Sorghum chlorotic spot virus binds to potyvirus cylindrical inclusions in tobacco leaf cells

Nicotiana benthamiana can be doubly infected with either potato virus Y or tobacco etch virus and sorghum chlorotic spot virus (SCSV). Immunogold labeling showed that cylindrical inclusions of either potyvirus bind virions of the unrelated rod-shaped furovirus SCSV. Not all cells in doubly infected N. benthamiana plants contained both viruses. In cells infected by the potyviruses but not by SCSV, cylindrical inclusions did not label with the antiserum to SCSV. Numbers of cells infected with SCSV did not increase in doubly infected plants compared to those in plants infected with SCSV alone. Systemic infection of N. benthamiana by either potyvirus was not prevented by SCSV infections. This provides further evidence that unrelated rod-shaped viruses can bind to potyvirus cylindrical inclusion bodies, and that this phenomenon is not limited to graminaceous hosts.     

Distinct functions of capsid protein in assembly and movement of tobacco etch potyvirus in plants.

Tobacco etch potyvirus engineered to express the reporter protein beta-glucuronidase (TEV-GUS) was used for direct observation and quantitation of virus translocation in plants. Four TEV-GUS mutants were generated containing capsid proteins (CPs) with single amino acid substitutions (R154D and D198R), a double substitution (DR), or a deletion of part of the N-terminal domain (delta N). Each modified virus replicated as well as the parental virus in protoplasts, but was defective in cell-to-cell movement through inoculated leaves. The R154D, D198R and DR mutants were restricted essentially to single, initially infected cells. The delta N variant exhibited slow cell-to-cell movement in inoculated leaves, but was unable to move systemically due to a lack of entry into or replication in vascular-associated cells. Both cell-to-cell and systemic movement defects of each mutant were rescued in transgenic plants expressing wild-type TEV CP. Cell-to-cell movement, but not systemic movement, of the DR mutant was rescued partially in transgenic plants expressing TEV CP lacking the C-terminal domain, and in plants expressing CP from the heterologous potyvirus, potato virus Y. Despite comparable levels of accumulation of parental virus and each mutant in symptomatic tissue of TEV CP-expressing transgenic plants, virions were detected only in parental virus- and delta N mutant-infected plants, as revealed using three independent assays. These data suggest that the potyvirus CP possesses distinct, separable activities required for virion assembly, cell-to-cell movement and long-distance transport.     

Comparison of resistance to potyviruses within Solanaceae: infection of potatoes with tobacco etch potyvirus and peppers with potato A and Y potyviruses

The reaction of several cultivated potato varieties (Solarium tuberosum L.) to three strains of tobacco etch potyvirus (TEV-F, TEV-Mex21 and TEV-ATCC) and the reaction of several pepper lines (Capsicum annuum L. and C. chinense L.) to two strains of potato Y potyvirus (PVY^O and PVY^N) and one strain of potato A potyvirus (PVA-M) was tested. The potato varieties included in this study carried resistance genes against PVY, PVA and potato V potyvirus, but all were susceptible to TEV and developed mottle and mosaic symptoms. TEV was readily transmitted by mechanical inoculation from tobacco and potato to potato, whereas transmission from pepper to potato occurred infrequently. TEV was transmitted through potato tubers, and from pepper to potato plants by aphids. Lack of detectable systemic infection following graft-inoculation indicated extreme resistance to PVY^O and PVA in several pepper lines. No pepper line was systemically infected with PVY^N following mechanical inoculation (graft-inoculation was not carried out with PVY^N). The development of necrotic lesions following mechanical and graft-inoculation indicated hypersensitive response to PVY^O in several pepper lines which resembled the resistance responses to these potyvirus strains in potato. Results of this study together with previous work indicate that C. annuum cv. Avelar is resistant to four potyviruses [PVY, PVA, pepper mottle potyvirus (PepMoV) and some isolates of TEV]; C. annuum cv. Criollo de Morelos and C. chinense PI 152225 and PI 159236 are resistant to three potyviruses (PVY, PepMoV and PVA; and PVY, PepMoV and TEV, respectively); C. annuum 9093–1 and 92016–1 are resistant to PVY and PepMoV; and C. annuum cv. Jupiter and C. annuum cv. RNaky are resistant to PVY^N and PVA.     

Light and electron microscopy of virus inclusions inAmaranthus lividus cells

Summary Amaranthus plants infected with a virus of rod-shaped particles showed under the light microscope intracytoplasmic amorphous and crystalline inclusions.The submicroscopic organization of mesophyll cells from infectedAmaranthus leaves by electron microscopy is described. Besides big crystalline inclusions, long dark inclusions correspondent to needle-like inclusions observed by light microscopy are definable in the cytoplasm. The amorphous inclusion bodies were formed by an overgrown protrusion of vacuolate cytoplasm containing virus particles, long very dark stained inclusions forming dense bands and rings, normal elements of the cytoplasm such as mitochondria, endoplasmic reticulum and ribosomes, and some spherosomes. Inclusions and virus particles were not found in chloroplasts, mitochondria or nuclei of infected cells.     

RNA-Dependent RNA Polymerase (NIb) of the Potyviruses Is an Avirulence Factor for the Broad-Spectrum Resistance Gene Pvr4 in Capsicum annuum cv. CM334

Potyviruses are one of the most destructive viral pathogens of Solanaceae plants. In Capsicum annuum landrace CM334, a broad-spectrum gene, Pvr4 is known to be involved in resistance against multiple potyviruses, including Pepper mottle virus (PepMoV), Pepper severe mosaic virus (PepSMV), and Potato virus Y (PVY). However, a potyvirus avirulence factor against Pvr4 has not been identified. To identify the avirulence factor corresponding to Pvr4 in potyviruses, we performed Agrobacterium-mediated transient expressions of potyvirus protein coding regions in potyvirus-resistant (Pvr4) and -susceptible (pvr4) pepper plants. Hypersensitive response (HR) was observed only when a RNA-dependent RNA polymerase (NIb) of PepMoV, PepSMV, or PVY was expressed in Pvr4-bearing pepper leaves in a genotype-specific manner. In contrast, HR was not observed when the NIb of Tobacco etch virus (TEV), a virulent potyvirus, was expressed in Pvr4-bearing pepper leaves. Our results clearly demonstrate that NIbs of PepMoV, PepSMV, and PVY serve as avirulence factors for Pvr4 in pepper plants.     

Genetic variability of Potato virus Y (PVY) and Tobacco etch virus (TEV) from naturally infected pepper fields in the Hatay region of Turkey

The genetic structure of Potato virus Y (PVY) and Tobacco etch virus (TEV) (Potyvirus) populations was investigated in pepper fields in two regions in Turkey. The diversity of PVY and TEV populations according to coat protein (CP) and VPg coding regions showed some similarity. All the isolates built a monophyletic group due to a single introduction event or multiple introductions of genetically similar isolates. All the isolates of both viruses showed evidence to the diversification for a long time. Based on VPg and CP sequences, all PVY isolates corresponded to clade C1. Turkish potyvirus isolates were only able to break the pvr2¹ resistance allele and therefore belonged to pathotype (0,?1). The Pvr4 dominant gene was found to be efficient and durable against PVY but not at all efficient against TEV. Consequently, the pvr2² resistance allele, efficient resistance against PVY and TEV pathotype (0,?1) isolates, would be the most suitable strategy to control potyviruses.     

Host Ranges, Serology and Cytopathology of Eggplant and Tomato Strains of Eggplant Severe Mottle Virus, a New Potyvirus from Nigeria

Two potyvirus isolates from the eggplant (Solanum melongena L.) cultivars ‘Ex Benin’ and ‘Ex Jos’, respectively, in Nigeria proved to be almost identical in host range, symptomatology and reactivity with antisera to various potyviruses. In eggplant they caused a severe systemic mottle, blistering and malformation of leaves and an abnormal serration of the leaf margins. A potyvirus isolate from tomato showing mosaic symptoms was similar, but not identical to the eggplant isolates. In the slide, precipitin test the serological differentiation indices were between 1 and 3 for the eggplant and tomato isolates. In the immunoelectron microscopical decoration test all three virus isolates showed some reactivity with antisera to the following potyvir, uses: dioscorea green banding mosaic, groundnut eyespot, a mungbean isolate of peanut stripe, pepper veinal mottle, telfairia mosaic and a tomato isolate from Taiwan. No reactions were observed with antisera to other potyviruses. Cytopathogenic effects w,ere similar for all three isolates in the arrangement of virus particles, the structure of the cylindrical inclusions and the occurrence of clusters of small vesicles. However, other cytological alterations like accumulations of rod-shaped aggregates of,granular material, formation of giant mitochondria, degeneration of mitochondria and occurrence of a nucleolar inclusion differentiated the isolates.     

Genetic evidence for an essential role for potyvirus CI protein in cell‐to‐cell movement

The potyvirus cylindrical inclusion (CI) protein, an RNA helicase required for genome replication, was analyzed genetically using alanine-scanning mutagenesis. Thirty-one mutations were introduced into the CI protein coding region of modified tobacco etch virus (TEV) genomes expressing either β-glucuronidase or green fluorescent protein reporters. Twelve of the mutants were replication-defective in protoplast inoculation assays. Among the 19 replication-competent mutants, several possessed cell-to-cell or long-distance movement defects in tobacco plants. Two mutants, AS1 and AS8, were restricted to single cells in inoculated leaves despite genome amplification levels that were equivalent to that of parental virus. Other mutants, such as AS9 and AS14, were able to move cell to cell slowly but were debilitated in long-distance movement. These data provide genetic evidence for a direct role of CI protein in potyvirus intercellular movement, and for distinct roles of the CI protein in genome replication and movement. In combination with high-resolution ultrastructural analyzes and previous genetic data, these results support a model in which CI protein interacts directly with plasmodesmata and capsid protein-containing ribonucleoprotein complexes to facilitate potyvirus cell-to-cell movement.     

Formation of Complexes at Plasmodesmata for Potyvirus Intercellular Movement Is Mediated by the Viral Protein P3N-PIPO

Intercellular transport of viruses through cytoplasmic connections, termed plasmodesmata (PD), is essential for systemic infection in plants by viruses. Previous genetic and ultrastructural data revealed that the potyvirus cyclindrical inclusion (CI) protein is directly involved in cell-to-cell movement, likely through the formation of conical structures anchored to and extended through PD. In this study, we demonstrate that plasmodesmatal localization of CI in N. benthamiana leaf cells is modulated by the recently discovered potyviral protein, P3N-PIPO, in a CI:P3N-PIPO ratio-dependent manner. We show that P3N-PIPO is a PD-located protein that physically interacts with CI in planta. The early secretory pathway, rather than the actomyosin motility system, is required for the delivery of P3N-PIPO and CI to PD. Moreover, CI mutations that disrupt virus cell-to-cell movement compromise PD-localization capacity. These data suggest that the CI and P3N-PIPO complex coordinates the formation of PD-associated structures that facilitate the intercellular movement of potyviruses in infected plants.     

Expression of Multiple Virus-derived Resistance Determinants in Transgenic Plants Does Not Lead to Additive Resistance Properties

Plants can be protected against infection by potyviruses by expressing different portions of potyviral genomes as transgenes. This strategy has proven effective with several potyvirus genes, including the Nla, Nlb, and coat protein coding regions. Given the effectiveness of separate potyvirus coding regions as determinants of resistance, we tested the hypothesis that combinations of potyvirus coding regions would provide additively greater protection of plants against potyviruses. For this, we compared transgenic plant lines that expressed either the coat protein (CP) or the Nla+Nlb+coat protein (NNC) coding regions from tobacco vein mottling virus (TVMV). We found that plants that carry the NNC gene combination were invariably less resistant to TVMV than were lines that contain a CP gene alone. Additionally, we found that NNC lines displayed virtually no resistance to tobacco etch virus (TEV), in contrast to the CP lines. We conclude that combining more than one virus-derived resistance determinant in a single construct is detrimental to the production of virus-resistant plants.     

Cytopathology of Plgeonpea sterility mosaic virus in pigeonpea and Nicotiana benthamiana: similarities with those of eriophyid mite-borne agents of undefined aetiology

Pigeonpea sterility mosaic virus (PPSMV) is transmitted by the eriophyid mite, Aceria cajani, and is very closely associated with sterility mosaic disease (SMD) of pigeonpea (Cajanus cajah) in the Indian subcontinent. Antiserum produced to purified PPSMV preparations detected a virus‐specific 32 kDa protein in sap of SMD‐affected pigeonpea plants by ELISA and Western blotting. PPSMV was transmitted mechanically in sap of SMD‐affected pigeonpea leaves to Nicotiana benthamiana. Ultrastructural studies of symptom‐bearing leaves of two pigeonpea cultivars, (ICP8863 and ICP2376) and N. benthamiana infected with PPSMV, detected quasi‐spherical, membrane bound bodies (MBBs) of c. 100–150 nm and amorphous electron‐dense material (EDM). These structures were distributed singly or in groups, in the cytoplasm of all cells, except those in conductive tissues. Fibrous inclusions (FIs), composed of randomly dispersed fibrils with electron lucent areas, were present in the cytoplasm of palisade cells and rarely in mesophyll cells of the two pigeonpea cultivars but were not detected in infected TV. benthamiana plants. In the PPSMV‐infected pigeonpea cultivars and TV. benthamiana, immuno‐gold labelling, using antiserum to PPSMV, specifically labelled the MBBs and associated EDM, but not the FIs. The MBBs and associated inclusions are similar in appearance to those reported for plants infected with the eriophyid mite‐transmitted High Plains virus and the agents of unidentified aetiology associated with rose rosette, fig mosaic, thistle mosaic, wheat spot chlorosis and yellow ringspot of budwood. The nature of these different inclusions is discussed.     

Immunocytology Shows the Presence of Tobacco Etch Virus P3 Protein in Nuclear Inclusions

Intracellular localization studies of various potyvirus proteins have been made in hope of finding clues to their function(s). Immunocytological studies localized many of the tobacco etch virus (TEV)-encoded proteins in infected cells. We used antiserum against the nonstructural P3 protein of TEV to determine the subcellular location of the P3 protein in ultrathin sections of virus-infected cells. Immunogold labeling with the antiserum showed labels associated with nucleoli, nuclei, or NIs. Absorption of antiserum with purified NIs or P3 protein resulted in no labeling. TEV NIs are known to contain a bifunctional genome-linked protein–viral proteinase (NIa–VPg) and RNA-dependent RNA polymerase (NIb). It appeared that the TEV P3 protein was a third nonstructural viral protein of NIs of TEV if the NIa–VPg is considered one protein. The presence of P3 in NIs was also supported by Western blot assays. P3 protein in the nucleolus and nucleus could indicate that it, too, is involved in early stages of viral replication.     

Herpes simplex virus type 1 and pseudorabies virus bind to a common saturable receptor on Vero cells that is not heparan sulfate.

Herpes simplex virus type 1 (HSV-1) and pseudorabies virus (PRV) infect different natural hosts but are very similar in structure, replicative cycle, and entry into cultured cells. We determined whether HSV-1 and PRV use the same cellular components during entry into Vero cells, which are highly susceptible to each virus but are not from native hosts for either. UV-inactivated virions of either HSV-1 or PRV could saturate cell surfaces to block infection of challenge HSV-1 or PRV. In the presence of saturating levels for infection of either virus, radiolabeled virus bound well and in a heparin-sensitive manner. This result shows that heparan sulfate proteoglycans on Vero cells are not the limiting cellular component. To identify the virus component required for blocking, we used an HSV-1 null mutant virus lacking gB, gD, or gH as blocking virus. Virions lacking gB were able to block infection of challenge virus to the same level as did virus containing gB. In contrast, virions lacking gD lost all and most of the ability to block infection of HSV-1 and PRV, respectively. HSV-1 lacking gH and PRV lacking gp50 also were less competent in blocking infection of challenge virus. We conclude that HSV-1 and PRV bind to a common receptor for infection of Vero cells. Although both viruses bind a heparin-like cell component on many cells, including Vero cells, they also attach to a different and limited cell surface component that is bound at least by HSV-1 gD and possibly gH and to some degree by PRV gp50 but not gB. These results clearly demonstrate binding of both HSV-1 and PRV to a common cell receptor that is not heparan sulfate and demonstrate that several types of attachment occur for both viruses during infectious entry.     

Alpha-herpesvirus glycoprotein D interaction with sensory neurons triggers formation of varicosities that serve as virus exit sites

Alpha-herpesviruses constitute closely related neurotropic viruses, including herpes simplex virus in man and pseudorabies virus (PRV) in pigs. Peripheral sensory neurons, such as trigeminal ganglion (TG) neurons, are predominant target cells for virus spread and lifelong latent infections. We report that in vitro infection of swine TG neurons with the homologous swine alpha-herpesvirus PRV results in the appearance of numerous synaptophysin-positive synaptic boutons (varicosities) along the axons. Nonneuronal cells that were juxtaposed to these varicosities became preferentially infected with PRV, suggesting that varicosities serve as axonal exit sites for the virus. Viral envelope glycoprotein D (gD) was found to be necessary and sufficient for the induction of varicosities. Inhibition of Cdc42 Rho GTPase and p38 mitogen-activated protein kinase signaling pathways strongly suppressed gD-induced varicosity formation. These data represent a novel aspect of the cell biology of alpha-herpesvirus infections of sensory neurons, demonstrating that virus attachment/entry is associated with signaling events and neuronal changes that may prepare efficient egress of progeny virus.     

Further Studies on a Virus Causing a Green Mosaic Disease of Eggplant in Nigeria

A virus reported earlier to cause a green mosaic disease of eggplant in Nigeria was studied in more detail. Its filamentous particles with a normal length of 820 nm reacted in immunoelectron microscopical tests strongly with the homologous antiserum and less strongly with antisera to dioscorea green banding mosaic, groundnut eyespot, zucchini yellow mosaic viruses and to a tomato potyvirus isolate from Taiwan. No reactions were seen with antisera to 25 other potyviruses. Several new host plants were identified. Infected cells contained cylindrical inclusions with scrolls and short curved laminated aggregates and clusters of small vesicles with electron-dense content. Host range and serological reactivities differentiate the virus for which the name eggplant green mosaic virus is suggested from all potyviruses so far known.     

Expression of the PVYO coat protein (CP) under the control of the PVX CP gene leader sequence: protection under greenhouse and field conditions against PVYO and PVYN infection in three potato cultivars

Coat protein-mediated resistance (CPMR), resistance conferred as a result of the expression of viral coat proteins in transgenic plants, has been illustrated to be an effective way of protecting plants against several plant viruses. Nonetheless, consistent protection has not been achieved for transgenic plants expressing the coat protein of potato virus Y (PVY), the type member of the potyvirus family. In this report, three different potato cultivars were transformed with a chimeric construct consisting of the capsid protein (CP) coding sequences of PVY flanked by the AUG codon and the translational enhancer from the coat protein gene of potato virus X (PVX). These cultivars were shown to express high levels of PVY CP and confer a high degree of protection against PVY^o and PVY^N under both greenhouse and field conditions. In addition, transgenic plants infected with potato virus A (PVA), a related potyvirus, exhibited a delay in virus accumulation, which could be easily overcome with increasing virus concentrations. Received: 26 October 1995 / Accepted: 14 June 1996     

Immunocytochemical investigation of the causal agent of cassava mosaic disease in southern Africa

Cassava mosaic disease (CMD) exists throughout Africa, and cassava latent virus (CLV) has been implicated as the etiological agent in Kenya and West Africa. However, in Southern Africa, the causal agent of CMD was not until recently associated with CLV, and the possibility of a second flexuous virus particle has not been ignored. Attempts to isolate and visualize CLV antigen have been successful with Nicotiana benthamiana, an indicator host plant of CLV, but all efforts to isolate and visualize particles in infected cassava plants have failed. Immunocytochemical studies were undertaken in an attempt to localize virus antigen in infected cassava tissue.Cytochemical staining (light microscope) of infected cassava leaf material revealed the presence of inclusion bodies in epidermal and palaside mesophyll cells, and in epidermal collenchyma and outer parenchyma cells from the petiole and stem. However, transmission electron-microscopical (TEM) investigations revealed electron dense bodies in the cytoplasm, and no characteristic CLV nuclear inclusion bodies were evident. Transmission experiments to N. benthamiana and N. tabacum were attempted and leaves, exhibiting symptoms, examined microscopically. The nuclei appeared swollen (in comparison to uninfected leaves), a characteristic of CLV- infected N. benthamiana. However at the TEM level, no characteristic fibrillar-ring inclusion bodies or particles, could be visualized.Further immunocytochemical investigations were initiated, employing antisera raised against CLV isolated from N. benthamiana, and antisera for cassava common mosaic virus (CCMV), cassava brown streak virus (CBSV) and cassava X virus (CsXV). Goat anti-rabbit IgG-gold was used as a direct stain. No labelling occurred with CCMV and CBSV antisera. Intense gold labelling was located in the cytoplasm of phloem, mesophyll and epidermal cells of infected cassava and to a lesser extent in N. tabacum and N. benthamiana using affinity chromatography purified CLV antiserum. Little labelling was observed in nuclei of infected cells. Inconclusive results were obtained with CsXV antiserum.Immunogold labelling located CLV viral antigens in infected cassava leaf tissue. This observation, together with positive ELISA, transmission and DNA hybridization experiments, proves conclusively that CLV viral antigen is present in infected cassava in Southern Africa. However, most viral antigen in infected cassava, unlike N. benthamiana (fibrillar and granular nuclear inclusions) appears to be in the cytoplasm. This may tentatively suggest that the CLV protein is synthesized in the cytoplasm of its natural host, cassava, even though the virus may assemble in the nucleus at the appropriate time. However, as yet no virus inclusions have been observed in nuclei of infected cassava. Due to previous isolation of a flexuous rod and ambiguous staining results, the possibility of two viruses in cassava cannot be ruled out.     

The Natural Occurrence of Turnip Mosaic Potyvirus in Allium ampeloprasum

An isolate of turnip mosaic potyvirus (TuMV) was obtained from Allium ampeloprasum grown in commercial greenhouses in Israel. Symptoms on infected plants include systemic chlorosis and yellow stripes, accompanied by growth reduction. Leaves were distorted, often showing necrotic flecking. The virus was readily transmitted mechanically, and in a non-persistent manner by aphids, among Allium, Chenopodium. Gomphrena and some Nicotiana spp. Purified preparations contained numerous filamentous particles similar to those observed in crude extracts of infected leaves. Particles from crude plant extracts had a normal length of 806 nm. Cells of infected plants contained cylindrical cytoplasmic inclusions with pinwheel, scrolls and laminated aggregates which indicated the presence of a potyvirus of Edwardson's subgroup III. and which resemble those of turnip mosaic virus (TuMV), The virus reacted strongly with antiserum to typical isolates of TuMV in immunoelectron microscopy and western blotting but not with antisera to several other potyviruses. Based on serological reactivity, electron microscopy, aphid transmission and cytopathology, the virus was identified as an isolate of TuMV.     

The Isolation and Evaluation of Two Naturally Occurring Mild Strains of Vanilla Necrosis Potyvirus for Control by Cross-Protection

In an attempt to find mild virus strains that would cross-protect sgainst vanilla necrosis potyvirus (VNPV), Vanilla fragrans plants in Tonga were surveyed for the presence of mild or symptomless potyvirus infections. Potyviruses were detected by indirect ELISA using a commercially available portyvirus group monoclonal anibody. From 28 plants with mild or symptomless infections two portyvirus isolates, designated V1 and V3, included systemic infections in Nicotiana benthamiana following mechanical inoculation. V1, which causes a mild mottle in N. benthamiana, is serologically related to VNPV, while V3 which causes mild vein banding is serologically unrelated to VNPV. Prior inoculation with V1 protected N. benthamiana against the severe mosaic symptoms of VNPV when challenge inoculated after 14 and 21 days, but not after 7 days. When V3 was used as the protecting strain, cross-protection was observed in some, but not all plants, when chalenged with VNPV after 14 and 21 days.     

Ultrastructural pathology of leaf cells of ryegrass (Lolium multiflorum) infected with ryegrass mosaic virus.

Ryegrass mosaic virus particles and virus induced lamellar inclusions were found in mesophyll and epidermal cells of virus infected ryegrass leaves. The lamellar inclusions were occasionally found in phloem cells also. Virus particles occurred in cytoplasm, inside plasmodesmata and often in membrane bound sacs embedded in a matrix between plasmalemma and cell wall at or near plasmodesmata. Electron dense plugs protruding from plasmodesmata, finger-like cell wall outgrowths and cell wall deposits usually at plasmodesmata were also observed. Cytopathological changes in organelles in infected cells included dense deposits in the cisternae of endosplasmic reticulum and Golgi apparatus, mitochondria with electron-dense or opaque matrix, proliferating cristae and deteriorating unit membrane; and disintegrating chloroplasts.