A.L.N. Rao

Replication-Coupled Packaging Mechanism in Positive-Strand RNA Viruses: Synchronized Coexpression of Functional Multigenome RNA Components of an Animal and a Plant Virus in Nicotiana benthamiana Cells by Agroinfiltration

ABSTRACT Flock house virus (FHV), a bipartite RNA virus of insects and a member of the Nodaviridae family, shares viral replication features with the tripartite brome mosaic virus (BMV), an RNA virus that infects plants and is a member of the Bromoviridae family. In BMV and FHV, genome packaging is coupled to replication, a widely conserved mechanism among positive-strand RNA viruses of diverse origin. To unravel the events that modulate the mechanism of replication-coupled packaging, in this study, we have extended the transfer DNA (T-DNA)-based agroinfiltration system to express functional genome components of FHV in plant cells (Nicotiana benthamiana). Replication, intracellular membrane localization, and packaging characteristics in agroinfiltrated plant cells revealed that T-DNA plasmids of FHV were biologically active and faithfully mimicked complete replication and packaging behavior similar to that observed for insect cells. Synchronized coexpression of wild-type BMV and FHV genome components in plant cells resulted in the assembly of virions packaging the respective viral progeny RNA. To further elucidate the link between replication and packaging, coat protein (CP) open reading frames were precisely exchanged between BMV RNA 3 (B3) and FHV RNA 2 (F2), creating chimeric RNAs expressing heterologous CP genes (B3/FCP and F2/BCP). Coinfiltration of each chimera with its corresponding genome counterpart to provide viral replicase (B1+B2+B3/FCP and F1+F2/BCP) resulted in the expected progeny profiles, but virions exhibited a nonspecific packaging phenotype. Complementation with homologous replicase (with respect to CP) failed to enhance packaging specificity. Taken together, we propose that the transcription of CP mRNA from homologous replication and its translation must be synchronized to confer packaging specificity.

Subcellular Localization and Rearrangement of Endoplasmic Reticulum by Brome Mosaic Virus Capsid Protein

ABSTRACT Genome packaging in the plant-infecting Brome mosaic virus (BMV), a member of the alphavirus-like superfamily, as well as in other positive-strand RNA viruses pathogenic to humans (e.g., poliovirus) and animals (e.g., Flock House virus), is functionally coupled to replication. Although the subcellular localization site of BMV replication has been identified, that of the capsid protein (CP) has remained elusive. In this study, the application of immunofluorescence confocal microscopy to Nicotiana benthamiana leaves expressing replication-derived BMV CP as a green fluorescent protein (GFP) fusion, in conjunction with antibodies to the CP and double-stranded RNA, a presumed marker of RNA replication, revealed that the subcellular localization sites of replication and CP overlap. Our temporal analysis by transmission electron microscopy of ultrastructural modifications induced in BMV-infected N. benthamiana leaves revealed a reticulovesicular network of modified endoplasmic reticulum (ER) incorporating large assemblies of vesicles derived from ER accumulated in the cytoplasm during BMV infection. Additionally, for the first time, we have found by ectopic expression experiments that BMV CP itself has the intrinsic property of modifying ER to induce vesicles similar to those present in BMV infections. The significance of CP-induced vesicles in relation to CP-organized viral functions that are linked to replication-coupled packaging is discussed.

A Bromodomain-Containing Host Protein Mediates the Nuclear Importation of a Satellite RNA of Cucumber Mosaic Virus

ABSTRACT Replication of the satellite RNA (satRNA) of Cucumber Mosaic Virus is dependent on replicase proteins of helper virus (HV). However, we recently demonstrated that like with Potato spindle tuber viroid (PSTVd), a satRNA associated with Cucumber Mosaic Virus strain Q (Q-satRNA) has the propensity to localize in the nucleus and generate multimers that subsequently serve as templates for HV-dependent replication. But the mechanism regulating the nuclear importation of Q-satRNA is unknown. Here we show that the nuclear importation of Q-satRNA is mediated by a bromodomain-containing host protein (BRP1), which is also apparently involved in the nuclear localization of PSTVd. A comparative analysis of nuclear and cytoplasmic fractions from Nicotiana benthamiana plants coinfected with Q-satRNA and its HV confirmed the association of Q-satRNA but not HV with the nuclear compartment. A combination of the MS2-capsid protein-based RNA tagging assay and confocal microscopy demonstrated that the nuclear localization of Q-satRNA was completely blocked in transgenic lines of Nicotiana benthamiana (ph5.2nb) that are defective in BRP1 expression. This defect, however, was restored when the ph5.2nb lines of N. benthamiana were trans-complemented by ectopically expressed BRP1. The binding specificity of BRP1 with Q-satRNA was confirmed in vivo and in vitro by coimmunoprecipitation and electrophoretic mobility shift assays, respectively. Finally, infectivity assays involving coexpression of Q-satRNA and its HV in wild-type and ph5.2nb lines of N. benthamiana accentuated a biological role for BRP1 in the Q-satRNA infection cycle. The significance of these results in relation to a possible evolutionary relationship to viroids is discussed.

Integration of replication and assembly of infectious virions in plant RNA viruses

For all plant pathogenic viruses with positive-strand RNA genomes, the assembly of infectious virions is a carefully orchestrated process. The mature virions of such viruses exhibit a remarkable degree of packaging specificity, despite the opportunity that exists to package cellular RNAs. Recent technical developments in the fields of molecular and cellular biology have revealed that the processes regulating genome replication and virion assembly are integrated. The main focus of this review is to (i) apprise readers of the technical breakthroughs that have facilitated the dissection of replication from virion assembly and genome packaging in vivo and (ii) describe the critical factors that have been shown to be involved in the regulation and integration of these processes.

Effect of C-terminal deletions in the movement protein of cowpea chlorotic mottle virus on cell-to-cell and long-distance movement

In order to elucidate the function of the C-terminal region of cowpea chlorotic mottle bromovirus (CCMV) movement protein (MP) in cell-to-cell movement, a set of deletions ranging from 10 to 80 amino acids (deltaMP10, deltaMP20, deltaMP33, deltaMP43, deltaMP60 and deltaMP80) was engineered into the MP gene encoded by the biologically active clone C3/deltaCP-EGFP, a variant of CCMV RNA3 that contained wild-type (wt) MP and the enhanced green fluorescent protein (EGFP) gene in place of the coat protein (CP). The effect of each MP deletion on cell-to-cell movement was examined in three susceptible host plants: Chenopodium quinoa, Nicotiana benthamiana and cowpea (Vigno sinensis cv. Black Eye). The results indicate that, except for mutant deltaMP43, infections resulting from the deletion mutants remained subliminal. Interestingly, infections resulting from inoculating mutant deltaMP43, which lacked the 43 most C-terminal amino acids, spread rapidly between cells and the number of infected cells expressing EGFP approached that of control inoculations made with C3/deltaCP-EGFP. To verify whether the presence of wt CP altered the movement behaviour of these mutants, each MP deletion was also incorporated into the genetic background of wt CCMV RNA3 (pCC3) and inoculated independently to all three hosts. The results suggest that the overall movement process exhibited by each MP mutant is influenced profoundly by the presence of CP and the particular host plant tested.

Packaging and structural phenotype of brome mosaic virus capsid protein with altered N-terminal β-hexamer structure

The first 45 amino acid region of brome mosaic virus (BMV) capsid protein (CP) contains RNA binding and structural domains that are implicated in the assembly of infectious virions. One such important structural domain encompassing amino acids 28QPVIV32, highly conserved between BMV and cowpea chlorotic mottle virus (CCMV), exhibits a β-hexamer structure. In this study we report that alteration of the β-hexamer structure by mutating 28QPVIV32 to 28AAAAA32 had no effect either on symptom phenotype, local and systemic movement in Chenopodium quinoa and RNA profile of in vivo assembled virions. However, sensitivity to RNase and assembly phenotypes distinguished virions assembled with CP subunits having β-hexamer from those of wild type. A comparison of 3-D models obtained by cryo electron microscopy revealed overall similar structural features for wild type and mutant virions, with small but significant differences near the 3-fold axes of symmetry.

A shift in plant proteome profile for a Bromodomain containing RNA binding Protein (BRP1) in plants infected with Cucumber mosaic virus and its satellite RNA.

UNLABELLED Host proteins are the integral part of a successful infection caused by a given RNA virus pathogenic to plants. Therefore, identification of crucial host proteins playing an important role in establishing the infection process is likely to help in devising approaches to curbing disease spread. Cucumber mosaic virus (Q-CMV) and its satellite RNA (QsatRNA) are important pathogens of many economically important crop plants worldwide. In a previous study, we demonstrated the biological significance of a Bromodomain containing RNA-binding Protein (BRP1) in the infection cycle of QsatRNA, making BRP1 an important host protein to study. To further shed a light on the mechanistic role of BRP1 in the replication of Q-CMV and QsatRNA, we analyzed the Nicotiana benthamiana host protein interactomes either for BRP1 alone or in the presence of Q-CMV or QsatRNA. Co-immunoprecipitation, followed by LC-MS/MS analysis of BRP1-FLAG on challenging with Q-CMV or QsatRNA has led us to observe a shift in the host protein interactome of BRP1. We discuss the significance of these results in relation to Q-CMV and its QsatRNA infection cycle. BIOLOGICAL SIGNIFICANCE Host proteins play an important role in replication and infection of eukaryotic cells by a wide-range of RNA viruses pathogenic to humans, animals and plants. Since a given eukaryotic cell typically contains ~30,000 different proteins, recent advances made in proteomics and bioinformatics approaches allowed the identification of host proteins critical for viral replication and pathogenesis. Although Cucumber mosaic virus (CMV) and its satRNA are well characterized at molecular level, information concerning the network of host factors involved in their replication and pathogenesis is still on its infancy. We have recently observed that a Bromodomain containing host protein (BRP1) is obligatory to transport satRNA to the nucleus. Consequently, it is imperative to apply proteomics and bioinformatics approaches in deciphering how host interactome network regulates the replication of CMV and its satRNA. In this study, first we established the importance of BRP1 in CMV replication. Then, application of co-immunoprecipitation in conjunction with LC-MS/MS allowed the identification of a wide range of host proteins that are associated with the replication of CMV and its satRNA. Interestingly, a shift in the plant proteome was observed when plants infected with CMV were challenged with its satRNA.

Functionality of host proteins in Cucumber mosaic virus replication: GAPDH is obligatory to promote interaction between replication-associated proteins

Here, we evaluated the role of two host proteins, a Bromo domain containing RNA binding protein (BRP1) and Glyceraldehyde 3-phosphate dehydrogenase (GAPDH), in the replication of Cucumber mosaic virus (CMV). LC-MS/MS analysis of host/viral proteins pull down against BRP1 from CMV-infected plants co-infiltrated with BRP1-FLAG agroconstruct identified that BRP1 specifically interacts with a ten amino acid motif (843-SPQDVVPLVR-852) encompassing the helicase domain of replicase protein p1a. The interaction between BRP1 and p1a was subsequently confirmed using a BiFC assay. Among fourteen other host proteins identified to interact with BRP1 during CMV infection, six were found to block accumulation of viral progeny in Arabidopsis thaliana lines defective in each of these host proteins. Additional BiFC assays followed by trans-complementation assays identified that plant lines defective in the expression of GAPDH blocked CMV replication by interfering with p1a:p2a interaction. Distinct roles of BRP1 and GAPDH in the replication of CMV are discussed.

Simple and robust in vivo and in vitro approach for studying virus assembly.

In viruses with positive-sense RNA genomes pathogenic to humans, animals and plants, progeny encapsidation into mature and stable virions is a cardinal phase during establishment of infection in a given host. Consequently, study of encapsidation deciphers the information regarding the know-how of the mechanism regulating virus assembly to form infectious virions. Such information is vital in formulating novel methods of curbing virus spread and disease control. Virus encapsidation can be studied in vivo and in vitro. Genome encapsidation in vivo is a highly regulated selective process involving macromolecular interactions and subcellular compartmentalization. Therefore, study leading to dissect events encompassing virus encapsidation in vivo would provide basic knowledge to understand how viruses proliferate and assemble. Recently in vitro encapsidation has been exploited for the research in the area of biomedical imaging and therapeutic applications. Non-enveloped plant viruses stand far ahead in the venture of in vitro encapsidation of the negatively charged foreign material. Brome mosaic virus (BMV), a non-enveloped multicomponent RNA virus pathogenic to plants, has been used as a model system for studying genome packaging in vivo and in vitro. For encapsidation assays in Nicotiana benthamiana plants, Agrobacterium -mediated transient expression, refer to as agroinfiltration, is an efficient and robust technique for the synchronized delivery and expression of multiple components to the same cell. In this approach, a suspension of Agrobacterium tumefaciens cells carrying binary plasmid vectors carrying cDNAs of desiredviral mRNAs is infiltrated into the intercellular space withina leaf using nothing more sophisticated than a 1 ml disposable syringe (without needle). This process results in the transfer of DNA insert into plant cells; the T-DNA insert remains transiently in the nucleus and is then transcribed by the host polymerase II, leading to the transient expression. The resulting mRNA transcript (capped and polyadenylated) is then exported to the cytoplasm for translation. After approximately 24 to 48 hours of incubation,sections of infiltrated leaves can be sampled for microscopyor biochemical analyses. Agroinfiltration permits large numbers (hundreds to thousands) of cells to be transfected simultaneously. For in vitro encapsidation, purified virions of BMV are dissociated into capsid protein by dialyzing against dissociation buffer containing calcium chloride followed by removal of RNA and un-dissociated virions by centrifugation. Genome depleted capsid protein subunits are then reassembled with desired viral genome components or non-viral components such as indocyanine dye.

Molecular and biological factors regulating the genome packaging in single-strand positive-sense tripartite RNA plant viruses

Plant pathogenic single strand positive-sense RNA viruses with the tripartite genome are classified into two families: Bromoviridae and Virgaviridae. Family Bromoviridae contains four genera Bromo, Cucumo, Alfamo, and Ilarviruses characterized by icosahedral particles. By contrast family Virgaviridae contains only one genus, Hordeivirus, with tripartite genome and characterized by helical particles. Unlike in monopartite plant viruses, packaging in tripartite RNA viruses requires a well-orchestrated process to ensure that viral progeny is selectively encapsidated and distributed optimally into three or four different viral capsids. Among the tripartite RNA viruses mentioned above, brome mosaic virus (BMV), the type member of the genus bromovirus, has been extensively used as a model system to unravel the mechanism of genome packaging. Using the available research data on BMV, this review is focused in updating the readers on how various macromolecular interactions (e.g. packaging signals) and biological factors (i.e. type of host plant) modulate genome packaging. The review also offers new directions of research to further our knowledge on the genome packaging in tripartite viruses.