The informosome-like virus-specific ribonucleoprotein (vRNP) may be involved in the transport of tobacco mosaic virus infection

Binding of monoclonal antibodies to the movement protein (MP) of Tobacco mosaic virus: influence of subcellular MP localization and phosphorylation

Monoclonal antibodies (mAbs) to recombinant movement protein (MP(REC)) of Tobacco mosaic virus (TMV) were used to reveal the dependence of MP epitope accessibility to mAbs on subcellular MP localization and post-translational MP phosphorylation. Leaves of Nicotiana benthamiana or N. tabacum were inoculated mechanically with TMV or agroinjected with an MP expression vector. At different time post-inoculation, ER membrane- and cell wall-enriched fractions (ER-MP and CW-MP, respectively) were isolated and analysed. The N-terminal region (residues 1-30) as well as regions 186-222 and 223-257 of MP from the CW and ER fractions were accessible for interaction with mAbs. By contrast, the MP regions including residues 76-89 and 98-129 were not accessible. The C-terminal TMV MP region (residues 258-268) was inaccessible to mAbs not only in CW-MP, but also in ER-MP fractions. Evidence is presented that phosphorylation of the majority of TMV MP C-terminal sites occurred on ER membranes at an early stage of virus infection, i.e. not after, but before reaching the cell wall. C-terminal phosphorylation of purified MP(REC) abolished recognition of C-proximal residues 258-268 by specific mAbs, which could be restored by MP dephosphorylation. Likewise, accessibility to mAbs of the C-terminal MP epitope in ER-MP and CW-MP leaf fractions was restored by dephosphorylation. Substitution of three or four C-terminal Ser/Thr residues with non-phosphorylatable Ala also resulted in abolition of interaction of mAbs with MP.

Transport of TMV movement protein particles associated with the targeting of RNA to plasmodesmata

The cell-to-cell movement of Tobacco mosaic virus through plasmodesmata (PD) requires virus-encoded movement protein (MP). The MP targets PD through the endoplasmic reticulum (ER)/actin network, whereas the intercellular movement of the viral RNA genome has been correlated with the association of the MP with mobile, microtubule-proximal particles in cells at the leading front of infection as well as the accumulation of the protein on the microtubule network during later infection stages. To understand how the associations of MP with ER and microtubules are functionally connected, we applied multiple marker three-dimensional confocal and time-lapse video microscopies to Nicotiana benthamiana cells expressing fluorescent MP, fluorescent RNA and fluorescent cellular markers. We report the reconstitution of MP-dependent RNA transport to PD in a transient assay. We show that transiently expressed MP occurs in association with small particles as observed during infection. The same MP accumulates in PD and mediates the transport of its messenger RNA transcript to the pore. In the cellular cortex, the particles occur at microtubule-proximal sites and can undergo ER-associated and latrunculin-sensitive movements between such sites. These and other observations suggest that the microtubule network performs anchorage and release functions for controlling the assembly and intracellular movement of MP-containing RNA transport particles in association with the ER.

Tobacco mosaic virus movement protein interacts with green fluorescent protein-tagged microtubule end-binding protein 1

The targeting of the movement protein (MP) of Tobacco mosaic virus to plasmodesmata involves the actin/endoplasmic reticulum network and does not require an intact microtubule cytoskeleton. Nevertheless, the ability of MP to facilitate the cell-to-cell spread of infection is tightly correlated with interactions of the protein with microtubules, indicating that the microtubule system is involved in the transport of viral RNA. While the MP acts like a microtubule-associated protein able to stabilize microtubules during late infection stages, the protein was also shown to cause the inactivation of the centrosome upon expression in mammalian cells, thus suggesting that MP may interact with factors involved in microtubule attachment, nucleation, or polymerization. To further investigate the interactions of MP with the microtubule system in planta, we expressed the MP in the presence of green fluorescent protein (GFP)-fused microtubule end-binding protein 1a (EB1a) of Arabidopsis (Arabidopsis thaliana; AtEB1a:GFP). The two proteins colocalize and interact in vivo as well as in vitro and exhibit mutual functional interference. These findings suggest that MP interacts with EB1 and that this interaction may play a role in the associations of MP with the microtubule system during infection.

Validation of microtubule-associated Tobacco mosaic virus RNA movement and involvement of microtubule-aligned particle trafficking

Functional studies of Tobacco mosaic virus (TMV) infection using virus derivatives expressing functional, dysfunctional, and temperature-sensitive movement protein (MP) mutants indicated that the cell-to-cell transport of TMV RNA is functionally correlated with the association of MP with microtubules. However, the role of microtubules in the movement process during early infection remains unclear, since MP accumulates on microtubules rather late in infection and treatment of plants with microtubule-disrupting agents fails to strongly interfere with cell-to-cell movement of TMV RNA. To further test the role of microtubules in TMV cell-to-cell movement, we investigated TMV strain Ni2519, which is temperature-sensitive for movement. We demonstrate that the temperature-sensitive defect in movement is correlated with temperature-sensitive changes in the localization of MP to microtubules. Furthermore, we show that during early phases of recovery from non-permissive conditions, the MP localizes to microtubule-associated particles. Similar particles are found in cells at the leading front of spreading TMV infection sites. Initially mobile, the particles become immobile when MP starts to accumulate along the length of the particle-associated microtubules. Our observations confirm a role for microtubules in the spread of TMV infection and associate this role with microtubule-associated trafficking of MP-containing particles in cells engaged in the cell-to-cell movement of the TMV genome.

Effects of brefeldin A on the localization of Tobamovirus movement protein and cell-to-cell movement of the virus

It has been demonstrated that the subcellular location of Tobamovirus movement protein (MP) which was fused with green fluorescent protein (MP:GFP) changed during the infection process. However, the intracellular route through which MP is transported and its biological meaning are still obscure. Treatment with brefeldin A (BFA), which disrupts ER-to-Golgi transport, inhibited the formation of irregularly shaped and filamentous structures of MP. In this condition, MP was still targeted to plasmodesmata in leaf cells. Furthermore, the viral cell-to-cell movement was not inhibited by BFA treatment. These data indicated that the targeting of viral replication complexes (VRCs) to plasmodesmata is mediated by a BFA-insensitive pathway and that the ER-to-Golgi transport pathway is not involved in viral intercellular movement.

Macromolecular Transport and Signaling Through Plasmodesmata

Plasmodesmata (Pd) are channels in the plant cell wall that in conjunction with associated phloem form an intercellular communication network that supports the cell-to-cell and long-distance trafficking of a wide spectrum of endogenous proteins and ribonucleoprotein complexes. The trafficking of such macromolecules is of importance in the orchestration of non-cell autonomous developmental and physiological processes. Plant viruses encode movement proteins (MPs) that subvert this communication network to facilitate the spread of infection. These viral proteins thus represent excellent experimental keys for exploring the mechanisms involved in intercellular trafficking and communication via Pd.

Intramolecular complementing mutations in tobacco mosaic virus movement protein confirm a role for microtubule association in viral RNA transport

The movement protein (MP) of Tobacco mosaic virus (TMV) facilitates the cell-to-cell transport of the viral RNA genome through plasmodesmata (Pd). A previous report described the functional reversion of a dysfunctional mutation in MP (Pro81Ser) by two additional amino acid substitution mutations (Thr104Ile and Arg167Lys). To further explore the mechanism underlying this intramolecular complementation event, the mutations were introduced into a virus derivative expressing the MP as a fusion to green fluorescent protein (GFP). Microscopic analysis of infected protoplasts and of infection sites in leaves of MP-transgenic Nicotiana benthamiana indicates that MP(P81S)-GFP and MP(P81S;T104I;R167K)-GFP differ in subcellular distribution. MP(P81S)-GFP lacks specific sites of accumulation in protoplasts and, in epidermal cells, exclusively localizes to Pd. MP(P81S;T104I;R167K)-GFP, in contrast, in addition localizes to inclusion bodies and microtubules and thus exhibits a subcellular localization pattern that is similar, if not identical, to the pattern reported for wild-type MP-GFP. Since accumulation of MP to inclusion bodies is not required for function, these observations confirm a role for microtubules in TMV RNA cell-to-cell transport.

The 6K2 protein and the VPg of potato virus A are determinants of systemic infection in Nicandra physaloides

Infection with the isolate PVA-M of potato virus A (PVA; genus Potyvirus) is restricted to the inoculated leaves of Nicandra physaloides (Solanaceae), whereas the isolate PVA-B11 infects plants systemically by 10 days post inoculation. Resistance to systemic infection was shown to develop during plant growth. A recombinant virus (B11-M) in which a 1,208-nucleotide sequence of the full-length cDNA clone of PVA-B11 was replaced with the corresponding sequence from PVA-M displayed a phenotype similar to that of PVA-M. The replaced sequence contained four amino acid differences between the two isolates: one in the 6K2 protein and three in the viral genome-linked protein (VPg). Site-directed mutagenesis of the cDNA clones and inoculation of the mutants to N. physaloides indicated that the amino acid substitutions of Met5Val in the 6K2 protein or Leu185Ser in the VPg permitted vascular movement and systemic infection. However, resistance was only partially overcome by these changes, since systemic infection proceeded at a slower rate than with PVA-B11. The amino acid substitution Val116Met in the VPg alone was sufficient to overcome resistance and recover the phenotype of the isolate PVA-B11. These data indicated that both the 6K2 protein and the VPg were avirulence determinants of PVa-M in N. physaloides and suggested a possibly coordinated function of them in the vascular movement of PVA.

Replication in the phloem is not necessary for efficient vascular transport of tobacco mosaic tobamovirus

Plant viruses move systemically from one leaf to another via phloem. However, the viral functions needed for systemic movement are not fully elucidated. An experimental system was designed to study the effects of low temperature on the vascular transport of the tobacco mosaic tobamovirus (TMV). Vascular transport of TMV from lower inoculated leaves to upper non-inoculated leaves via a stem segment kept at low temperature (4 degrees C) was not affected. On the other hand, several experiments were performed on tobacco leaves to demonstrate that virus replication did not occur at the same temperature. The data suggest that replication of TMV in the phloem of wild-type tobacco plants is not necessary for the vascular transport of TMV, and that the virus moves with photoassimilates as suggested previously.

Virus particles of cucumber green mottle mosaic tobamovirus move systemically in the phloem of infected cucumber plants

Systemic movement through the phloem of infected host plants is a key process in the life cycle of plant viruses, knowledge of which is scant. A main point to be elucidated is the structural form in which virus infection moves within the phloem. Indirect evidence suggests that virions might be the viral structure that moves in the phloem, but data from direct analysis in phloem sap have not been reported. We have done such analysis in the system cucumber (from which phloem exudate can be collected)/cucumber green mottle mosaic tobamovirus (CGMMV). CGMMV has structurally well-characterized particles. Both CGMMV coat protein and RNA were found in phloem exudate from infected cucumbers. Analysis of the accessibility of CGMMV RNA in phloem exudate to RNase A indicates that it is protected within a ribonucleoprotein structure. The accessibility to RNase A of the RNA in these structures was as in virus particles. Centrifugation analyses showed that the ribonucleoprotein structures in the phloem exudate have the same mass and isopycnic density as virions. Virus particles indistinguishable from purified virions were detected by electron microscopy in phloem exudate. No evidence of free RNA or other CGMMV-related structure was found in phloem exudate of infected plants. These results indicate that CGMMV movement in the phloem occurs mainly, if not exclusively, in the form of virus particles.

Nontranslatability and dissimilar behavior in plants and protoplasts of viral RNA and movement protein complexes formed in vitro

It was found that the fusion (His)6-movement proteins (MPs) of two tobamoviruses (TMV UI and a crucifer-infecting tobamovirus, crTMV) were efficient nonspecific translational repressors. The in vitro translation of viral RNAs was blocked by incomplete 30K MP-RNA complexes formed at the MP:RNA molar ratios of 100-150:1. Similar results were obtained with the barley stripe mosaic hordeivirus (BSMV)-encoded 58K MP; however, the translation inhibiting activity of the 58K MP was manifested only in the presence of magnesium. By contrast, the 25K MP of potato virus X (PVX) was incapable of forming MP-RNA complexes under experimental conditions used and did not inhibit in vitro translation. The translation repressing ability correlated with the level of MP affinity to RNA. The complexes of the 30K MP and 58K MP with TMV RNA were not infectious in isolated protoplasts; however, they were infectious in indicator plants. Reduction of MP affinity to RNA resulted in translatability of MP-TMV RNA complexes that apparently was due to their destabilization. Thus, the deletion mutant DEL4 MP formed MP-TMV RNA complexes that were translatable in vitro, infectious to protoplasts and plants. In contrast to this, the complexes of TMV RNA with the mammalian RNA-binding protein p50 were nontranslatable and noninfectious to either protoplasts or intact plants. These results implied that nontranslatable MP-RNA complexes which could not replicate in the primary infected cells were converted into a translatable and replicatable form in the course of passage through plasmodesmata in planta.

Plasmodesmal cell-to-cell transport of proteins and nucleic acids

The complexity associated with post-translational processing, in terms of protein sorting and delivery is now well understood. Although such studies have been focused almost exclusively on the fate of proteins within the cell in which they are synthesized, recent studies indicate that it is time to broaden this focus to incorporate the concept of intercellular targeting of proteins. Direct evidence is now available that viral and endogenous proteins can be synthesized in a particular cell and subsequently transported into neighboring (or more distant) cells. Plasmodesmata, plasma membrane-lined cytoplasmic pores, are thought to establish the intercellular pathway responsible for this cell-to-cell trafficking of macromolecules (proteins and nucleic acids). These recent findings establish a new paradigm for understanding the manner in which higher plants exert control over developmental processes. We discuss the concept that programming of plant development involves supracellular control achieved by plasmodesmal trafficking of informational molecules, herein defined as supracellular control proteins (SCPs). This novel concept may explain why, in plants, cell fate is determined by position rather than cell lineage. Finally, the circulation of long-distance SCPs, within the phloem, may provide the mechanism by which the plant signals to the shoot apical meristem that it is time to switch to the reproductive phase of its development.

The immobilized movement proteins of two tobamoviruses form stable ribonucleoprotein complexes with full-length viral genomic RNA

The movement proteins of two tobamoviruses (tobacco mosaic virus, TMV, common strain U1 and cruciferous TMV strain) containing amino-terminal hexahistidine affinity tags were overexpressed in Escherichia coli and purified by metal chelate affinity chromatography. Purified recombinant proteins were immobilized to a Ni(2+)-chelate adsorbent and their ability to interact with full-length genomic TMV RNA was tested. Here we report that binding of viral RNA to hexahistidine fusion movement proteins results in the formation of stable ribonucleoprotein complexes.

Cell-to-cell movement of plant viruses. Insights from amino acid sequence comparisons of movement proteins and from analogies with cellular transport systems

Cell-to-cell movement is a crucial step in plant virus infection. In many viruses, the movement function is secured by specific virus-encoded proteins. Amino acid sequence comparisons of these proteins revealed a vast superfamily containing a conserved sequence motif that may comprise a hydrophobic interaction domain. This superfamily combines proteins of viruses belonging to all principal groups of positive-strand RNA viruses, as well as single-stranded DNA containing geminiviruses, double-stranded DNA-containing pararetroviruses (caulimoviruses and badnaviruses), and tospoviruses that have negative-strand RNA genomes with two ambisense segments. In several groups of positive-strand RNA viruses, the movement function is provided by the proteins encoded by the so-called triple gene block including two putative small membrane-associated proteins and a putative RNA helicase. A distinct type of movement proteins with very high content of proline is found in tymoviruses. It is concluded that classification of movement proteins based on comparison of their amino acid sequences does not correlate with the type of genome nucleic acid or with grouping of viruses based on phylogenetic analysis of replicative proteins or with the virus host range. Recombination between unrelated or distantly related viruses could have played a major role in the evolution of the movement function. Limited sequence similarities were observed between i) movement proteins of dianthoviruses and the MIP family of cellular integral membrane proteins, and ii) between movement proteins of bromoviruses and cucumoviruses and M1 protein of influenza viruses which is involved in nuclear export of viral ribonucleoproteins. It is hypothesized that all movement proteins of plant viruses may mediate hydrophobic interactions between viral and cellular macromolecules.

The TMV movement protein: role of the C-terminal 73 amino acids in subcellular localization and function

The role of the C-terminal one-third of the tobacco mosaic virus (TMV) 30-kDa movement protein (MP) on its subcellular localization and on virus spread was investigated. We have constructed eight cDNAs encoding MPs with variable size deletions from the C-terminal end. Expression of the truncated proteins was verified in recombinant yeast using an antiserum directed to a synthetic peptide corresponding to 21 amino acids near the N-terminal end of the MP. In transgenic tobacco plants, MP from which more than 55 amino acids were deleted no longer accumulated in the cell wall fraction of a cellular extract, where the complete MP accumulates. Dye diffusion studies showed that both unmodified and modified MPs that accumulate in the cell wall fraction are able to alter plasmodesmatal size exclusion limits. Biological function of the modified MPs was tested in the transgenic plants with the TMV thermosensitive mutant Ls1 and a TMV genomic RNA transcript lacking a functional MP. There was a correlation between the cell wall localization of the modified MPs and its ability to potentiate virus spread. The results presented here demonstrate the dispensability of the C-terminal 55 amino acids of the MP in its subcellular localization in tobacco plants and its role in virus movement. Moreover, our results show that a stretch of 19 amino acids (195 to 213) is essential for localization of the MP to the cell wall fraction of plant cells.

Complementation of coat protein-defective TMV mutants in transgenic tobacco plants expressing TMV coat protein

Transgenic tobacco plants (Nicotiana tabacum cv. Xanthi) which express tobacco mosaic virus (TMV) U1 strain coat protein (CP) can complement both the assembly and the long-distance spread of CP-defective (DT1) or coat proteinless (DT1G) mutants of TMV. Both mutants arose spontaneously from PM2 and exist only as unencapsidated RNA in the inoculated leaves of control tobacco plants, where they are unable to form virus particles or to spread systemically. TMV CP expressed in transgenic tobacco plants [CP+ line 3404; P. Powell Abel, R. S. Nelson, B. De, N. Hoffman, S. G. Rogers, R. T. Fraley, and R. N. Beachy, 1986, Science 232, 738-743] was able to package some of either mutant viral RNA into TMV-like particles in vivo and resulted in the long-range spread of infection. In vivo encapsidated DT1 RNA was recovered and reinoculated onto control or new CP+ transgenic tobacco plants. Localized infection of control plants confirmed that no RNA recombination or reversion of the mutant RNA to wild-type had occurred during passage in the first CP+ plant. In contrast, encapsidated DT1 RNA was unable to produce even local infection in CP+ transgenic plants confirming that CP-mediated protection operates during the early stages of virus infection, including particle uncoating. By positive complementation, these results also confirm that TMV CP is required for the long-distance spread of infection.

Long-distance movement and viral assembly of tobacco mosaic virus mutants

Spreading of tobacco mosaic virus in infected plants is of two modes: cell-to-cell movement (to adjacent cells) and long-distance movement (to distant parts of the plant). Viral coat protein has been suggested to be involved in long-distance movement. To analyze the function of coat protein in the movement, we used mutants with modifications in the coat protein gene or in the assembly origin on the genomic RNA. A mutant which has the coding region for the C-terminal 5 amino acids of the protein deleted and mutants with 1 amino acid inserted after residue 101 or 152 of the protein retained both the abilities of long-distance movement and assembly into virus particles. Other mutants in the coat protein gene eliminated the two abilities. A mutant with modifications in the assembly origin displayed greatly reduced abilities of both the movement and assembly. These results suggest that both the coat protein with its ability to assemble into virus particles and the assembly origin are involved in long-distance movement, and that virus particles may play a pivotal role in the movement.

Virus-ribosome complexes from cell-free translation systems supplemented with cowpea chlorotic mottle virus particles

When particles of cowpea chlorotic mottle virus (CCMV) were added to cell-free extracts from wheat germ, the encapsidated viral genome was translated into polypeptides similar to the translation products specified by unencapsidated viral RNA (as shown before by M.J. Brisco, R. Hull, and T.M.A. Wilson, 1986, Virology 148, 210-217). The rate of protein synthesis observed upon addition of virus particles was much slower than that of extracted RNA and the quantity of protein formed was only 10% of that of extracted RNA. Using sucrose and cesium-chloride gradient analysis, virus-ribosome complexes, containing up to four ribosomes per virus particle, were isolated from translation mixtures supplemented with CCMV particles. These complexes, with densities intermediate of those of virus (1.36 g cm-3) and ribosomes (1.58 g cm-3), were analyzed and quantified in the electron microscope. Less than 5% of the particles was found in association with ribosomes. To verify whether these complexes were involved in the process of cotranslational disassembly, tobacco mosaic virus was analyzed with the same techniques and methods. The results found for TMV were similar to those found for CCMV except that virus-ribosome complexes with up to 20 ribosomes per virus particle were observed. The implications of the process of virion-directed translation for the structure of the particle as well as the role of this process in vivo are discussed.