The interplay between capsid dynamics and pathogenesis in tripartite bromoviruses.

Infectious virus capsids or virions are considered static structures and undergo various conformational transitions to replicate and infect a wide range of eukaryotic cells. Therefore, virus capsids must be stable enough to overcome the physicochemical environment and flexible enough to reorganize their biologically relevant surface peptides for optimal interaction with the host machinery. Although viral capsid fluctuations, referred to as dynamics or breathing, have been well studied in RNA viruses pathogenic to animals, such information is limited among plant viruses. However, more recent attempts have been made in characterizing the capsid dynamics in the plant virus genus bromovirus characterized by having a tripartite, positive-sense RNA genome. Using the available research data on the genus bromovirus members, this review is focused on updating the readers on the interrelationships between the viral capsid dynamics and host-pathogen interactions.

Cell-penetrating peptides derived from viral capsid proteins.

Cell-penetrating peptides (CPP) can translocate across the cell membrane and have been extensively studied for the delivery of proteins, nucleic acids, and therapeutics in mammalian cells. However, characterizations of CPP in plants have only recently been initiated. We showed that the intact virion and a recombinant capsid protein (CaP) from a plant-infecting nonenveloped icosahedral RNA virus, Brome mosaic virus (BMV), can penetrate the membranes of plant protoplasts but are trapped by the extracellular matrix. Furthermore, a 22-residue peptide derived from the N-terminal region of the CaP (CPNT) can enter barley protoplasts and cells of intact barley and Arabidopsis roots. An inhibitor of the macropinocytosis reduced CPNT entry, while treatment with NiCl(2) changed the cellular localization of CPNT. CPNT increased uptake of the green flourescent protein (GFP) into the cell when covalently fused to GFP or when present in trans of GFP. The BMV CPNT overlaps with the sequence known to bind BMV RNA, and it can deliver BMV RNAs into cells, resulting in viral replication, as well as deliver double-stranded RNAs that can induce gene silencing.

Are Sunflower chlorotic mottle virus infection symptoms modulated by early increases in leaf sugar concentration?

Symptom development in a susceptible sunflower line inoculated with Sunflower chlorotic mottle virus (SuCMoV) was followed in the second pair of leaves at different post-inoculation times: before symptom expression (BS), at early (ES) and late (LS) symptom expression. Sugar and starch increases and photoinhibition were observed as early effects BS, and were maintained or enhanced later on, however, chlorophyll loss was detected only at LS. Photoinhibition correlated with a drastic decrease in D1 protein level. The progress of infection was accompanied by decreasing levels of apoplastic reactive oxygen species (ROS). In infected leaves, higher antioxidant enzyme activities (superoxide dismutase, SOD; ascorbate peroxidase, APX; glutathione reductase, GR) were observed from BS. The purpose of this work was to evaluate whether the early increases in carbohydrate accumulation may participate in SuCMoV symptom expression. Similar effects on photoinhibition, apoplastic ROS generation and antioxidant activity were generated when healthy leaves were treated with sugars. These results suggest that photoinhibitory processes and lower apoplastic superoxide levels induced by SuCMoV infection may be modulated by sugar increases.

Melandrium yellow fleck bromovirus infects Arabidopsis thaliana and has genomic RNA sequence characteristics that are unique among bromoviruses.

Melandrium yellow fleck bromovirus (MYFV) systemically infected Arabidopsis thaliana, although the susceptibility of several A. thaliana accessions to MYFV differed from their susceptibility to the other two bromoviruses infecting A. thaliana. We constructed full-length cDNA clones of MYFV genomic RNAs 1, 2, and 3 and determined their complete nucleotide sequences. Similar to Broad bean mottle bromovirus, (1) the 5'-terminal nucleotide of the MYFV genomic RNAs was adenine, and (2) the "D-arm" was absent from the tRNA-like structure in the 3' untranslated regions (UTRs) of MYFV RNAs. As unique characteristics, MYFV RNA3 lacked the poly(A) tract in the intercistronic region and contained a directly repeated sequence of about 200 nucleotides and polypyrimidine tracts of heterogeneous lengths in the 5' UTR. Co-infection experiments using RNA3 clones with or without the duplicated sequence demonstrated that the duplication contributed to the competitive fitness of the virus in Nicotiana benthamiana.

Genetic analysis of a host determination mechanism of bromoviruses in Arabidopsis thaliana.

Brome mosaic virus (BMV) and Spring beauty latent virus (SBLV) are closely related, tripartite RNA plant viruses. In Arabidopsis thaliana, BMV shows limited multiplication whereas SBLV efficiently multiplies. Such distinct multiplication abilities have been observed commonly in all Arabidopsis accessions tested. We used this model system to analyze the molecular mechanism of viral resistance in plants at the species level. Unlike SBLV, BMV multiplication was limited even in protoplasts and a reassortment assay indicated that at least viral RNA1 and/or RNA2 determine such distinct infectivities. By screening Arabidopsis mutants with altered defense responses, we found that BMV multiplies efficiently in cpr5-2 mutant plants. This mutation specifically enhanced BMV multiplication in protoplasts, which depended on the functions of RNA1 and RNA2. In the experiment using DNA vectors to express BMV replication proteins encoded by RNA1 and RNA2, BMV RNA3 accumulation in cpr5-2 protoplasts was similar to that in wild-type Col-0 protoplasts, despite significant reduction of accumulation levels of replication proteins, suggesting that cpr5-2 mutation could enhance BMV multiplication independently of increased accumulation, therefore enhanced translation and stabilization, of the replication proteins.

Tobacco mosaic virus 126-kDa protein increases the susceptibility of Nicotiana tabacum to other viruses and its dosage affects virus-induced gene silencing.

The Tobacco mosaic virus (TMV) 126-kDa protein is a suppressor of RNA silencing previously shown to delay the silencing of transgenes in Nicotiana tabacum and N. benthamiana. Here, we demonstrate that expression of a 126-kDa protein-green fluorescent protein (GFP) fusion (126-GFP) in N. tabacum increases susceptibility to a broad assortment of viruses, including Alfalfa mosaic virus, Brome mosaic virus, Tobacco rattle virus (TRV), and Potato virus X. Given its ability to enhance TRV infection in tobacco, we tested the effect of 126-GFP expression on TRV-mediated virus-induced gene silencing (VIGS) and demonstrate that this protein can enhance silencing phenotypes. To explain these results, we examined the poorly understood effect of suppressor dosage on the VIGS response and demonstrated that enhanced VIGS corresponds to the presence of low levels of suppressor protein. A mutant version of the 126-kDa protein, inhibited in its ability to suppress silencing, had a minimal effect on VIGS, suggesting that the suppressor activity of the 126-kDa protein is indeed responsible for the observed dosage effects. These findings illustrate the sensitivity of host plants to relatively small changes in suppressor dosage and have implications for those interested in enhancing silencing phenotypes in tobacco and other species through VIGS.

A simple technique for separation of Cowpea chlorotic mottle virus from Cucumber mosaic virus in natural mixed infections.

A simple technique was developed to separate Cowpea chlorotic mottle virus (CCMV) from Cucumber mosaic virus (CMV) in natural mixed infections. Sap from cowpea leaves infected naturally with a mixture of CCMV and CMV was inoculated mechanically on the first tri-foliolate leaf of cowpea seedlings. Both inoculated and non-inoculated upper leaves were sampled 3 or 8 days post-inoculation and tested by reverse transcription polymerase chain reaction (RT-PCR) using primers specific to CCMV and CMV. RT-PCR analysis showed the presence of only CCMV in the inoculated leaf and both viruses in the non-inoculated systemically infected upper leaves. Total RNA from the inoculated leaves positive to CCMV only was further confirmed upon re-inoculation to cowpea seedlings. Typical CCMV symptoms were produced within 1 week and RT-PCR analysis showed only the presence of CCMV in both inoculated and non-inoculated systemically infected upper leaves. Systemically infected upper leaves of the same plants were used for CCMV purification. RT-PCR analysis of the purified virion and RNA extracted from the virion further confirmed the absence of CMV contamination. To our knowledge, this is the first report of a method separating CCMV directly from mixed infections with CMV in cowpea.

Functional analysis of brome mosaic virus coat protein RNA-interacting domains.

The coat proteins (CP) of cowpea chlorotic mottle (CCMV) and brome mosaic virus (BMV), two members of the genus Bromovirus, share 70% identity at the amino acid (aa) level and contain four highly conserved regions, identified as putative RNA-interacting domains (RIDs). To assess the contribution of the conserved aa sequence within each RID and the structural features contained therein toward virion assembly and RNA packaging, we engineered a set of fourteen independent mutations (deletions and substitutions) encompassing all four RIDs. The effect of each mutation on viral biology, pathogenesis, and RNA packaging was analyzed in whole-plant infection assays. Among the four RIDs, two mutations engineered into the N-proximal domain (RID I) and two of the four mutations engineered into the C-proximal domain (RID IV) proved to be more debilitating (compared to wild-type) while only selected regions in the central domains (RID II or III) showed a detectable effect. Neutral effects were observed when aa residues that are predicted to affect calcium binding were mutated. To further analyze the importance of N and C terminal interactions leading to virus assembly and RNA packaging, four CP hybrids were constructed by precisely exchanging either the N-terminal 77 or the C-terminal 113/112aa between BMV and CCMV. Despite the fact that the CP composition of the hybrid viruses is distinct from either of the parents, the symptom phenotype in Chenopodium quinoa, migration pattern of CP in Western blots and virion mobility in agarose gels was indistinguishable from the respective parent providing the genetic background. Collectively, the data provide insight for assessing the relative importance of each RID during genome packaging and in molecular processes regulating the overall architecture of the assembled virions.

Analysis of gene function in rice through virus-induced gene silencing.

Virus-induced gene silencing (VIGS) is a powerful RNA-silencing based technology adapted for the study of host-gene function. VIGS functions through the expression of a host gene from a virus vector. Both the virus-encoded host sequence and the homologous host target messenger RNA are destroyed or made inactive through a host surveillance system. Here, we describe procedures for the use of a new virus vector for VIGS in monocotyledonous hosts and, in particular, in rice (Oryza sativa), a species for which no VIGS vector was previously available.

Characterization of a Brome mosaic virus strain and its use as a vector for gene silencing in monocotyledonous hosts.

Virus-induced gene silencing (VIGS) is used to analyze gene function in dicotyledonous plants but less so in monocotyledonous plants (particularly rice and corn), partially due to the limited number of virus expression vectors available. Here, we report the cloning and modification for VIGS of a virus from Festuca arundinacea Schreb. (tall fescue) that caused systemic mosaic symptoms on barley, rice, and a specific cultivar of maize (Va35) under greenhouse conditions. Through sequencing, the virus was determined to be a strain of Brome mosaic virus (BMV). The virus was named F-BMV (F for Festuca), and genetic determinants that controlled the systemic infection of rice were mapped to RNAs 1 and 2 of the tripartite genome. cDNA from RNA 3 of the Russian strain of BMV (R-BMV) was modified to accept inserts from foreign genes. Coinoculation of RNAs 1 and 2 from F-BMV and RNA 3 from R-BMV expressing a portion of a plant gene to leaves of barley, rice, and maize plants resulted in visual silencing-like phenotypes. The visual phenotypes were correlated with decreased target host transcript levels in the corresponding leaves. The VIGS visual phenotype varied from maintained during silencing of actin 1 transcript expression to transient with incomplete penetration through affected tissue during silencing of phytoene desaturase expression. F-BMV RNA 3 was modified to allow greater accumulation of virus while minimizing virus pathogenicity. The modified vector C-BMV(A/G) (C for chimeric) was shown to be useful for VIGS. These BMV vectors will be useful for analysis of gene function in rice and maize for which no VIGS system is reported.

Coat protein-independent cell-to-cell movement of bromoviruses expressing brome mosaic virus movement protein with an adaptation-related amino acid change in the central region.

The movement protein (MP) of Brome mosaic virus (BMV) depends on the coat protein (CP) to mediate the cell-to-cell movement of BMV and CCMV(B3a), a recombinant Cowpea chlorotic mottle virus (CCMV) expressing BMV MP. Previous studies identified gain-of-function mutations in the central region of BMV MP that enable CCMV(B3a) to adapt to a resistant host. This study demonstrates that all adaptation-related MPs can partially or almost fully mediate the cell-to-cell movement of CCMV(B3a) and BMV without CP. Based on these results, we discuss adaptation mechanisms of CCMV(B3a) and the role of the central region of MP in the determination of virus movement mode.

Synthesis of infectious in vitro transcripts from Cassia yellow blotch bromovirus cDNA clones and a reassortment analysis with other bromoviruses in protoplasts.

Cassia yellow blotch virus (CYBV), genus Bromovirus, was isolated from the Australian native legume, Cassia pleurocarpa, in western Queensland, and its host range was found to be distinct from other bromoviruses. In this study, CYBV was shown to infect systemically and efficiently a model plant species, Arabidopsis thaliana, as we recently reported for another bromovirus, Spring beauty latent virus (SBLV). We constructed full-length cDNA clones of CYBV genomic RNAs from which infectious in vitro transcripts can be transcribed, and determined their complete nucleotide sequences. CYBV RNA3 contains the box B motif in the intercistronic region, but lacks the subgenomic promoter-like sequence in the 5' noncoding region, as does Brome mosaic virus (BMV). To understand relationships among bromoviruses, we generated reassortants between CYBV and three other bromoviruses, BMV, SBLV and Cowpea chlorotic mottle virus. We found that all reassortants between BMV and CYBV accumulated viral RNAs to detectable levels in protoplasts of Nicotiana benthamiana, even when RNAs 1 and 2, which encode the replication proteins 1a and 2a, respectively, were heterologous. Sequence comparison and reassortment experiments of CYBV and other bromoviruses demonstrated that CYBV is closely related to BMV.

Natural isolates of Brome mosaic virus with the ability to move from cell to cell independently of coat protein.

Brome mosaic virus (BMV) requires encapsidation-competent coat protein (CP) for cell-to-cell movement and the 3a movement protein (MP) is involved in determining the CP requirement for BMV movement. However, these conclusions have been drawn by using BMV strain M1 (BMV-M1) and a related strain. Here, the ability of the MPs of five other natural BMV strains to mediate the movement of BMV-M1 in the absence of CP was tested. The MP of BMV M2 strain (BMV-M2) efficiently mediated the movement of CP-deficient BMV-M1 and the MPs of two other strains functioned similarly to some extent. Furthermore, BMV-M2 itself moved between cells independently of CP, demonstrating that BMV-M1 and -M2 use different movement modes. Reassortment between CP-deficient BMV-M1 and -M2 showed the involvement of RNA3 in determining the CP requirement for cell-to-cell movement and the involvement of RNAs 1 and 2 in movement efficiency and symptom induction in the absence of CP. Spontaneous BMV MP mutants generated in planta that exhibited CP-independent movement were also isolated and analysed. Comparison of the nucleotide differences of the MP genes of BMV-M1, the natural strains and mutants capable of CP-independent movement, together with further mutational analysis of BMV-M1 MP, revealed that single amino acid differences at the C terminus of MP are sufficient to alter the requirement for CP in the movement of BMV-M1. Based on these findings, a possible virus strategy in which a movement mode is selected in plant viruses to optimize viral infectivity in plants is discussed.

Identification and characterization of the SSB1 locus involved in symptom development by Spring beauty latent virus infection in Arabidopsis thaliana.

The natural variation of Arabidopsis thaliana in response to a bromovirus, Spring beauty latent virus (SBLV), was examined. Of 63 Arabidopsis accessions tested, all were susceptible when inoculated with SBLV, although there was a large degree of variation in symptom development. Most accessions, including Columbia (Col-0), were symptomless or developed only mild symptoms, but four accessions, including S96, showed severe symptoms of SBLV infection. Genetic analysis suggested that the difference in the responses of Col-0 and S96 to SBLV was controlled by a single semidominant locus. We have designated this locus SSB1 (symptom development by SBLV infection). By using genetic markers, SSB1 was mapped to chromosome IV. The patterns of distribution and accumulation of SBLV in sensitive accessions were similar to those in the insensitive accessions. In addition, symptom development in S96 by SBLV infection was critically interrupted by the presence of the NahG gene, which encodes salicylic acid (SA) hydroxylase. These data suggest that symptom development in A. thaliana controlled by SSB1 is independent of the efficiency of SBLV multiplication and is dependent on SA signaling.

Infection and RNA recombination of Brome mosaic virus in Arabidopsis thaliana.

Ecotypes of Arabidopsis thaliana supported the replication and systemic spread of Brome mosaic virus (BMV) RNAs. Infection was induced either by manual inoculation with viral RNA or by BMV virions, demonstrating that virus disassembly did not prevent infection. When in vitro-transcribed BMV RNAs 1-3 were used, production of subgenomic RNA4 was observed, showing that BMV RNA replication and transcription had occurred. Furthermore, inoculations of the transgenic Arabidopsis line that expressed a suppressor of RNA interference (RNAi) pathway markedly increased the BMV RNA concentrations. Inoculations with designed BMV RNA3 recombination vectors generated both homologous and nonhomologous BMV RNA-RNA recombinants. Thus, all cellular factors essential for BMV RNA replication, transcription, and RNA recombination were shown to be present in Arabidopsis. The current scope of understanding of the model Arabidopsis plant system should facilitate the identification of these factors governing the BMV life cycle.

Effects of artificial codon changes in the movement protein gene on adaptation of a hybrid bromovirus to cowpea.

A hybrid Cowpea chlorotic mottle virus(CCMV) with the movement protein (MP) gene replaced with that of the closely related Brome mosaic virus cannot infect cowpea systemically. Twenty-nine spontaneous mutants from the hybrid CCMV capable of systemic infection in cowpea appeared through biased codon changes that resulted in Lys or Arg at five specific positions in the MP gene. In this study, we report that systemic infection of cowpea with the hybrid CCMV can be achieved by artificial codon changes that do not result in Lys or Arg. We discuss mechanisms that restrict the occurrence of cowpea-adapted mutants in nature.

Use of Spring beauty latent virus to identify compatible interactions between bromovirus components required for virus infection.

Spring beauty latent virus (SBLV) is a member of the genus Bromovirus, and is closely related to Brome mosaic virus (BMV) and Cowpea chlorotic mottle virus (CCMV). Compatible interactions between viral components are required for successful infection of plants by BMV and CCMV. To further our understanding of interactions between bromovirus components, we used SBLV to produce reassortants among the three bromoviruses. We found that SBLV RNA 2 functioned with heterologous bromovirus RNA 1 in infections of whole plants and protoplasts of Nicotiana benthamiana, although SBLV RNA 1 did not function with heterologous bromovirus RNA 2. A DNA-based transient assay for 1a and 2a proteins, which are encoded by RNAs 1 and 2, respectively further suggested that SBLV 2a protein may function in combination with heterologous bromovirus 1a protein. Moreover, analysis of the ability of reassortants to spread locally revealed that an RNA 2-mediated interaction between viral components may be required for efficient cell-to-cell movement of bromoviruses.

A transcriptionally active subgenomic promoter supports homologous crossovers in a plus-strand RNA virus.

Genetic RNA recombination plays an important role in viral evolution, but its molecular mechanism is not well understood. In this work we describe homologous RNA recombination activity that is supported by a subgenomic promoter (sgp) region in the RNA3 segment of brome mosaic bromovirus (BMV), a tripartite plus-strand RNA virus. The crossover frequencies were determined by coinoculations with pairs of BMV RNA3 variants that carried a duplicated sgp region flanked by marker restriction sites. A region composed of the sgp core, a poly(A) tract, and an upstream enhancer supported homologous exchanges in 25% of the analyzed RNA3 progeny. However, mutations in the sgp core stopped both the transcription of the sgp RNA and homologous recombination. These data provide evidence for an association of RNA recombination with transcription.

Complete nucleotide sequence of spring beauty latent virus, a bromovirus infectious to Arabidopsis thaliana.

Spring beauty latent virus (SBLV), a bromovirus, systemically and efficiently infected Arabidopsis thaliana, whereas the well-studied bromoviruses brome mosaic virus (BMV) and cowpea chlorotic mottle virus (CCMV) did not infect and poorly infected A. thaliana, respectively. We constructed biologically active cDNA clones of SBLV genomic RNAs and determined their complete nucleotide sequences. Interestingly, SBLV RNA3 contains both the box B motif in the intercistronic region, as does BMV, and the subgenomic promoter-like sequence in the 5' noncoding region, as does CCMV. Sequence comparisons of SBLV, BMV, CCMV, and broad bean mottle virus demonstrated that SBLV is closely related to BMV and CCMV.

Studies on functional interaction between brome mosaic virus replicase proteins during RNA recombination, using combined mutants in vivo and in vitro.

Two viral proteins, 1a and 2a, direct replication of brome mosaic bromovirus (BMV) RNAs as well as they participate in BMV RNA recombination. To study the relationship between replication and recombination, double BMV variants that carried mutations in 1a and 2a genes were tested. The observed effects revealed that the 1a helicase and 2a N-terminal or core domains were functionally linked during both processes in vivo. The use of a series of mutant BMV replicase (RdRp) preparations demonstrated in vitro the participation of the 1a and 2a domains in BMV RNA copying and in template switching during minus-strand synthesis. The observed effects support previous observations that the characteristics of homologous and nonhomologous recombination can be modified separately by mutations at different sites on BMV replicase proteins.