Long-distance movement factor: a transport function of the potyvirus helper component proteinase

Plant viral synergism: the potyviral genome encodes a broad-range pathogenicity enhancer that transactivates replication of heterologous viruses

Synergistic viral diseases of higher plants are caused by the interaction of two independent viruses in the same host and are characterized by dramatic increases in symptoms and in accumulation of one of the coinfecting viruses. In potato virus X (PVX)/potyviral synergism, increased pathogenicity and accumulation of PVX are mediated by the expression of potyviral 5' proximal sequences encoding P1, the helper component proteinase (HC-Pro), and a fraction of P3. Here, we report that the same potyviral sequence (termed P1/HC-Pro) enhances the pathogenicity and accumulation of two other heterologous viruses: cucumber mosaic virus and tobacco mosaic virus. In the case of PVX-potyviral synergism, we show that the expression of the HC-Pro gene product, but not the RNA sequence itself, is sufficient to induce the increase in PVX pathogenicity and that both P1 and P3 coding sequences are dispensable for this aspect of the synergistic interaction. In protoplasts, expression of the potyviral P1/HC-Pro region prolongs the accumulation of PVX (-) strand RNA and transactivates expression of a reporter gene from a PVX subgenomic promoter. Unlike the synergistic enhancement of PVX pathogenicity, which requires only expression of HC-Pro, the enhancement of PVX (-) strand RNA accumulation in protoplasts is significantly greater when the entire P1/HC-Pro sequence is expressed. These results indicate that the potyviral P1/HC-Pro region affects a step in disease development that is common to a broad range of virus infections and suggest a mechanism involving transactivation of viral replication.

Mutations in the region encoding the central domain of helper component-proteinase (HC-Pro) eliminate potato virus X/potyviral synergism

Coinfection of tobacco plants with potato virus X (PVX) and any of several members of the potyvirus group causes a synergistic disease characterized by a dramatic increase in symptom severity correlated with a 3- to 10-fold increase in the accumulation of PVX in the first systemically infected leaves. We have recently shown that PVX/potyviral synergistic disease is mediated by expression of potyviral 5'-proximal sequences encoding P1, helper component-proteinase (HC-Pro), and a fraction of P3 (termed P1/HC-Pro sequence). Here we report the effect of mutations in this potyviral sequence on the induction of synergistic disease. Three transgenic tobacco lines expressing the tobacco etch potyvirus (TEV) P1/HC-Pro sequence with mutations within the P1 coding region were not impaired in their ability to mediate synergism when infected with PVX. In contrast, two of three transgenic lines with mutations in the HC-Pro coding region were unable to induce the synergistic increases in either symptom severity or PVX accumulation. Loss of synergistic function was associated with mutations within the region encoding the central domain of HC-Pro, while the ability to induce synergism was retained in a transgenic line expressing HC-Pro with an alteration in the amino-terminal "zinc-finger domain." In coinoculation experiments, a TEV mutant lacking the sequence encoding the zinc-linger domain of HC-Pro induced a typical synergistic response in interaction with PVX. The results indicate that the zinc-finger domain comprising the first 66 amino acid residues of HC-Pro is dispensable for induction of synergistic disease and transactivation of PVX multiplication, while regions within the central domain of HC-Pro are essential for both of these responses.

Genome amplification and long-distance movement functions associated with the central domain of tobacco etch potyvirus helper component-proteinase

The tobacco etch potyvirus (TEV) helper component-proteinase (HC-Pro, 460 amino acid residues) is a multifunctional protein involved in aphid-mediated transmission, genome amplification, polyprotein processing, and long-distance movement. To investigate the interrelationships between three of these functions, 25 alanine-scanning mutations affecting clusters of charged residues were introduced into the HC-Pro coding sequence. The resulting mutants were analyzed with respect to HC-Pro proteolytic activity in vitro, genome amplification in protoplasts, and long-distance movement in tobacco plants. Three classes of mutants were identified. Class I mutants (total of 17) were capable of genome amplification, long-distance movement, and HC-Pro proteolysis with efficiencies similar to parental virus. The class III mutant (total of 1) encoded a proteolytically debilitated HC-Pro and was replication-defective. Class II mutants (total of 7) encoded proteolytically active HC-Pro, but each exhibited a suppressed amplification phenotype that was characterized by a progressive shutoff during the course of infection in protoplasts. The class II mutants also exhibited defects in long-distance movement, accumulating to relative levels of 0 to 7.5% in noninoculated tissue. Wild-type HC-Pro supplied in trans was able to partially rescue the class II mutant amplification defects in protoplasts and long-distance movement defects in plants, although the extent of complementation of movement function varied for each mutant. Six of the seven class II mutations affected the central region of HC-Pro between residues 126 and 300, whereas only one affected the C-terminal proteolytic domain. These results indicate that the central region of HC-Pro is necessary for efficient genome amplification and long-distance movement, and that the one or more HC-Pro functions involved in these processes is at least partially trans-active. Additionally, the long-distance movement properties of a previously characterized HC-Pro-defective mutant (TEV-GUS/CCCE) were characterized further using grafted nontransgenic and HC-Pro-expressing transgenic plants. The results indicated that HC-Pro is required in both inoculated and noninoculated tissues to complement the TEV-GUS/CCCE movement defects.

Invasion of minor veins of tobacco leaves inoculated with tobacco mosaic virus mutants defective in phloem-dependent movement

To fully understand vascular transport of plant viruses, the viral and host proteins, their structures and functions, and the specific vascular cells in which these factors function must be determined. We report here on the ability of various cDNA-derived coat protein (CP) mutants of tobacco mosaic virus (TMV) to invade vascular cells in minor veins of Nicotiana tabacum L. cv. Xanthi nn. The mutant viruses we studied, TMV CP-O, U1mCP15-17, and SNC015, respectively, encode a CP from a different tobamovirus (i.e., from odontoglossum ringspot virus) resulting in the formation of non-native capsids, a mutant CP that accumulates in aggregates but does not encapsidate the viral RNA, or no CP. TMV CP-O is impaired in phloem-dependent movement, whereas U1mCP15-17 and SNC015 do not accumulate by phloem-dependent movement. In developmentally-defined studies using immunocytochemical analyses we determined that all of these mutants invaded vascular parenchyma cells within minor veins in inoculated leaves. In addition, we determined that the CPs of TMV CP-O and U1mCP15-17 were present in companion (C) cells of minor veins in inoculated leaves, although more rarely than CP of wild-type virus. These results indicate that the movement of TMV into minor veins does not require the CP, and an encapsidation-competent CP is not required for, but may increase the efficiency of, movement into the conducting complex of the phloem (i.e., the C cell/sieve element complex). Also, a host factor(s) functions at or beyond the C cell/sieve element interface with other cells to allow efficient phloem-dependent accumulation of TMV CP-O.

The complete nucleotide sequence of yam mosaic virus (Ivory Coast isolate) genomic RNA

The complete nucleotidic sequence of the yam mosaic virus (YMV) RNA was determined following the cloning of partial segments of the genome by reverse transcription and polymerase chain reactions (RT-PCR) using degenerate and/or specific oligonucleotide primers. YMV genomic RNA is 9,608 nucleotides in length and contains one open reading frame (ORF) encoding a polyprotein of 3,103 amino acids (aa) with a calculated Mr of 350,915. The 5' leader sequence of YMV RNA preceding the ORF is 134 nucleotides (nt) long while the 3' untranslated region (UTR) is 165 nt excluding the poly(A) tail. A computer algorithm predicted that the 3'UTR forms four stem loop structures which form a cloverleaf-like secondary structure. These structures apparently share some homologies with those observed in the 3'UTR of the potato virus Y-NL1 strain. Seven potential recognition sites for the NIa protease were found: one putative cleavage site for the P1 proteinase and one for the HC proteinase. The organization of the YMV genome is therefore similar to the other members of the genus Potyvirus based upon conserved sequence motifs common amongst members of this group. Despite its similarity with the other potyviruses in these conserved regions, YMV appears to be a distinct potyvirus species based upon a comparison of its sequence with those of other potyviruses.

Suppression of long-distance movement of tobacco etch virus in a nonsusceptible host

To investigate host functions involved in the tobacco etch potyvirus (TEV) infection process, a tobacco line (V20) with a strain-specific defect in supporting systemic infection was analyzed. Using a modified TEV encoding a reporter protein, beta-glucuronidase (GUS), genome amplification, cell-to-cell movement, and long-distance movement were measured in V20 and a susceptible line, Havana425. Comparable levels of TEV-GUS genome amplification were measured in inoculated protoplasts from both tobacco lines. The rates of cell-to-cell movement of virus in inoculated leaves were nearly identical in V20 and Havana425 between 48 and 72 h postinoculation. In contrast, long-distance movement from leaf to leaf was markedly restricted in V20 relative to Havana425. In situ histochemical analysis of inoculated leaves revealed that infection foci expanded radially over time, providing the potential for contact of virus with veins. Immunocytochemical analysis of V20 tissue from infection foci indicated that TEV-GUS entered the phloem parenchyma or companion cells adjacent to the sieve elements, suggesting that the block in long-distance movement was associated with entry into, or exit from, sieve elements. The genetic basis for the V20 restriction was characterized in a segregation analysis of a cross between V20 and Havana425. The heterozygous F1 progeny displayed the susceptible phenotype, indicating that the V20 restriction was a recessive trait. Segregation in the F2 progeny indicated that the restriction was likely due to the interaction of recessive genes at two nonlinked loci. These data support the hypothesis that long-distance movement requires a set of host functions that are distinct from those involved in cell-to-cell movement.

Plant virus gene vectors for transient expression of foreign proteins in plants

The development of plant virus gene vectors for expression of foreign genes in plants provides attractive biotechnological tools to complement conventional breeding and transgenic methodology. The benefits of virus-based transient RNA and DNA replicons versus transgenic gene expression include rapid and convenient engineering coupled with flexibility for expeditious application in various plant species. These characteristics are especially advantageous when very high levels of gene expression are desired within a short time, although instability of the foreign gene in the viral genome can present some problems. The strategies that have been tested for foreign gene expression in various virus-based vectors include gene replacement, gene insertion, epitope presentation, use of virus controlled gene expression cassettes, and complementation. Recent reports of the utilization of virus vectors for foreign gene expression in fundamental research and biotechnology applications are discussed.

Helper-dependent vector transmission of plant viruses

A variety of noncirculatively transmitted viruses have evolved a vector transmission strategy that involves, in addition to virions, virus-encoded proteins that are not constituents of virions. These "helpers" and the genes encoding them have been characterized for viruses in the genera Potyvirus and Caulimovirus. Several lines of evidence support the hypothesis that these helpers act by mediating retention of virions in regions of the vector's alimentary tract from which they subsequently can be egested to initiate an infection. The possible advantage this convergently evolved strategy could confer to noncirculatively transmitted virus quasispecies is discussed.

Principles of molecular organization, expression, and evolution of closteroviruses: over the barriers

This chapter focuses on the molecular organization, evolution, and expression of closterovirus genomes, as well as on their unique particle structure. The closterovirus group combines several positive-strand RNA viruses with very flexuous filamentous particles, of which beet yellows virus (BYV) is the type virus. Closteroviruses are distinct from other RNA viruses of plants in some important phenomenological aspects. They have genomes of up to 20 kilobases (kb), a value comparable only to those of the animal coronaviruses and toroviruses, which have the largest RNA genomes of all positive-strand RNA viruses. The existence of such genomes having a coding capacity several times that of an average RNA virus genome raises questions as to the trend whereby the long genomes have evolved and the possible novel functions they have acquired. The dramatic increase in the closterovirus genome coding capacity may be linked to the distinct ecological niche they occupy. Thus, closteroviruses are the only elongated plant viruses known so far to cause phloem-limited infections in plants and to persist in their insect vectors for many hours, in contrast to only minutes.