Evidence that tobacco mosaic virus particles disassemble contranslationally in vivo

Engineered Resistance to Tobamoviruses

Tobacco mosaic virus (TMV) was the first virus to be studied in detail and, for many years, TMV and other tobamoviruses, particularly tomato mosaic virus (ToMV) and tobamoviruses infecting pepper (Capsicum spp.), were serious crop pathogens. By the end of the twentieth and for the first decade of the twenty-first century, tobamoviruses were under some degree of control due to introgression of resistance genes into commercial tomato and pepper lines. However, tobamoviruses remained important models for molecular biology, biotechnology and bio-nanotechnology. Recently, tobamoviruses have again become serious crop pathogens due to the advent of tomato brown rugose fruit virus, which overcomes tomato resistance against TMV and ToMV, and the slow but apparently inexorable worldwide spread of cucumber green mottle mosaic virus, which threatens all cucurbit crops. This review discusses a range of mainly molecular biology-based approaches for protecting crops against tobamoviruses. These include cross-protection (using mild tobamovirus strains to 'immunize' plants against severe strains), expressing viral gene products in transgenic plants to inhibit the viral infection cycle, inducing RNA silencing against tobamoviruses by expressing virus-derived RNA sequences in planta or by direct application of double-stranded RNA molecules to non-engineered plants, gene editing of host susceptibility factors, and the transfer and optimization of natural resistance genes.

Methyltransferases of Riboviria

Many viruses from the realm Riboviria infecting eukaryotic hosts encode protein domains with sequence similarity to S-adenosylmethionine-dependent methyltransferases. These protein domains are thought to be involved in methylation of the 5'-terminal cap structures in virus mRNAs. Some methyltransferase-like domains of Riboviria are homologous to the widespread cellular FtsJ/RrmJ-like methyltransferases involved in modification of cellular RNAs; other methyltransferases, found in a subset of positive-strand RNA viruses, have been assigned to a separate "Sindbis-like" family; and coronavirus-specific Nsp13/14-like methyltransferases appeared to be different from both those classes. The representative structures of proteins from all three groups belong to a specific variety of the Rossmann fold with a seven-stranded β-sheet, but it was unclear whether this structural similarity extends to the level of conserved sequence signatures. Here I survey methyltransferases in Riboviria and derive a joint sequence alignment model that covers all groups of virus methyltransferases and subsumes the previously defined conserved sequence motifs. Analysis of the spatial structures indicates that two highly conserved residues, a lysine and an aspartate, frequently contact a water molecule, which is located in the enzyme active center next to the methyl group of S-adenosylmethionine cofactor and could play a key role in the catalytic mechanism of the enzyme. Phylogenetic evidence indicates a likely origin of all methyltransferases of Riboviria from cellular RrmJ-like enzymes and their rapid divergence with infrequent horizontal transfer between distantly related viruses.

From stars to stripes: RNA-directed shaping of plant viral protein templates-structural synthetic virology for smart biohybrid nanostructures

The self-assembly of viral building blocks bears exciting prospects for fabricating new types of bionanoparticles with multivalent protein shells. These enable a spatially controlled immobilization of functionalities at highest surface densities-an increasing demand worldwide for applications from vaccination to tissue engineering, biocatalysis, and sensing. Certain plant viruses hold particular promise because they are sustainably available, biodegradable, nonpathogenic for mammals, and amenable to in vitro self-organization of virus-like particles. This offers great opportunities for their redesign into novel "green" carrier systems by spatial and structural synthetic biology approaches, as worked out here for the robust nanotubular tobacco mosaic virus (TMV) as prime example. Natural TMV of 300 x 18 nm is built from more than 2,100 identical coat proteins (CPs) helically arranged around a 6,395 nucleotides ssRNA. In vitro, TMV-like particles (TLPs) may self-assemble also from modified CPs and RNAs if the latter contain an Origin of Assembly structure, which initiates a bidirectional encapsidation. By way of tailored RNA, the process can be reprogrammed to yield uncommon shapes such as branched nanoobjects. The nonsymmetric mechanism also proceeds on 3'-terminally immobilized RNA and can integrate distinct CP types in blends or serially. Other emerging plant virus-deduced systems include the usually isometric cowpea chlorotic mottle virus (CCMV) with further strikingly altered structures up to "cherrybombs" with protruding nucleic acids. Cartoon strips and pictorial descriptions of major RNA-based strategies induct the reader into a rare field of nanoconstruction that can give rise to utile soft-matter architectures for complex tasks. This article is categorized under: Biology-Inspired Nanomaterials > Protein and Virus-Based Structures Nanotechnology Approaches to Biology > Nanoscale Systems in Biology Biology-Inspired Nanomaterials > Nucleic Acid-Based Structures.

Evidence that Hsc70 Is Associated with Cucumber Necrosis Virus Particles and Plays a Role in Particle Disassembly

Uncoating of a virus particle to expose its nucleic acid is a critical aspect of the viral multiplication cycle, as it is essential for the establishment of infection. In the present study, we investigated the role of plant HSP70 homologs in the uncoating process of Cucumber necrosis virus (CNV), a nonenveloped positive-sense single-stranded RNA [(+)ssRNA] virus having a T=3 icosahedral capsid. We have found through Western blot analysis and mass spectrometry that the HSP70 homolog Hsc70-2 copurifies with CNV particles. Virus overlay and immunogold labeling assays suggest that Hsc70-2 is physically bound to virions. Furthermore, trypsin digestion profiles suggest that the bound Hsc70-2 is partially protected by the virus, indicating an intimate association with particles. In investigating a possible role of Hsc70-2 in particle disassembly, we showed that particles incubated with Hsp70/Hsc70 antibody produce fewer local lesions than those incubated with prebleed control antibody on Chenopodium quinoa In conjunction, CNV virions purified using CsCl and having undetectable amounts of Hsc70-2 produce fewer local lesions. We also have found that plants with elevated levels of HSP70/Hsc70 produce higher numbers of local lesions following CNV inoculation. Finally, incubation of recombinant Nicotiana benthamiana Hsc70-2 with virus particles in vitro leads to conformational changes or partial disassembly of capsids as determined by transmission electron microscopy, and particles are more sensitive to chymotrypsin digestion. This is the first report suggesting that a cellular Hsc70 chaperone is involved in disassembly of a plant virus.

IMPORTANCE

Virus particles must disassemble and release their nucleic acid in order to establish infection in a cell. Despite the importance of disassembly in the ability of a virus to infect its host, little is known about this process, especially in the case of nonenveloped spherical RNA viruses. Previous work has shown that host HSP70 homologs play multiple roles in the CNV infection cycle. We therefore examined the potential role of these cellular components in the CNV disassembly process. We show that the HSP70 family member Hsc70-2 is physically associated with CNV virions and that HSP70 antibody reduces the ability of CNV to establish infection. Statistically significantly fewer lesions are produced when virions having undetectable HSc70-2 are used as an inoculum. Finally incubation of Hsc70-2 with CNV particles results in conformational changes in particles. Taken together, our data point to an important role of the host factor Hsc70-2 in CNV disassembly.

Cis-acting RNA elements in positive-strand RNA plant virus genomes

Positive-strand RNA viruses are the most common type of plant virus. Many aspects of the reproductive cycle of this group of viruses have been studied over the years and this has led to the accumulation of a significant amount of insightful information. In particular, the identification and characterization of cis-acting RNA elements within these viral genomes have revealed important roles in many fundamental viral processes such as virus disassembly, translation, genome replication, subgenomic mRNA transcription, and packaging. These functional cis-acting RNA elements include primary sequences, secondary and tertiary structures, as well as long-range RNA-RNA interactions, and they typically function by interacting with viral or host proteins. This review provides a general overview and update on some of the many roles played by cis-acting RNA elements in positive-strand RNA plant viruses.

Helical viruses

Virtually all studies of structure and assembly of viral filaments have been made on plant and bacterial viruses. Structures have been determined using fiber diffraction methods at high enough resolution to construct reliable molecular models or several of the rigid plant tobamoviruses (related to tobacco mosaic virus, TMV) and the filamentous bacteriophages including Pf1 and fd. Lower-resolution structures have been determined for a number of flexible filamentous plant viruses using fiber diffraction and cryo-electron microscopy. Virions of filamentous viruses have numerous mechanical functions, including cell entry, viral disassembly, viral assembly, and cell exit. The plant viruses, which infect multicellular organisms, also use virions or virion-like assemblies for transport within the host. Plant viruses are generally self-assembling; filamentous bacteriophage assembly is combined with secretion from the host cell, using a complex molecular machine. Tobamoviruses and other plant viruses disassemble concomitantly with translation, by various mechanisms and involving various viral and host assemblies. Plant virus movement within the host also makes use of a variety of viral proteins and modified host assemblies.

Hydrogen-bonding networks and RNA bases revealed by cryo electron microscopy suggest a triggering mechanism for calcium switches

Helical assemblies such as filamentous viruses, flagella, and F-actin represent an important category of structures in biology. As the first discovered virus, tobacco mosaic virus (TMV) was at the center of virus research. Previously, the structure of TMV was solved at atomic detail by X-ray fiber diffraction but only for its dormant or high-calcium-concentration state, not its low-calcium-concentration state, which is relevant to viral assembly and disassembly inside host cells. Here we report a helical reconstruction of TMV in its calcium-free, metastable assembling state at 3.3 Å resolution by cryo electron microscopy, revealing both protein side chains and RNA bases. An atomic model was built de novo showing marked differences from the high-calcium, dormant-state structure. Although it could be argued that there might be inaccuracies in the latter structure derived from X-ray fiber diffraction, these differences can be interpreted as conformational changes effected by calcium-driven switches, a common regulatory mechanism in plant viruses. Our comparisons of the structures of the low- and high-calcium states indicate that hydrogen bonds formed by Asp116 and Arg92 in the place of the calcium ion of the dormant (high-calcium) state might trigger allosteric changes in the RNA base-binding pockets of the coat protein. In turn, the coat protein-RNA interactions in our structure favor an adenine-X-guanine (A*G) motif over the G*A motif of the dormant state, thus offering an explanation underlying viral assembly initiation by an AAG motif.

Visualising a viral RNA genome poised for release from its receptor complex

We describe the cryo-electron microscopy structure of bacteriophage MS2 bound to its receptor, the bacterial F-pilus. The virus contacts the pilus at a capsid 5-fold vertex, thus locating the surface-accessible portion of the single copy of the pilin-binding maturation protein present in virions. This arrangement allows a 5-fold averaged map to be calculated, showing for the first time in any virus-receptor complex the nonuniform distribution of RNA within the capsid. Strikingly, at the vertex that contacts the pilus, a rod of density that may include contributions from both genome and maturation protein sits above a channel that goes through the capsid to the outside. This density is reminiscent of the DNA density observed in the exit channel of double-stranded DNA phages, suggesting that the RNA-maturation protein complex is poised to leave the capsid as the first step of the infection process.

Cross-protection: a century of mystery

Cross-protection is a phenomenon in which infection of a plant with a mild virus or viroid strain protects it from disease resulting from a subsequent encounter with a severe strain of the same virus or viroid. In this chapter, we review the history of cross-protection with regard to the development of ideas concerning its likely mechanisms, including RNA silencing and exclusion, and its influence on the early development of genetically engineered virus resistance. We also examine examples of the practical use of cross-protection in averting crop losses due to viruses, as well as the use of satellite RNAs to ameliorate the impact of virus-induced diseases. We also discuss the potential of cross-protection to contribute in future to the maintenance of crop health in the face of emerging virus diseases and related threats to agricultural production.

The N-glycosidase activity of the ribosome-inactivating protein ME1 targets single-stranded regions of nucleic acids independent of sequence or structural motifs

ME(1), a type I ribosome-inactivating protein (RIP), belongs to a family of enzymes long believed to possess rRNA N-glycosidase activity directed solely at the universally conserved residue A4324 in the sarcin/ricin loop of large eukaryotic and prokaryotic rRNAs. We have investigated the effect of modifying the structure of nonribosomal RNA substrates on their interaction with ME(1) and other RIPs. ME(1) was shown to depurinate a variety of partially denatured nucleic acids, randomly removing adenine residues from single-stranded regions and, to a lesser extent, guanine residues from wobble base-pairs in hairpin stems. A defined sequence motif was not required for recognition of non-paired adenosines and cleavage of the N-glycosidic bond. Substrate recognition and ME(1) activity appeared to depend on the physical availability of nucleotides, and denaturation of nucleic acid substrates increased their interaction with ME(1). Pretreatment of mRNA at 75 degrees C rather than 60 degrees C, for example, lowered the apparent K(D) from 87.1 to 73.9 nm, making it more vulnerable to depurination by RIPs. Exposure to ME(1) in vitro completely abolished the infectivity of partially denatured RNA transcripts of the potato spindle tuber viroid, suggesting that RIPs may target invading nucleic acids before they reach host ribosomes in vivo. Our data suggest that the extensive folding of many potential substrates interferes with their ability to interact with RIPs, thereby blocking their inactivation by ME(1) (or other RIPs).

The 5'-leader of tobacco mosaic virus promotes translation through enhanced recruitment of eIF4F

The 5'-leader sequence (called Omega) of tobacco mosaic virus (TMV) functions as a translational enhancer in plants. A poly(CAA) region within Omega is responsible for the translation enhancement and serves as a binding site for the heat shock protein, HSP101, which is required for the translational enhancement. Genetic analysis of the HSP101-mediated enhancement of translation from Omega-containing mRNA suggested that two eukaryotic initiation factors (eIFs), i.e. eIF4G and eIF3, were necessary. In this study, the functional interaction between Omega and other RNA elements known to participate in the recruitment of eIF4G, i.e. the 5'-cap and the poly(A) tail, was examined. Omega exhibited functional overlap with the 5'-cap and the poly(A) tail but not with the native TMV 3'-UTR which contains an independent translational enhancer. Consistent with the role of HSP101 in mediating the translational function of Omega, the enhancement afforded by Omega increased following a heat shock, which elevates expression of HSP101. The use of a fractionated translation lysate revealed that of the two eIF4F proteins present in plants, eIF4F was specifically required for the activity of Omega. The data suggest that Omega is functionally similar to a 5'-cap and a poly(A) tail in that it serves to recruit eIF4F in order to enhance translation from an mRNA.

Tobacco mosaic virus assembly and disassembly: determinants in pathogenicity and resistance

The structural proteins of plant viruses have evolved to self-associate into complex macromolecules that are centrally involved in virus biology. In this review, the structural and biophysical properties of the Tobacco mosaic virus (TMV) coat protein (CP) are addressed in relation to its role in host resistance and disease development. TMV CP affects the display of several specific virus and host responses, including cross-protection, systemic virus movement, hypersensitive disease resistance, and symptom development. Studies indicate that the three-dimensional structure of CP is critical to the control of these responses, either directly through specific structural motifs or indirectly via alterations in CP assembly. Thus, both the structure and assembly of the TMV CP function as determinants in the induction of disease and resistance responses.

Tobacco mosaic virus and the study of early events in virus infections

In order to establish infections, viruses must be delivered to the cells of potential hosts and must then engage in activities that enable their genomes to be expressed and replicated. With most viruses, the events that precede the onset of production of progeny virus particles are referred to as the early events and, in the case of positive-strand RNA viruses, they include the initial interaction with and entry of host cells and the release (uncoating) of the genome from the virus particles. Though the early events remain one of the more poorly understood areas of plant virology, the virus with which most of the relevant research has been performed is tobacco mosaic virus (TMV). In spite of this effort, there remains much uncertainty about the form or constituent of the virus that actually enters the initially invaded cell in a plant and about the mechanism(s) that trigger the subsequent uncoating (virion disassembly) reactions. A variety of approaches have been used in attempts to determine the fate of TMV particles that are involved in the establishment of an infection and these are briefly described in this review. In some recent work, it has been proposed that the uncoating process involves the bidirectional release of coat protein subunits from the viral RNA and that these activities may be mediated by cotranslational and coreplicational disassembly mechanisms.

Historical overview of research on the tobacco mosaic virus genome: genome organization, infectivity and gene manipulation

Early in the development of molecular biology, TMV RNA was widely used as a mRNA [corrected] that could be purified easily, and it contributed much to research on protein synthesis. Also, in the early stages of elucidation of the genetic code, artificially produced TMV mutants were widely used and provided the first proof that the genetic code was non-overlapping. In 1982, Goelet et al. determined the complete TMV RNA base sequence of 6395 nucleotides. The four genes (130K, 180K, 30K and coat protein) could then be mapped at precise locations in the TMV genome. Furthermore it had become clear, a little earlier, that genes located internally in the genome were expressed via subgenomic mRNAs. The initiation site for assembly of TMV particles was also determined. However, although TMV contributed so much at the beginning of the development of molecular biology, its influence was replaced by that of Escherichia coli and its phages in the next phase. As recombinant DNA technology developed in the 1980s, RNA virus research became more detached from the frontier of molecular biology. To recover from this setback, a gene-manipulation system was needed for RNA viruses. In 1986, two such systems were developed for TMV, using full-length cDNA clones, by Dawson's group and by Okada's group. Thus, reverse genetics could be used to elucidate the basic functions of all proteins encoded by the TMV genome. Identification of the function of the 30K protein was especially important because it was the first evidence that a plant virus possesses a cell-to-cell movement function. Many other plant viruses have since been found to encode comparable 'movement proteins'. TMV thus became the first plant virus for which structures and functions were known for all its genes. At the birth of molecular plant pathology, TMV became a leader again. TMV has also played pioneering roles in many other fields. TMV was the first virus for which the amino acid sequence of the coat protein was determined and first virus for which cotranslational disassembly was demonstrated both in vivo and in vitro. It was the first virus for which activation of a resistance gene in a host plant was related to the molecular specificity of a product of a viral gene. Also, in the field of plant biotechnology, TMV vectors are among the most promising. Thus, for the 100 years since Beijerinck's work, TMV research has consistently played a leading role in opening up new areas of study, not only in plant pathology, but also in virology, biochemistry, molecular biology, RNA genetics and biotechnology.

Coat protein interactions involved in tobacco mosaic tobamovirus cross-protection

To investigate the molecular role of the tobacco mosaic tobamovirus (TMV) coat protein (CP) in conferring cross-protection, a potato X potexvirus (PVX) vector (S. Chapman, Plant J. 2, 549-557, 1992) was used to systemically express a set of TMV mutant CPs in Nicotiana benthamiana prior to challenge inoculation with TMV. PVX-expressed wild-type TMV CP delayed TMV accumulation for up to 2 weeks compared to unprotected plants or plants preinfected with the unmodified PVX vector. Similar delays in TMV accumulation were obtained using TMV CPs that were deficient in virion formation but competent to assemble into helical aggregates. In contrast, TMV CPs that were incapable of helical aggregation or unable to bind viral RNA did not delay the accumulation of TMV. Furthermore, TMV CPs with enhanced intersubunit interactions that favor helical aggregation produced significantly greater delays in the accumulation of challenge TMV than obtained from the wild-type CP. Thus the capabilities of TMV CP to interact with viral RNA and self-associate in a helical fashion appear to be essential to its ability to confer protection. Taken together, these findings support a model for CP-mediated resistance in which the protecting CP recoats the challenge virus RNA as it disassembles.

Cotranslational disassembly of flock house virus in a cell-free system

Intact, purified particles of the nodaviruses flock house virus and nodamura virus that were either transfected into cells that were resistant to infection or introduced into in vitro translation systems directed the synthesis of viral proteins. We infer that direct interaction of these nodavirus particles with cytoplasmic components mediated virion disassembly that resulted in release of the viral RNA.

A ribozyme gene and an antisense gene are equally effective in conferring resistance to tobacco mosaic virus on transgenic tobacco

Ribozymes of the hammerhead class can be designed to cleave a target RNA in a sequence-specific manner and can potentially be used to specifically modulate gene activity. We have targeted the tobacco mosaic virus (TMV) genome with a ribozyme containing three catalytic hammerhead domains embedded within a 1 kb antisense RNA. The ribozyme was able to cleave TMV RNA at all three target sites in vitro at 25 degrees C. Transgenic tobacco plants were generated which expressed the ribozyme or the corresponding antisense constructs directed at the TMV genome. Six of 38 independent transgenic plant lines expressing the ribozyme and 6 of 39 plant lines expressing the antisense gene showed some level of protection against TMV infection. Homozygous progeny of some lines were highly resistant to TMV; at least 50% of the plants remained asymptomatic even when challenged with high levels of TMV. These plants also displayed resistance to infection with TMV RNA or the related tomato mosaic virus (ToMV). In contrast, hemizygous plants of the same lines displayed only very weak resistance when inoculated with low amounts of TMV and no resistance against high inoculation levels. Resistance in homozygous plants was not overcome by a TMV strain which was altered at the three target sites to abolish ribozyme-mediated cleavage, suggesting that the ribozyme conferred resistance primarily by an antisense mechanism.

The product of the tobacco mosaic virus resistance gene N: similarity to toll and the interleukin-1 receptor

The products of plant disease resistance genes are postulated to recognize invading pathogens and rapidly trigger host defense responses. Here we describe isolation of the resistance gene N of tobacco that mediates resistance to the viral pathogen tobacco mosaic virus (TMV). The N gene was isolated by transposon tagging using the maize Activator transposon. A genomic DNA fragment containing the N gene conferred TMV resistance to TMV susceptible tobacco. Sequence analysis of the N gene shows that it encodes a protein of 131.4 kDa with an amino-terminal domain similar to that of the cytoplasmic domain of the Drosophila Toll protein and the interleukin-1 receptor (IL-1R) in mammals, a nucleotide-binding site (NBS), and 14 [corrected] imperfect leucine-rich repeats (LRR). The sequence similarity of N, Toll, and IL-1R suggests that N mediates rapid gene induction and TMV resistance through a Toll-IL-1-like pathway.

Adaptation of positive-strand RNA viruses to plants

The vast majority of positive-strand RNA viruses (more than 500 species) are adapted to infection of plant hosts. Genome sequence comparisons of these plant RNA viruses have revealed that most of them are genetically related to animal cell-infecting counterparts; this led to the concept of "superfamilies". Comparison of genetic maps of representative plant and animal viruses belonging to the same superfamily (e.g. cowpea mosaic virus [CPMV] versus picornaviruses and tobacco mosaic virus versus alphaviruses) have revealed genes in the plant viral genomes that appear to be essential adaptations needed for successful invasion and spread through their plant hosts. The best studied example represents the "movement protein" gene that is actively involved in cell-to-cell spread of plant viruses, thereby playing a key role in virulence and pathogenesis. In this paper the host adaptations of a number of plant viruses will be discussed, with special emphasis on the cell-to-cell movement mechanism of comovirus CPMV.

Role of ribosomes in Semliki Forest virus nucleocapsid uncoating

The mechanism by which Semliki Forest virus nucleocapsids are uncoated was analyzed in living cells and in vitro. In BHK-21 cells, uncoating occurred with virtually complete efficiency within 1 to 2 min after the nucleocapsids entered the cytoplasm. It was inhibited by monensin, which blocks nucleocapsid penetration from endosomes. As previously shown for Sindbis virus (G. Wengler and G. Wengler, Virology 134:435-442, 1984), the capsid proteins from incoming nucleocapsids became associated with ribosomes. The ribosome-bound capsid proteins were distributed throughout the cytoplasm, while the viral RNA remained associated with vacuolar membranes. Using purified nucleocapsids and ribosomes in vitro, we established that ribosomes alone were sufficient for uncoating. Their role was to release the capsid proteins from nucleocapsids and irreversibly sequester them, in a process independent of energy and translation. The process was stoichiometric rather than catalytic, with a maximum of three to six capsid proteins bound to each ribosome. More than 80% of the capsid proteins could thus be removed from the viral RNA, resulting in the formation of nucleocapsid remnants whose sedimentation coefficients progressively decreased from 140S to 80S as uncoating proceeded.

Structure of the U2 strain of tobacco mosaic virus refined at 3.5 A resolution using X-ray fiber diffraction

The structure of the U2 strain of tobacco mosaic virus (TMV) has been determined by fiber diffraction methods at 3.5 A resolution, and refined by a combination of restrained least-squares and molecular dynamics methods to an R-factor of 0.096. The structure is extremely similar to that of the common strain of TMV, with the largest differences being in the protein loop that makes up the inner surface of the virus, and in the C-terminal region on the outer surface. Differences in the inner loop can be correlated with differences in the properties of the two viruses.

Interaction of non-enveloped plant viruses and their viral coat proteins with phospholipid vesicles

The interaction of the non-enveloped plant viruses TMV (rod-shaped) and CCMV (spherical) and of their coat proteins in several well-defined aggregation states, with artificial membranes was investigated to study the early stages of the cellular infection process. Information about the separate steps in the interaction mechanisms was obtained by employing three assays, performed as a function of vesicle size, net membrane charge, pH and ionic strength. The assays allow to discriminate between aggregation of vesicles (turbidity assay) and membrane destabilization (vesicle leakage assay and lipid mixing assay). The aggregation of the vesicles is a result of electrostatic interactions between the viral material and vesicles surface (cross-linking), while the destabilization of the membrane is a result of penetration or bilayer disruption by hydrophobic protein domains. TMV virions and its coat protein, and CCMV virions, due to their net negative charge, predominantly interact with positively charged membranes. The coat protein of CCMV was found to interact with negatively charged membranes, an interaction that can be assigned to its basical N-terminal sequence. Changing the aggregational state of the viral coat proteins yielded most significant interactions in case of TMV coat protein aggregated in the disk form and CCMV coat protein aggregated in empty capsids with oppositely charged membranes. These protein aggregates are found to be the best compromise between efficiency (capacity of the protein to bridge vesicles and destabilize their membranes) and concentration of protein aggregates. The results are discussed with respect to previously proposed biological models of the early stages of plant virus infection.

Inhibition of uncoating of tobacco mosaic virus particles in protoplasts from transgenic tobacco plants that express the viral coat protein gene

The uncoating of tobacco mosaic virus (TMV) particles in protoplasts isolated from leaves of transgenic tobacco plants that express the TMV coat protein gene was investigated. Extracts of these protoplasts collected up to 1 hr after inoculation with TMV contained fewer of the complexes ("striposomes") thought to be involved in cotranslational disassembly of virus particles than did extracts of protoplasts that do not express the viral coat protein gene. These results are consistent with the hypothesis that TMV coat protein-mediated resistance is at least in part the result of inhibition of the uncoating of the virus particles in the inoculum.

Sequential removal of Ca2+ from satellite tobacco necrosis virus. Crystal structure of two EDTA-treated forms

Two forms of EDTA-treated satellite tobacco necrosis virus (STNV) have been studied with X-ray crystallography methods. The crystals of both forms were isomorphous with native STNV crystals, and (FEDTA-Fnat) maps as well as (2FEDTA-Fnat) maps were calculated with phases from the native structure. The maps were based on partial data sets to 2.8 A resolution, and averaged using the 60-fold non-crystallographic symmetry. In the first crystal form, calcium ions were absent from one of the three sites in the icosahedral protein shell. The crystals were produced at pH 5.0 from a virus solution treated with EDTA at pH 6.5. The virions were not expanded, and no essential changes were seen in the protein shell. In the second crystal form, all calcium ions in the protein shell were absent. The virus material in these crystals had been subjected to treatment with EDTA at pH 8.0 before crystallization at pH 6.5. The high pH treatment caused degradation of the viral RNA. No expansion of the virion had occurred and all protein--protein contacts were retained. These results are compared with the previously presented low-resolution structure of slightly expanded STNV with intact RNA, where calcium ions from two sites were absent. The relevance of Ca2(+)-depleted virions for infection in vivo is discussed as well as the possibility that the Ca2(+)-binding sites may be parts of ion channels in the viral capsid. One possible RNA-binding site was found in the maps of both crystal types, and the same site could also be localized in the high-resolution map of native STNV.

Regulation of tobamovirus gene expression

This chapter discusses tobacco mosaic virus (TMV) strains U1, OM, L, CGMMV, 0, and Cc. The production of each TMV protein is regulated differently, both in amounts and times of production. The chapter discusses some of the strategies that tobamoviruses uses to control gene expression: (1) different subgenomic RNA promoter/leader sequences control timing of expression of genes, (2) genes expressed via subgenomic mRNAs are expressed in decreasing amounts with increasing distances from the 3' terminus, and (3) TMV mRNAs appear to be translationally regulated differently from host mRNAs. Genome organization affects gene expression, but it appears to be equally important for the efficiency of replication and the ability of the genomic structure to be stably propagated. Different virus groups have evolved different gene arrangements. Tobamovirus genes expressed via subgenomic mRNAs appear to be expressed in increasing amounts when positioned nearer the 3’ terminus.

Structure-function relationships of icosahedral plant viruses

X-ray diffraction studies on single crystals of a few viruses have led to the elucidation of their three dimensional structure at near atomic resolution. Both the tertiary structure of the coat protein subunit and the quaternary organization of the icosahedral capsid in these viruses are remarkably similar. These studies have led to a critical re-examination of the structural principles in the architecture of isometric viruses and suggestions of alternative mechanisms of assembly. Apart from their role in the assembly of the virus particle, the coat proteins of certian viruses have been shown to inhibit the replication of the cognate RNA leading to cross-protection. The coat protein amino acid sequence and the genomic sequence of several spherical plant RNA viruses have been determined in the last decade. Experimental data on the mechanisms of uncoating, gene expression and replication of several classes of viruses have also become available. The function of the non-structural proteins of some viruses have been determined. This rapid progress has provided a wealth of information on several key steps in the life cycle of RNA viruses. The function of the viral coat protein, capsid architecture, assembly and disassembly and replication of isometric RNA plant viruses are discussed in the light of this accumulated knowledge.

Visualization of protein-nucleic acid interactions in a virus. Refined structure of intact tobacco mosaic virus at 2.9 A resolution by X-ray fiber diffraction

The structure of tobacco mosaic virus (TMV) has been determined by fiber diffraction methods at 2.9 A resolution, and refined by restrained least-squares to an R-factor of 0.096. Protein-nucleic acid interactions are clearly visible. The final model contains all of the non-hydrogen atoms of the RNA and the protein, 71 water molecules, and two calcium-binding sites. Viral disassembly is driven by electrostatic repulsions between the charges in two carboxyl-carboxylate pairs and a phosphate-carboxylate pair. The phosphate-carboxylate pair and at least one of the carboxyl-carboxylate pairs appear to be calcium-binding sites. Nucleotide specificity, enabling TMV to recognize its own RNA by a repeating pattern of guanine residues, is provided by two guanine-specific hydrogen bonds in one of the three base-binding sites.

The expression of the TMV-specific 30-kDa protein in tobacco protoplasts is strongly and selectively enhanced by actinomycin

The TMV-encoded 30-kDa protein has been implicated in the cell-to-cell transport of TMV in the infected plant. The polyethylene glycol-mediated inoculation of tobacco protoplasts with TMV particles and TMV RNA was used to compare the time courses of the viral 30-kDa protein synthesis in vivo. Upon infection of protoplasts with TMV RNA, the synthesis of the viral 30-kDa protein starts after 4 to 6 hr, has its maximum after 8 to 10 hr, and decreases. After inoculation of protoplasts with TMV, however, the start of the viral 30-kDa protein synthesis and its maximum are delayed by 2 hr, followed by the same decrease. We show that actinomycin D dramatically stimulates the synthesis of the 30-kDa protein by up to 2 orders of magnitude, whereas the synthesis of the viral 126 kDa, the 183 kDa, and the coat protein is increased only by a factor of 2. Surprisingly, actinomycin V is twice as active as actinomycin D, whereas actinomycin I is nearly inactive. The specific stimulation of the 30-kDa synthesis by actinomycin D in vivo depends neither on the Nicotiana variety nor on the TMV strain used. Final evidence that the 30-kDa protein is truly TMV-derived is provided by the slightly different electrophoretic mobilities of the 30-kDa proteins encoded by TMV strains vulgare, dahlemense, and U2. The identification of the 30-kDa protein in two-dimensional gels was achieved for the first time by a combination of ionic and nonionic detergents for the solubilization of the 30-kDa protein and by the specific stimulation of its synthesis by actinomycin D. The mechanism of the strong and selective actinomycin effect on the viral 30-kDa protein synthesis in vivo is as yet obscure. Actinomycin does not appear to act directly on viral protein biosynthesis, since it neither stimulates the 30-kDa synthesis upon translation of TMV RNA in vitro nor alters the ratio of the products. Actinomycin may rather act by inhibiting selectively the synthesis of a host factor whose synthesis starts at least 4 hr after TMV infection and which strongly inhibits the expression of the viral 30-kDa transport protein.

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.

Resistance to TMV in transgenic plants results from interference with an early event in infection

Constitutive expression of the tobacco mosaic virus (TMV) coat protein (CP) gene in transgenic tobacco plants results in inhibition of disease symptom development following inoculation with TMV. Evidence is presented here that this protection is also observed in leaf mesophyll protoplasts isolated from these plants. Protoplasts were resistant to infection by TMV at concentrations of 10 microgram/ml to 1 mg/ml when introduced by either electroporation or polyethylene glycol-mediated inoculation. There was little protection against infection by TMV RNA and the protection was lost as the concentration of TMV RNA in the inoculum increased. When virus was incubated briefly at pH 8.0 prior to inoculation, protection broke down in a manner similar to that observed following RNA inoculation. Analogous results were obtained in experiments with whole plants. Because virus treated in this manner has presumably lost little or no CP, these results suggest that expression of the TMV CP gene in transgenic plant cells prevents TMV from uncoating. A model is presented for the mechanism of this blockage which relates these results to early events in TMV infection.

Selective encapsidation of CAT gene transcripts in TMV-infected transgenic tobacco inhibits CAT synthesis

Young tobacco seedlings (F1-progeny), transformed to express chloramphenicol acetyltransferase (CAT) mRNA with or without a 3'-proximal copy of the origin-of-assembly sequence (OAS) from tobacco mosaic virus (TMV) RNA (residues 5118-5550), were inoculated with TMV. After 21 days, virus symptoms were observed and systemic TMV infections were confirmed by Western blotting for viral coat protein and by electron microscopy of leaf saps. CAT activities were measured in extracts of leaf discs taken before, and 21 days after, virus inoculation. On average, the systemic leaves from TMV-infected CAT-transgenic plants containing the OAS exhibited 3.2-fold less CAT activity than the equivalent leaves from CAT-transgenic control plants lacking the OAS. Hence selective, OAS-dependent encapsidation of nuclear DNA transcripts into TMV-like (pseudovirus) particles can reduce expression of a particular mRNA, post-transcriptionally, in vivo. Furthermore, these data indicate that TMV self-assembly is not restricted to an exclusive subcellular compartment in vivo, and that formation of natural pseudovirions (A. Siegel, Virology 46, 50-59 (1971)) may shut off specific host RNA functions.

Anti-sense RNAs of cucumber mosaic virus in transgenic plants assessed for control of the virus

Three synthetic genes for the production of anti-sense RNA to different regions of the cucumber mosaic virus (CMV) genome were constructed using virus-derived double-stranded cDNA coupled to a promoter sequence from cauliflower mosaic virus. The genes were used to transform tobacco plants by a Ti plasmid vector. Transgenic plants obtained with the three constructs produced anti-sense RNA at different levels. Plants expressing each of the three anti-sense RNAs were inoculated with CMV and their sensitivity to the virus infection was compared with the non-transformed plants. Only one plant line which expressed relatively low levels of one of the anti-sense RNAs showed resistance to CMV but other plants expressing the same or the other two antisense RNAs had similar sensitivity to CMV infection as the non-transformed plants.

Binding of cowpea chlorotic mottle virus to cowpea protoplasts and relation of binding to virus entry and infection

Cowpea chlorotic mottle virus (CCMV) and cowpea protoplasts were used to study initial interactions between virus and protoplast. Protoplasts and virus were incubated under varying conditions of temperature, pH, ionic strength, and the presence of added compounds. Both the amount of 35S-labeled virus bound to protoplasts and the percentage of infected cells were determined. At 0 and 25 degrees the amount of virus associated with protoplasts increased with the amount of virus added. With inoculum of 25 x 10(6) virus particles per protoplast, 4 x 10(3) and 14 x 10(3) particles per protoplast were bound at 0 and 25 degrees, respectively. In the presence of polyethylene glycol, 85 x 10(3) associated particles per protoplast were bound at both temperatures and ca. 50% of the protoplasts became infected. No infection occurred in the absence of PEG. Variation of pH or ionic strength in the absence of PEG caused little to no change in binding and no infection. In the presence of PEG, increase of pH resulted in lower binding, but infectivity was not affected. Increasing ionic strength, however, increased both binding and infectivity. The presence of unlabeled CCMV, tobacco mosaic virus coat protein, bovine serum albumin, and polycations during inoculation in the absence of PEG decreased the amount of bound CCMV. In contrast, CCMV coat protein, which has a positively charged N-terminal arm, increased binding. In the presence of PEG the effects were similar, although larger amounts of virus were bound. The percentage of infection was reduced by all additives to 5-25%. Addition of ammonium chloride, which inhibits endocytotic virus uptake in animal cells, during inoculation as well as in culture media, did not reduce infectivity. These data do not support a specific receptor-mediated endocytotic uptake of virus but favor a nonspecific mechanism of entry, possibly through membrane lesions. Observations in the electron microscope support the latter mechanism.

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.