Structure of the RNA inside the vesicular stomatitis virus nucleocapsid

Sendai Virus and a Unified Model of Mononegavirus RNA Synthesis

Vesicular stomatitis virus (VSV), the founding member of the mononegavirus order (Mononegavirales), was found to be a negative strand RNA virus in the 1960s, and since then the number of such viruses has continually increased with no end in sight. Sendai virus (SeV) was noted soon afterwards due to an outbreak of newborn pneumonitis in Japan whose putative agent was passed in mice, and nowadays this mouse virus is mainly the bane of animal houses and immunologists. However, SeV was important in the study of this class of viruses because, like flu, it grows to high titers in embryonated chicken eggs, facilitating the biochemical characterization of its infection and that of its nucleocapsid, which is very close to that of measles virus (MeV). This review and opinion piece follow SeV as more is known about how various mononegaviruses express their genetic information and carry out their RNA synthesis, and proposes a unified model based on what all MNV have in common.

The Nucleoprotein and Phosphoprotein of Measles Virus

Measles virus is a negative strand virus and the genomic and antigenomic RNA binds to the nucleoprotein (N), assembling into a helical nucleocapsid. The polymerase complex comprises two proteins, the Large protein (L), that both polymerizes RNA and caps the mRNA, and the phosphoprotein (P) that co-localizes with L on the nucleocapsid. This review presents recent results about N and P, in particular concerning their intrinsically disordered domains. N is a protein of 525 residues with a 120 amino acid disordered C-terminal domain, N_tail. The first 50 residues of N_tail extricate the disordered chain from the nucleocapsid, thereby loosening the otherwise rigid structure, and the C-terminus contains a linear motif that binds P. Recent results show how the 5′ end of the viral RNA binds to N within the nucleocapsid and also show that the bases at the 3′ end of the RNA are rather accessible to the viral polymerase. P is a tetramer and most of the protein is disordered; comprising 507 residues of which around 380 are disordered. The first 37 residues of P bind N, chaperoning against non-specific interaction with cellular RNA, while a second interaction site, around residue 200 also binds N. In addition, there is another interaction between C-terminal domain of P (XD) and N_tail. These results allow us to propose a new model of how the polymerase binds to the nucleocapsid and suggests a mechanism for initiation of transcription.

RNA Synthesis and Capping by Non-segmented Negative Strand RNA Viral Polymerases: Lessons From a Prototypic Virus

Non-segmented negative strand (NNS) RNA viruses belonging to the order Mononegavirales are highly diversified eukaryotic viruses including significant human pathogens, such as rabies, measles, Nipah, and Ebola. Elucidation of their unique strategies to replicate in eukaryotic cells is crucial to aid in developing anti-NNS RNA viral agents. Over the past 40 years, vesicular stomatitis virus (VSV), closely related to rabies virus, has served as a paradigm to study the fundamental molecular mechanisms of transcription and replication of NNS RNA viruses. These studies provided insights into how NNS RNA viruses synthesize 5′-capped mRNAs using their RNA-dependent RNA polymerase L proteins equipped with an unconventional mRNA capping enzyme, namely GDP polyribonucleotidyltransferase (PRNTase), domain. PRNTase or PRNTase-like domains are evolutionally conserved among L proteins of all known NNS RNA viruses and their related viruses belonging to Jingchuvirales, a newly established order, in the class Monjiviricetes, suggesting that they may have evolved from a common ancestor that acquired the unique capping system to replicate in a primitive eukaryotic host. This article reviews what has been learned from biochemical and structural studies on the VSV RNA biosynthesis machinery, and then focuses on recent advances in our understanding of regulatory and catalytic roles of the PRNTase domain in RNA synthesis and capping.

R7A mutation in N protein renders temperature sensitive phenotype of VSV by affecting its replication and transcription in vitro

Viral genomic RNA encapsidated by nucleoprotein (N) forms functional template for the transcription and replication of vesicular stomatitis virus (VSV). The crystal structure of the N-RNA complex shows that RNA is tightly sequestered between the two lobes of the N protein. The residue (R7) in N-terminal arm of N is of great importance to the formation of functional N-RNA template. In our study, we found that single amino acid substitution (R7A) resulted in the loss of CAT expression in vitro minigenome system at 37 °C. But the R7A had little effect on CAT expression at 31 °C. Further analysis showed that R7A had great effects on the RNA synthesis and the formation of cytoplasmic inclusions of VSV only at 37 °C not at 31 °C. For the further investigation of the effect of R7A on virus replication, we checked the dominant-negative effect of N_R7A in minigenome system and the single step curve of recombinant virus with R7A mutation in N protein (rVSV_R7A) under 37 °C and 31 °C separately. Our results showed that the mutation of R7A within the N-terminal arm of N affected both replication and transcription and induced VSV to become temperature sensitive.

Nonsegmented Negative-Sense RNA Viruses-Structural Data Bring New Insights Into Nucleocapsid Assembly

Viruses with a nonsegmented negative-sense RNA genome (NNVs) include important human pathogens as well as life-threatening zoonotic viruses. These viruses share a common RNA replication complex, including the genomic RNA and three proteins, the nucleoprotein (N), the phosphoprotein (P), and the RNA-dependent RNA polymerase (L). During genome replication, the RNA polymerase complex first synthesizes positive-sense antigenomes, which in turn serve as template for the production of negative-sense progeny genomes. These newly synthesized antigenomic and genomic RNAs must be encapsidated by N, and the source of soluble, RNA-free N, competent for the encapsidation is a complex between N and P, named the N⁰-P complex. In this review, we summarize recent progress made in the structural characterization of the different components of this peculiar RNA polymerase machinery. We discuss common features and replication strategies and highlight idiosyncrasies encountered in different viruses, along with the key role of the dual ordered/disordered architecture of protein components and the dynamics of the viral polymerase machinery. In particular, we focus on the N⁰-P complex and its role in the nucleocapsid assembly process. These new results provide evidence that the mechanism of NC assembly is conserved between the different families and thus support a divergent evolution from a common ancestor. In addition, the successful inhibition of infection due to different NNVs by peptides derived from P suggests that the mechanism of NC assembly is a potential target for antiviral development.

Paramyxovirus RNA synthesis, mRNA editing, and genome hexamer phase: A review

The recent flurry of high resolution structures of Negative Strand RNA Virus RNA-dependent RNA polymerases has rekindled interest in the manner in which these polymerases, and in particular those of the nonsegmented viruses, recognize the RNA sequences that control mRNA synthesis and genome replication. In the light of these polymerase structures, we re-examine some unusual aspects of the Paramyxoviridae, namely bipartite replication promoters and mRNA editing, and the manner in which these properties are governed by genome hexamer phase.

Mechanism of preferential packaging of negative sense genomic RNA by viral nucleoproteins in Crimean-Congo hemorrhagic Fever virus

The Crimean-Congo Hemorrhagic Fever (CCHF) is an infectious disease of high virulence and mortality caused by a negative sense RNA nairovirus. The genomic RNA of CCHFV is enwrapped by its nucleoprotein. Positively charged residues on CCHFV nucleoprotein provide multiple binding sites to facilitate genomic RNA encapsidation. In the present work, we investigated the mechanism underlying preferential packaging of the negative sense genomic RNA by CCHFV nucleoprotein in the presence of host cell RNAs during viral assembly. The work included genome sequence analyses for different families of negative and positive sense RNA viruses, using serial docking experiments and molecular dynamic simulations. Our results indicated that the main determinant parameter of the nucleoprotein binding affinity for negative sense RNA is the ratio of purine/pyrimidine in the RNA molecule. A negative sense RNA with a purine/pyrimidine ratio (>1) higher than that of a positive sense RNA (<1) exhibits higher affinity for the nucleoprotein. Our calculations revealed that a negative sense RNA expresses about 0.5 kJ/mol higher binding energy per nucleotide compared to a positive sense RNA. This energy difference produces a binding energy high enough to make the negative sense RNA, the preferred substrate for packaging by CCHFV nucleoprotein in the presence of cellular or complementary positive sense RNAs. The outcome of this study may contribute to ongoing researches on other viral diseases caused by negative sense RNA viruses such as Ebola virus which poses a security threat to all humanity.

Self-organization of the vesicular stomatitis virus nucleocapsid into a bullet shape

The typical bullet shape of Rhabdoviruses is thought to rely on the matrix protein for stabilizing the nucleocapsid coil. Here we scrutinize the morphology of purified and recombinant nucleocapsids of vesicular stomatitis virus in vitro. We elucidate pH and ionic strength conditions for their folding into conical tips and further growth into whole bullets, and provide cryo-electron microscopy reconstructions of the bullet tip and the helical trunk. We address conformational variability of the reconstituted nucleocapsids and the issue of constraints imposed by the binding of matrix protein. Our findings bridge the gap between the isolated nucleoprotein-RNA string in its form of an undulating ribbon, and the tight bullet-shaped virion skeleton.

Monomeric nucleoprotein of influenza A virus

Isolated influenza A virus nucleoprotein exists in an equilibrium between monomers and trimers. Samples containing only monomers or only trimers can be stabilized by respectively low and high salt. The trimers bind RNA with high affinity but remain trimmers, whereas the monomers polymerise onto RNA forming nucleoprotein-RNA complexes. When wild type (wt) nucleoprotein is crystallized, it forms trimers, whether one starts with monomers or trimers. We therefore crystallized the obligate monomeric R416A mutant nucleoprotein and observed how the domain exchange loop that leads over to a neighbouring protomer in the trimer structure interacts with equivalent sites on the mutant monomer surface, avoiding polymerisation. The C-terminus of the monomer is bound to the side of the RNA binding surface, lowering its positive charge. Biophysical characterization of the mutant and wild type monomeric proteins gives the same results, suggesting that the exchange domain is folded in the same way for the wild type protein. In a search for how monomeric wt nucleoprotein may be stabilized in the infected cell we determined the phosphorylation sites on nucleoprotein isolated from virus particles. We found that serine 165 was phosphorylated and conserved in all influenza A and B viruses. The S165D mutant that mimics phosphorylation is monomeric and displays a lowered affinity for RNA compared with wt monomeric NP. This suggests that phosphorylation may regulate the polymerisation state and RNA binding of nucleoprotein in the infected cell. The monomer structure could be used for finding new anti influenza drugs because compounds that stabilize the monomer may slow down viral infection.

The RNAs of negative strand RNA viruses are encapsidated by their specific viral nucleoproteins, forming helical nucleoprotein-RNA structures that are the template for transcription and replication. All these nucleoproteins have two activities in common: RNA binding and self-polymerisation, and it is likely that these activities are coupled. All these viruses have to keep their nucleoprotein from binding to cellular RNA and from polymerisation before viral RNA binding. The non-segmented viruses solve this by coding for a phosphoprotein that binds to the nucleoprotein, blocking both activities. The segmented viruses, such as influenza and Bunyaviruses, do not code for a phosphoprotein and need to solve this problem differently. Here we present the atomic structure of monomeric influenza virus nucleoprotein. Although the structures of the influenza virus and the Rift Valley Fever Virus (Bunya virus) nucleoproteins are different, there are functional similarities when the monomer and polymer structures are compared. Both nucleoproteins have a core structure that is identical in the monomer and the polymer. They contain a flexible arm that moves over to a neighbouring protomer in the polymer structure but that folds onto the core in the monomer structure, hiding the RNA binding groove in the Rift valley Fever Virus nucleoprotein and modifying the electrostatic potential of the RNA binding platform of the influenza virus protein.

Chandipura Virus: an emerging tropical pathogen

Chandipura Virus (CHPV), a member of Rhabdoviridae, is responsible for an explosive outbreak in rural areas of India. It affects mostly children and is characterized by influenza-like illness and neurologic dysfunctions. It is transmitted by vectors such as mosquitoes, ticks and sand flies. An effective real-time one step reverse-transcriptase PCR assay method is adopted for diagnosis of this virus. CHPV has a negative sense RNA genome encoding five different proteins (N, P, M, G, and L). P protein plays a vital role in the virus's life cycle, while M protein is lethal in nature. There is no specific treatment available to date, symptomatic treatment involves use of mannitol to reduce brain edema. A Vero cell based vaccine candidate against CHPV was evaluated efficiently as a preventive agent against it. Prevention is the best method to suppress CHPV infection. Containment of disease transmitting vectors, maintaining good nutrition, health, hygiene and awareness in rural areas will help in curbing the menace of CHPV. Thus, to control virus transmission some immense preventive measures need to be attempted until a good anti-CHPV agent is developed.

Structural properties of the C terminus of vesicular stomatitis virus N protein dictate N-RNA complex assembly, encapsidation, and RNA synthesis

The vesicular stomatitis virus (VSV) nucleoprotein (N) associates tightly with the viral genomic RNA. This N-RNA complex constitutes the template for the RNA-dependent RNA polymerase L, which engages the nucleocapsid via its phosphoprotein cofactor P. While N and P proteins play important roles in regulating viral gene expression, the molecular basis of this regulation remains incompletely understood. Here we show that mutations in the extreme C terminus of N cause defects in viral gene expression. To determine the underlying cause of such defects, we examined the effects of the mutations separately on encapsidation and RNA synthesis. Expression of N together with P in Escherichia coli results predominantly in the formation of decameric N-RNA rings. In contrast, nucleocapsid complexes containing the substitution N(Y415A) or N(K417A) were more loosely coiled, as revealed by electron microscopy (EM). In addition, the N(EF419/420AA) mutant was unable to encapsidate RNA. To further characterize these mutants, we engineered an infectious cDNA clone of VSV and employed N-RNA templates from those viruses to reconstitute RNA synthesis in vitro. The transcription assays revealed specific defects in polymerase utilization of the template that result in overall decreased RNA quantities, including reduced amounts of leader RNA. Passage of the recombinant viruses in cell culture led to the accumulation of compensatory second-site mutations in close proximity to the original mutations, underscoring the critical role of structural features within the C terminus in regulating N function.

Mechanism of RNA synthesis initiation by the vesicular stomatitis virus polymerase

The minimal RNA synthesis machinery of non-segmented negative-strand RNA viruses comprises a genomic RNA encased within a nucleocapsid protein (N-RNA), and associated with the RNA-dependent RNA polymerase (RdRP). The RdRP is contained within a viral large (L) protein, which associates with N-RNA through a phosphoprotein (P). Here, we define that vesicular stomatitis virus L initiates synthesis via a de-novo mechanism that does not require N or P, but depends on a high concentration of the first two nucleotides and specific template requirements. Purified L copies a template devoid of N, and P stimulates L initiation and processivity. Full processivity of the polymerase requires the template-associated N protein. This work provides new mechanistic insights into the workings of a minimal RNA synthesis machine shared by a broad group of important human, animal and plant pathogens, and defines a mechanism by which specific inhibitors of RNA synthesis function.

Structural insights into the rhabdovirus transcription/replication complex

The rhabdoviruses have a non-segmented single stranded negative-sense RNA genome. Their multiplication in a host cell requires three viral proteins in addition to the viral RNA genome. The nucleoprotein (N) tightly encapsidates the viral RNA, and the N-RNA complex serves as the template for both transcription and replication. The viral RNA-dependent RNA polymerase is a two subunit complex that consists of a large subunit, L, and a non-catalytic cofactor, the phosphoprotein, P. P also acts as a chaperone of nascent RNA-free N by forming a N(0)-P complex that prevents N from binding to cellular RNAs and from polymerizing in the absence of RNA. Here, we discuss the recent molecular and structural studies of individual components and multi-molecular complexes that are involved in the transcription/replication complex of these viruses with regard to their implication in viral transcription and replication.

Structure, interactions with host cell and functions of rhabdovirus phosphoprotein

Rabies is an incurable albeit preventable disease that remains an important human health issue, with the number of deaths exceeding 50,000 people each year. Its causative agent, the rabies virus, is a negative-sense RNA virus, the genome of which encodes five proteins. Three of these proteins, the nucleoprotein, the phosphoprotein (P) and the large protein, are required to synthesize viral RNA in an efficient and regulated manner. P plays multiple roles during the transcription and replication of the RNA genome. It acts as a noncatalytic cofactor of the large protein polymerase and it chaperones nucleoprotein. Recent structural characterizations of rabies virus P revealed that P forms elongated and flexible dimers and uncovered the structural basis of its modular organization, revealing the existence of two independent structured domains and two long intrinsically disordered regions. In addition, recent studies also revealed that P interacts with nucleocytoplasmic trafficking carriers and with the host cell cytoskeleton, probably allowing viral components to be transported within the host cell and blocking the innate immune response by inhibiting different steps of the interferon pathway. With multiple binding sites for different viral and cellular partners located in either its structured or disordered regions, P appears to be a flexible ‘hub’ protein that connects viral or cellular proteins and allows their assembly into multimolecular complexes. These new findings shed light on the mechanism of replication of the virus and on the intimate interactions between the virus and its host cell, and will also help to identify new targets for the development of antiviral treatments.

Access to RNA encapsidated in the nucleocapsid of vesicular stomatitis virus

The genomic RNA of negative-strand RNA viruses, such as vesicular stomatitis virus (VSV), is completely enwrapped by the nucleocapsid protein (N) in every stage of virus infection. During viral transcription/replication, however, the genomic RNA in the nucleocapsid must be accessible by the virus-encoded RNA-dependent RNA polymerase in order to serve as the template for RNA synthesis. With the VSV nucleocapsid and a nucleocapsid-like particle (NLP) produced in Escherichia coli, we have found that the RNA in the VSV nucleocapsid can be removed by RNase A, in contrast to what was previously reported. Removal of the RNA did not disrupt the assembly of the N protein, resulting in an empty capsid. Polyribonucleotides were reencapsidated into the empty NLP, and the crystal structures were determined. The crystal structures revealed variable degrees of association of the N protein with a specific RNA sequence.

Importance of hydrogen bond contacts between the N protein and RNA genome of vesicular stomatitis virus in encapsidation and RNA synthesis

Vesicular stomatitis virus (VSV) genomic RNA encapsidated by the nucleocapsid (N) protein is the template for transcription and replication by the viral polymerase. We analyzed the 2.9-A structure of the VSV N protein bound to RNA (T. J. Green, X. Zhang, G. W. Wertz, and M. Luo, Science 313:357-360, 2006) and identified amino acid residues with the potential to interact with RNA via hydrogen bonds. The contributions of these interactions to N protein function were investigated by individually substituting the residues with alanine and assaying the effect of these mutations on N protein expression, on the ability of the N protein to interact with the phosphoprotein (P), and on its ability to encapsidate RNA and generate templates that can support transcription and RNA replication. These studies identified individual amino acids critical for N protein function. Nine nucleotides are associated with each N monomer and contorted into two quasi-helices within the N protein RNA binding cavity. We found that N protein residues that formed hydrogen bond contacts with the nucleotides in quasi-helix 2 were critical to the encapsidation of RNA and the production of templates that can support RNA synthesis. Individual hydrogen bond interactions between the N protein and the nucleotides of quasi-helix 1 were not essential for ribonucleoprotein (RNP) template function. Residue R143 forms a hydrogen bond with nucleotide 9, the nucleotide that extends between N monomers. R143A mutant N protein failed to encapsidate RNA and to support RNA synthesis and suppressed wild-type N protein function. These studies show a direct correlation between viral RNA synthesis and N protein residues structurally positioned to interact with RNA.

Binding of rabies virus polymerase cofactor to recombinant circular nucleoprotein-RNA complexes

In rabies virus, the attachment of the L polymerase (L) to the viral nucleocapsids (NCs)-a nucleoprotein (N)-RNA complex that serves as template for RNA transcription and replication-is mediated by the polymerase cofactor, the phosphoprotein (P). P forms dimers (P(2)) that bind through their C-terminal domains (P(CTD)) to the C-terminal region of the N. Recombinant circular N(m)-RNA complexes containing 9 to 12 protomers of N (hereafter, the subscript m denotes the number of N protomers) served here as model systems for studying the binding of P to NC-like N(m)-RNA complexes. Titration experiments show that there are only two equivalent and independent binding sites for P dimers on the N(m)-RNA rings and that each P dimer binds through a single P(CTD). A dissociation constant in the nanomolar range (160+/-20 nM) was measured by surface plasmon resonance, indicating a strong interaction between the two partners. Small-angle X-ray scattering (SAXS) data and small-angle neutron scattering data showed that binding of two P(CTD) had almost no effect on the size and shape of the N(m)-RNA rings, whereas binding of two P(2) significantly increased the size of the complexes. SAXS data and molecular modeling were used to add flexible loops (N(NTD) loop, amino acids 105-118; N(CTD) loop, amino acids 376-397) missing in the recently solved crystal structure of the circular N(11)-RNA complex and to build a model for the N(10)-RNA complex. Structural models for the N(m)-RNA-(P(CTD))(2) complexes were then built by docking the known P(CTD) structure onto the completed structures of the circular N(10)-RNA and N(11)-RNA complexes. A multiple-stage flexible docking procedure was used to generate decoys, and SAXS and biochemical data were used for filtering the models. In the refined model, the P(CTD) is bound to the C-terminal top of one N protomer (N(i)), with the C-terminal helix (alpha(6)) of P(CTD) lying on helix alpha(14) of N(i). By an induced-fit mechanism, the N(CTD) loop of the same protomer (N(i)) and that of the adjacent one (N(i)(-1)) mold around the P(CTD), making extensive protein-protein contacts that could explain the strong affinity of P for its template. The structural model is in agreement with available biochemical data and provides new insights on the mechanism of attachment of the polymerase complex to the NC template.

Mutations in the C-terminal loop of the nucleocapsid protein affect vesicular stomatitis virus RNA replication and transcription differentially

The 2.9-A structure of the vesicular stomatitis virus nucleocapsid (N) protein bound to RNA shows the RNA to be tightly sequestered between the two lobes of the N protein. Domain movement of the lobes of the N protein has been postulated to facilitate polymerase access to the RNA template. We investigated the roles of individual amino acid residues in the C-terminal loop, involved in long-range interactions between N protein monomers, in forming functional ribonucleoprotein (RNP) templates. The effects of specific N protein mutations on its expression, interaction with the phosphoprotein, and formation of RNP templates that supported viral RNA replication and transcription were examined. Mutations introduced into the C-terminal loop, predicted to break contact with other residues in the loop, caused up to 10-fold increases in RNA replication without an equivalent stimulation of transcription. Mutation F348A, predicted to break contact between the C-terminal loop and the N-terminal arm, formed templates that supported wild-type levels of RNA replication but almost no transcription. These data show that mutations in the C-terminal loop of the N protein can disparately affect RNA replication and transcription, indicating that the N protein plays a role in modulating RNP template function beyond its structural role in RNA encapsidation.

Investigating the specificity and stoichiometry of RNA binding by the nucleocapsid protein of Bunyamwera virus

Bunyamwera virus (BUNV) is the prototypic member of both the Orthobunyavirus genus and the Bunyaviridae family of negative stranded RNA viruses. In common with all negative stranded RNA viruses, the BUNV genomic and anti-genomic strands are not naked RNAs, but instead are encapsidated along their entire lengths with the virus-encoded nucleocapsid (N) protein to form a ribonucleoprotein (RNP) complex. This association is critical for the negative strand RNA virus life cycle because only RNPs are active for productive RNA synthesis and RNA packaging. We are interested in understanding the molecular details of how N and RNA components associate within the bunyavirus RNP, and what governs the apparently selective encapsidation of viral replication products. Toward this goal, we recently devised a protocol that allowed generation of native BUNV N protein that maintained solubility under physiological conditions and allowed formation of crystals that yielded high-resolution x-ray diffraction data. Here we extend this work to show that this soluble N protein is able to oligomerize and bind RNA to form a highly uniform RNP complex, which exhibits characteristics in common with the viral RNP. By extracting and sequencing RNAs bound to these model RNPs, we determined the stoichiometry of N-RNA association to be approximately 12 nucleotides per N monomer. In addition, we defined the minimal sequence requirement for BUNV RNA replication. By comparing this minimal sequence to those bound to our model RNP, we conclude that N protein does not obligatorily require a sequence or structure for RNA encapsidation.

Nucleocapsid structure and function

Measles virus belongs to the Paramyxoviridae family within the Mononegavirales order. Its nonsegmented, single-stranded, negative-sense RNA genome is encapsidated by the nucleoprotein (N) to form a helical nucleocapsid. This ribonucleoproteic complex is the substrate for both transcription and replication. The RNA-dependent RNA polymerase binds to the nucleocapsid template via its co-factor, the phosphoprotein (P). This chapter describes the main structural information available on the nucleoprotein, showing that it consists of a structured core (N(CORE)) and an intrinsically disordered C-terminal domain (N(TAIL)). We propose a model where the dynamic breaking and reforming of the interaction between N(TAIL) and P would allow the polymerase complex (L-P) to cartwheel on the nucleocapsid template. We also propose a model where the flexibility of the disordered N and P domains allows the formation of a tripartite complex (No-P-L) during replication, followed by the delivery of N monomers to the newly synthesized genomic RNA chain. Finally, the functional implications of structural disorder are also discussed in light of the ability of disordered regions to establish interactions with multiple partners, thus leading to multiple biological effects.

Solution structure of the C-terminal nucleoprotein-RNA binding domain of the vesicular stomatitis virus phosphoprotein

Beyond common features in their genome organization and replication mechanisms, the evolutionary relationships among viruses of the Rhabdoviridae family are difficult to decipher because of the great variability in the amino acid sequence of their proteins. The phosphoprotein (P) of vesicular stomatitis virus (VSV) is an essential component of the RNA transcription and replication machinery; in particular, it contains binding sites for the RNA-dependent RNA polymerase and for the nucleoprotein. Here, we devised a new method for defining boundaries of structured domains from multiple disorder prediction algorithms, and we identified an autonomous folding C-terminal domain in VSV P (P(CTD)). We show that, like the C-terminal domain of rabies virus (RV) P, VSV P(CTD) binds to the viral nucleocapsid (nucleoprotein-RNA complex). We solved the three-dimensional structure of VSV P(CTD) by NMR spectroscopy and found that the topology of its polypeptide chain resembles that of RV P(CTD). The common part of both proteins could be superimposed with a backbone RMSD from mean atomic coordinates of 2.6 A. VSV P(CTD) has a shorter N-terminal helix (alpha(1)) than RV P(CTD); it lacks two alpha-helices (helices alpha(3) and alpha(6) of RV P), and the loop between strands beta(1) and beta(2) is longer than that in RV. Dynamical properties measured by NMR relaxation revealed the presence of fast motions (below the nanosecond timescale) in loop regions (amino acids 209-214) and slower conformational exchange in the N- and C-terminal helices. Characterization of a longer construct indicated that P(CTD) is preceded by a flexible linker. The results presented here support a modular organization of VSV P, with independent folded domains separated by flexible linkers, which is conserved among different genera of Rhabdoviridae and is similar to that proposed for the P proteins of the Paramyxoviridae.

DMS footprinting of structured RNAs and RNA-protein complexes

We describe a protocol in which dimethyl sulfate (DMS) modification of the base-pairing faces of unpaired adenosine and cytidine nucleotides is used for structural analysis of RNAs and RNA-protein complexes (RNPs). The protocol is optimized for RNAs of small to moderate size (< or = 500 nt). The RNA or RNP is first exposed to DMS under conditions that promote formation of the folded structure or complex, as well as 'control' conditions that do not allow folding or complex formation. The positions and extents of modification are then determined by primer extension, polyacrylamide gel electrophoresis and quantitative analysis. From changes in the extent of modification upon folding or protein binding (appearance of a 'footprint'), it is possible to detect local changes in the secondary and tertiary structure of RNA, as well as the formation of RNA-protein contacts. This protocol takes 1.5-3 d to complete, depending on the type of analysis used.

Reviewing Chandipura: a vesiculovirus in human epidemics

Chandipura virus, a member of the rhabdoviridae family and vesiculovirus genera, has recently emerged as human pathogen that is associated with a number of outbreaks in different parts of India. Although, the virus closely resembles with the prototype vesiculovirus, Vesicular Stomatitis Virus, it could be readily distinguished by its ability to infect humans. Studies on Chandipura virus while shed light into distinct stages of viral infection; it may also allow us to identify potential drug targets for antiviral therapy. In this review, we have summarized our current understanding of Chandipura virus life cycle at the molecular detail with particular interest in viral RNA metabolisms, namely transcription, replication and packaging of viral RNA into nucleocapsid structure. Contemporary research on otherwise extensively studied family member Vesicular Stomatitis Virus has also been addressed to present a more comprehensive picture of vesiculovirus life cycle. Finally, we reveal examples of protein economy in Chandipura virus life-cycle whereby each viral protein has evolved complexity to perform multiple tasks.

Development of a challenge-protective vaccine concept by modification of the viral RNA-dependent RNA polymerase of canine distemper virus

We demonstrate that insertion of the open reading frame of enhanced green fluorescent protein (EGFP) into the coding sequence for the second hinge region of the viral L (large) protein (RNA-dependent RNA polymerase) attenuates a wild-type canine distemper virus. Moreover, we show that single intranasal immunization with this recombinant virus provides significant protection against challenge with the virulent parental virus. Protection against wild-type challenge was gained either after recovery of cellular immunity postimmunization or after development of neutralizing antibodies. Insertion of EGFP seems to result in overattenuation of the virus, while our previous experiments demonstrated that the insertion of an epitope tag into a similar position did not affect L protein function. Thus, a desirable level of attenuation could be reached by manipulating the length of the insert (in the second hinge region of the L protein), providing additional tools for optimization of controlled attenuation. This strategy for controlled attenuation may be useful for a "quick response" in vaccine development against well-known and "new" viral infections and could be combined efficiently with other strategies of vaccine development and delivery systems.

Sendai virus RNA polymerase scanning for mRNA start sites at gene junctions

Mini-genomes expressing two reporter genes and a variable gene junction were used to study Sendai virus RNA polymerase (RdRp) scanning for the mRNA start signal of the downstream gene (gs2). We found that RdRp could scan the template efficiently as long as the initiating uridylate of gs2 (3' UCCCnnUUUC) was preceded by the conserved intergenic region (3' GAA) and the last 3 uridylates of the upstream gene end signal (ge1; 3' AUUCUUUUU). The end of the leader sequence (3' CUAAAA, which precedes gs1) could also be used for gene2 expression, but this sequence was considerably less efficient. Increasing the distance between ge1 and gs2 (up to 200 nt) led to the progressive loss of gene2 expression, in which half of gene2 expression was lost for each 70 nucleotides of intervening sequence. Beyond 200 nt, gene2 expression was lost more slowly. Our results suggest that there may be two populations of RdRp that scan at gene junctions, which can be distinguished by the efficiency with which they can scan the genome template for gs.

Role of the sonchus yellow net virus N protein in formation of nuclear viroplasms

Sonchus yellow net virus is a plant nucleorhabdovirus whose nucleocapsid (N), phosphoprotein (P), and polymerase (L) proteins form large viroplasms in the nuclei of infected plants (C. R. F. Martins, J. A. Johnson, D. M. Lawrence, T. J. Choi, A. Pisi, S. L. Tobin, D. Lapidus, J. D. O. Wagner, S. Ruzin, K. McDonald, and A. O. Jackson, J. Virol. 72:5669-5679, 1998). When expressed alone, the N protein localizes to the nuclei of plant and yeast (Saccharomyces cerevisiae) cells and the P protein is distributed throughout the cells, but coexpression of N and P results in formation of subnuclear viroplasm-like foci (M. M. Goodin, J. Austin, R. Tobias, M. Fujita, C. Morales, and A. O. Jackson, J. Virol. 75:9393-9406, 2001; M. M. Goodin, R. G. Dietzgen, D. Schichnes, S. Ruzin, and A. O. Jackson, Plant J. 31:375-383, 2002). We now show that the N protein and various fluorescent derivatives form similar subnuclear foci in plant cells and that homologous interactions mediated by a helix-loop-helix region near the amino terminus are required for formation of the foci. Mutations within the helix-loop-helix region also interfere with N- and P-protein interactions that are required for N and P colocalization in the subnuclear foci. Affinity purification of N proteins harboring single mutations within the motif revealed that Tyr40 is critical for N-N and N-P interactions. Additional in vitro binding assays also indicated that the N protein binds to yeast and plant importin alpha homologues, whereas mutations in the carboxy-terminal nuclear localization signal abrogate importin alpha binding. The P protein did not bind to the importin alpha homologues, suggesting that the N and P proteins use different pathways for nuclear entry. Our results in toto support a model suggesting that during infection, the N and P proteins enter the nucleus independently, that viroplasm formation requires homologous N-protein interactions, and that P protein targeting to the viroplasm requires N-P protein interactions that occur after N and P protein import into the nucleus.

Isolation and crystallization of a unique size category of recombinant Rabies virus Nucleoprotein-RNA rings

In order to study the packaging of rabies virus RNA inside the viral nucleocapsid, rabies nucleoprotein was expressed in insect cells. In the cells, it binds to cellular RNA to form long, helical or short circular complexes, depending on the length of the bound RNA. The circular complexes contained from 9 up to 13 N-protomers per ring. Separation of the rings into defined size classes was impossible through regular column chromatographies or gradient centrifugation. The size classes could be separated by native polyacrylamide gel electrophoresis. A large-scale separation was achieved with a 4% native gel using a preparative electrophoresis apparatus. Crystallization trials were set up with N-RNA rings from three size classes and crystals were obtained in all cases. The best diffracting crystals, diffracting up to 6A, contained rings with 11 N-protomers plus an RNA molecule of 99 nucleotides. The diffraction limit was improved to 3.5A by air dehydration prior to flash freezing.

Structure and Function of RNA Replication

Contrary to their host cells, many viruses contain RNA as genetic material and hence encode an RNA-dependent RNA polymerase to replicate their genomes. This review discusses the present status of our knowledge on the structure of these enzymes and the mechanisms of RNA replication. The simplest viruses encode only the catalytic subunit of the replication complex, but other viruses also contribute a variable number of ancillary factors. These and other factors provided by the host cell play roles in the specificity and affinity of template recognition and the assembly of the replication complex. Usually, these host factors are involved in protein synthesis or RNA modification in the host cell, but they play roles in remodeling RNA-RNA, RNA-protein, and protein-protein interactions during virus RNA replication. Furthermore, viruses take advantage of and modify previous cell structural elements, frequently membrane vesicles, for the formation of RNA replication complexes.

Unravelling the complexities of respiratory syncytial virus RNA synthesis

Human respiratory syncytial virus (RSV) is the leading cause of paediatric respiratory disease and is the focus of antiviral- and vaccine-development programmes. These goals have been aided by an understanding of the virus genome architecture and the mechanisms by which it is expressed and replicated. RSV is a member of the order Mononegavirales and, as such, has a genome consisting of a single strand of negative-sense RNA. At first glance, transcription and genome replication appear straightforward, requiring self-contained promoter regions at the 3' ends of the genome and antigenome RNAs, short cis-acting elements flanking each of the genes and one polymerase. However, from these minimal elements, the virus is able to generate an array of capped, methylated and polyadenylated mRNAs and encapsidated antigenome and genome RNAs, all in the appropriate ratios to facilitate virus replication. The apparent simplicity of genome expression and replication is a consequence of considerable complexity in the polymerase structure and its cognate cis-acting sequences; here, our understanding of mechanisms by which the RSV polymerase proteins interact with signals in the RNA template to produce different RNA products is reviewed.

Structure of the vesicular stomatitis virus nucleoprotein-RNA complex

Vesicular stomatitis virus is a negative-stranded RNA virus. Its nucleoprotein (N) binds the viral genomic RNA and is involved in multiple functions including transcription, replication, and assembly. We have determined a 2.9 angstrom structure of a complex containing 10 molecules of the N protein and 90 bases of RNA. The RNA is tightly sequestered in a cavity at the interface between two lobes of the N protein. This serves to protect the RNA in the absence of polynucleotide synthesis. For the RNA to be accessed, some conformational change in the N protein should be necessary.

Crystal structure of the rabies virus nucleoprotein-RNA complex

Negative-strand RNA viruses condense their genome into a helical nucleoprotein-RNA complex, the nucleocapsid, which is packed into virions and serves as a template for the RNA-dependent RNA polymerase complex. The crystal structure of a recombinant rabies virus nucleoprotein-RNA complex, organized in an undecameric ring, has been determined at 3.5 angstrom resolution. Polymerization of the nucleoprotein is achieved by domain exchange between protomers, with flexible hinges allowing nucleocapsid formation. The two core domains of the nucleoprotein clamp around the RNA at their interface and shield it from the environment. RNA sequestering by nucleoproteins is likely a common mechanism used by negative-strand RNA viruses to protect their genomes from the innate immune response directed against viral RNA in human host cells at certain stages of an infectious cycle.

Initiation of encapsidation as evidenced by deoxycholate-treated Nucleocapsid protein in the Chandipura virus life cycle

Encapsidation of nascent genome RNA into an RNase-resistant form by nucleocapsid protein, N is a necessary step in the rhabdoviral life cycle. However, the precise mechanism for viral RNA specific yet processive encapsidation remains elusive. Using Chandipura virus as a model system, we examined RNA binding specificity of N protein and dissected the biochemical steps involved in the rhabdoviral encapsidation process. Our analysis suggested that N protein in its monomeric form specifically binds to the first half of the leader RNA in a 1:1 complex, whereas, oligomerization imparts a broad RNA binding specificity. We also observed that viral P protein and dissociating detergent deoxycholate, both were able to maintain N in a monomeric form and thus promote specific RNA recognition. Finally, use of a minigenome length RNA in an in vitro encapsidation assay revealed the monomeric N and not its oligomeric counterpart, to be the true encapsidating unit. Based on our observations, we propose a model to explain encapsidation that involves two discrete biochemically separable steps, initiation and elongation.

Paramyxovirus mRNA editing, the "rule of six" and error catastrophe: a hypothesis

The order Mononegavirales includes three virus families that replicate in the cytoplasm: the Paramyxoviridae, composed of two subfamilies, the Paramyxovirinae and Pneumovirinae, the Rhabdoviridae and the Filoviridae. These viruses, also called non-segmented negative-strand RNA viruses (NNV), contain five to ten tandemly linked genes, which are separated by conserved junctional sequences that act as mRNA start and poly(A)/stop sites. For the NNV, downstream mRNA synthesis depends on termination of the upstream mRNA, and all NNV RNA-dependent RNA polymerases reiteratively copy ("stutter" on) a short run of template uridylates during transcription to polyadenylate and terminate their mRNAs. The RNA-dependent RNA polymerase of a subset of the NNV, all members of the Paramyxovirinae, also stutter in a very controlled fashion to edit their phosphoprotein gene mRNA, and Ebola virus, a filovirus, carries out a related process on its glycoprotein mRNA. Remarkably, all viruses that edit their phosphoprotein mRNA are also governed by the "rule of six", i.e. their genomes must be of polyhexameric length (6n+0) to replicate efficiently. Why these two seemingly unrelated processes are so tightly linked in the Paramyxovirinae has been an enigma. This paper will review what is presently known about these two processes that are unique to viruses of this subfamily, and will discuss whether this enigmatic linkage could be due to the phenomenon of RNA virus error catastrophe.

Hantavirus nucleocapsid protein: a multifunctional molecule with both housekeeping and ambassadorial duties

In recent years important progress has been made studying the nucleocapsid (N) protein of hantaviruses. The N protein presents a good example of a multifunctional viral macromolecule. It is a major structural component of a virion that encapsidates viral RNA (vRNA). It also interacts with the virus polymerase (L protein) and one of the glycoproteins. On top of these "house keeping" duties, the N protein performs interactive "ambassadorial" functions interfering with important regulatory pathways in the infected cells.

Visualizing the RNA molecule in the bacterially expressed vesicular stomatitis virus nucleoprotein-RNA complex

Packaging of the RNA molecule in viruses is important for the preservation and expression of viral genomic information. The vesicular stomatitis virus (VSV) nucleoproteins are kept associated with its negative-strand RNA during the mRNA synthesis and replication, in contrast to the tobacco mosaic virus whose nucleoproteins are released from RNA. It has been a puzzle how the VSV RNA is packaged to meet the contradicting requirements of protection and the accessibility to the polymerase. We report an 18 A resolution structure of the recombinant nucleoprotein-RNA complex determined by single-particle electron microscopy. In the 3D density map, a ring of density is resolved on the inner surface and the density is proposed to be the RNA. The RNA is located on the inner surface of the decameric complex near the top end. This is dramatically different from the RNA packaging in TMV, but consistent with previously published biochemical findings.

The 12 A structure of trypsin-treated measles virus N-RNA

Recombinant measles virus nucleoprotein (N) was produced in insect cells where it bound to cellular RNA to form helical N-RNA structures. These structures were observed by electron microscopy but were too flexible for high-resolution image analysis. Removal of the C-terminal tail of N by trypsin treatment resulted in structures that were much more rigid and seemed more regular. Several methods of image analysis were employed in order to make a helical reconstruction of the digested N-RNA. During this analysis, it became clear that the apparently regular coils of digested N-RNA consisted of a series of closely related helical states. The iterative helical real space reconstruction method allowed the identification of two helical states for which a reconstruction could be calculated. The model with the highest resolution shows N monomers that consist of three domains and that are connected to their neighbours by two narrow connections, one close to the helical axis and another toward the middle of the monomers. There are no connections between N molecules in subsequent helical turns. After labelling the RNA in the structure with cis-platinum, the connection closest to the helical axis increased in density, suggesting the position of the RNA. The shapes of the monomers of the nucleoproteins of influenza virus, rabies virus (both determined before) and that of measles virus (determined here) are all similar, whereas the overall shapes of their respective N-RNAs (nucleocapsids) is very different. This is probably due to the position and number of the connections between the N subunits in the N-RNA, one for influenza virus allowing much flexibility, two for rabies virus at either end of the N molecules leading to ribbons and two for measles virus leading to the typical paramyxovirus helical nucleocapsid.

Contributions of vesicular stomatitis virus to the understanding of RNA virus evolution

Vesicular stomatitis virus has been a preferred system to study evolution for several decades. New approaches to antiviral treatment, such as lethal mutagenesis, stem from investigations done with VSV. Recent work has shed new light in the way we view neutrality, a fundamental concept to understand the evolutionary history of RNA viruses.

Chemical modification of nucleotide bases and mRNA editing depend on hexamer or nucleoprotein phase in Sendai virus nucleocapsids

The minus-strand genome of Sendai virus is an assembly of the nucleocapsid protein (N) and RNA, in which each N subunit is associated with precisely 6 nt. Only genomes that are a multiple of 6 nt long replicate efficiently or are found naturally, and their replication promoters contain sequence elements with hexamer repeats. Paramyxoviruses that are governed by this hexamer rule also edit their P gene mRNA during its synthesis, by G insertions, via a controlled form of viral RNA polymerase "stuttering" (pseudo-templated transcription). This stuttering is directed by a cis-acting sequence (3' UNN UUUUUU CCC), whose hexamer phase is conserved within each virus group. To determine whether the hexamer phase of a given nucleotide sequence within nucleocapsids affected its sensitivity to chemical modification, and whether hexamer phase of the mRNA editing site was important for the editing process, we prepared a matched set of viruses in which a model editing site was displaced 1 nt at a time relative to the genome ends. The relative abilities of these Sendai viruses to edit their mRNAs in cell culture infections were examined, and the ability of DMS to chemically modify the nucleotides of this cis-acting signal within resting viral nucleocapsids was also studied. Cytidines at hexamer phases 1 and 6 were the most accessible to chemical modification, whereas mRNA editing was most extensive when the stutter-site C was in positions 2 to 5. Apparently, the N subunit imprints the nucleotide sequence it is associated with, and affects both the initiation of viral RNA synthesis and mRNA editing. The N-subunit assembly thus appears to superimpose another code upon the genetic code.

Given the opportunity, the Sendai virus RNA-dependent RNA polymerase could as well enter its template internally

The negative-stranded RNA viral genome is an RNA-protein complex of helicoidal symmetry, resistant to nonionic detergent and high salt, in which the RNA is protected from RNase digestion. The 15,384 nucleotides of the Sendai virus genome are bound to 2,564 subunits of the N protein, each interacting with six nucleotides so tightly that the bases are poorly accessible to soluble reagents. With such a uniform structure, the question of template recognition by the viral RNA polymerase has been raised. In a previous study, the N-phase context has been proposed to be crucial for this recognition, a notion referring to the importance of the position in which the nucleotides interact with the N protein. The N-phase context ruled out the role of the template 3'-OH congruence, a feature resulting from the obedience to the rule of six that implies the precise interaction of the last six 3'-OH nucleotides with the last N protein. The N-phase context then allows prediction of the recognition by the RNA polymerase of a replication promoter sequence even if internally positioned, a promoter which normally lies at the template extremity. In this study, with template minireplicons bearing tandem replication promoters separated by intervening sequences, we present data that indeed show that initiation of RNA synthesis takes place at the internal promoter. This internal initiation can best be interpreted as the result of the polymerase entering the template at the internal promoter. In this way, the data are consistent with the importance of the N-phase context in template recognition. Moreover, by introducing between the two promoters a stretch of 10 A residues which represent a barrier for RNA synthesis, we found that the ability of the RNA polymerase to cross this barrier depends on the type of replication promoter, strong or weak, that the RNA polymerase starts on, a sign that the RNA polymerase may be somehow imprinted in its activity by the nature of the promoter on which it starts synthesis.

Morphology of Marburg virus NP-RNA

When Marburg virus (MBGV) nucleoprotein (NP) is expressed in insect cells, it binds to cellular RNA and forms NP-RNA complexes such as insect cell-expressed nucleoproteins from other nonsegmented negative-strand RNA viruses. Recombinant MBGV NP-RNA forms loose coils that resemble rabies virus N-RNA. MBGV NP monomers are rods that are spaced along the coil similar to the nucleoprotein monomers of the rabies virus N-RNA. High salt treatment induces tight coiling of the MBGV NP-RNA, again a characteristic observed for other nonsegmented negative-strand virus N-RNAs. Electron microscopy of fixed Marburg virus particles shows that the viral nucleocapsid has a smaller diameter than the free, recombinant NP-RNA. This difference in helical parameters could be caused by the interaction of other viral proteins with the NP-RNA. A similar but opposite phenomenon is observed for rhabdovirus nucleocapsids that are condensed by the viral matrix protein upon which they acquire a larger diameter. Finally, there appears to be an extensive and regular protein scaffold between the viral nucleocapsid and the membrane that seems not to exist in the other negative-strand RNA viruses.

"Rule of six": how does the Sendai virus RNA polymerase keep count?

The "rule of six" stipulates that the Paramyxovirus RNA polymerase efficiently replicates only viral genomes counting 6n + 0 nucleotides. Because the nucleocapsid proteins (N) interact with 6 nucleotides, an exact nucleotide-N match at the RNA 3'-OH end (3'-OH congruence) may be required for recognition of an active replication promoter. Alternatively, assuming that the six positions for the interaction of N with the nucleotides are not equivalent, the nucleotide position relative to N may be critical (N phase context). The replication abilities of various minireplicons, designed so that the 3'-OH congruence could be discriminated from the N phase context, were studied. The results strongly suggest that the application of the rule of six depends on the recognition of nucleotides positioned in the proper N phase context.

Structure of recombinant rabies virus nucleoprotein-RNA complex and identification of the phosphoprotein binding site

Rabies virus nucleoprotein (N) was produced in insect cells, in which it forms nucleoprotein-RNA (N-RNA) complexes that are biochemically and biophysically indistinguishable from rabies virus N-RNA. We selected recombinant N-RNA complexes that were bound to short insect cellular RNAs which formed small rings containing 9 to 11 N monomers. We also produced recombinant N-RNA rings and viral N-RNA that were treated with trypsin and that had lost the C-terminal quarter of the nucleoprotein. Trypsin-treated N-RNA no longer bound to recombinant rabies virus phosphoprotein (the viral polymerase cofactor), so the presence of the C-terminal part of N is needed for binding of the phosphoprotein. Both intact and trypsin-treated recombinant N-RNA rings were analyzed with cryoelectron microscopy, and three-dimensional models were calculated from single-particle image analysis combined with back projection. Nucleoprotein has a bilobed shape, and each monomer has two sites of interaction with each neighbor. Trypsin treatment cuts off part of one of the lobes without shortening the protein or changing other structural parameters. Using negative-stain electron microscopy, we visualized phosphoprotein bound to the tips of the N-RNA rings, most likely at the site that can be removed by trypsin. Based on the shape of N determined here and on structural parameters derived from electron microscopy on free rabies virus N-RNA and from nucleocapsid in virus, we propose a low-resolution model for rabies virus N-RNA in the virus.

Establishment of a rescue system for canine distemper virus

Canine distemper virus (CDV) has been rescued from a full-length cDNA clone. Besides Measles virus (MV) and Rinderpest virus, a third morbillivirus is now available for genetic analysis using reverse genetics. A plasmid p(+)CDV was constructed by sequential cloning using the Onderstepoort vaccine strain large-plaque-forming variant. The presence of a T7 promoter allowed transcription of full-length antigenomic RNA by a T7 RNA polymerase, which was provided by a host range mutant of vaccinia virus (MVA-T7). Plasmids expressing the nucleocapsid protein, the phosphoprotein, and the viral RNA-dependent RNA polymerase, also under control of a T7 promoter, have been generated. Infection of HeLa cells with MVA-T7 and subsequent transfection of p(+)CDV plus the helper plasmids led to syncytium formation and release of infectious recombinant (r) CDV. Comparison of the rescued virus with the parental virus revealed no major differences in the progression of infection or in the shape and size of syncytia. A genetic tag, consisting of two nucleotide changes within the coding region of the L protein, has been identified in the rCDV genome. Expression by rCDV of all the major viral structural proteins has been demonstrated by immunofluorescence.

Study of the assembly of vesicular stomatitis virus N protein: role of the P protein

To derive structural information about the vesicular stomatitis virus (VSV) nucleocapsid (N) protein, the N protein and the VSV phosphoprotein (P protein) were expressed together in Escherichia coli. The N and P proteins formed soluble protein complexes of various molar ratios when coexpressed. The major N/P protein complex was composed of 10 molecules of the N protein, 5 molecules of the P protein, and an RNA. A soluble N protein-RNA oligomer free of the P protein was isolated from the N/P protein-RNA complex using conditions of lowered pH. The molecular weight of the N protein-RNA oligomer, 513,879, as determined by analytical ultracentrifugation, showed that it was composed of 10 molecules of the N protein and an RNA of approximately 90 nucleotides. The N protein-RNA oligomer had the appearance of a disk with outer diameter, inner diameter, and thickness of 148 +/- 10 A, 78 +/- 9 A, and 83 +/- 8 A, respectively, as determined by electron microscopy. RNA in the complexes was protected from RNase digestion and was stable at pH 11. This verified that N/P protein complexes expressed in E. coli were competent for encapsidation. In addition to coexpression with the full-length P protein, the N protein was expressed with the C-terminal 72 amino acids of the P protein. This portion of the P protein was sufficient for binding to the N protein, maintaining it in a soluble state, and for assembly of N protein-RNA oligomers. With the results provided in this report, we propose a model for the assembly of an N/P protein-RNA oligomer.