Expression of the Arabidopsis Xrn4p 5′–3′ exoribonuclease facilitates degradation of tombusvirus RNA and promotes rapid emergence of viral variants in plants

Self Cite

150

To study the replication of Tomato bushy stunt virus (TBSV), a small tombusvirus of plants, we have developed a cell-free system based on a Saccharomyces cerevisiae extract. The cell-free system was capable of performing a complete replication cycle on added plus-stranded TBSV replicon RNA (repRNA) that led to the production of ϳ30-fold-more plus-stranded progeny RNAs than the minus-stranded replication intermediate. The cell-free system also replicated the full-length TBSV genomic RNA, which resulted in production of subgenomic RNAs as well. The cell-free system showed high template specificity, since a mutated repRNA, minus-stranded repRNA, or a heterologous viral RNA could not be used as templates by the tombusvirus replicase. Similar to the in vivo situation, replication of the TBSV replicon RNA took place in a membraneous fraction, in which the viral replicase-RNA complex was RNase and protease resistant but sensitive to detergents. In addition to faithfully replicating the TBSV replicon RNA, the cell-free system was also capable of generating TBSV RNA recombinants with high efficiency. Altogether, tombusvirus replicase in the cell-free system showed features remarkably similar to those of the in vivo replicase, including carrying out a complete cycle of replication, high template specificity, and the ability to recombine efficiently.Plus-strand RNA [(ϩ)RNA] viruses replicate their genomes via a multistep process in the infected cells. After translation of the invading viral RNA, which leads to production of the viral replication proteins, the viral RNA is selected/recruited for replication. This is followed by the assembly of the viral replicase on subcellular membrane surfaces and complementary minus-strand synthesis. Then, the (Ϫ)RNA intermediate is used by the viral replicase to synthesize an excess amount of new (ϩ)RNA progeny, which are released from the site of replication to the cytosol (1, 24). To understand the mechanism of (ϩ)RNA virus replication, several model RNA viruses, including plant viruses, have been exploited in this intensively studied area in recent years (1,3,19,39,44).Assembling the viral replicase complex on the cytosolic surfaces of intracellular membranes is a poorly understood process (39). The viral replicase consists of virally encoded RNAdependent RNA polymerase (RdRp) and viral auxiliary replication proteins as well as co-opted host proteins, whose contribution to the viral replication process is the least understood. To identify the host factors present in the viral replicase complex, a recent proteomics approach revealed that 4 to 10 host proteins, including molecular chaperone Ssa1/2p (yeast homologue of heat shock protein 70 [Hsp70]), Tdh2/3p (glyceraldehyde-3-phosphate dehydrogenase, an RNA binding protein), and Pdc1p (pyruvate decarboxylase), were part of the highly purified functional tombusvirus replicase (41, 47). Similarly, the purified Tobacco mosaic virus (ToMV) replicase preparation contained at least four host proteins, including RNA-binding protein GCD10, whic...

Section: Resultsmentioning

confidence: 60%

Section: Resultsmentioning

confidence: 78%

Authentic Replication and Recombination of Tomato Bushy Stunt Virus RNA in a Cell-Free Extract from Yeast

Pogany

Nagy

2008

Self Cite

150

“…These RNA recombinants in the TBSV system are generated via the template-switching mechanism by the viral replicase using viral repRNA templates that are cleaved by cellular endo-and exoribonucleases (schematically shown in Fig. 1A) (14,15,21,22,24,50,51). In addition, yeast expressing the rpn11 -14 ts mutant as the only copy of Rpn11p led to an ϳ11-fold increase in TBSV recRNA levels at the semipermissive temperature (Fig.…”

Section: Rpn11 Mutants Support Increased Level Of Tombusvirus Rna Recmentioning

confidence: 99%

“…For example, the cytosolic Xrn1p 5=-to-3= exoribonuclease (Xrn4 in plants) suppresses TBSV recombination via rapidly degrading TBSV RNAs (degRNAs) (Fig. 1A) cleaved by cellular endoribonucleases (22)(23)(24)(25). Thus, the degRNAs have only limited time to participate in RNA recombination in wild-type (wt) cells.…”

mentioning

confidence: 99%

The Proteasomal Rpn11 Metalloprotease Suppresses Tombusvirus RNA Recombination and Promotes Viral Replication via Facilitating Assembly of the Viral Replicase Complex

Prasanth

Barajas

Nagy

2015

Self Cite

RNA viruses co-opt a large number of cellular proteins that affect virus replication and, in some cases, viral genetic recombination. RNA recombination helps viruses in an evolutionary arms race with the host's antiviral responses and adaptation of viruses to new hosts. Tombusviruses and a yeast model host are used to identify cellular factors affecting RNA virus replication and RNA recombination. In this study, we have examined the role of the conserved Rpn11p metalloprotease subunit of the proteasome, which couples deubiquitination and degradation of proteasome substrates, in tombusvirus replication and recombination in Saccharomyces cerevisiae and plants. Depletion or mutations of Rpn11p lead to the rapid formation of viral RNA recombinants in combination with reduced levels of viral RNA replication in yeast or in vitro based on cell extracts. Rpn11p interacts with the viral replication proteins and is recruited to the viral replicase complex (VRC). Analysis of the multifunctional Rpn11p has revealed that the primary role of Rpn11p is to act as a "matchmaker" that brings the viral p92 pol replication protein and the DDX3-like Ded1p/RH20 DEAD box helicases into VRCs. Overexpression of Ded1p can complement the defect observed in rpn11 mutant yeast by reducing TBSV recombination. This suggests that Rpn11p can suppress tombusvirus recombination via facilitating the recruitment of the cellular Ded1p helicase, which is a strong suppressor of viral recombination, into VRCs. Overall, this work demonstrates that the co-opted Rpn11p, which is involved in the assembly of the functional proteasome, also functions in the proper assembly of the tombusvirus VRCs. IMPORTANCERNA viruses evolve rapidly due to genetic changes based on mutations and RNA recombination. Viral genetic recombination helps viruses in an evolutionary arms race with the host's antiviral responses and facilitates adaptation of viruses to new hosts. Cellular factors affect viral RNA recombination, although the role of the host in virus evolution is still understudied. In this study, we used a plant RNA virus, tombusvirus, to examine the role of a cellular proteasomal protein, called Rpn11, in tombusvirus recombination in a yeast model host, in plants, and in vitro. We found that the cellular Rpn11 is subverted for tombusvirus replication and Rpn11 has a proteasome-independent function in facilitating viral replication. When the Rpn11 level is knocked down or a mutated Rpn11 is expressed, then tombusvirus RNA goes through rapid viral recombination and evolution. Taken together, the results show that the co-opted cellular Rpn11 is a critical host factor for tombusviruses by regulating viral replication and genetic recombination. V iruses and their hosts go through continuous evolution, including a genetic arms race between viral and host factors that decides if the given virus could accomplish successful infection in that host. RNA virus adaptation to the host is facilitated by the ability of RNA viruses to evolve rapidly due to high-frequency muta...

“…Empty vector pGD-35S was used as a negative control. Transformed Agrobacterium cells were selected, grown, and infiltrated into young N. benthamiana leaves as described earlier (63). Agrobacterium cultures transformed with pGD-p19 with an optical density at 600 nm (OD 600 ) of 0.5 were mixed separately with Agrobacterium cultures, transformed with pGD-35S, pGD-dnBro1, pGD-dnVps23-1, or pGD-dnVps23-2 (OD 600 , 0.5) or mixtures of cultures pGD-dnBro1 with pGD-dnVps23-1 or pGD-dnBro1 with pGDdnVps23-1 (OD 600 , 0.25 each).…”

mentioning

confidence: 99%

Role of Viral RNA and Co-opted Cellular ESCRT-I and ESCRT-III Factors in Formation of Tombusvirus Spherules Harboring the Tombusvirus Replicase

Kovalev

Martín

Pogany

et al. 2016

Self Cite

Plus-stranded RNA viruses induce membrane deformations in infected cells in order to build viral replication complexes (VRCs).One of the intriguing aspects of VRC formation is the need for extensive subcellular membrane deformations. Accordingly, (ϩ)RNA viruses replicate in various membranous structures that could be formed from various membranes, such as endoplasmic reticulum, mitochondria, endosome, chloroplast, peroxisome, and plasma membranes, or induced de novo (1,(3)(4)(5). Membrane deformations are possibly induced by co-opted cellular phospholipid kinases, local enrichment of sterols, and subverted membrane-bending proteins, such as ESCRT factors, reticulons, and amphiphysins (6-12).A major type of subcellular membrane deformation induced by some (ϩ)RNA viruses is represented by vesicle-like small invaginations with single narrow openings toward the cytosol (13,14). These structures, called spherules, contain the membranebound VRCs consisting of viral and co-opted cellular proteins in the infected cells (1)(2)(3)(15)(16)(17)(18). The membranous spherule structures sequester all the replication factors into a confined cytosolic area and likely protect the fragile viral (ϩ)RNA from degradation