Semiconservative synthesis of single-stranded RNA by bacteriophage phi 6 RNA polymerase

Discovery and Classification of the φ6 Bacteriophage: An Historical Review

The year 2023 marks the fiftieth anniversary of the discovery of the bacteriophage φ6. The review provides a look back on the initial discovery and classification of the lipid-containing and segmented double-stranded RNA (dsRNA) genome-containing bacteriophage-the first identified cystovirus. The historical discussion describes, for the most part, the first 10 years of the research employing contemporary mutation techniques, biochemical, and structural analysis to describe the basic outline of the virus replication mechanisms and structure. The physical nature of φ6 was initially controversial as it was the first bacteriophage found that contained segmented dsRNA, resulting in a series of early publications that defined the unusual genomic quality. The technology and methods utilized in the initial research (crude by current standards) meant that the first studies were quite time-consuming, hence the lengthy period covered by this review. Yet when the data were accepted, the relationship to the reoviruses was apparent, launching great interest in cystoviruses, research that continues to this day.

Structure Unveils Relationships between RNA Virus Polymerases

RNA viruses are the fastest evolving known biological entities. Consequently, the sequence similarity between homologous viral proteins disappears quickly, limiting the usability of traditional sequence-based phylogenetic methods in the reconstruction of relationships and evolutionary history among RNA viruses. Protein structures, however, typically evolve more slowly than sequences, and structural similarity can still be evident, when no sequence similarity can be detected. Here, we used an automated structural comparison method, homologous structure finder, for comprehensive comparisons of viral RNA-dependent RNA polymerases (RdRps). We identified a common structural core of 231 residues for all the structurally characterized viral RdRps, covering segmented and non-segmented negative-sense, positive-sense, and double-stranded RNA viruses infecting both prokaryotic and eukaryotic hosts. The grouping and branching of the viral RdRps in the structure-based phylogenetic tree follow their functional differentiation. The RdRps using protein primer, RNA primer, or self-priming mechanisms have evolved independently of each other, and the RdRps cluster into two large branches based on the used transcription mechanism. The structure-based distance tree presented here follows the recently established RdRp-based RNA virus classification at genus, subfamily, family, order, class and subphylum ranks. However, the topology of our phylogenetic tree suggests an alternative phylum level organization.

Controlled Disassembly and Purification of Functional Viral Subassemblies Using Asymmetrical Flow Field-Flow Fractionation (AF4)

Viruses protect their genomes by enclosing them into protein capsids that sometimes contain lipid bilayers that either reside above or below the protein layer. Controlled dissociation of virions provides important information on virion composition, interactions, and stoichiometry of virion components, as well as their possible role in virus life cycles. Dissociation of viruses can be achieved by using various chemicals, enzymatic treatments, and incubation conditions. Asymmetrical flow field-flow fractionation (AF4) is a gentle method where the separation is based on size. Here, we applied AF4 for controlled dissociation of enveloped bacteriophage φ6. Our results indicate that AF4 can be used to assay the efficiency of the dissociation process and to purify functional subviral particles.

Dual Role of a Viral Polymerase in Viral Genome Replication and Particle Self-Assembly

Double-stranded RNA viruses infect a wide spectrum of hosts, including animals, plants, fungi, and bacteria. Yet genome replication mechanisms of these viruses are conserved. During the infection cycle, a proteinaceous capsid, the polymerase complex, is formed. An essential component of this capsid is the viral RNA polymerase that replicates and transcribes the enclosed viral genome. The polymerase complex structure is well characterized for many double-stranded RNA viruses. However, much less is known about the hierarchical molecular interactions that take place in building up such complexes. Using the bacteriophage Φ6 self-assembly system, we obtained novel insights into the processes that mediate polymerase subunit incorporation into the polymerase complex for generation of functional structures. The results presented pave the way for the exploitation and engineering of viral self-assembly processes for biomedical and synthetic biology applications. An understanding of viral assembly processes at the molecular level may also facilitate the development of antivirals that target viral capsid assembly.

Double-stranded RNA (dsRNA) viruses package several RNA-dependent RNA polymerases (RdRp) together with their dsRNA genome into an icosahedral protein capsid known as the polymerase complex. This structure is highly conserved among dsRNA viruses but is not found in any other virus group. RdRp subunits typically interact directly with the main capsid proteins, close to the 5-fold symmetric axes, and perform viral genome replication and transcription within the icosahedral protein shell. In this study, we utilized Pseudomonas phage Φ6, a well-established virus self-assembly model, to probe the potential roles of the RdRp in dsRNA virus assembly. We demonstrated that Φ6 RdRp accelerates the polymerase complex self-assembly process and contributes to its conformational stability and integrity. We highlight the role of specific amino acid residues on the surface of the RdRp in its incorporation during the self-assembly reaction. Substitutions of these residues reduce RdRp incorporation into the polymerase complex during the self-assembly reaction. Furthermore, we determined that the overall transcription efficiency of the Φ6 polymerase complex increased when the number of RdRp subunits exceeded the number of genome segments. These results suggest a mechanism for RdRp recruitment in the polymerase complex and highlight its novel role in virion assembly, in addition to the canonical RNA transcription and replication functions.

Diphosphates at the 5' end of the positive strand of yeast L-A double-stranded RNA virus as a molecular self-identity tag

The 5'end of RNA conveys important information on self-identity. In mammalian cells, double-stranded RNA (dsRNA) with 5'di- or triphosphates generated during virus infection is recognized as foreign and elicits the host innate immune response. Here, we analyze the 5' ends of the dsRNA genome of the yeast L-A virus. The positive strand has largely diphosphates with a minor amount of triphosphates, while the negative strand has only diphosphates. Although the virus can produce capped transcripts by cap snatching, neither strand carried a cap structure, suggesting that only non-capped transcripts serve as genomic RNA for encapsidation. We also found that the 5' diphosphates of the positive but not the negative strand within the dsRNA genome are crucial for transcription in vitro. Furthermore, the presence of a cap structure in the dsRNA abrogated its template activity. Given that the 5' diphosphates of the transcripts are also essential for cap acquisition and that host cytosolic RNAs (mRNA, rRNA, and tRNA) are uniformly devoid of 5' pp-structures, the L-A virus takes advantage of its 5' terminal diphosphates, using them as a self-identity tag to propagate in the host cytoplasm.

Initiation of RNA Polymerization and Polymerase Encapsidation by a Small dsRNA Virus

During the replication cycle of double-stranded (ds) RNA viruses, the viral RNA-dependent RNA polymerase (RdRP) replicates and transcribes the viral genome from within the viral capsid. How the RdRP molecules are packaged within the virion and how they function within the confines of an intact capsid are intriguing questions with answers that most likely vary across the different dsRNA virus families. In this study, we have determined a 2.4 Å resolution structure of an RdRP from the human picobirnavirus (hPBV). In addition to the conserved polymerase fold, the hPBV RdRP possesses a highly flexible 24 amino acid loop structure located near the C-terminus of the protein that is inserted into its active site. In vitro RNA polymerization assays and site-directed mutagenesis showed that: (1) the hPBV RdRP is fully active using both ssRNA and dsRNA templates; (2) the insertion loop likely functions as an assembly platform for the priming nucleotide to allow de novo initiation; (3) RNA transcription by the hPBV RdRP proceeds in a semi-conservative manner; and (4) the preference of virus-specific RNA during transcription is dictated by the lower melting temperature associated with the terminal sequences. Co-expression of the hPBV RdRP and the capsid protein (CP) indicated that, under the conditions used, the RdRP could not be incorporated into the recombinant capsids in the absence of the viral genome. Additionally, the hPBV RdRP exhibited higher affinity towards the conserved 5'-terminal sequence of the viral RNA, suggesting that the RdRP molecules may be encapsidated through their specific binding to the viral RNAs during assembly.

Rescue of maturation off-pathway products in the assembly of Pseudomonas phage φ 6

Many complex viruses use an assembly pathway in which their genome is packaged into an empty procapsid which subsequently matures into its final expanded form. We utilized Pseudomonas phage 6, a well-established virus assembly model, to probe the plasticity of the procapsid maturation pathway. The 6 packaging nucleoside triphosphatase (NTPase), which powers sequential translocation of the three viral genomic single-stranded RNA molecules to the procapsid during capsid maturation, is part of the mature 6 virion but may spontaneously be dissociated from the procapsid shell. We demonstrate that the dissociation of NTPase subunits results in premature capsid expansion, which is detected as a change in the sedimentation velocity and as defects in RNA packaging and transcription activity. However, this dead-end conformation of the procapsids was rescued by the addition of purified NTPase hexamers, which efficiently associated on the NTPase-deficient particles and subsequently drove their contraction to the compact naive conformation. The resulting particles regained their biological and enzymatic activities, directing them into a productive maturation pathway. These observations imply that the maturation pathways of complex viruses may contain reversible steps that allow the rescue of the off-pathway conformation in an overall unidirectional virion assembly pathway. Furthermore, we provide direct experimental evidence that particles which have different physical properties (distinct sedimentation velocities and conformations) display different stages of the genome packaging program and show that the transcriptional activity of the 6 procapsids correlates with the number of associated NTPase subunits.

Effects of viscogens on RNA transcription inside reovirus particles

The dsRNA genome of mammalian reovirus (MRV), like the dsDNA genomes of herpesviruses and many bacteriophages, is packed inside its icosahedral capsid in liquid-crystalline form, with concentrations near or more than 400 mg/ml. Viscosity in such environments must be high, but the relevance of viscosity for the macromolecular processes occurring there remains poorly characterized. Here, we describe the use of simple viscogens, glycerol and sucrose, to examine their effects on RNA transcription inside MRV core particles. Transcription inside MRV cores was strongly inhibited by these agents and to a greater extent than either predicted by theory or exhibited by a nonencapsidated transcriptase, suggesting that RNA transcription inside MRV cores is unusually sensitive to viscogen effects. The elongation phase of transcription was found to be a primary target of this inhibition. Similar results were obtained with particles of a second dsRNA virus, rhesus rotavirus, from a divergent taxonomic subfamily. Polymeric viscogens such as polyethylene glycol also inhibited RNA transcription inside MRV cores, but in a size-limited manner, suggesting that diffusion through channels in the MRV core is required for their activity. Modeling of the data suggested that the inherent intracapsid viscosity of both reo- and rotavirus is indeed high, two to three times the viscosity of water. The capacity for quantitative comparisons of intracapsid viscosity and effects of viscogens on macromolecular processes in confined spaces should be similarly informative in other systems.

Packaging, replication and recombination of the segmented genome of bacteriophage Phi6 and its relatives

The genomes of bacteriophage Phi6 and its relatives are packaged through a mechanism that involves the recognition and translocation of the three different plus strand transcripts of the segmented dsRNA genomes into preformed polyhedral structures called procapsids or inner cores. The packaging requires hydrolysis of NTPs and takes place in the order S:M:L. Minus strand synthesis begins after the completion of the plus strand packaging. The packaging and replication reactions can be studied in vitro with purified components. A model has been presented that proposes that the program of serially dependent packaging is determined by the conformational changes at the surface of the procapsid due to the amount of RNA packaged at each step. The in vitro packaging and replication system has facilitated the application of reverse genetics and the study of recombination in the family of Cystoviridae.

A structural and primary sequence comparison of the viral RNA-dependent RNA polymerases

A systematic bioinformatic approach to identifying the evolutionarily conserved regions of proteins has verified the universality of a newly described conserved motif in RNA-dependent RNA polymerases (motif F). In combination with structural comparisons, this approach has defined two regions that may be involved in unwinding double-stranded RNA (dsRNA) for transcription. One of these is the N-terminal portion of motif F and the second is a large insertion in motif F present in the RNA-dependent RNA polymerases of some dsRNA viruses.

The polymerase subunit of a dsRNA virus plays a central role in the regulation of viral RNA metabolism

Bacteriophage φ6 has a three-segmented double-stranded (ds) RNA genome, which resides inside a polymerase complex particle throughout the entire life cycle of the virus. The polymerase subunit P2, a minor constituent of the polymerase complex, has previously been reported to replicate both φ6-specific and heterologous single-stranded (ss) RNAs, giving rise to dsRNA products. In this study, we show that the enzyme is also able to use dsRNA templates to perform semi-conservative RNA transcription in vitro without the assistance of other proteins. The polymerase synthesizes predominantly plus-sense copies of φ6 dsRNA, medium and small segments being more efficient templates than the large one. This distribution of the test-tube reaction products faithfully mimics viral transcription in vivo. Experiments with chimeric ssRNAs and dsRNAs show that short terminal nucleotide sequences can account for the difference in efficiency of RNA synthesis. Taken together, these results suggest a model explaining important aspects of viral RNA metabolism regulation in terms of enzymatic properties of the polymerase subunit.

Mechanism of genome transcription in segmented dsRNA viruses

Genome transcription is a critical stage in the life cycle of a virus, as this is the process by which the viral genetic information is presented to the host cell protein synthesis machinery for the production of the viral proteins needed for genome replication and progeny virion assembly. Viruses with dsRNA genomes face a particular challenge in that host cells do not produce proteins which can transcribe from a dsRNA template. Therefore, dsRNA viruses contain all of the necessary enzymatic machinery to synthesize complete mRNA transcripts within the core without the need for disassembly. Indeed one of the more striking observations about genome transcription in dsRNA viruses is that this process occurs efficiently only when the transcriptionally competent particle is fully intact. This observation suggests that all of the components of the TCP, including the viral genome, the transcription enzymes, and the viral capsid, function together to produce and release mRNA transcripts and that each component has a specific and critical role to play in promoting the efficiency of this process. This review has examined the process of genome transcription in dsRNA viruses from the perspective of rotavirus as a model system. However, despite numerous architectural and organizational differences among the families of dsRNA viruses, numerous studies suggest that the basic mechanism of mRNA production may be similar in most, if not all, viruses having dsRNA genomes. Important functional similarities include (1) the presence of a capsid-bound RNA-dependent RNA polymerase, which produces single-stranded mRNA transcripts from the dsRNA genome and regenerates the dsRNA genome from single-stranded RNA templates; (2) in viruses infecting eukaryotic hosts, the presence of all the enzymatic activities needed to generate the 5' cap required by the eukaryotic translation machinery; (3) the high degree of structural order present in the packaged genome, suggesting the requirement for organization in the viral core; (4) the role of the innermost capsid protein as a scaffold on which the core components of the transcription apparatus are assembled; and (5) the release of nascent mRNA transcripts through channels at the icosahedral vertices. The process of genome transcription in dsRNA viruses will become better understood as structural studies progress to higher resolution and as more viruses become amenable to study using site-directed mutagenesis coupled with viral reconstitution to generate recombinant particles having precise functional and structural changes. Future studies will dissect important intermolecular interactions required for efficient mRNA synthesis and will shed further light on the reasons for which the viral core must be structurally intact in order for transcription to occur efficiently. Structural studies of the capping enzymes at atomic resolution will reveal how multiple enzyme activities reside within a single polypeptide and how they act in concert to synthesize the 5' cap on the end of each mature transcript. Perhaps most interestingly, high resolution structural studies of actively transcribing virions will provide insight into the conformational changes that occur within the core during mRNA synthesis. Together, these studies will clarify the function of this complex macromolecular machine and will also shed additional light on the basic principles of virus architecture and assembly, as well as provide avenues for the design of antiviral therapies.

High-temperature inducible cell-free transcription and replication of double-stranded RNAs within the parasitic protozoan Cryptosporidium parvum

Sporozoites of the protozoan parasite, Cryptosporidium parvum, were found to contain free, full-size plus strands transcribed from two extrachromosomal, cytoplasmic, virus-like double-stranded RNAs (dsRNAs). Cell-free transcription and replication of both dsRNAs were observed in crude sporozoite lysates. RNA polymerase activity was found to be dependent upon addition of Mg2+ or Mn2+, as well as the four ribonucleoside triphosphates, and was insensitive to inhibitors of cellular DNA-dependent RNA polymerase. Semiconservative transcription of the dsRNAs (plus strand synthesis) was observed at a wide range of temperatures, with an optimum of 50 degrees C. In contrast, replication (minus strand synthesis) was detected only at 50 and 60 degrees C.

Incomplete dsRNA genomes in purified infectious pancreatic necrosis virus

The dsRNA containing birnavirus, infectious pancreatic necrosis virus, possesses a virion-associated RNA-dependent RNA polymerase which acts both as primer and as polymerase during in vitro RNA synthesis (P. Dobos, 1995, Virology 208, 19-25). Using [alpha 32P]GTP, we have radiolabeled virion RNA in vitro and found that after deproteinization most of the labeled product comigrated in agarose gels with the 3-kbp viral genome, while the remainder migrated faster than the dsRNA and as a heterogeneous smear. Agarose gel electrophoresis (AGE) of denatured labeled virion RNA showed a radioactive smear ranging from approximately 100 nucleotides to up to 3000 nucleotide the size of genome length single stranded RNA. Hybridization experiments using strand-specific and end-specific obligonucleotides on Northern blots revealed that the radioactivity which migrates with the dsRNA during AGE represents small, 5' end plus RNA molecules of 100-500 nucleotides. The radioactivity in the faster migrating smear denotes incomplete dsRNAs where full-length, unlabeled minus strands are base-paired with labeled plus strands that are 3' truncated to different extents. This was confirmed by reverse transcription-polymerase chain reaction (RT-PCR) using end- and strand-specific obligonucleotide primers. The results indicated that 95% of incomplete dsRNA molecules consisted of full-length minus strands and 3' truncated plus strands. The implications of these findings are discussed in light of RNA replication mechanisms of dsRNA viruses belonging to other families.

Comparison of the replication of positive-stranded RNA viruses of plants and animals

It is clear from the experimental data that there are some similarities in RNA replication for all eukaryotic positive-stranded RNA viruses—that is, the mechanism of polymerization of the nucleotides is probably similar for all. It is noteworthy that all mechanisms appear to utilize host membranes as a site of replication. Membranes appear to function not only as a way of compartmentalizing virus RNA replication but also appear to have a central role in the organization and functioning of the replication complex, and further studies in this area are needed. Within virus supergroups, similarities are evident between animal and plant viruses—for example, in the nature and arrangements of replication genes and in sequence similarities of functional domains. However, it is also clear that there has been considerable divergence, even within supergroups. For example, the animal alpha-viruses have evolved to encode proteinases which play a central controlling function in the replication cycle, whereas this is not common in the plant alpha-like viruses and even when it occurs, as in the tymoviruses, the strategies that have evolved appear to be significantly different. Some of the divergence could be host-dependent and the increasing interest in the role of host proteins in replication should be fruitful in revealing how different systems have evolved. Finally, there are virus supergroups that appear to have no close relatives between animals and plants, such as the animal coronavirus-like supergroup and the plant carmo-like supergroup.

RNA duplex unwinding activity of poliovirus RNA-dependent RNA polymerase 3Dpol

The ability of highly purified preparations of poliovirus RNA-dependent RNA polymerase, 3Dpol, to unwind RNA duplex structures was examined during a chain elongation reaction in vitro. Using an antisense RNA prehybridized to an RNA template, we show that poliovirus polymerase can elongate through a highly stable RNA duplex of over 1,000 bp. Radiolabeled antisense RNA was displaced from the template during the reaction, and product RNAs which were equal in length to the template strand were synthesized. Unwinding did not occur in the absence of chain elongation and did not require hydrolysis of the gamma-phosphate of ATP. The rate of elongation through the duplex region was comparable to the rate of elongation on the single-stranded region of the template. Parallel experiments conducted with avian myeloblastosis virus reverse transcriptase showed that this enzyme was not able to unwind the RNA duplex, suggesting that strand displacement by poliovirus 3Dpol is not a property shared by all polymerases.

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.

In vitro packaging and replication of individual genomic segments of bacteriophage phi 6 RNA

The genome of bacteriophage phi 6 contains three segments of double-stranded RNA. Procapsid structures whose formation was directed by cDNA copies of the large genomic segment are capable of packaging the three viral message sense RNAs in the presence of ATP. Addition of UTP, CTP, and GTP results in the synthesis of minus strands to form double-stranded RNA. In this report, we show that procapsids are capable of taking up any of the three plus-strand single-stranded RNA segments independently of the others. In manganese-containing buffers, synthesis of the corresponding minus strand takes place. In magnesium-containing buffers, individual message sense viral RNA segments were packaged, but minus-strand replication did not take place unless all three viral single-stranded RNA segments were packaged. Since the conditions of packaging in magnesium buffer more closely resemble those in vivo, these results indicated that there is no specific order or dependence in packaging and that replication is regulated so that it does not begin until all segments are in place.

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 packaging of the bacteriophage phi 6 ssRNA genomic precursors

Bacteriophage phi 6 contains three segments of double-stranded RNA within a nucleocapsid. Plasmids containing cDNA copies of the large genomic segment direct the synthesis of viral proteins that assemble into procapsids in Escherichia coli or Pseudomonas phaseolicola. These structures are dodecahedral assemblages of proteins P1, P2, P4, and P7. We report in this paper that these particles are capable of packaging viral single-stranded plus-sense RNA in vitro. The packaging reaction requires the presence of ATP or dATP. Synthesis of minus strands takes place within this filled procapsid in the presence of all four nucleoside triphosphates. Packaged ssRNA is found to be protected from added ribonuclease.

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.

In vitro replication, packaging, and transcription of the segmented double-stranded RNA genome of bacteriophage phi 6: studies with procapsids assembled from plasmid-encoded proteins

The genome of the lipid-containing bacteriophage phi 6 contains three segments of double-stranded RNA (dsRNA). We prepared cDNA copies of the viral genome and cloned this material in plasmids that replicate in Escherichia coli and Pseudomonas phaseolicola, the natural host of phi 6. These plasmids direct the formation of viral proteins and the assembly of structures similar to viral procapsids containing proteins P1, P2, P4, and P7. We found that these particles are capable of taking up viral single-stranded RNA and synthesizing the minus strands to produce dsRNA structures. Once the dsRNA is formed, it is then used as a template for the production of viral plus strands in a reaction that resembles normal transcription. The particles were also capable of directly transcribing exogenous dsRNA. The replicase reactions were specific for phi 6 RNA, were specific for procapsids, and resulted in substantial incorporation of product dsRNA into particles. These results offer strong support to a model in which genomic packaging is done by preformed procapsids.

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.

RNA-protein complexes responsible for replication and transcription of the double-stranded RNA bacteriophage phi 6

RNA-protein complexes active for transcription and replication of the double-stranded RNA bacteriophage phi 6 have been partially purified from lysates of infected Pseudomonas phaseolicola. Transcribing particles (filled procapsids) contain the three viral dsRNAs and all four procapsid proteins P1, P2, P4, and P7. Particles with replicase activity contain the same four proteins as well as single plus RNA strands duplexed with various extents of minus strands initiated in vivo. The in vitro replication reaction is insensitive to RNaseA. Sarkosyl destroys transcription complexes but does not reduce the activity of replication complexes, although the latter lose 80% of their P4 and the single-strand RNA template becomes sensitive to RNase. The detection of complexes that replicate small only, or both small and medium, RNA suggests that the RNAs are packaged sequentially in the order small, medium, large.

Detection of bacteriophage phi 6 minus-strand RNA and novel mRNA isoconformers synthesized in vivo and in vitro, by strand-separating agarose gels

Two urea-free agarose gel protocols that resolve the six individual strands of bacteriophage phi 6 dsRNA were developed and used to analyze phage RNA synthesis in vivo and in vitro. Citrate gels separate strands of the large and medium chromosomes while Tris-borate-EDTA (TBE) gels resolve the medium and small dsRNA segments. Minus strands migrate faster than plus strands on citrate gels but are retarded on TBE gels. A study of electrophoretic conditions showed that pH affects strand resolution on citrate gels, and that voltage gradient, agarose concentration, and ethidium bromide significantly alter strand migration on TBE gels. Analysis of native phi 6 RNA synthesized in vivo and in vitro showed that the large and medium message RNAs comigrate with the corresponding plus strands of denatured virion dsRNA. The small messenger RNA is exceptional. Native small mRNA was detected as three isoconformers in vivo and in vitro. The isoconformers were converted by heat denaturation to a single RNA species that comigrates with the virion s+ strand. Minus strands labeled in vivo were detected only after heat denaturation. Minus strand synthesis was detected also in heat-denatured samples from in vitro phi 6 nucleocapsid RNA polymerase reactions at pH values suboptimal for transcription.

Minus-strand RNA synthesis by the segmented double-stranded RNA bacteriophage phi 6 requires continuous protein synthesis

Bacteriophage phi 6 contains three dsRNA chromosomes. Strand-separating agarose gels were used to study plus- and minus-strand synthesis in vivo and the effect of protein synthesis inhibitors. Analysis of phi 6 RNA synthesis shows low levels of all three dsRNAs and ssRNAs at 10 min, increasing label uptake into all RNAs except the large message from 20 to 60 min, and a greater abundance of medium and small messages than large mRNAs at late times. Isoconformers of the small message are synthesized throughout infection. Northern analysis suggests that large messages made early may persist to direct continuing translation of L-segment-encoded transcription and replication proteins. The time course of phi 6 minus-strand RNA synthesis in vivo, in the absence of background label in host RNAs, is reported for the first time. Label in minus strands is detected only after heat denaturation of RNA samples and appears sequentially in the small, medium, and large strands beginning at 20 min. At both early and late times, chloramphenicol arrests minus-strand synthesis rapidly and all three mRNAs accumulate. The results are consistent with the reovirus asynchronous model for dsRNA viral replication: plus ssRNAs made first are used as templates for minus-strand synthesis. They also indicate that replication protein(s) acts stoichiometrically.

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 replication and transcription of the segmented double-stranded RNA bacteriophage phi 6

In vitro conditions that support viral-specific replication and transcription have been developed from Pseudomonas phaseolicola cells infected with the segmented double-stranded RNA bacteriophage phi 6. Transcription activity, previously shown to occur by semiconservative strand displacement, labeled (+) strands of all three genome segments and produced all three corresponding genome length messenger RNAs. Replication activity for each of the three double-stranded RNA segments is observed. Our criteria for replication were formation of genomic length double-stranded RNA products and at least (-) strand synthesis activity. Mn2+ and Sarkosyl together selectively inhibited transcription. Analysis of replication alone suggested that replication templates are the viral (+) messenger RNAs.

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.

Generation of cDNA clones of the bacteriophage phi 6 segmented dsRNA genome: characterization and expression of L segment clones

Bacteriophage phi 6 has three dsRNA genome segments of about 3.0, 4.0, and 6.4 kbp. More than 90% of the segmented phi 6 dsRNA genome has been cloned as subchromosomal cDNA fragments, generated by reverse transcription of denatured polyadenylated dsRNA, RNA removal, annealing, filling, size fractionation, tailing, and insertion at the PstI site of pBR322. All of the large (L) segment is represented by five overlapping fragments, 98% of the small (S) segment is present in three fragments, and 67% of the medium (M) segment is contained in two fragments. Fragments have been aligned in linear arrays by Southern blot hybridization and restriction enzyme analysis. The orientation of the ordered fragments with respect to genomic RNA and phi 6 transcriptional direction was determined by comparison of terminal DNA sequences with RNA sequences at the genomic ends of phi 6 RNA. Expression of L segment clones using both Escherichia coli minicells and T7 polymerase/promoter vectors indicate that the order of known phi 6 genes on the large chromosome is: 5'--gene 7, gene 2, gene 4, gene 1--3'. cDNA complementation of a ts mutant, ts411, has located this mutation in gene 4.

In vitro L-A double-stranded RNA synthesis in virus-like particles from Saccharomyces cerevisiae

Most strains of Saccharomyces cerevisiae harbor L-A double-stranded RNA (dsRNA), 4.5 kilobases long, contained in virus-like particles (VLPs). These L-A VLPs can be separated by CsCl density gradient centrifugation into a main peak of particles, containing full-length L-A dsRNA, which synthesizes only plus-strand single-stranded RNA (ssRNA), and a lighter fraction of VLPs, containing plus-strand ssRNA, which has L-A dsRNA-synthesizing activity. This dsRNA-synthesizing activity was present in particles from logarithmically growing cells but not from stationary-phase cells. The newly synthesized strand of dsRNA in the lightest particles was full-length minus strand. All or almost all of the new minus strand was synthesized in vitro, and the rate of chain elongation was approximately 100 nucleotides per minute. The lightest particles synthesized plus-strand ssRNA only after completion of dsRNA synthesis, indicating that the same particle contains dsRNA- and ssRNA-synthesizing enzyme(s). We also observed dsRNA-synthesizing activity in L-BC dsRNA-containing particles similar to that in L-A VLPs.

Conservative replication and transcription of Saccharomyces cerevisiae viral double-stranded RNA in vitro

All double-stranded RNA viruses have capsid-associated RNA polymerase activities. In the reoviruses, the transcriptase synthesizes the viral plus strand in a conservative mode and the replicase synthesizes the viral minus strand, again conservatively. In bacteriophage phi 6 and in some fungal viruses, the transcriptase activity is semiconservative, acting by displacement synthesis. In this work we demonstrate Saccharomyces cerevisiae viral RNA replication in vitro for the first time and, using more sensitive techniques than those previously used, show that both the transcriptase and the replicase appear to act conservatively, like those of reovirus. There is therefore clearly no universal life cycle for the double-stranded RNA viruses.

Terminal sequences of the bacteriophage phi 6 segmented dsRNA genome and its messenger RNAs

The ends of the three dsRNA genome segments (L, M, and S) of bacteriophage phi 6 (strand separated and/or intact) and the 5' ends of the middle and small single-strand messenger RNAs have been sequenced by base-specific partial enzymatic digestion. Terminal sequences for the large and middle dsRNA strands extend about 60 bases. The three dsRNA segments have 18 homologous bases at the left end except for position 2, which differs in the L segment. A 17-base homology defines the right ends of L and M dsRNAs and probably S dsRNA as well. The 5' ends of middle and small messenger RNAs are identical to the corresponding viral (+) strands.

Conservative replication of double-stranded RNA in Saccharomyces cerevisiae by displacement of progeny single strands

Saccharomyces cerevisiae contains two double-stranded RNA (dsRNA) molecules, L and M, encapsulated in virus-like particles. After cells are transferred from dense (13C 15N) to light (12C 14N) medium, only two density classes of dsRNA are found, fully light (LL) and fully dense (HH). Cells contain single-stranded copies of both dsRNAs and, at least for L dsRNA, greater than 99% of these single strands are the positive protein-encoding strand. Single-stranded copies of L and M dsRNA accumulate rapidly in cells arrested in the G1 phase. These results parallel previous observations on L dsRNA synthesis and are consistent with a role of the positive single strands as intermediates in dsRNA replication. We propose that new positive strands are displaced from parental molecules and subsequently copied to produce the completely new duplexes.

Conservative replication of double-stranded RNA in Saccharomyces cerevisiae by displacement of progeny single strands

Saccharomyces cerevisiae contains two double-stranded RNA (dsRNA) molecules, L and M, encapsulated in virus-like particles. After cells are transferred from dense (13C 15N) to light (12C 14N) medium, only two density classes of dsRNA are found, fully light (LL) and fully dense (HH). Cells contain single-stranded copies of both dsRNAs and, at least for L dsRNA, greater than 99% of these single strands are the positive protein-encoding strand. Single-stranded copies of L and M dsRNA accumulate rapidly in cells arrested in the G1 phase. These results parallel previous observations on L dsRNA synthesis and are consistent with a role of the positive single strands as intermediates in dsRNA replication. We propose that new positive strands are displaced from parental molecules and subsequently copied to produce the completely new duplexes.

Transcriptional regulation of three double-stranded RNA segments of bacteriophage phi 6 in vitro

Three double-stranded RNA segments of bacteriophage phi 6 (L, M, and S) were transcribed in vitro by a virion-associated RNA polymerase. Regulation of L transcription was distinct from regulation of M and S transcription. Transcription of the L segment, which codes for early proteins, required manganous ion and high concentrations of all four ribonucleoside triphosphates and was inhibited by polyamines such as spermine. Transcription of the M and S segments, which code for late proteins, required manganous or magnesium ion and relatively low concentrations of all ribonucleoside triphosphates except GTP and was enhanced by polyamines. Optimal conditions for L transcription were more stringent than those for M and S transcription. These two apparently different patterns produced in in vitro transcription presumably reflect the two distinct in vivo transcription patterns; i.e., (i) similar amounts of three single-stranded RNA species were transcribed from the three corresponding segments of double-stranded RNA (early pattern) and (ii) a much larger amount of single-stranded RNA species was transcribed from M and S segments than from the L segment (late pattern). The early transcription pattern may be changed into the late pattern by a change of environment, such as substrate concentration. This suggests that the different enzymatic properties under the different environmental conditions of the virion-associated transcriptase are responsible for the transcriptional regulation throughout the infection cycle of bacteriophage phi 6.

Virion-associated RNA polymerase of bacteriophage phi 6 synthesizes three complete transcripts of double-stranded RNA genome in vitro

Three single-stranded RNA transcripts synthesized in vitro by a virion-associated RNA polymerase of bacteriophage phi 6 were sequenced at their 5'- and 3'-termini. The sequences agreed with those of the + strands of the 3 double-stranded RNA segments [FEBS Lett. (1982) 141,111-115]. The results show that the transcription by phi 6 RNA polymerase initiates exactly at the 3'-ends of the template RNAs (-strands of the genomic RNA) and terminates exactly at the 5'-ends.

Replication of double-stranded RNA of the virus-like particles in Saccharomyces cerevisiae

The mode of replication of the L double-stranded RNA (dsRNA) present in virus-like particles in Saccharomyces cerevisiae was examined by density transfer experiments. After transfer to light medium, significant amounts of fully heavy dsRNA persisted over a number of cell doublings. In addition, very little material of hybrid density was ever formed, and the accumulation of fully light material began as early as 0.5 doubling after transfer to light medium. Our results are compatible with a conservative mode of replication or with a semiconservative mode of replication carried out by a small portion of the total dsRNA population. In additional experiments the synthesis of dsRNA relative to the cell cycle was studied. This was done by determining the ratio of short-term to long-term radioactive label in size-separated cell fractions of a prelabeled exponential culture. The ratio of short-term to long-term label remained constant for all fractions, implying that dsRNA is synthesized throughout the cell cycle, increasing through the cell cycle at an exponential rate.

Yeast viral RNA polymerase is a transcriptase

ScV-L is a simple double-stranded RNA virus of yeast, consisting of a 4.8 kilobase pair double-stranded RNA (L) encapsidated in isometric particles composed mainly of one polypeptide (ScV-Pl) of 88,000 daltons. L encodes ScV-Pl. There is a capsid-associated RNA polymerase that synthesizes in vitro predominantly single-stranded RNA. We show that this polymerase activity is a transcriptase, at the least one product of which is the mRNA for ScV-Pl. The transcript, like its template, is uncapped.

In vitro translation of the three bacteriophage phi 6 RNAs

In vitro translation of the three single-stranded RNAs transcribed in vitro by bacteriophage phi 6 RNA polymerase revealed that the large RNA codes for phage proteins P1, P2, P4, and P7, the medium RNA codes for P3, P6, and P10, and the smaller RNA for P5, P8, and P9.

Displacement of parental RNA strands during in vitro transcription by bacteriophage phi 6 nucleocapsids

We have studied the mode of transcription of the three double-stranded RNA segments found in bacteriophage phi 6. Stable transcription intermediates, isolated following in vitro incorporation of nucleoside triphosphates by phi 6 nucleocapsids, were examined by electron microscopy. Specimens were either spread and shadowed or deposited on polylysine film and stained. In either case, branched molecules with one or more single-stranded arms were seen. The single-stranded arm, in all molecules observed, has about half the contour length of one double-stranded arm. The branched molecules are stable in high salt or hot phenol, resistant to proteinase K, but sensitive to RNAase A in high salt, yielding fragments of double-stranded RNA. These results are consistent with a transcription mechanism in which each new transcript displaces one of the parental RNA strands. From the rate of movement of the branch point, we found transcription rates in vitro of similar to or approximately 25 nucleotides per sec at 30 degrees C and 19 nucleotides per sec at 25 degrees C. Based on the spacing between branches in multiply branched molecules, initiation occurs approximately once every 40 sec at 30 degrees C on M or S RNA templates and about 6 times less frequently on L RNA.