The nucleocapsid of the lipid-containing double-stranded RNA bacteriophage phi 6 contains a protein skeleton consisting of a single polypeptide species

Structural Studies of Bacteriophage Φ6 and Its Transformations during Its Life Cycle

From the first isolation of the cystovirus bacteriophage Φ6 from Pseudomonas syringae 50 years ago, we have progressed to a better understanding of the structure and transformations of many parts of the virion. The three-layered virion, encapsulating the tripartite double-stranded RNA (dsRNA) genome, breaches the cell envelope upon infection, generates its own transcripts, and coopts the bacterial machinery to produce its proteins. The generation of a new virion starts with a procapsid with a contracted shape, followed by the packaging of single-stranded RNA segments with concurrent expansion of the capsid, and finally replication to reconstitute the dsRNA genome. The outer two layers are then added, and the fully formed virion released by cell lysis. Most of the procapsid structure, composed of the proteins P1, P2, P4, and P7 is now known, as well as its transformations to the mature, packaged nucleocapsid. The outer two layers are less well-studied. One additional study investigated the binding of the host protein YajQ to the infecting nucleocapsid, where it enhances the transcription of the large RNA segment that codes for the capsid proteins. Finally, I relate the structural aspects of bacteriophage Φ6 to those of other dsRNA viruses, noting the similarities and differences.

Diversity and Current Classification of dsRNA Bacteriophages

Half a century has passed since the discovery of Pseudomonas phage phi6, the first enveloped dsRNA bacteriophage to be isolated. It remained the sole known dsRNA phage for a quarter of a century and the only recognised member of the Cystoviridae family until the year 2018. After the initial discovery of phi6, additional dsRNA phages have been isolated from globally distant locations and identified in metatranscriptomic datasets, suggesting that this virus type is more ubiquitous in nature than previously acknowledged. Most identified dsRNA phages infect Pseudomonas strains and utilise either pilus or lipopolysaccharide components of the host as the primary receptor. In addition to the receptor-mediated strictly lytic lifestyle, an alternative persistent infection strategy has been described for some dsRNA phages. To date, complete genome sequences of fourteen dsRNA phage isolates are available. Despite the high sequence diversity, similar sets of genes can typically be found in the genomes of dsRNA phages, suggesting shared evolutionary trajectories. This review provides a brief overview of the recognised members of the Cystoviridae virus family and related dsRNA phage isolates, outlines the current classification of dsRNA phages, and discusses their relationships with eukaryotic RNA viruses.

RNA Packaging in the Cystovirus Bacteriophages: Dynamic Interactions during Capsid Maturation

The bacteriophage family Cystoviridae consists of a single genus, Cystovirus, that is lipid-containing with three double-stranded RNA (ds-RNA) genome segments. With regard to the segmented dsRNA genome, they resemble the family Reoviridae. Therefore, the Cystoviruses have long served as a simple model for reovirus assembly. This review focuses on important developments in the study of the RNA packaging and replication mechanisms, emphasizing the structural conformations and dynamic changes during maturation of the five proteins required for viral RNA synthesis, P1, P2, P4, P7, and P8. Together these proteins constitute the procapsid/polymerase complex (PC) and nucleocapsid (NC) of the Cystoviruses. During viral assembly and RNA packaging, the five proteins must function in a coordinated fashion as the PC and NC undergo expansion with significant position translation. The review emphasizes this facet of the viral assembly process and speculates on areas suggestive of additional research efforts.

Component tree analysis of cystovirus φ6 nucleocapsid Cryo-EM single particle reconstructions

The 3-dimensional structure of the nucleocapsid (NC) of bacteriophage φ6 is described utilizing component tree analysis, a topological and geometric image descriptor. The component trees are derived from density maps of cryo-electron microscopy single particle reconstructions. Analysis determines position and occupancy of structure elements responsible for RNA packaging and transcription. Occupancy of the hexameric nucleotide triphosphorylase (P4) and RNA polymerase (P2) are found to be essentially complete in the NC. The P8 protein lattice likely fixes P4 and P2 in place during maturation. We propose that the viral procapsid (PC) is a dynamic structural intermediate where the P4 and P2 can attach and detach until held in place in mature NCs. During packaging, the PC expands to accommodate the RNA, and P2 translates from its original site near the inner 3-fold axis (20 sites) to the inner 5-fold axis (12 sites) with excess P2 positioned inside the central region of the NC.

Single-molecule measurements of viral ssRNA packaging

Genome packaging of double-stranded RNA (dsRNA) phages has been widely studied using biochemical and molecular biology methods. We adapted the existing in vitro packaging system of one such phage for single-molecule experimentation. To our knowledge, this is the first attempt to study the details of viral RNA packaging using optical tweezers. Pseudomonas phage φ6 is a dsRNA virus with a tripartite genome. Positive-sense (+) single-stranded RNA (ssRNA) genome precursors are packaged into a preformed procapsid (PC), where negative strands are synthesized. We present single-molecule measurements of the viral ssRNA packaging by the φ6 PC. Our data show that packaging proceeds intermittently in slow and fast phases, which likely reflects differences in the unfolding of the RNA secondary structures of the ssRNA being packaged. Although the mean packaging velocity was relatively low (0.07-0.54 nm/sec), packaging could reach 4.62 nm/sec during the fast packaging phase.

The ϕ6 cystovirus protein P7 becomes accessible to antibodies in the transcribing nucleocapsid: a probe for viral structural elements

Protein P7 is a component of the cystovirus viral polymerase complex. In the unpackaged procapsid, the protein is situated in close proximity to the viral directed RNA polymerase, P2. Cryo-electron microscopy difference maps from the species ϕ6 procapsid have demonstrated that P7 and P2 likely interact prior to viral RNA packaging. The location of P7 in the post-packaged nucleocapsid (NC) remains unknown. P7 may translocate closer to the five-fold axis of a filled procapsid but this has not been directly visualized. We propose that monoclonal antibodies (Mabs) can be selected that serve as probe- reagents for viral assembly and structure. A set of Mabs have been isolated that recognize and bind to the ϕ6 P7. The antibody set contains five unique Mabs, four of which recognize a linear epitope and one which recognizes a conformational epitope. The four unique Mabs that recognize a linear epitope display restricted utilization of V_κ and V_H genes. The restricted genetic range among 4 of the 5 antibodies implies that the antibody repertoire is limited. The limitation could be the consequence of a paucity of exposed antigenic sites on the ϕ6 P7 surface. It is further demonstrated that within ϕ6 nucleocapsids that are primed for early-phase transcription, P7 is partially accessible to the Mabs, indicating that the nucleocapsid shell (protein P8) has undergone partial disassembly exposing the protein’s antigenic sites.

New enveloped dsRNA phage from freshwater habitat

Cystoviridae is a family of bacteriophages with a tri-segmented dsRNA genome enclosed in a tri-layered virion structure. Here, we present a new putative member of the Cystoviridae family, bacteriophage ϕNN. ϕNN was isolated from a Finnish lake in contrast to the previously identified cystoviruses, which originate from various legume samples collected in the USA. The nucleotide sequence of the virus reveals a strong genetic similarity (~80 % for the L-segments, ~55 % for the M-segments and ~84 % for the S-segments) to Pseudomonas phage ϕ6, the type member of the virus family. However, the relationship between ϕNN and other cystoviruses is more distant. In general, proteins located in the internal parts of the virion were more conserved than those exposed on the virion surface, a phenomenon previously reported among eukaryotic dsRNA viruses. Structural models of several putative ϕNN proteins propose that cystoviral structures are highly conserved.

Protein P7 of the cystovirus φ6 is located at the three-fold axis of the unexpanded procapsid

The objective of this study was to determine the location of protein P7, the RNA packaging factor, in the procapsid of the φ6 cystovirus. A comparison of cryo-electron microscopy high-resolution single particle reconstructions of the φ6 complete unexpanded procapsid, the protein P2-minus procapsid (P2 is the RNA directed RNA-polymerase), and the P7-minus procapsid, show that prior to RNA packaging the P7 protein is located near the three-fold axis of symmetry. Difference maps highlight the precise position of P7 and demonstrate that in P7-minus particles the P2 proteins are less localized with reduced densities at the three-fold axes. We propose that P7 performs the mechanical function of stabilizing P2 on the inner protein P1 shell which ensures that entering viral single-stranded RNA is replicated.

Stepwise expansion of the bacteriophage ϕ6 procapsid: possible packaging intermediates

The initial assembly product of bacteriophage ϕ6, the procapsid, undergoes major structural transformation during the sequential packaging of its three segments of single-stranded RNA. The procapsid, a compact icosahedrally symmetric particle with deeply recessed vertices, expands to the spherical mature capsid, increasing the volume available to accommodate the genome by 2.5-fold. It has been proposed that expansion and packaging are linked, with each stage in expansion presenting a binding site for a particular RNA segment. To investigate procapsid transformability, we induced expansion by acidification, heating, and elevated salt concentration. Cryo-electron microscopy reconstructions after all three treatments yielded the same partially expanded particle. Analysis by cryo-electron tomography showed that all vertices of a given capsid were either in a compact or an expanded state, indicating a highly cooperative transition. To benchmark the mature capsid, we analyzed filled (in vivo packaged) capsids. When these particles were induced to release their RNA, they reverted to the same intermediate state as expanded procapsids (intermediate 1) or to a second, further expanded state (intermediate 2). This partial reversibility of expansion suggests that the mature spherical capsid conformation is obtained only when sufficient outward pressure is exerted by packaged RNA. The observation of two intermediates is consistent with the proposed three-step packaging process. The model is further supported by the observation that a mutant capable of packaging the second RNA segment without previously packaging the first segment has enhanced susceptibility for switching spontaneously from the procapsid to the first intermediate state.

Initial location of the RNA-dependent RNA polymerase in the bacteriophage Phi6 procapsid determined by cryo-electron microscopy

The RNA-dependent RNA polymerases (RdRPs) of Cystoviridae bacteriophages, like those of eukaryotic viruses of the Reoviridae, function inside the inner capsid shell in both replication and transcription. In bacteriophage Phi6, this inner shell is first assembled as an icosahedral procapsid with recessed 5-fold vertices that subsequently undergoes major structural changes during maturation. The tripartite genome is packaged as single-stranded RNA molecules via channels on the 5-fold vertices, and transcripts probably exit the mature capsid by the same route. The RdRP (protein P2) is assembled within the procapsid, and it was thought that it should be located on the 5-fold axes near the RNA entry and exit channels. To determine the initial location of the RdRP inside the procapsid of bacteriophage Phi6, we performed cryo-electron microscopy of wild type and mutant procapsids and complemented these data with biochemical determinations of copy numbers. We observe ring-like densities on the 3-fold axes that are strong in a mutant that has approximately 10 copies of P2 per particle; faint in wild type, reflecting the lower copy number of approximately 3; and completely absent in a P2-null mutant. The dimensions and shapes of these densities match those of the known crystal structure of the P2 monomer. We propose that, during maturation, the P2 molecules rotate to occupy positions closer to adjacent 5-fold vertices where they conduct replication and transcription.

Self-assembly of double-stranded RNA bacteriophages

Double-stranded RNA viruses infecting bacterial hosts belong to the Cystoviridae family. Bacteriophage phi6 is one of the best characterized dsRNA viruses and shares structural as well as functional similarities with other well-studied eukaryotic dsRNA viruses (e.g. L-A, rotavirus, bluetongue virus, and reovirus). The assembly pathway of the enveloped, triple-layered phi6 virion has been well documented and can be divided into four distinct steps which are (1) procapsid formation, (2) genome encapsidation and replication, (3) nucleocapsid surface shell assembly, and (4) envelope formation. In this review, we focus primarily on the procapsid and nucleocapsid assembly for which in vitro systems have been established. The in vitro assembly systems have been instrumental in revealing assembly intermediates and conformational changes that are common to phi6 and phi8, two cystoviruses with negligible sequence homology. Two viral enzymes, the packaging NTPase (P4) and the RNA-dependent RNA polymerase (P2), were found essential for the nucleation step. The nucleation complex contains one or more tetramers of the major procapsid protein (P1) and is further stabilized by protein P4. Interaction of P1 and P4 during assembly is accompanied by an additional folding of their respective polypeptide chains. The in vitro assembled procapsids were shown to selectively package and replicate the genomic ssRNA. Furthermore, in vitro assembly of infectious nucleocapsids has been achieved in the case of phi6. The in vitro studies indicate that the nucleocapsid coat protein (P8) assembles around the polymerase complex in a template-assisted manner. Implications for the assembly of other dsRNA viruses are also presented.

Nonspecific nucleoside triphosphatase P4 of double-stranded RNA bacteriophage phi6 is required for single-stranded RNA packaging and transcription

Bacteriophage phi6 has a segmented double-stranded RNA genome. The genomic single-stranded RNA (ssRNA) precursors are packaged into a preformed protein capsid, the polymerase complex, composed of viral proteins P1, P2, P4, and P7. Packaging of the genomic precursors is an energy-dependent process requiring nucleoside triphosphates. Protein P4, a nonspecific nucleoside triphosphatase, has previously been suggested to be the prime candidate for the viral packaging engine, based on its location at the vertices of the viral capsid and its biochemical characteristics. In this study we were able to obtain stable polymerase complex particles that are completely devoid of P4. Such particles were not able to package ssRNA segments and did not display RNA polymerase (either minus- or plus-strand synthesis) activity. Surprisingly, a mutation in P4, S250Q, which reduced the level of P4 in the particles to about 10% of the wild-type level, did not affect RNA packaging activity or change the kinetics of packaging. Moreover, such particles displayed minus-strand synthesis activity. However, no plus-strand synthesis was observed, suggesting that P4 has a role in the plus-strand synthesis reaction also.

Self-assembly of a viral molecular machine from purified protein and RNA constituents

We present the assembly of the polymerase complex (procapsid) of a dsRNA virus from purified recombinant proteins. This molecular machine packages and replicates viral ssRNA genomic precursors in vitro. After addition of an external protein shell, these in vitro self-assembled viral core particles can penetrate the host plasma membrane and initiate a productive infection. Thus, a viral procapsid has been assembled and rendered infectious using purified components. Using this system, we have studied the mechanism of assembly of the common dsRNA virus shell and the incorporation of a symmetry mismatch within an icosahedral capsid. Our work demonstrates that this molecular machine, self-assembled under defined conditions in vitro, can function in its natural environment, the cell cytoplasm.

RNA secondary structures of the bacteriophage phi6 packaging regions

Bacteriophage phi6 genome consists of three segments of double-stranded RNA. During maturation, single-stranded copies of these segments are packaged into preformed polymerase complex particles. Only phi6 RNA is packaged, and each particle contains only one copy of each segment. An in vitro packaging and replication assay has been developed for phi6, and the packaging signals (pac sites) have been mapped to the 5' ends of the RNA segments. In this study, we propose secondary structure models for the pac sites of phi6 single-stranded RNA segments. Our models accommodate data from structure-specific chemical modifications, free energy minimizations, and phylogenetic comparisons. Previously reported pac site deletion studies are also discussed. Each pac site possesses a unique architecture, that, however, contains common structural elements.

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.

Packaging and replication regulation revealed by chimeric genome segments of double-stranded RNA bacteriophage phi6

Bacteriophage phi6 has a double-stranded RNA genome composed of three linear segments, L, M, and S. The innermost particle in the virion of phi6, like in the other dsRNA viruses, is an RNA-dependent RNA polymerase complex, which carries out all the functions needed for the replication of the viral genome. Empty polymerase complexes can package the single-stranded copies of the viral genome segments, replicate the packaged segments into double-stranded form (minus strand synthesis), and then produce new plus strands (transcripts) from the double-stranded RNA templates. The three viral genomic segments contain unique packaging signals at their 5' ends, and minus strand synthesis initiation is dependent on the sequence at the 3' end. Here we have constructed chimeric segments that have the packaging signal from one segment and the minus strand synthesis initiation signal from another segment. Using purified recombinant polymerase complexes and single-stranded/chimeric and original RNA segments, we have analyzed the packaging and replication regulation operating in in vitro conditions. We show that the 5' end of the L genome segment in single-stranded form is needed to switch from the packaging to the minus strand synthesis and the same sequence is required in double-stranded form to switch on plus strand synthesis. In addition we have constructed deletions to the M segment to analyze the possible regulatory role of the internal noncoding area of this segment.

Precise packaging of the three genomic segments of the double-stranded-RNA bacteriophage phi6

Bacteriophage phi6 has a genome of three segments of double-stranded RNA. Each virus particle contains one each of the three segments. Packaging is effected by the acquisition, in a serially dependent manner, of the plus strands of the genomic segments into empty procapsids. The empty procapsids are compressed in shape and expand during packaging. The packaging program involves discrete steps that are determined by the amount of RNA inside the procapsid. The steps involve the exposure and concealment of binding sites on the outer surface of the procapsid for the plus strands of the three genomic segments. The plus strand of segment S can be packaged alone, while packaging of the plus strand of segment M depends upon prior packaging of S. Packaging of the plus strand of L depends upon the prior packaging of M. Minus-strand synthesis begins when the particle has a full complement of plus strands. Plus-strand synthesis commences upon the completion of minus-strand synthesis. All of the reactions of packaging, minus-strand synthesis, and plus-strand synthesis can be accomplished in vitro with isolated procapsids. Live-virus constructions that are in accord with the model have been prepared. Mutant virus with changes in the packaging program have been isolated and analyzed.

Mutational analysis of the role of nucleoside triphosphatase P4 in the assembly of the RNA polymerase complex of bacteriophage phi6

Bacteriophage phi6 is a complex enveloped double-stranded RNA virus with a segmented genome and replication strategy quite similar to that of the Reoviridae. An in vitro packaging and replication system using purified components is available. The positive-polarity genomic segments are translocated into a preformed polymerase complex (procapsid) particle. This particle is composed of four proteins: the shell-forming protein P1, the RNA polymerase P2, and two proteins active in packaging. Protein P7 is involved in stable packaging, and protein P4 is a homomultimeric potent nucleoside triphosphatase that provides the energy for the RNA translocation event. In this investigation, we used mutational analysis to study P4 multimerization and assembly. P4 is assembled onto a preformed particle containing proteins P2 and P7 in addition to P1. Only simultaneous production of P1 and P4 in the same cell leads to P4 assembly on P1 alone, whereas the P1 shell is incompetent for accepting P4 if produced separately. The C-terminal part of P4 is essential for particle assembly but not for multimerization or enzymatic activity. Altering the P4 nucleoside triphosphate binding site destroys the ability to form multimers.

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.

Intermediates in the assembly pathway of the double-stranded RNA virus phi6

The double-stranded RNA bacteriophage phi6 contains a nucleocapsid enclosed by a lipid envelope. The nucleocapsid has an outer layer of protein P8 and a core consisting of the four proteins P1, P2, P4 and P7. These four proteins form the polyhedral structure which acts as the RNA packaging and polymerase complex. Simultaneous expression of these four proteins in Escherichia coli gives rise to procapsids that can carry out the entire RNA replication cycle. Icosahedral image reconstruction from cryo-electron micrographs was used to determine the three-dimensional structures of the virion-isolated nucleocapsid and core, and of several procapsid-related particles expressed and assembled in E. coli. The nucleocapsid has a T = 13 surface lattice, composed primarily of P8. The core is a rounded structure with turrets projecting from the 5-fold vertices, while the procapsid is smaller than the core and more dodecahedral. The differences between the core and the procapsid suggest that maturation involves extensive structural rearrangements producing expansion. These rearrangements are co-ordinated with the packaging and RNA polymerization reactions that result in virus assembly. This structural characterization of the phi6 assembly intermediates reveals the ordered progression of obligate stages leading to virion assembly along with striking similarities to the corresponding Reoviridae structures.

Double-stranded RNA bacteriophage phi 6 protein P4 is an unspecific nucleoside triphosphatase activated by calcium ions

Double-stranded RNA bacteriophage phi 6 has an envelope surrounding the nucleocapsid (NC). The NC is composed of a surface protein, P8, and proteins P1, P2, P4, and P7, which form a dodecahedral polymerase complex enclosing the segmented viral genome. Empty polymerase complex particles (procapsids) package positive-sense viral single-stranded RNAs provided that energy is available in the form of nucleoside triphosphates (NTPs). Photoaffinity labelling of both the NC and the procapsid has earlier been used to show that ATP binds to protein P4 and that the NC hydrolyzes NTPs. Using the NC and the NC core particles (NCs lacking surface protein P8) and purified protein P4, we demonstrate here that multimeric P4 is the active NTPase. Isolation of multimeric P4 is successful only in the presence of NTPs. The activity of P4 is the same in association with the viral particles as it is in pure form. P4 is an unspecific NTPase hydrolyzing ribo-NTPs, deoxy NTPs, and dideoxy NTPs to the corresponding nucleoside diphosphates. The Km of the reaction for ATP, GTP, and UTP is around 0.2 to 0.3 mM. The NTP hydrolysis by P4 absolutely requires residual amounts of Mg2+ ions and is greatly activated when the Ca2+ concentration reaches 0.5 mM. Competition experiments indicate that Mg2+ and Ca2+ ions have approximately equal binding affinities for P4. They might compete for a common binding site. The nucleotide specificity and enzymatic properties of the P4 NTPase are similar to the NTP hydrolysis reaction conditions needed to translocate and condense the viral positive-sense RNAs to the procapsid particle.

The large genome segment of dsRNA bacteriophage phi6 is the key regulator in the in vitro minus and plus strand synthesis

Bacteriophage phi6 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. Empty preformed procapsids are able to package the plus-sense single-stranded RNA (ssRNA) of each genome segment, to synthesize the corresponding minus strands ("replication") to form dsRNA segments, and to continue to the plus strand synthesis ("transcription") in which the dsRNA segments are used as templates in production of plus-sense ssRNA. In this study, we have investigated the requirements for the switch-on of minus and plus strand syntheses. We show that there exists an inverse relationship between regulation of the ssRNA packaging and minus strand synthesis. The packaging of single-stranded l, which has previously been shown to be packaged as the last, is the necessary signal for the onset of the minus strand synthesis. The absolute requirement for plus strand synthesis is minus strand synthesis of l, but in addition, the minus strand synthesis of m and the packaging of s segment are needed for efficient plus strand synthesis. Furthermore, the second nucleotide at the 5'-end of each segment regulates the extent of the transcription.

Protein P4 of double-stranded RNA bacteriophage phi 6 is accessible on the nucleocapsid surface: epitope mapping and orientation of the protein

Protein P4, an early protein of double-stranded RNA bacteriophage phi 6, is a component of the virion-associated RNA polymerase complex and possesses a nucleoside triphosphate (NTP) phosphohydrolase activity. We have produced and characterized a panel of 20 P4-specific monoclonal antibodies. Epitope mapping using truncated molecules of recombinant P4 revealed seven linear epitopes. The accessibility of the epitopes on the phi 6 nucleocapsid (NC) surface showed that at least the C terminus and an internal domain, containing the consensus sequence for NTP binding, protrude the NC shell. Four of the NC-binding antibodies distorted the integrity of the NC by releasing protein P4 and the major NC surface protein P8. This finding suggests a close contact between these two proteins. The dissociation of the NC led to the activation of the virion-associated RNA polymerase. The multimeric status of the recombinant P4 was similar to that of the virion-associated P4, indicating that no accessory virus proteins are needed for its multimerization.

Bacteriophage phi 6 envelope elucidated by chemical cross-linking, immunodetection, and cryoelectron microscopy

Bacteriophage phi 6 is an enveloped dsRNA virus which infects the plant pathogenic Pseudomonas syringae bacterium. Using low dose cryoelectron microscopy we show that the nucleocapsid, spikeless virion, and intact virion have radii of 29, 35, and 43 nm, respectively. Thus, the membrane is 6 nm thick and the surface spikes of the receptor binding protein P3 extend 8 nm from the membrane surface. Cross-linking, immunological, and complementation evidence suggest that the spikes are formed of multimeric P3 molecules and that P3 is associated with membrane-bound protein P6. We observe that the envelope can accommodate up to 400 molecules of P3 but that the average virion contains less than one-fourth of this amount. Assembly of a very small number of P3 or truncated P3 molecules onto inactive virions restores infectivity, showing that only a few spikes are necessary for receptor binding and membrane fusion.

Bacteriophage structure

The purpose of this review is to provide information of the role played by electron microscopy in respect of bacteriophage structure. This 40 years' "love story" between phages and microscopy was a valuable contribution to the progress of scientific knowledge in molecular biology. In spite of the rather drastic treatment required for electron microscopical analysis, it was possible to reveal the molecular organization and morphogenic pathway of many of the bacteriophages cited in this paper.

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.

In vitro assembly of infectious nucleocapsids of bacteriophage phi 6: formation of a recombinant double-stranded RNA virus

A system is described for assembling infectious bacteriophage phi 6 nucleocapsids in vitro. Procapsids encoded by cDNA copies of genomic segment L in Escherichia coli were used to package and replicate viral RNA segments. The resulting filled particles were shown to be capable of infecting host cell spheroplasts after incubation with purified nucleocapsid shell protein P8. The infected spheroplasts yielded infectious virions. A modified cDNA-derived RNA segment was inserted into virions by this method. The resulting infectious virions contained the same 4-base-pair deletion as the modified cDNA. These findings support the contention that the preformed procapsids are the "machine" that replicates the phi 6 genome, by showing that the cDNA-derived procapsids are competent to package and replicate RNA properly.

Purified phi 6 nucleocapsids are capable of productive infection of host cells with partially disrupted outer membranes

Purified nucleocapsids of bacteriophage phi 6, lacking the phage lipid envelope, are unable to infect intact Pseudomonas syringae host cells. A method for studying the process by which a naked virus particle, the phi 6 nucleocapsid, penetrates the host cytoplasmic membrane was developed. Host cells were rendered competent for nucleocapsid infection by treatment with repeated washings with salt and sucrose and the subsequent addition of lysozyme. This treatment disrupts the outer membrane, permitting the nucleocapsid to reach the cytoplasmic membrane and to infect the cell. The nucleocapsid infection is blocked by monoclonal antibodies raised against the nucleocapsid shell protein P8.

Quantitation of the adsorption and penetration stages of bacteriophage phi 6 infection

The enveloped dsRNA bacteriophage phi 6 uses the pilus of Pseudomonas syringae as its receptor. It enters the host cell by fusion of the virus envelope with the host outer membrane, followed by penetration of the cytoplasmic membrane by the phage nucleocapsid. In this investigation we quantitated the adsorption and penetration of phi 6wt and a host range mutant, phi 6h 1s, to five bacterial strains. Adsorption rate constants were measured for the different phage-host combinations, the constant for phi 6wt with the standard host was 3.3 X 10(10) ml/min. Infections with 14C-labeled phage at different phage/cell ratios were used to measure the numbers of adsorbing and entering virions/sensitive cell. At high phage/cell ratios (200-250) the standard host adsorbed on the average 35-40 wild-type virions/cell, the saturation level being somewhat higher. It was shown that at phage/host cell ratios of 0.1-1 practically every virion produces an infectious center. The average number of entering phage particles per infectious center reached saturation around the phage/cell ratio of 50 and did not exceed 3 for the standard host. The phi 6 preparations used in this study had a specific infectivity of 0.7-0.9.

In vitro assembly of the outer shell of bacteriophage phi 6 nucleocapsid

Following dissociation of bacteriophage phi 6 nucleocapsid (NC) by EDTA, a particle composed of protein P8 and corresponding to the outer shell of the NC was assembled in vitro in the presence of Ca2+ and Mg2+. Assembly was obtained from soluble protein constituents above 100 micrograms/ml and was optimal within a temperature range of 22-30 degrees. Assembly did not require the presence of genomic RNA. Crosslinking results of intact NCs and in vitro-assembled outer shells suggested that protein P8 dimers are the structural subunits of the shell. Analysis of the assembly kinetics by electron microscopy suggested that ring-like particles of uniform size, packed in flat hexagonal arrays, are intermediates in outer shell assembly.

Chemical crosslinking of bacteriophage phi 6 nucleocapsid proteins

phi 6 is a lipid-containing dsRNA bacteriophage of Pseudomonas syringae. Its nucleocapsid (NC) has common features with Reoviridae core particles. We report here the crosslinking of phi 6 NC proteins with cleavable 12-A span chemical crosslinker, dithiobis(succinimidyl propionate). The crosslinked complexes were analyzed in two-dimensional polyacrylamide gels or by using monoclonal antibodies to uncleaved protein complexes in one-dimensional protein gels. The NC surface protein (P8) forms a series of multimeric homopolymers. The phi 6 lytic enzyme, protein P5, is associated with P8 on the NC surface. The interior NC proteins P1 and P4, associated with the virus polymerase activity, are also in contact with the P8 shell. A P1 + P4 complex is also formed. Only one of the NC proteins (P7) did not easily form complexes with the other NC proteins. These results indicate a very closely packed P8 surface lattice with specific contacts to the internal NC proteins.

Monoclonal antibodies to the major structural proteins of bacteriophage phi 6

A panel of 38 monoclonal antibodies to the five major structural proteins of phi 6 was generated and characterized. The panel includes antibodies recognizing the receptor recognition protein P3, the major hydrophobic envelope protein P9, the nucleocapsid surface protein P8, and the nucleocapsid proteins P1 and P4, which are involved in the viral RNA polymerase activity and form the internal protein skeleton of the nucleocapsid. Six out of the fourteen antibodies to the receptor recognition protein, P3, showed neutralizing activity, interfering with the adsorption of phi 6 to host cells.

Nucleotide sequence of the large double-stranded RNA segment of bacteriophage phi 6: genes specifying the viral replicase and transcriptase

The genome of the lipid-containing bacteriophage phi 6 contains three segments of double-stranded RNA. We determined the nucleotide sequence of cDNA derived from the largest RNA segment (L). This segment specifies the procapsid proteins necessary for transcription and replication of the phi 6 genome. The coding sequences of the four proteins on this segment were identified on the basis of size and the correlation of predicted N-terminal amino acid sequences with those found through analysis of isolated proteins. This report completes the sequence analysis of phi 6. This constitutes the first complete sequence of a double-stranded RNA genome virus.

Production of a polyhedral particle in Escherichia coli from a cDNA copy of the large genomic segment of bacteriophage phi 6

A polyhedral particle that resembles in composition and structure the procapsid of bacteriophage phi 6 was produced in Escherichia coli containing cDNA copies of the entire large genomic segment inserted into expression vector plasmids under the control of lac or tac promoters. The particles were composed of proteins P1, P2, P4, and P7 in the same stoichiometry as in the intact virion. In electron micrographs of negatively stained samples, the particles appeared as hexagons, stars, or rings of 10 knobs, which are characteristic of the five-, three-, and twofold axes of symmetry characteristic of phi 6 procapsids. Stable particles were also produced from cDNA deletions that produce only P1 and P4. Other cDNA deletions producing P1 and P7 and P1 alone resulted in unstable particles which could only be visualized in electron micrographs of thin sections of E. coli transformed by the recombinant plasmids. Our results indicate that the assembly of the phi procapsid is independent of other phage proteins and of normal phage RNA.

The dodecahedral framework of the bacteriophage phi 6 nucleocapsid is composed of protein P1

The outer layer of the bacteriophage phi 6 nucleocapsid (NC) was removed by EDTA and reassociated with the core in the presence of Ca2+ or Mg2+. The core was relatively inaccessible to trypsin digestion, was composed of protein P1, and was in the dodecahedral framework reported previously. (H.T. Steely, Jr., and D. Lang, J. Virol. 51:479-483, 1984; Y. Yang and D. Lang, J. Virol. 51:484-488, 1984). The double-stranded RNA genome became RNase sensitive after EDTA treatment of the nucleocapsid.