Host factors involved in viral movement through plants

Seaberg, Bonnie Lee

15 May 2009

Tomato bushy stunt virus (TBSV) is a positive-sense single-stranded RNA virus. It encodes five open reading frames (ORFs), including two nested genes, expressing movement-associated proteins. One of these proteins, P22, interacts with a host transcription factor containing a homeodomain leucine-zipper motif, known as HFi22. Similar proteins of this type traffic their RNA from cell-to-cell, suggesting the possiblity that HFi22 is involved in the cell-to-cell movement of TBSV RNA. To further characterize the nature of the interaction between P22 and HFi22 on the cellular level, cellular fractionation experiments were conducted. To investigate the functional role of HFi22 in viral movement I attempted to inactivate its expression using a virus induced gene silencing system with a Tobacco rattle virus (TRV) vector. A final objective was based on the notion that different hosts can impact the stability of viruses used to express foreign genes of biotechnological interest. To compare virus stability in different hosts, TBSV expressing the green fluorescent protein (GFP) was inoculated onto various TBSV hosts, and infected leaf tissue was then used as inoculum to be rubbed onto a local lesion host. This technique made it possible to quantify the number of fluorescent foci versus total lesions. Results obtained for the first objective indicate that P22 and HFi22 co-fractionate in nucleus and membrane-enriched samples. In addition, it was found that HFi22 is largely conserved through a wide variety of plant species but not in lettuce, which was found to be compromised for effective virus spread. Control experiments for the second objective showed that plants were successfully silenced with TRV carrying the phytoene desaturase (PDS) gene resulting in photobleaching, however attempts to silence HFi22 have not yielded conclusive results. The results obtained for the third objective indicate there is a difference in how efficiently a foreign gene insert is maintained by TBSV in different host plants. In summary, the overall results of this research showed that host factors influence the host-virus interaction but their exact contributions remain elusive.

Tomato bushy stunt virus

P22

HFi22

Host factors involved in viral movement through plants

Seaberg, Bonnie Lee

15 May 2009

Tomato bushy stunt virus (TBSV) is a positive-sense single-stranded RNA virus. It encodes five open reading frames (ORFs), including two nested genes, expressing movement-associated proteins. One of these proteins, P22, interacts with a host transcription factor containing a homeodomain leucine-zipper motif, known as HFi22. Similar proteins of this type traffic their RNA from cell-to-cell, suggesting the possiblity that HFi22 is involved in the cell-to-cell movement of TBSV RNA. To further characterize the nature of the interaction between P22 and HFi22 on the cellular level, cellular fractionation experiments were conducted. To investigate the functional role of HFi22 in viral movement I attempted to inactivate its expression using a virus induced gene silencing system with a Tobacco rattle virus (TRV) vector. A final objective was based on the notion that different hosts can impact the stability of viruses used to express foreign genes of biotechnological interest. To compare virus stability in different hosts, TBSV expressing the green fluorescent protein (GFP) was inoculated onto various TBSV hosts, and infected leaf tissue was then used as inoculum to be rubbed onto a local lesion host. This technique made it possible to quantify the number of fluorescent foci versus total lesions. Results obtained for the first objective indicate that P22 and HFi22 co-fractionate in nucleus and membrane-enriched samples. In addition, it was found that HFi22 is largely conserved through a wide variety of plant species but not in lettuce, which was found to be compromised for effective virus spread. Control experiments for the second objective showed that plants were successfully silenced with TRV carrying the phytoene desaturase (PDS) gene resulting in photobleaching, however attempts to silence HFi22 have not yielded conclusive results. The results obtained for the third objective indicate there is a difference in how efficiently a foreign gene insert is maintained by TBSV in different host plants. In summary, the overall results of this research showed that host factors influence the host-virus interaction but their exact contributions remain elusive.

Tomato bushy stunt virus

P22

HFi22

A Study of Nicotiana Benthamiana Protein Interactions with Tomato Bushy Stunt Virus

McLachlan, Juanita

03 October 2013

Two Tomato bushy stunt virus (TBSV) proteins, P19 and P22, have been found to interact with the Nicotiana benthamiana host proteins Hin19 and HFi22 in yeast two,hybrid assays. To determine functional roles of these interacting host proteins, viral induced gene silencing (VIGS) was employed to knock,down their expression. TBSV has been demonstrated to activate a virus,specific antiviral response pathway in N. benthamiana. To characterize this pathway, the antiviral RNAi induced silencing complex (RISC) was isolated from TBSV-infected plants. Additionally, putative RISC-associated proteins were identified in silico and suggested roles for these have been identified through literature and database searches. A further aim was the identification of proteins that coimmunoprecipitate with the TBSV-induced RISC following RISC isolation. A primary aim of this investigation was to identify functional roles for host proteins that interact with the two TBSV 3-terminal encoded proteins, P22 and P19. Each of these has functional roles in viral movement and pathogenicity. In yeast two-hybrid assays, P22 has been shown to interact with HFi22 while P19 interacts with Hin19. VIGS was utilized in attempts to silence the expression of these two host proteins in order to determine their functional roles. VIGS-mediated suppression of the TBSV-interacting proteins Hin19 and HFi22 has not been accomplished. Despite multiple attempts and multiple approaches, these proteins have not been amenable to silencing. In light of this finding, it is proposed that rather than utilizing VIGS to down-regulate protein levels for Hin19 and HFi22, other approaches should be utilized. To characterize the TBSV-mediated RNAi pathway, functionally active antiviral RISC was purified from TBSV-infected N. benthamiana plants using ion-exchange chromatography. This RISC was found to be active only in the degradation of TBSV transcripts, indicating the specificity expected from a programmed RISC. Characterization and identification of proteins that copurify with RISC has not yet been accomplished, though in silico analysis has yielded over 150 putative RISC-associated proteins. Of these, a subset has been identified as highly likely candidates based upon function and/or homology to RISC-associated proteins in non-plant organisms, and a model for the TBSV-induced antiviral pathway has been proposed.

TBSV

Tomato bushy stunt virus

RNAi

vRISC

THE ROLE OF TOMBUSVIRUS REPLICASE PROTEINS AND RNA IN REPLICASE ASSEMBLY, REPLICATION AND RECOMBINATION

Panaviene, Zivile Sliesaraviciute

01 January 2004

Tombusviruses are single, positive strand RNA viruses of plants, often associated with parasitic defective interfering (DI) RNAs. Two viral- coded gene products, namely p33 and p92, are required for tombusvirus replication. The overlapping domains of p33 and p92 contain an arginine/proline-rich (RPR) RNA binding motif. In this study, the role of RPR motif and viral RNA in tombusvirus replication and recombination, as well as involvement of viral RNA in tombusvirus replicase assembly was examined. Using site-directed mutagenesis I generated a series of RPR mutants of Cucumber necrosis tombusvirus (CNV). Analysis of RPR mutants defined that wild type RPR motif, especially two of the four arginines, were required for efficient RNA binding in vitro, for replication of tombusviruses, their associated DI RNAs, subgenomic (sg)RNA synthesis and DI RNA recombination in vivo. Experiments using a two-component tombusvirus replication system showed that RPR motif is critical for functions of both p33 and p92 in replication, but its role in these proteins might not be identical. Recombination studies using a novel tombusvirus three-component system revealed that mutations in RPR motif of p33 replicase protein resulted in an altered viral RNA recombination rate. Identified DI RNA recombinants were mostly imprecise, with recombination sites clustered around a replication enchancer and an additional putative cis-acting element that might facilitate the template switching events by the tombusvirus replicase. To study the role of RNA during the assembly of functional tombusvirus replicase, recombinant CNV replicase that showed similar properties to plant-derived CNV replicase was purified from Saccharomyces cerevisiae. When in addition to p33 and p92 proteins DI RNA was co-expressed in yeast cells, the isolated replicase activity was increased ~40 fold. Further studies defined RNA motifs within two short DI RNA regions that enhanced active CNV replicase formation. In summary, this study showed that the conserved RNA binding motif of the tombusvirus replicase proteins and viral RNA are involved in replicase assembly, viral RNA replication, subgenomic RNA synthesis and RNA recombination. This data shed new light on the complex roles of the viral elements in replication, and will help future studies aimed at interfering with viral infections.

IDENTIFICATION OF VIRAL AND HOST FACTORS INVOLVED IN TOMBUSVIRUS REPLICATION AND RECOMBINATION

Shapka, Natalia

01 January 2006

Rapid evolution of RNA viruses with mRNA-sense genomes is a major concern to health and economic welfare due to the devastating diseases these viruses inflict on humans, animals and plants. Rapid viral RNA evolution is frequently due to RNA recombination, which can be facilitated by recombination signals present in viral RNAs. Among such signals are short sequences with high AU contents that constitute recombination hot spots in Brome mosaic virus (BMV) and retroviruses. We have demonstrated that a defective interfering (DI) RNA, a model template associated with Tomato bushy stunt virus (TBSV), a tombusvirus, undergoes frequent recombination in plants and protoplast cells when it carries the AU-rich hot spot sequence from BMV. Similar to the situation with BMV, most of the recombination junction sites in the DI RNA recombinants were found within the AU-rich region. Our results support the idea that common AU-rich recombination signals might promote interviral recombination between unrelated viruses. To test if host genes can affect the evolution of RNA viruses, we used a Saccharomyces cerevisiae single-gene deletion library, which includes ~80% of yeast genes, in RNA recombination studies based on a small viral replicon RNA derived from TBSV. The genome-wide screen led to the identification of five host genes, whose absence resulted in rapid generation of novel viral RNA recombinants. Thus, these genes normally suppress viral RNA recombination, but in their absence hosts become viral recombination hotbeds. Four of the five recombination suppressor genes are likely involved in RNA degradation, suggesting that RNA degradation could play a role in viral RNA recombination. Overall, our results demonstrate for the first time that a set of host genes have major effect on RNA virus recombination and evolution. Replication of the non-segmented, plus-stranded RNA genome of Cucumber necrosis tombusvirus (CNV) requires two essential overlapping viral-coded replication proteins, the p33 replication co-factor and the p92 RNA-dependent RNA polymerase. We have demonstrated that p33 is phosphorylated in vivo and in vitro by a membrane-bound plant kinase. Based on in vitro studies with purified recombinant p33, we show evidence for phosphorylation of threonine and serine residues adjacent to the essential RNA-binding site in p33. Our findings suggest that phosphorylation of threonine/serine residues adjacent to the essential RNA-binding site in the auxiliary p33 protein likely plays a role in viral RNA replication and subgenomic RNA synthesis during tombusvirus infections.

DISSECTING THE FUNCTIONS OF CARMOVIRUS AND TOMBUSVIRUS REPLICASE PROTEINS

Rajendran, Kottampatty

01 January 2004

Replication of genetic material is the most important and central process during the viral life cycle. Most RNA viruses assign one or more proteins translated from their own genome for replicating genomic RNAs. Understanding the various biochemical activities of these replication proteins is the aim of this dissertation research. The replicase proteins of Turnip crinkle virus (TCV) and Tomato bushy stunt virus (TBSV) were selected for this study. Both viruses have small, messenger-sense, single-stranded RNA genomes. Replicase proteins p28/p88 of TCV and p33/p92 of TBSV- were expressed and purified from E. coli as N-terminal fusions to maltose binding protein. In vitro assays revealed that the recombinant p88 has RNA-dependent RNA polymerase (RdRp) and RNAbinding activities. Deletion of the N-terminal p28 domain in p88 resulted in a highly active RdRp, while further deletions at both N- and C-terminal ends abolished RdRp activity. Comparison of p88, the N-terminal p28-deletion mutant of p88 and a TCV RdRp preparation obtained from infected plants revealed remarkable similarities in RNA template recognition and plus and minus strands synthesis. Contrary to recombinant TCV RdRp activities under similar experimental conditions. p33 preferentially binds to singlestranded (ss) RNA with positive cooperativity in vitro. The RNA binding activity was mapped to arginine/proline-rich motif (RPR-motif) at the C-terminus of p33 and the corresponding sequence in p92. The non-overlapping C-terminal domain of p92 also contained additional RNA-binding regions that flank the conserved RdRp motifs on both sides. Cooperative RNA binding by p33 suggested inter-molecular interactions between p33 monomers. Indeed the yeast two-hybrid and surface plasmon resonance assays revealed interactions between p33 and p33 and also between p33 and p92. The sequence involved in the protein-protein interactions was mapped to the C-terminal region in p33, proximal to RPR-motif. Within this region, mutations introduced at two short stretches of amino acid residues were found to affect p33:p33 and p33:p92 interactions in vivo and also decreased the replication of a TBSV-defective interfering RNA in yeast, a model system, supporting the significance of these protein interactions in tombusvirus replication.

Characterization of peroxisomal multivesicular body morphology and the role of host-cell and viral components in their biogenesis in plant and yeast cells

Gibson, Kimberley

21 December 2009

Peroxisome biogenesis is complex, involving a diverse array of intracellular pathways and mechanisms that mediate their biogenesis and cellular functions. Relevant to our understanding of peroxisome biogenesis is the utilization of peroxisomal membranes for viral genome replication as observed in plant cells infected by several members of the Tombusviridae family of positive-strand RNA viruses. Tomato Bushy Stunt Virus (TBSV), for instance, usurps an array of host factors that facilitate the transformation of peroxisomes into peroxisomal multivesicular bodies (pMVB) the sites of viral RNA replication. In this study, pMVB topology and biogenesis was investigated using transmission electron and epifluorescence microscopy of tobacco and wildtype or mutant budding yeast that were transformed with TBSV replicase proteins and a defective interfering viral RNA. Overall, the results suggest that host-virus interactions specifically associated with Endosomal Sorting Complex Required for Transport (ESCRT) and lipid metabolism are involved in TBSV replication and pMVB biogenesis.

escrt

plant virus

host-viral interaction

host-virus interaction

pMVB

peroxisomal multivesicular body

peroxisomes

peroxisome biogenesis

tbsv

tomato bushy stunt virus