The Glycolytic Pyruvate Kinase Is Recruited Directly into the Viral Replicase Complex to Generate ATP for RNA Synthesis.

Viruses accomplish their replication by exploiting many cellular resources, including metabolites and energy. Similarly to other (+)RNA viruses, tomato bushy stunt virus (TBSV) induces major changes in infected cells. However, the source of energy required to fuel TBSV replication is unknown. We find that TBSV co-opts the cellular glycolytic ATP-generating pyruvate kinase (PK) directly into the viral replicase complex to boost progeny RNA synthesis. The co-opted PK generates high levels of ATP within the viral replication compartment at the expense of a reduction in cytosolic ATP pools. The ATP generated by the co-opted PK is used to promote the helicase activity of recruited cellular DEAD-box helicases, which are involved in the production of excess viral (+)RNA progeny. Altogether, recruitment of PK and local production of ATP within the replication compartment allow the virus replication machinery an access to plentiful ATP, facilitating robust virus replication.

Noncanonical role for the host Vps4 AAA+ ATPase ESCRT protein in the formation of Tomato bushy stunt virus replicase.

Assembling of the membrane-bound viral replicase complexes (VRCs) consisting of viral- and host-encoded proteins is a key step during the replication of positive-stranded RNA viruses in the infected cells. Previous genome-wide screens with Tomato bushy stunt tombusvirus (TBSV) in a yeast model host have revealed the involvement of eleven cellular ESCRT (endosomal sorting complexes required for transport) proteins in viral replication. The ESCRT proteins are involved in endosomal sorting of cellular membrane proteins by forming multiprotein complexes, deforming membranes away from the cytosol and, ultimately, pinching off vesicles into the lumen of the endosomes. In this paper, we show an unexpected key role for the conserved Vps4p AAA+ ATPase, whose canonical function is to disassemble the ESCRT complexes and recycle them from the membranes back to the cytosol. We find that the tombusvirus p33 replication protein interacts with Vps4p and three ESCRT-III proteins. Interestingly, Vps4p is recruited to become a permanent component of the VRCs as shown by co-purification assays and immuno-EM. Vps4p is co-localized with the viral dsRNA and contacts the viral (+)RNA in the intracellular membrane. Deletion of Vps4p in yeast leads to the formation of crescent-like membrane structures instead of the characteristic spherule and vesicle-like structures. The in vitro assembled tombusvirus replicase based on cell-free extracts (CFE) from vps4Δ yeast is highly nuclease sensitive, in contrast with the nuclease insensitive replicase in wt CFE. These data suggest that the role of Vps4p and the ESCRT machinery is to aid building the membrane-bound VRCs, which become nuclease-insensitive to avoid the recognition by the host antiviral surveillance system and the destruction of the viral RNA. Other (+)RNA viruses of plants and animals might also subvert Vps4p and the ESCRT machinery for formation of VRCs, which require membrane deformation and spherule formation.

The p33 auxiliary replicase protein of Cucumber necrosis virus targets peroxisomes and infection induces de novo peroxisome formation from the endoplasmic reticulum.

Tombusviruses replicate on pre-existing organelles such as peroxisomes or mitochondria, the membranes of which become extensively reorganized into multivesicular bodies (MVBs) during the infection process. Cucumber necrosis virus (CNV) has previously been shown to replicate in association with peroxisomes in yeast. We show that CNV induces MVBs from peroxisomes in infected plants and that GFP-tagged p33 auxiliary replicase protein colocalizes with YFP(SKL), a peroxisomal marker. Most remarkably, the ER of CNV infected Nicotiana benthamiana 16C plants undergoes a dramatic reorganization producing numerous new peroxisome-like structures that associate with CNV p33, thus likely serving as a new site for viral RNA replication. We also show that plants agroinfiltrated with p33 develop CNV-like necrotic symptoms which are associated with increased levels of peroxide. Since peroxisomes are a site for peroxide catabolism, and peroxide is known to induce plant defense responses, we suggest that dysfunctional peroxisomes contribute to CNV induced necrosis.

A unique N-terminal sequence in the Carnation Italian ringspot virus p36 replicase-associated protein interacts with the host cell ESCRT-I component Vps23.

UNLABELLED: Like most positive-strand RNA viruses, infection by plant tombusviruses results in extensive rearrangement of specific host cell organelle membranes that serve as the sites of viral replication. The tombusvirus Tomato bushy stunt virus (TBSV) replicates within spherules derived from the peroxisomal boundary membrane, a process that involves the coordinated action of various viral and cellular factors, including constituents of the endosomal sorting complex required for transport (ESCRT). ESCRT is comprised of a series of protein subcomplexes (i.e., ESCRT-0 -I, -II, and -III) that normally participate in late endosome biogenesis and some of which are also hijacked by certain enveloped retroviruses (e.g., HIV) for viral budding from the plasma membrane. Here we show that the replication of Carnation Italian ringspot virus (CIRV), a tombusvirus that replicates at mitochondrial membranes also relies on ESCRT. In plant cells, CIRV recruits the ESCRT-I protein, Vps23, to mitochondria through an interaction that involves a unique region in the N terminus of the p36 replicase-associated protein that is not conserved in TBSV or other peroxisome-targeted tombusviruses. The interaction between p36 and Vps23 also involves the Vps23 C-terminal steadiness box domain and not its N-terminal ubiquitin E2 variant domain, which in the case of TBSV (and enveloped retroviruses) mediates the interaction with ESCRT. Overall, these results provide evidence that CIRV uses a unique N-terminal sequence for the recruitment of Vps23 that is distinct from those used by TBSV and certain mammalian viruses for ESCRT recruitment. Characterization of this novel interaction with Vps23 contributes to our understanding of how CIRV may have evolved to exploit key differences in the plant ESCRT machinery. IMPORTANCE: Positive-strand RNA viruses replicate their genomes in association with specific host cell membranes. To accomplish this, cellular components responsible for membrane biogenesis and modeling are appropriated by viral proteins and redirected to assemble membrane-bound viral replicase complexes. The diverse pathways leading to the formation of these replication structures are poorly understood. We have determined that the cellular ESCRT system that is normally responsible for mediating late endosome biogenesis is also involved in the replication of the tombusvirus Carnation Italian ringspot virus (CIRV) at mitochondria. Notably, CIRV recruits ESCRT to the mitochondrial outer membrane via an interaction between a unique motif in the viral protein p36 and the ESCRT component Vps23. Our findings provide new insights into tombusvirus replication and the virus-induced remodeling of plant intracellular membranes, as well as normal ESCRT assembly in plants.

Cyclophilin A binds to the viral RNA and replication proteins, resulting in inhibition of tombusviral replicase assembly.

Replication of plus-stranded RNA viruses is greatly affected by numerous host-encoded proteins that act as restriction factors. Cyclophilins, which are a large family of cellular prolyl isomerases, have been found to inhibit Tomato bushy stunt tombusvirus (TBSV) replication in a Saccharomyces cerevisiae model based on genome-wide screens and global proteomics approaches. In this report, we further characterize single-domain cyclophilins, including the mammalian cyclophilin A and plant Roc1 and Roc2, which are orthologs of the yeast Cpr1p cyclophilin, a known inhibitor of TBSV replication in yeast. We found that recombinant CypA, Roc1, and Roc2 strongly inhibited TBSV replication in a cell-free replication assay. Additional in vitro studies revealed that CypA, Roc1, and Roc2 cyclophilins bound to the viral replication proteins, and CypA and Roc1 also bound to the viral RNA. These interactions led to inhibition of viral RNA recruitment, the assembly of the viral replicase complex, and viral RNA synthesis. A catalytically inactive mutant of CypA was also able to inhibit TBSV replication in vitro due to binding to the replication proteins and the viral RNA. Overexpression of CypA and its mutant in yeast or plant leaves led to inhibition of tombusvirus replication, confirming that CypA is a restriction factor for TBSV. Overall, the current work has revealed a regulatory role for the cytosolic single-domain Cpr1-like cyclophilins in RNA virus replication.

In vitro assembly of the Tomato bushy stunt virus replicase requires the host Heat shock protein 70.

To gain insights into the functions of a viral RNA replicase, we have assembled in vitro and entirely from nonplant sources, a fully functional replicase complex of Tomato bushy stunt virus (TBSV). The formation of the TBSV replicase required two purified recombinant TBSV replication proteins, which were obtained from E. coli, the viral RNA replicon, rATP, rGTP, and a yeast cell-free extract. The in vitro assembly of the replicase took place in the membraneous fraction of the yeast extract, in which the viral replicase-RNA complex became RNase- and proteinase-resistant. The assembly of the replicase complex required the heat shock protein 70 (Hsp70 = yeast Ssa1/2p) present in the soluble fraction of the yeast cell-free extract. The assembled TBSV replicase performed a complete replication cycle, synthesizing RNA complementary to the provided RNA replicon and using the complementary RNA as template to synthesize new TBSV replicon RNA.

Proteomics analysis of the tombusvirus replicase: Hsp70 molecular chaperone is associated with the replicase and enhances viral RNA replication.

Plus-strand RNA virus replication occurs via the assembly of viral replicase complexes involving multiple viral and host proteins. To identify host proteins present in the cucumber necrosis tombusvirus (CNV) replicase, we affinity purified functional viral replicase complexes from yeast. Mass spectrometry analysis of proteins resolved by two-dimensional gel electrophoresis revealed the presence of CNV p33 and p92 replicase proteins as well as four major host proteins in the CNV replicase. The host proteins included the Ssa1/2p molecular chaperones (yeast homologues of Hsp70 proteins), Tdh2/3p (glyceraldehyde-3-phosphate dehydrogenase, an RNA-binding protein), Pdc1p (pyruvate decarboxylase), and an unknown approximately 35-kDa acidic protein. Copurification experiments demonstrated that Ssa1p bound to p33 replication protein in vivo, and surface plasmon resonance measurements with purified recombinant proteins confirmed this interaction in vitro. The double mutant strain (ssa1 ssa2) showed 75% reduction in viral RNA accumulation, whereas overexpression of either Ssa1p or Ssa2p stimulated viral RNA replication by approximately threefold. The activity of the purified CNV replicase correlated with viral RNA replication in the above-mentioned ssa1 ssa2 mutant and in the Ssa overexpression strains, suggesting that Ssa1/2p likely plays an important role in the assembly of the CNV replicase.

Single-chain antibodies against a plant viral RNA-dependent RNA polymerase confer virus resistance.

Crop loss due to viral diseases is still a major problem for agriculture today. We present a strategy to achieve virus resistance based on the expression of single-chain Fv fragments (scFvs) against a conserved domain in a plant viral RNA-dependent RNA polymerase (RdRp), a key enzyme in virus replication. The selected scFvs inhibited complementary RNA synthesis of different plant virus RdRps in vitro and virus replication in planta. Moreover, the scFvs also bound to the RdRp of the distantly related hepatitis C virus. T(1) and T(2) progeny of transgenic lines of Nicotiana benthamiana expressing different scFvs either in the cytosol or in the endoplasmic reticulum showed varying degrees of resistance against four plant viruses from different genera, three of which belong to the Tombusviridae family. Virus resistance based on antibodies to RdRps adds another tool to the repertoire for combating plant viruses.

Analysis of minimal promoter sequences for plus-strand synthesis by the Cucumber necrosis virus RNA-dependent RNA polymerase.

Tombusviruses are small, plus-sense, single-stranded RNA viruses of plants. A partially purified RNA-dependent RNA polymerase (RdRp) preparation of Cucumber necrosis virus (CNV), which is capable of de novo initiation of complementary RNA synthesis from either plus-strand or minus-strand templates, was used to dissect minimal promoter sequences for tombusviruses and their defective interfering (DI) RNAs. In vitro RdRp assay revealed that the core plus-strand initiation promoter included only the 3'-terminal 11 nucleotides. A hypothetical promoter-like sequence, which has been termed consensus sequence by Wu and White (1998, J. Virol. 72, 9897-9905), is recognized less efficiently by the CNV RdRp than the core plus-strand initiation promoter. The CNV RdRp can efficiently recognize the core plus-strand initiation promoter for a satellite RNA associated with the distantly related Turnip crinkle virus, while artificial AU- or GC-rich 3'-terminal sequences make poor templates in the in vitro assays. Comparison of the "strength" of minimal plus-strand and minus-strand initiation promoters reveals that the latter is almost twice as efficient in promoting complementary RNA synthesis. Template competition experiments, however, suggest that the minimal plus-strand initiation promoter makes an RNA template more competitive than the minimal minus-strand initiation promoter. Taken together, these results demonstrate that promoter recognition by the tombusvirus RdRp requires only short sequences present at the 3' end of templates.

Internal initiation by the cucumber necrosis virus RNA-dependent RNA polymerase is facilitated by promoter-like sequences.

Tombusviruses, small positive sense RNA viruses of plants, are replicated by the viral-coded RNA-dependent RNA polymerase (RdRp) in infected cells. An unusual feature of the tombusvirus RdRp that is partially purified from cucumber necrosis virus (CNV)-infected plants is the ability to initiate complementary RNA synthesis from several internal positions on minus-strand templates derived from DI RNAs ( Nagy and Pogany, 2000 ). In this study, we used template deletion, mutagenesis, and oligo-based inhibition of RNA synthesis to map the internal initiation sites observed with the in vitro CNV RdRp system. Comparing sequences around the internal initiation sites reveals that they have either (i) similar sequences to the core minus-strand initiation promoter; or (ii) similar structures to the core plus-strand initiation promoter. In addition, we find similarities among the internal initiation sites and the subgenomic RNA initiation sites. These similarities suggest that the mechanism of internal initiation is similar to initiation from the terminal core promoters or the putative subgenomic promoter sequences. We propose that internal initiation on full-length RNA templates may be important in defective interfering (DI) RNA formation/evolution by producing intermediate templates for RNA recombination in tombusviruses. This may explain why tombusviruses are frequently associated with DI RNAs.

Retention of a small replicase gene segment in tomato bushy stunt virus defective RNAs inhibits their helper-mediated trans-accumulation.

Tomato bushy stunt virus (TBSV) and other tombusviruses are notorious for their propensity to accumulate defective interfering RNAs (DIs) upon serial passage through experimental Nicotiana species. Hallmarks of this occurrence include reduced levels of helper RNA and protein accumulation and amelioration of the lethal necrosis induced upon infection of the host with the helper viruses alone. The objective of this study was to determine whether the prolific trans-accumulation of defective RNAs typically occurs for all replicase-deficient TBSV mutants, or if this process is influenced by internal cis-acting elements that have been excised from DIs. For this purpose, various replicase-deficient TBSV cDNA constructs were generated and their transcripts were tested for trans-accumulation competence in the presence of helper virus. The results revealed that a region of ca. 150 nucleotides near the center of the replicase gene, with a predicted high degree of secondary structure, was a potent inhibitor of trans-rescue (ITR) by TBSV. Relocation of the ITR into efficiently trans-replicating DIs inhibited their accumulation drastically, but only when inserted in the reverse orientation and with an intact 5' ITR-specific predicted hairpin structure. Insertion of the ITR element in the positive orientation yielded DI transcripts that were able to replicate, but failed to interfere noticeably with either accumulation of the helper RNA or the onset of the lethal necrosis phenotype in N. benthamiana. In conclusion, the ITR has an intrinsic capacity to inhibit trans-accumulation of defective RNAs, but its stringency and biological effects are strongly influenced by the overall sequence context.

Partial purification and characterization of Cucumber necrosis virus and Tomato bushy stunt virus RNA-dependent RNA polymerases: similarities and differences in template usage between tombusvirus and carmovirus RNA-dependent RNA polymerases.

Tombusviruses are small, plus-sense, single-stranded RNA viruses of plants. RNA-dependent RNA polymerases (RdRp) of two tombusviruses, Tomato bushy stunt virus (TBSV) and Cucumber necrosis virus (CNV), have been partially purified from infected Nicotiana benthamiana plants. The obtained RdRp complexes are capable of de novo initiation of complementary RNA synthesis using either plus- or minus-strand templates derived from tombusvirus defective interfering (DI) RNAs. In addition to template-sized products, shorter than full-length products were also generated efficiently apparently because of internal initiation of RNA synthesis by the tombusvirus RdRp. This property could be important for the formation of DI RNAs that are observed in tombusvirus infections. The tombusvirus RdRp is also able to use heterologous RNAs derived from satellite RNAs associated with Turnip crinkle virus (TCV) as templates. Generation of full-length, complementary RNA by the tombusvirus RdRp suggests that it can correctly and efficiently recognize the heterologous TCV-specific promoters. Reduced generation of a 3'-terminal extension product in the preceding assay suggests that the previously characterized replication enhancer present in sat-RNA C (Nagy et al., 1999, EMBO J. 18, 5653-5665) does not stimulate tombusvirus RdRp activity. Taken together, these results suggest that template usage by the tombusvirus and carmovirus RdRps are similar, but not identical.

The tomato bushy stunt virus replicase proteins are coordinately expressed and membrane associated.

Two open reading frames at the 5'-end of the tomato bushy stunt virus genomic RNA are predicted to encode a 33-kDa (p33) protein and its 92-kDa (p92) readthrough product. From amino acid sequence comparisons with other small single-stranded RNA viruses, these proteins resemble viral components of the replicase-transcriptase complex. To investigate the accumulation of these proteins in the infected cell, two chimeric proteins were produced that expressed either a portion of p33 or the carboxy-terminal "half" of p92 fused with glutathione S-transferase, and polyclonal ascites fluids specific to p33 or p92 were elicited in mice. As expected, the anti-p33 antibody recognized p33 and the p92 readthrough protein, but the anti-p92 antibody was specific for p92. Immunoblot analyses revealed that at an early stage of infection both proteins were associated with the membrane fractions isolated from virus-infected plants, but later in the infection, prior to collapse of the tissues, these proteins were also associated with the cytoplasmic fraction. At all time points in plants and protoplasts p33 was about 20-fold more abundant than p92. A series of mutations derived from an infectious cDNA clone demonstrated that both the p33 and the p92 proteins were required for replication in protoplasts and the ratio of the two proteins was maintained in the replication-competent mutants. The wild-type amber (UAG) and in vitro-generated ochre (UAA) readthrough codon derivatives replicated in protoplasts. However, the tyrosine mutants (UAC or UAU) that were predicted to express only p92 were not viable in protoplasts.

Evidence that ORF 1 and 2 are the only virus-encoded replicase genes of cymbidium ringspot tombusvirus.

The 33-kDa and its 92-kDa readthrough protein genes (open reading frames (ORFs) 1 and 2) of cymbidium ringspot tombusvirus (CyRSV) were introduced into Nicotiana benthamiana plants. Protoplasts derived from transgenic plants expressing the first two ORFs were inoculated with in vitro transcripts of defective interfering (DI) RNA. The efficient replication of input DI RNA, which is incapable of autonomous replication, confirmed the biological activity of the expressed viral replicase. In addition, in vitro transcripts of a genomic RNA deletion mutant clone encoding only ORFs 1 and 2 were able to replicate on their own and could support the replication of CyRSV DI RNAs in N. benthamiana protoplasts.

Immunodetection of the 33 K/92 K polymerase proteins in cymbidium ringspot virus-infected and in transgenic plant tissue extracts.

An antiserum was raised against the 33 K protein encoded by the 5' proximal gene of cymbidium ringspot tombusvirus RNA. This antiserum reacts specifically with the 33 K and 92 K proteins, which constitute the viral replicase, in CyRSV-infected Nicotiana benthamiana plants and in transgenic plants transformed with the full-length replicase gene. In inoculated leaves of infected plants, synthesis of the 33 K/92 K proteins stops ten days after inoculation, whereas in newly produced systemically infected leaves there was continuous production of these proteins. In transgenic plants, both proteins were detected showing that readthrough of the termination codon of the 33 K protein does not depend on the presence of the replicating virus. The subcellular localization of the 33 K/92 K proteins is similar in infected and transgenic plants. No correlation was found between the level of expression of integrated virus gene and level of resistance to the challenging virus.