Newly isolated Nodularia phage influences cyanobacterial community dynamics.

Cyanophages, that is, viruses infecting cyanobacteria, are a key component driving cyanobacterial community dynamics both ecologically and evolutionarily. In addition to reducing biomass and influencing the genetic diversity of their host populations, they can also have a wider community-level impact due to the release of nutrients by phage-induced cell lysis. In this study, we isolated and characterized a new cyanophage, a siphophage designated as vB_NpeS-2AV2, capable of infecting the filamentous nitrogen fixing cyanobacterium Nodularia sp. AV2 with a lytic cycle between 12 and 18 hours. The role of the phage in the ecology of its host Nodularia and competitor Synechococcus was investigated in a set of microcosm experiments. Initially, phage-induced cell lysis decreased the number of Nodularia cells in the cultures. However, around 18%-27% of the population was resistant against the phage infection. Nitrogen was released from the Nodularia cells as a consequence of phage activity, resulting in a seven-fold increase in Synechococcus cell density. In conclusion, the presence of the cyanophage vB_NpeS-2AV2 altered the ecological dynamics in the cyanobacterial community and induced evolutionary changes in the Nodularia population, causing the evolution from a population dominated by susceptible cells to a population dominated by resistant ones.

Temperature and pH dependence of DNA ejection from archaeal lemon-shaped virus His1.

The archaeal virus His1 isolated from a hypersaline environment infects an extremely halophilic archaeon Haloarcula hispanica. His1 features a lemon-shaped capsid, which is so far found only in archaeal viruses. This unique capsid can withstand high salt concentrations, and can transform into a helical tube, which in turn is resistant to extremely harsh conditions. Hypersaline environments exhibit a wide range of temperatures and pH conditions, which present an extra challenge to their inhabitants. We investigated the influence of pH and temperature on DNA ejection from His1 virus using single-molecule fluorescence experiments. The observed number of ejecting viruses is constant in pH 5 to 9, while the ejection process is suppressed at pH below 5. Similarly, the number of ejections within 15-42 °C shows only a minor increase around 25-37 °C. The maximum velocity of single ejected DNA increases with temperature, in qualitative agreement with the continuum model of dsDNA ejection.

Ratification vote on taxonomic proposals to the International Committee on Taxonomy of Viruses (2015).

Changes to virus taxonomy approved and ratified by the International Committee on Taxonomy of Viruses in February 2015 are listed.

Lipid fingerprints of intact viruses by MALDI-TOF/mass spectrometry.

A number of viruses contain lipid membranes, which are in close contact with capsid proteins and/or nucleic acids and have an important role in the viral infection process. In this study membrane lipids of intact viruses have been analysed by MALDI-TOF/MS with a novel methodology avoiding lipid extraction and separation steps. To validate the novel method, a wide screening of viral lipids has been performed analysing highly purified intact bacterial and archaeal viruses displaying different virion architectures. Lipid profiles reported here contain all lipids previously detected by mass spectrometry analyses of virus lipid extracts. Novel details on the membrane lipid composition of selected viruses have also been obtained. In addition we show that this technique allows the study of lipid distribution easily in subviral particles during virus fractionation. The possibility to reliably analyse minute amounts of intact viruses by mass spectrometry opens new perspectives in analytical and functional lipid studies on a wider range of viruses including pathogenic human ones, which are difficult to purify in large amounts.

DNA ejection from an archaeal virus--a single-molecule approach.

The translocation of genetic material from the viral capsid to the cell is an essential part of the viral infection process. Whether the energetics of this process is driven by the energy stored within the confined nucleic acid or cellular processes pull the genome into the cell has been the subject of discussion. However, in vitro studies of genome ejection have been limited to a few head-tailed bacteriophages with a double-stranded DNA genome. Here we describe a DNA release system that operates in an archaeal virus. This virus infects an archaeon Haloarcula hispanica that was isolated from a hypersaline environment. The DNA-ejection velocity of His1, determined by single-molecule experiments, is comparable to that of bacterial viruses. We found that the ejection process is modulated by the external osmotic pressure (polyethylene glycol (PEG)) and by increased ion (Mg(2+) and Na(+)) concentration. The observed ejection was unidirectional, randomly paused, and incomplete, which suggests that cellular processes are required to complete the DNA transfer.

A novel virus-host cell membrane interaction. Membrane voltage-dependent endocytic-like entry of bacteriophage straight phi6 nucleocapsid.

Studies on the virus-cell interactions have proven valuable in elucidating vital cellular processes. Interestingly, certain virus-host membrane interactions found in eukaryotic systems seem also to operate in prokaryotes (Bamford, D.H., M. Romantschuk, and P. J. Somerharju, 1987. EMBO (Eur. Mol. Biol. Organ.) J. 6:1467-1473; Romantschuk, M., V.M. Olkkonen, and D.H. Bamford. 1988. EMBO (Eur. Mol. Biol. Organ.) J. 7:1821-1829). straight phi6 is an enveloped double-stranded RNA virus infecting a gram-negative bacterium. The viral entry is initiated by fusion between the virus membrane and host outer membrane, followed by delivery of the viral nucleocapsid (RNA polymerase complex covered with a protein shell) into the host cytosol via an endocytic-like route. In this study, we analyze the interaction of the nucleocapsid with the host plasma membrane and demonstrate a novel approach for dissecting the early events of the nucleocapsid entry process. The initial binding of the nucleocapsid to the plasma membrane is independent of membrane voltage (DeltaPsi) and the K(+) and H(+) gradients. However, the following internalization is dependent on plasma membrane voltage (DeltaPsi), but does not require a high ATP level or K(+) and H(+) gradients. Moreover, the nucleocapsid shell protein, P8, is the viral component mediating the membrane-nucleocapsid interaction.

Membrane-containing virus particles exhibit the mechanics of a composite material for genome protection.

The protection of the viral genome during extracellular transport is an absolute requirement for virus survival and replication. In addition to the almost universal proteinaceous capsids, certain viruses add a membrane layer that encloses their double-stranded (ds) DNA genome within the protein shell. Using the membrane-containing enterobacterial virus PRD1 as a prototype, and a combination of nanoindentation assays by atomic force microscopy and finite element modelling, we show that PRD1 provides a greater stability against mechanical stress than that achieved by the majority of dsDNA icosahedral viruses that lack a membrane. We propose that the combination of a stiff and brittle proteinaceous shell coupled with a soft and compliant membrane vesicle yields a tough composite nanomaterial well-suited to protect the viral DNA during extracellular transport.

Macromolecular assemblies: greater than their parts.

Increasingly powerful methods of analysis have opened up complex macromolecular assemblies to scrutiny at atomic detail. They reveal not only examples of assembly from preformed and prefolded components, but also examples in which the act of assembly drives changes to the components. In the most extreme of these examples, some of the components only achieve a folded state when the complex is formed. Striking results have appeared for systems ranging from the already mature field of virus structure and assembly, where notable progress has been made for rather complex capsids, to descriptions of ribosome structures in atomic detail, where recent results have emerged at breathtaking speed.

Combined EM/X-ray imaging yields a quasi-atomic model of the adenovirus-related bacteriophage PRD1 and shows key capsid and membrane interactions.

BACKGROUND: The dsDNA bacteriophage PRD1 has a membrane inside its icosahedral capsid. While its large size (66 MDa) hinders the study of the complete virion at atomic resolution, a 1.65-A crystallographic structure of its major coat protein, P3, is available. Cryo-electron microscopy (cryo-EM) and three-dimensional reconstruction have shown the capsid at 20-28 A resolution. Striking architectural similarities between PRD1 and the mammalian adenovirus indicate a common ancestor. RESULTS: The P3 atomic structure has been fitted into improved cryo-EM reconstructions for three types of PRD1 particles: the wild-type virion, a packaging mutant without DNA, and a P3-shell lacking the membrane and the vertices. Establishing the absolute EM scale was crucial for an accurate match. The resulting "quasi-atomic" models of the capsid define the residues involved in the major P3 interactions, within the quasi-equivalent interfaces and with the membrane, and show how these are altered upon DNA packaging. CONCLUSIONS: The new cryo-EM reconstructions reveal the structure of the PRD1 vertex and the concentric packing of DNA. The capsid is essentially unchanged upon DNA packaging, with alterations limited to those P3 residues involved in membrane contacts. These are restricted to a few of the N termini along the icosahedral edges in the empty particle; DNA packaging leads to a 4-fold increase in the number of contacts, including almost all copies of the N terminus and the loop between the two beta barrels. Analysis of the P3 residues in each quasi-equivalent interface suggests two sites for minor proteins in the capsid edges, analogous to those in adenovirus.

Structure of the lipid-containing bacteriophage phi 6. Disruption by Triton X-100 treatment.

The structure of the lipid-containing bacteriophage phi 6 was studied by means of controlled Triton X-100 disruption and subsequent isolation of subviral particles. Rate-zonal centrifugation yielded two fractions, a nucleocapsid fraction with RNA, proteins P1, P2, P4, P7, P8, and about half of the protein P5 and a membrane fraction with associated proteins P3, P6, P9, P10, and the rest of the protein P5. Following isopycnic sucrose gradient centrifugation, an empty capsid fraction was obtained which lacked RNA but contained a protein composition similar to the nucleocapsid except for the absence of P5. The membrane fraction isolated after isopycnic centrifugation was morphologically indistinguishable from that isolated after rate-zonal centrifugation but contained only proteins P3, P6, P9 and P10. By treating phi 6 with Triton X-100 prior to isopycnic sucrose gradient centrifugation the viral membrane was further separated into submembrane structures and the attachment protein, P3, could be isolated in rather pure form.

The lytic enzyme of the Pseudomonas phage phi 6. Purification and biochemical characterization.

The lytic enzyme of the lipid-containing bacteriophage phi 6, protein P5, has been purified to apparent homogeneity from disrupted viral particles. The enzyme is a monomer with a molecular mass of approx. 24 kDa. The optimal pH for P5 activity is 8.5 and the protein is readily inactivated at temperatures above 20 degrees C. Protein P5 is active against several Gram-negative bacteria, but no activity against Gram-positive species was detected. Analysis of cell wall digests indicates that P5 is not a glycosidase, but an endopeptidase splitting the peptide bridge formed by meso-diaminopimelic acid and D-alanine.

RNA binding, packaging and polymerase activities of the different incomplete polymerase complex particles of dsRNA bacteriophage phi 6.

phi 6 is an enveloped dsRNA bacterial virus. Its segmented genome resides inside the virion associated polymerase complex which is formed by four proteins (P1, P2, P4 and P7) encoded by the viral L segment. Complete and incomplete polymerase complex particles can be produced using cDNA copies of this largest genome segment. We have analysed the capacity of the different purified particles to (1) package phi 6 (+) sense genomic precursors and unspecific RNA, (2) synthesize (-) and (+) strands and (3) bind phi 6 specific and unspecific RNAs. Both (-) and (+) strand synthesis polymerase activities were found to be associated with protein P2. In addition to complete particles, particles lacking protein P2 were found to package and protect genomic precursor ssRNAs. Protein P7 was needed for efficient packaging. Regulation and specificity of the packaging were found to be independent of P2. Particles composed of proteins P1 and P4 did not package or protect RNA but did bind phi 6 genomic (+) strand RNAs. The three phi 6 (+) strands bound in equal amounts to the particles when tested alone in a filter binding assay. In competition experiments they competed each other for binding, indicating that individual binding sites for the three genomic (+) strands do not exist. Differences in RNA binding competition among the four particles were observed, suggesting that packaging specificity is achieved by complex interactions of proteins and genomic (+) strand RNAs during the advancement of the packaging process after the initial binding events.

Protein P7 of phage phi6 RNA polymerase complex, acquiring of RNA packaging activity by in vitro assembly of the purified protein onto deficient particles.

The RNA polymerase complex of double-stranded RNA bacteriophage phi6 is composed of four proteins, P1, P2, P4 and P7. These four proteins are capable of performing all the functions required for the replication of the double-stranded RNAs of the phi6 genome. The polymerase complex containing the three genomic dsRNA segments is the core particle of the phi6 virion. In this study purified protein P7 was found to form highly asymmetric dimers. Using polyclonal anti-P7 antibody, P7 was shown to be accessible on the surface of the nucleocapsid. Treatment of nucleocapsids with polyclonal anti-P7 antibody released coat protein P8 with ensuing activation of the plus strand RNA synthesis from the resulting core particles. Purified P7 could be assembled onto particles lacking P7 and particles lacking both P2 (RNA polymerase) and P7. In both cases RNA packaging activity was acquired. Assembly of P7 onto deficient particles took place also in the absence of host proteins. Protein P7 is known to be necessary for stable packaging of the three genomic phi6 plus strand RNAs into preformed polymerase complex particles. Additionally, protein P7 seems to be involved in the regulation of plus strand synthesis (i.e. transcription) as a fidelity factor. Particles lacking protein P7 produce anomalous size transcripts. Analysis of the polymerase complex stability revealed that proteins P2, P4 and P7 are independently associated with the major structural protein P1. The number of P7 molecules in one virion was estimated to be 60 and a location at the 5-fold symmetry position is proposed.

In vitro packaging of the single-stranded RNA genomic precursors of the segmented double-stranded RNA bacteriophage phi 6: the three segments modulate each other's packaging efficiency.

Bacteriophage phi 6 is a double-stranded RNA (dsRNA) virus that has a genome composed of three linear dsRNA segments (l, m, s). These are encapsidated into a dodecahedral procapsid particle consisting of proteins P1, P2, P4 and P7. Expression of the cDNA copy of the L segment in Escherichia coli leads to the formation of empty procapsid particles. These particles are able to package the plus-sense single-stranded RNA (ssRNA)s of each genome segment in vitro. We have used this in vitro system for a detailed study of phi 6 RNA packaging. The reaction conditions for RNA packaging were optimized using a RNase protection assay. The RNA packaging reaction is dependent on divalent cations (either Mg2+ or Mn2+) and requires a nucleoside triphosphate (NTP) as an energy source. Any one of the rNTPs, dNTPs or ddNTPs can support the RNA packaging. Purine nucleotides support packaging better than pyrimidine nucleotides, GTP being preferred to ATP. The plus-sense ssRNA of each the three genome segments can be packaged independently into the procapsid. However, when two or three segments are packaged simultaneously, regulatory effects modulating the packaging efficiency can be detected between the segments. The packaging of the s and m segments is more efficient when they are packaged alone, compared to a situation in which they are packaged with the other segments. In contrast, the packaging of the l segment is very inefficient alone, but is enhanced when packaged together with the m segment. We propose that each segment has a preferred high-affinity binding site in the procapsid particle and packaging of the m segment creates the high-affinity binding site for the l segment. If any of the segments is missing from the packaging reaction the other segments can occupy its binding site.

Structure and NTPase activity of the RNA-translocating protein (P4) of bacteriophage phi 6.

The RNA polymerase complex of bacteriophage phi 6 comprises four proteins, P1, P2, P4 and P7, and forms the core of the virion. Protein P4 is a non-specific NTPase that provides the energy required for RNA translocation (packaging). Characterization of purified recombinant P4 shows that the protein assembles into stable hexamers in the presence of ADP and divalent cations. Image averaging of electron micrographs reveals this hexamer as a slightly skewed ring with outer and inner diameters of 12 and 2 nm, respectively. NTPase activity of P4 is associated only with the hexameric form. Ca2+ and Zn2+ and non-specific single-stranded RNA stimulate the NTPase activity, while Mg2+ acts as a non-competitive inhibitor, presumably via a separate Mg2+ binding site. Binding affinities of different nucleotide mono-, di- and triphosphates and non-hydrolyzable analogs indicate that the beta-phosphate moiety is required for substrate binding. A slight preference for binding of purine nucleotides is also observed. Analysis of P4 by CD and Raman spectroscopy indicates an alpha/beta subunit fold that is altered only slightly by hexamer assembly. Raman markers of P4 secondary and tertiary structures are also largely invariant to nucleotide exchange and hydrolysis, suggesting that the mechanisms of RNA translocation involves movement of subunits relative to one another rather than large scale changes in the alpha/beta subunit fold. The stoichiometry of P4 in the mature phi 6 virion is estimated as 120 copies. Because the recombinant P4 hexamers exhibit hydrodynamic and enzymatic properties that are identical to those of P4 oligomers released from native phi 6, we propose that P4 occurs as hexamers in the native viral core particle.

Generation of infectious nucleocapsids by in vitro assembly of the shell protein on to the polymerase complex of the dsRNA bacteriophage phi 6.

A method for the in vitro uncoating of the phi 6 nucleocapsid (NC) was developed. The resulting particle, designated as the NC core, containing the genomic double-stranded (ds) RNA segments and the proteins P1, P2, P4 and P7, was not infectious but had a highly enhanced in vitro transcriptase activity compared to that of the intact NC. The NC shell protein P8 was purified by immunoaffinity chromatography, and it was shown to self-assemble to shell-like structures upon addition of calcium ions. The conditions for the self-assembly of the shell were optimized. Shell reassembly on to the NC cores restored the infectivity but resulted in a decrease of transcriptase activity. No reassembly of the shell on to RNA-less cores (procapsids) produced from a cDNA construction in Escherichia coli was observed. Our results suggest that the intracellular uncoating of the NC is the event activating the phi 6 dsRNA transcriptase and that the NC shell is necessary for infectivity, probably for the passage of the NC through the host cytoplasmic membrane. Packaging of the dsRNA segments into the procapsid appears to be a prerequisite for NC shell assembly.

A minor capsid protein P30 is essential for bacteriophage PRD1 capsid assembly.

Bacteriophage PRD1 is a double-stranded DNA virus infecting Gram-negative hosts. It has a membrane component located in the interior of the isometric capsid. In addition to the major capsid protein P3, the capsid contains a 9 kDa protein P30. Protein P30 is proposed to be located between the adjacent facets of the icosahedral capsid and is required for stable capsid assembly. In its absence, an empty phage-specific membrane vesicle is formed. The major protein component of this vesicle is a phage-encoded assembly factor, protein P10, that is not present in the final structure.

Crystallization of the major coat protein of PRD1, a bacteriophage with an internal membrane.

The major multimeric coat protein, P3, of the bacterial virus PRD1 has been crystallized by vapor diffusion from polyethylene glycol 4000. The PRD1-P3 crystals belong to the orthorhombic space group P2(1)2(1)2(1) with unit cell dimensions a = 121.6 A, b = 123.2 A, c = 128.6 A and diffract to 3.0 A resolution. Density measurements show that there is one trimer (3 x 43.1 kDa) per asymmetric unit and a high solvent content of 67%. A self-rotation function calculation shows a pronounced peak indicating a non-crystallographic threefold axis. This indicates that the major viral capsomer is a trimer and allows the viral T-number to be postulated.

Structure, interactions and dynamics of PRD1 virus II. Organization of the viral membrane and DNA.

Structure, dynamics and stability of the membrane and double-stranded (ds) DNA genome packaged within the native PRD1 virion have been probed by laser Raman spectroscopy. The Raman signature of PRD1 is complex, but exhibits distinctive marker bands diagnostic of the internal lipid bilayer and dsDNA. The Raman markers demonstrate, respectively, a liquid crystalline lipid phase(L(alpha)) and B DNA conformation throughout the temperature range (5 degrees to 50 degrees) of virion stability. Despite the absence of large scale lipid phase transitions or DNA melting, small temperature-dependent changes in the Raman markers of lipid and DNA are detected, indicating coupling between their structures. Minor deviations of DNA from the canonical B form are imposed by the membrane. The Raman markers indicate further that base stacking and phosphate group interactions of the packaged PRD1 genome differ from those of unpackaged PRD1 DNA. Specific Raman band perturbations are proposed as indicators of DNA-membrane interaction. Hydrogen-deuterium exchange kinetics of packaged and unpackaged PRD1 DNA are indistinguishable, demonstrating that base imino and amino protons are not affected significantly by either the condensation or membrane enclosure associated with DNA packaging. This contrasts with the significant acceleration of base exchanges detected in the packaged DNA of bacteriophage P22, which lacks a viral membrane. The distinctive H-->2H exchange profile of the PRD1 genome, the absence of packaging-induced acceleration of exchange kinetics and the apparent direct interaction between DNA and phospholipids suggest a specific role for the viral membrane in PRD1 assembly. We propose a "membrane-surface-catalyzed" model for dsDNA condensation and organization within the PRD1 virion.

Structural studies of the enveloped dsRNA bacteriophage phi 6 of Pseudomonas syringae by Raman spectroscopy. I. The virion and its membrane envelope.

We report and interpret the first Raman spectrum of a double-stranded RNA virus containing a membrane envelope. Spectra of the native bacteriophage phi 6 and of its isolated host-attachment (spike) protein and phospholipid-free core assembly were collected from aqueous solutions over a wide range of temperature. Comparison of the vibrational spectra by digital difference methods permits the following structural conclusions regarding molecular constituents of the fully assembled virion. (1) The double-stranded RNA, phospholipid and protein components of the phage exhibit Raman amplitudes in accordance with their biochemically determined compositions in the native virion (10, 20 and 70%, respectively). (2) alpha-Helix and irregular conformations are the dominant secondary structures in proteins of both the viral membrane and nucleocapsid. This represents a departure from previously examined icosahedral phage and plant viruses, which are dominated by beta-sheet structures. (3) The phospholipids of the viral membrane are liquid crystalline throughout the determined range of virus thermostability (0 to 40 degrees C). (4) The P3 spike protein of phi 6, which is anchored to, but not sequestered within the viral membrane, is largely alpha-helical (approximately 35%) and highly thermolabile. Denaturation of P3 at temperatures above 30 degrees C leads to appreciable loss (approximately 20%) of alpha-helix in favor of beta-strand structure, and alters significantly the environments of many aromatic side-chains. (5) The secondary structures of integral membrane proteins of phi 6 are overwhelmingly alpha-helical (approximately 70 to 80%) and also thermolabile. In contrast to P3, which exhibits aspartate and glutamate carboxyls in the ionized form (CO2-), the integral membrane proteins exhibit only protonated carboxyl groups (COOH). Treatment of phi 6 with butylated hydroxytoluene (BHT), which has been shown to remove the P3 spike protein, does not significantly perturb phospholipids and associated integral proteins of the viral membrane or structural proteins and packaged double-stranded RNA of the nucleocapsid. However, P3 subunits, which are recovered after BHT treatment, exhibit radically altered secondary and tertiary structures, including the loss of most subunit alpha-helices. Among the P3 side-chains affected by BHT treatment, we note a general trend toward greater hydrophilicity and greater solvent exposure of the aromatic residues Trp and Tyr. On the other hand, the cysteine sulfhydryl groups of the BHT-isolated P3 monomer are not solvent exposed and function as strong hydrogen-bond donors in the protein core.(ABSTRACT TRUNCATED AT 400 WORDS)