oceans. For all organisms studied so far, no obvious evidence of sequence specificity or other nonrandom process responsible for packaging genomic DNA into GTAs has been found. Here, we show that knock-out of an autoinducer synthase gene of Dinoroseobacter shibae resulted in overproduction and release of functional GTA particles (DsGTA). Next-generation sequencing of the 4.2-kb DNA fragments isolated from DsGTAs revealed that packaging was not random. DNA from low-GC conjugative plasmids but not from high-GC chromids was excluded from packaging. Seven chromosomal regions were strongly overrepresented in DNA isolated from DsGTA. These packaging peaks lacked identifiable conserved sequence motifs that might represent recognition sites for the GTA terminase complex. Low-GC regions of the chromosome, including the origin and terminus of replication, were underrepresented in DNA isolated from DsGTAs. DNA methylation reduced packaging frequency while the level of gene expression had no influence. Chromosomal regions found to be over- and underrepresented in DsGTA-DNA were regularly spaced. We propose that a “headful” type of packaging is initiated at the sites of coverage peaks and, after linearization of the chromosomal DNA, proceeds in both directions from the initiation site. GC-content, DNA-modifications, and chromatin structure might influence at which sides GTA packaging can be initiated.

1st German Phage Symposium-Conference Report

In Germany, phage research and application can be traced back to the beginning of the 20th century. However, with the triumphal march of antibiotics around the world, the significance of bacteriophages faded in most countries, and respective research mainly focused on fundamental questions and niche applications. After a century, we pay tribute to the overuse of antibiotics that led to multidrug resistance and calls for new strategies to combat pathogenic microbes. Against this background, bacteriophages came into the spotlight of researchers and practitioners again resulting in a fast growing “phage community”. In October 2017, part of this community met at the 1st German Phage Symposium to share their knowledge and experiences. The participants discussed open questions and challenges related to phage therapy and the application of phages in general. This report summarizes the presentations given, highlights the main points of the round table discussion and concludes with an outlook for the different aspects of phage application.

"French Phage Network"-Third Meeting Report

In its third year of existence, the French Phage Network (Phages.fr) is pursuing its expansion. With more than 25 groups, mostly based in France, working on the various aspects of phage research, the network has increased its visibility, interactivity, and activity. The third meeting of the Phages.fr network, held on November 2017 at the Gif-sur-Yvette Centre National de la Recherche Scientifique (CNRS) campus, was a great opportunity for many young scientists to present their work and interact with more senior scientists, amongst which several were invited from abroad. Here we provide a summary of the work presented at this occasion during the oral presentations and poster sessions.

Physical and Functional Characterization of a Viral Genome Maturation Complex

Genome packaging is strongly conserved in the complex double-stranded DNA viruses, including the herpesviruses and many bacteriophages. In these cases, viral DNA is packaged into a procapsid shell by a terminase enzyme. The packaging substrate is typically a concatemer composed of multiple genomes linked in a head-to-tail fashion, and terminase enzymes perform two essential functions: 1) excision of a unit length genome from the concatemer (genome maturation) and 2) translocation of the duplex into a procapsid (genome packaging). While the packaging motors have been described in some detail, the maturation complexes remain ill characterized. Here we describe the assembly, physical characteristics, and catalytic activity of the λ-genome maturation complex. The λ-terminase protomer is composed of one large catalytic subunit tightly associated with two DNA recognition subunits. The isolated protomer binds DNA weakly and does not discriminate between nonspecific DNA and duplexes that contain the packaging initiation sequence, cos. The Escherichia coli integration host factor protein (IHF) is required for efficient λ-development in vivo and a specific IHF recognition sequence is found within cos. We show that IHF and the terminase protomer cooperatively assemble at the cos site and that the small terminase subunit plays the dominant role in complex assembly. Analytical ultracentrifugation analysis reveals that the maturation complex is composed of four protomers and one IHF heterodimer bound at the cos site. Tetramer assembly activates the cos-cleavage nuclease activity of the enzyme, which matures the genome end in preparation for packaging. The stoichiometry and catalytic activity of the complex is reminiscent of the type IIE and IIF restriction endonucleases and the two systems may share mechanistic features. This study, to our knowledge, provides our first detailed glimpse into the structural and functional features of a viral genome maturation complex, an essential intermediate in the development of complex dsDNA viruses.

Natural history of a viral cohesive end site: cosN of the λ-like phages

The base pairs of cosN, the site where the 12 base-long cohesive ends are generated in λ-like phages, show partial-two fold rotational symmetry. In a bioinformatic survey, we found that the cosN changes in 12 natural cosN variants are restricted to bp 6-to-12 of the cohesive end sequence. In contrast, bp 1-5 of the cohesive end sequence are strictly conserved (13/13), as are the two bp flanking the left nicking site (bp -2 and -1). The bp flanking the right nick site (bp 13 and 14) are conserved in 12 of 13 variants. Five cosN variants differing by as many as five bp were used to replace lambda's cosN. No significant effects of the cosN changes on λ's virus yield were found. In sum, bp -2 to 5 are critical cosN function, and bp 6-12 of the cohesive end sequence are not critical for terminase recognition or virus fitness.