Phytopathogenic fungus hosts a plant virus: A naturally occurring cross-kingdom viral infection.

The transmission of viral infections between plant and fungal hosts has been suspected to occur, based on phylogenetic and other findings, but has not been directly observed in nature. Here, we report the discovery of a natural infection of the phytopathogenic fungus Rhizoctonia solani by a plant virus, cucumber mosaic virus (CMV). The CMV-infected R. solani strain was obtained from a potato plant growing in Inner Mongolia Province of China, and CMV infection was stable when this fungal strain was cultured in the laboratory. CMV was horizontally transmitted through hyphal anastomosis but not vertically through basidiospores. By inoculation via protoplast transfection with virions, a reference isolate of CMV replicated in R. solani and another phytopathogenic fungus, suggesting that some fungi can serve as alternative hosts to CMV. Importantly, in fungal inoculation experiments under laboratory conditions, R. solani could acquire CMV from an infected plant, as well as transmit the virus to an uninfected plant. This study presents evidence of the transfer of a virus between plant and fungus, and it further expands our understanding of plant-fungus interactions and the spread of plant viruses.

Assessment of the autonomy of replicative and structural functions encoded by the luteo-phase of pea enation mosaic virus.

The genome of pea enation mosaic virus (PEMV) is composed of two taxonomically unrelated RNAs, interacting to create what has traditionally been considered a bipartite virus. The cohesiveness of this interaction was assessed by examining the autonomy of each RNA in viral replication, coat protein expression and systemic invasion. Using a pea protoplast system, in vitro transcripts of RNA1 were found to be capable of initiating RNA2-independent replication, including the formation of the distinctive nuclear membrane-based replication complex associated with wild-type PEMV infection. Western blotting and electron microscopic analysis demonstrated that the synthesis of the RNA1-encoded coat protein, as well as virion assembly, was also independent of RNA2-directed functions. Mechanical inoculations with transcripts of RNA1 failed to establish a systemic RNA1 infection, whereas inoculations with RNA2 were able to establish a largely asymptomatic systemic infection. Combined inoculum containing RNA1 and RNA2 transcripts were able to recreate wild-type PEMV symptomatology, demonstrating the dependence of RNA1 on RNA2 for mechanical passage. With the notable exception of the adaptation of PEMV to establish a true systemic invasion, these data further strengthen the analogy between PEMV and the helper-dependent complexes associated with members of the luteovirus group.

Replication and translation of cowpea mosaic virus RNAs are tightly linked.

The genome of cowpea mosaic virus (CPMV) is divided among two positive strand RNA molecules. B-RNA is able to replicate independently from M-RNA in cowpea protoplasts. Replication of mutant B-transcripts could not be supported by co-inoculated wild-type B-RNA, indicating that B-RNA cannot be efficiently replicated in trans. Hence replication of a B-RNA molecule is tightly linked to its translation and/or at least one of the replicative proteins functions in cis only. Remarkably also for efficient replication of M-RNA one of its translation products was found to be required in cis. This 58K protein possibly helps in directing the B-RNA-encoded replication complex to the M-RNA. In order to identify the viral polymerase the CPMV B-RNA-specific proteins have been produced individually in cowpea protoplasts using CaMV 35S promoter based expression vectors. Only protoplasts transfected with a vector containing the 200K coding sequence were able to support replication of co-transfected M-RNA. Despite this, CPMV-specific RNA polymerase activity could not be detected in extracts of these protoplasts using a poly(A)/oligo(U) assay. These results indicate that, in contrast to the poliovirus polymerase, the CPMV polymerase is not able to accept oligo(U) as a primer and in addition support the concept that translation and replication are linked.

Protoplasts transiently expressing the 200K coding sequence of cowpea mosaic virus B-RNA support replication of M-RNA.

In order to identify the viral polymerase involved in cowpea mosaic virus (CPMV) RNA replication the 87K, 110K and 170K proteins as well as the complete 200K polyprotein of CPMV B-RNA have been produced in cowpea protoplasts, using expression vectors based on the 35S promoter of cauliflower mosaic virus. CPMV-specific proteins were obtained that were indistinguishable from proteins found in CPMV-infected protoplasts. Proteolytic processing of precursor proteins synthesized from the expression vectors proved that the 24K protease contained within these proteins is active. Moreover, it was established that protoplasts transfected with the expression vector containing the entire 200K coding sequence, but not those transfected with vectors containing the 170K, 110K or 87K coding sequences, were able to support replication of co-inoculated M-RNA. Despite the ability to support replication of M-RNA for protoplasts transiently expressing the 200K coding region, CPMV-specific RNA polymerase activity dependent on exogenous added template RNA could not be detected in extracts of these protoplasts in assays using poly(A).oligo(U) or other template/primer combinations. In contrast, extracts of protoplasts in which poliovirus polymerase was produced exhibited RNA polymerase activity in such assays. These results indicate that the CPMV polymerase, unlike the poliovirus polymerase, is not able to use oligo(U) as a primer or cannot function on exogenous template and primer RNA.

The involvement of cowpea mosaic virus M RNA-encoded proteins in tubule formation.

On the surface of cowpea protoplasts inoculated with cowpea mosaic virus (CPMV), tubular structures containing virus particles have been found. Such tubular structures are thought to be involved in cell-to-cell movement of CPMV in cowpea plants. To study the involvement of the 58K/48K and capsid proteins of CPMV in the formation of the tubular structures, mutations were introduced into M cDNA clones from which infectious transcripts could be derived. No tubules were found on protoplasts inoculated with a mutant that fails to produce the 48K protein nor with a mutant that has a deletion in the 48K coding region, suggesting that the 48K protein is essential for this process. However, a possible role of the 58K protein in tubule formation could not be excluded. A mutant that fails to produce the capsid proteins did produce tubules and therefore the capsid proteins are not involved in the formation of the tubular structures. Electron microscopic analysis revealed that the tubules produced by this mutant are, apart from the absence of virus particles, morphologically identical to the tubules formed by the wild-type virus.

The cowpea mosaic virus M RNA-encoded 48-kilodalton protein is responsible for induction of tubular structures in protoplasts.

Tubular structures extending from plasmodesmata in cowpea mosaic virus (CPMV)-infected tissue have been implicated to play an important role in cell-to-cell movement of this virus. Using a cauliflower mosaic virus 35S promoter-based transient expression vector, we show that expression of only the CPMV M RNA-encoded 48-kDa protein (48K protein) in cowpea protoplasts is sufficient to induce these structures. Strikingly, expression of the 48K protein in protoplasts from a number of nonhost plant species, such as barley, Arabidopsis thaliana, and carrot, also resulted in tubular structure formation. Thus, it is not likely that the viral 48K protein, though playing a key role in cell-to-cell movement of CPMV, has a role in determining the host range of CPMV.

Mutational analysis of the coat protein gene of potato virus X: effects on virion morphology and viral pathogenicity.

The role of the coat protein of potato virus X (PVX) was investigated by site-directed mutation of the coat protein gene. Mutant viruses with in-frame deletions in the 5' end of the coat protein gene were capable of systemically infecting plants, but produced virions with atypical morphology. Viruses with a frameshift mutation near the 5' end or with deletions in the central part of the coat protein gene failed to accumulate at detectable levels, even in the inoculated leaf. In protoplasts, mutants that infected systemically either had a wild-type phenotype or showed a small reduction in accumulation of genomic RNA. The other mutants, which did not accumulate in the inoculated leaf, were unaffected in genomic RNA accumulation 8 hr postinoculation, but at 16 hr and later they accumulated less genomic RNA than wild-type virus. None of the mutations had an effect on accumulation of negative-strand RNA. The data indicate that efficient accumulation and spread of PVX, even in the inoculated leaf, requires coat protein production and encapsidation of the viral RNA.

Triple gene block proteins of white clover mosaic potexvirus are required for transport.

The functions of the protein products encoded by a block of three overlapping genes (the triple gene block) of white clover mosaic potexvirus (WCIMV) have been determined. Mutations were introduced into each of the triple gene block open reading frames and in vitro RNA transcripts assayed in plants and protoplasts. None of the mutants was able to induce symptoms or spread in four systemic hosts and one local lesion host, but all were able to produce progeny genomic RNA, subgenomic RNA, coat protein, and virions in inoculated protoplasts, indicating that all the triple gene block proteins are involved in cell-to-cell spread. Based on observed homologies between the triple gene block proteins of the potex-, carla-, furo-, and hordeivirus groups and Nicotiana velutina mosaic virus, and the demonstrated transport function of the WCIMV and barley stripe mosaic virus triple gene block proteins, these proteins are proposed to constitute a new class of transport proteins.

Infectious in vitro transcripts from cowpea chlorotic mottle virus cDNA clones and exchange of individual RNA components with brome mosaic virus.

Complete cDNA copies of genomic RNA1, RNA2, and RNA3 of cowpea chlorotic mottle virus (CCMV) were cloned 1 base downstream from a T7 RNA polymerase promoter. The mixture of capped in vitro transcripts from all three clones produced normal CCMV infections in barley protoplasts and cowpea plants. By using transcripts from these clones and from a similar set of biologically active clones of the related brome mosaic virus (BMV), all possible single component exchanges between the BMV and CCMV tripartite genomes were tested. Viral RNA replication was not observed with any heterologous combination of RNA1 and RNA2, which encode trans-acting viral RNA replication factors. However, substitution of the heterologous RNA3 into either genome produced viable hybrid viruses, both of which replicated in barley protoplasts and produced lesions on Chenopodium hybridum, a local lesion host for both parent viruses. In hybrid infections, BMV and CCMV coat proteins each readily packaged RNAs from the heterologous virus, but BMV RNAs were replicated to a higher level than CCMV RNAs, even when trans-acting RNA replication factors were provided by CCMV genes. Neither hybrid systemically infected the natural host of either parent virus, suggesting that host specificity determinants in BMV and CCMV are encoded by RNA3 and at least one other genomic RNA.

In vivo uncoating and efficient expression of foreign mRNAs packaged in TMV-like particles.

The ribonucleocapsids of many plant viruses are extremely stable. The protein coat protects the RNA genome against degradation during the accumulation and spread of progeny virions. Chimeric single-stranded RNA molecules were transcribed in vitro from recombinant plasmids and later encapsidated, in vitro, into ribonucleoprotein particles (pseudoviruses) 60 nanometers long that resembled tobacco mosaic virus. Transcripts encoding an assayable enzyme, chloramphenicol acetyltransferase (CAT), were packaged into pseudovirus particles to assess the utility of this single-stranded RNA delivery system in a wide range of cell types. In all cases, packaged CAT messenger RNA was uncoated and transiently expressed. Significantly higher levels of CAT activity were detected with packaged than with naked CAT messenger RNA after inoculation of plant protoplasts in the presence of polyethylene glycol or abrasive inoculation of intact leaf surfaces. Structural events that lead to the uncoating and expression of CAT messenger RNA showed no cell specificity. This observation may support the view that the comparatively restricted host range of a true plant virus results from events that occur later during the infection cycle.