The Structure of the Potato Virus A Particles Elucidated by Small Angle X-Ray Scattering and Complementary Techniques.

Potato virus A (PVA) protein coat contains on its surface partially unstructured N-terminal domain of the viral coat protein (CP), whose structural and functional characteristics are important for understanding the mechanism of plant infection with this virus. In this work, we investigated the properties and the structure of intact PVA and partially trypsinized PVAΔ32 virions using small-angle X-ray scattering (SAXS) and complimentary methods. It was shown that after the removal of 32 N-terminal amino acids of the CP, the virion did not disintegrate and remained compact, but the helical pitch of the CP packing changed. To determine the nature of these changes, we performed ab initio modeling, including the multiphase procedure, with the geometric bodies (helices) and restoration of the PVA structure in solution using available high-resolution structures of the homologous CP from the PVY potyvirus, based on the SAXS data. As a result, for the first time, a low-resolution structure of the filamentous PVA virus, both intact and partially degraded, was elucidated under conditions close to natural. The far-UV circular dichroism spectra of the PVA and PVAΔ32 samples differed significantly in the amplitude and position of the main negative maximum. The extent of thermal denaturation of these samples in the temperature range of 20-55°C was also different. The data of transmission electron microscopy showed that the PVAΔ32 virions were mostly rod-shaped, in contrast to the flexible filamentous particles typical of the intact virus, which correlated well with the SAXS results. In general, structural analysis indicates an importance of the CP N-terminal domain for the vital functions of PVA, which can be used to develop a strategy for combating this plant pathogen.

Potato virus Y HCPro localization at distinct, dynamically related and environment-influenced structures in the cell cytoplasm.

Potyvirus HCPro is a multifunctional protein that, among other functions, interferes with antiviral defenses in plants and mediates viral transmission by aphid vectors. We have visualized in vivo the subcellular distribution and dynamics of HCPro from Potato virus Y and its homodimers, using green, yellow, and red fluorescent protein tags or their split parts, while assessing their biological activities. Confocal microscopy revealed a pattern of even distribution of fluorescence throughout the cytoplasm, common to all these modified HCPros, when transiently expressed in Nicotiana benthamiana epidermal cells in virus-free systems. However, in some cells, distinct additional patterns, specific to some constructs and influenced by environmental conditions, were observed: i) a small number of large, amorphous cytoplasm inclusions that contained α-tubulin; ii) a pattern of numerous small, similarly sized, dot-like inclusions distributing regularly throughout the cytoplasm and associated or anchored to the cortical endoplasmic reticulum and the microtubule (MT) cytoskeleton; and iii) a pattern that smoothly coated the MT. Furthermore, mixed and intermediate forms from the last two patterns were observed, suggesting dynamic transports between them. HCPro did not colocalize with actin filaments or the Golgi apparatus. Despite its association with MT, this network integrity was required neither for HCPro suppression of silencing in agropatch assays nor for its mediation of virus transmission by aphids.

Molecular characterization of a Chinese isolate of potato virus A (PVA) and evidence of a genome recombination event between PVA variants at the 3'-proximal end of the genome.

Potato plants that exhibited mosaic symptoms were collected in Xiangxi, Hunan province, China. Multiplex RT-PCR screening for common viruses revealed the presence of potato virus A (PVA) in these samples. ELISA with virus-specific antibodies confirmed infection by PVA in the plants. Rod-shaped virions of ~750 nm in length and ~13 nm in width were observed by transmission electron microscopy. One virus isolate (designated PVA-Hunan) was subjected to molecular characterization. The viral genome consisted of 9,567 nucleotides, excluding the poly(A) tail, and encoded a polyprotein of 3,059 amino acids. A second characteristic potyvirus open reading frame (ORF), pretty interesting Potyviridae ORF (pipo), was located at nucleotides 2,834-3,139. The isolate shared 84% to 98% and 93% to 99% sequence identity with other PVA isolates at the nucleotide and amino acid level, respectively. Phylogenetic analysis demonstrated that, within the PVA group, PVA-Hunan clustered most closely with the Finnish isolate Her, then with isolates 143, U, Ali, M and B11. The isolate TamMV stood alone at a separate branch. However, scanning of complete genome sequences using SimPlot revealed 99%-sequence identity between PVA-Hunan and TamMV in the 3'-proximal end of the genome (~nt 9,160 to the 3'end) and a 50%-94% (average~83%) identity upstream of nt 9,160. In contrast, 98% identity between PVA-Hunan and isolates M and B11 was detected for nucleotides 1 to ~9,160, but only ~94% for the 3'-proximal region, suggesting a genome recombination event (RE) at nt 9,133. The recombination breakpoint also was identified by the Recombination Detection Program (RDP). The RE was further confirmed by analysis of the CP gene, where the apparent RE was located.

A previously undescribed potyvirus isolated and characterized from arborescent Brugmansia.

A suspected virus disease was identified from an arborescent Brugmansia x candida Pers. (syn. Datura candida Pers.) tree. The causal agent was aphid transmissible at low rates. Viral particles were purified from infected tobacco tissue, analyzed, and purified virions were inoculated into healthy tobacco plants to recreate the symptoms. The virions had a mean length of 720-729 nm, and infected cells contained inclusion bodies typical of potyvirus infections. Analysis of infected tissues and purified virions with a panel of potyvirus-specific antibodies confirmed identification as a potyvirus. Viral host range, dilution end point, thermal tolerance and aphid transmission characteristics were examined. The viral genome (9761 nt) is typical of potyviruses, with the closest related potyvirus being pepper mottle virus, at 72 % nt sequence identity. Based on conventions for naming novel potyviruses, the virus was determined to be a member of a previously undescribed species, tentatively named "Brugmansia mosaic virus" (BruMV).

[Properties of potato virus M and potato virus Y isolates in Ukraine].

Monitoring of viruses of tomato plants (Lycopersicon esculentum Mill.) was carried out. Twenty-seven varieties of tomatoes from different regions of Ukraine were tested for the virus presence. New symptoms, which had not been described before, were revealed. It was found out that the diseases were caused by Potato virus M and Potato virus Y. This is the first report about the infection of tomato plants with such viruses in Ukraine. Some biological, physical and chemical properties of the pathogens are studied. Differences between PVM, PVY and the known isolates were found in morphology and molecular weight of structural protein.

Biological characteristic and identification of soybean virus isolated from different Ukraine regions.

To examine the presence and level of viral infection, field observations of the soybean crops in the Cherkassy, Vinnitsa and Kyiv regions have been performed. It was established that the diseases in the soybean plants growing in the examined areas have been caused by two major viruses--SMV (Soybean mosaic virus) and BYMV (Bean yellow mosaic virus). The results of field observations have been confirmed using light and electron microscopy and ELISA.

Distribution of Potato virus Y in potato plant organs, tissues, and cells.

The distribution of Potato virus Y (PVY) in the systemically infected potato (Solanum tuberosum) plants of the highly susceptible cultivar Igor was investigated. Virus presence and accumulation was analyzed in different plant organs and tissues using real-time polymerase chain reaction and transmission electron microscopy (TEM) negative staining methods. To get a complete insight into the location of viral RNA within the tissue, in situ hybridization was developed and optimized for the detection of PVY RNA at the cellular level. PVY was shown to accumulate in all studied leaf and stem tissues, in shoot tips, roots, and tubers; however, the level of virus accumulation was specific for each organ or tissue. The highest amounts of viral RNA and viral particles were found in symptomatic leaves and stem. By observing cell ultrastructure with TEM, viral cytoplasmic inclusion bodies were localized in close vicinity to the epidermis and in trichomes. Our results show that viral RNA, viral particles, and cytoplasmic inclusion bodies colocalize within the same type of cells or in close vicinity.

Turnip mosaic virus RNA replication complex vesicles are mobile, align with microfilaments, and are each derived from a single viral genome.

Nicotiana benthamiana plants were agroinoculated with an infectious cDNA clone of Turnip mosaic virus (TuMV) that was engineered to express a fluorescent protein (green fluorescent protein [GFP] or mCherry) fused to the viral 6K2 protein known to induce vesicle formation. Cytoplasmic fluorescent discrete protein structures were observed in infected cells, corresponding to the vesicles containing the viral RNA replication complex. The vesicles were motile and aligned with microfilaments. Intracellular movement of the vesicles was inhibited when cells were infiltrated with latrunculin B, an inhibitor of microfilament polymerization. It was also observed that viral accumulation in the presence of this drug was reduced. These data indicate that microfilaments are used for vesicle movement and are necessary for virus production. Biogenesis of the vesicles was further investigated by infecting cells with two recombinant TuMV strains: one expressed 6K2GFP and the other expressed 6K2mCherry. Green- and red-only vesicles were observed within the same cell, suggesting that each vesicle originated from a single viral genome. There were also vesicles that exhibited sectors of green, red, or yellow fluorescence, an indication that fusion among individual vesicles is possible. Protoplasts derived from TuMV-infected N. benthamiana leaves were isolated. Using immunofluorescence staining and confocal microscopy, viral RNA synthesis sites were visualized as punctate structures distributed throughout the cytoplasm. The viral proteins VPg-Pro, RNA-dependent RNA polymerase, and cytoplasmic inclusion protein (helicase) and host translation factors were found to be associated with these structures. A single-genome origin and presence of protein synthetic machinery components suggest that translation of viral RNA is taking place within the vesicle.

Genomic heterogeneity and host recovery of isolates of Malva vein clearing virus.

Malva vein clearing virus (MVCV), a tentative species of the genus Potyvirus, was identified as the causal agent of viral symptoms in Malva sp. weed plants. Amplified viral genomic fragments corresponding to approximately 20% of the 3' terminal region of its genome were obtained using non-species specific, genus-specific reagents. The sequences of the PCR fragments were determined. BLAST and phylogenetic analyses of the deduced amino acid sequence indicated that MVCV is a distinct species of the genus Potyvirus and close to Pea seed-borne mosaic virus (PSbMV) with which it forms a new phylogenetic cluster within the genus. The results show that MVCV is a definitive member of the Potyvirus genus. Specific MVCV PCR primers were designed and validated as diagnostic tools, and used to assess the variability of the species. Much variation was found and this was not correlated with either the geographical origin of the isolates, or the severity of the symptoms. Recovery from viral symptoms was observed in natural and experimental hosts. Tests in experimental hosts showed that it was a true viral recovery, in that the virus was absent and the recovered tissues could not be infected. This is the first reported example of true viral recovery of a potyvirus in a natural system.

A new potyvirus first isolated and identified from Angelica sinensis.

A filamentous virus was isolated in Angelica sinensis (Angelica sinensis (Oliv.) Diels) which shows mosaic symptoms on leaves in Minxian, Gansu province, China. According to morphology and molecular biology properties, this virus, which has a flexuous rod-shaped particle about 750 nm in length and 12 nm in width, was assigned to the genus Potyvirus, family Potyviridae. Its coat protein (CP) shows high similarity with six other potyviruses by analysis of peptide mass fingerprinting (PMF). The 919 bp nucleotides of 3' terminal covering partial CP gene and 3'-untranslated region was amplified by RT-PCR using degenerate primers which were designed according to the result of PMF. In sequence comparisons and phylogenetic analysis, the new isolate was found to be closely related to Japanese hornwort mosaic virus (JHMV), Konjak mosaic virus (KoMV), and Zantedeschia mosaic virus (ZaMV). The most closely related virus is JHMV03 (AB251346), with 96.59% aa and 87.60% nt identity to the isolate. All results suggest the presence of a new member of potyvirus, tentatively named Dang Gui strain of Japanese hornwort mosaic virus (JHMV-DG*). In our research the antiserum against the CP of JHMV-DG had also been prepared. To our knowledge, it is the first time that a potyvirus has been isolated and identified in Angelica sinensis.

Structure of Turnip mosaic virus and its viral-like particles.

Turnip mosaic virus (TuMV), a potyvirus, is a flexible filamentous plant virus that displays a helical arrangement of coat protein copies (CPs) bound to the ssRNA genome. TuMV is a bona fide representative of the Potyvirus genus, one of most abundant groups of plant viruses, which displays a very wide host range. We have studied by cryoEM the structure of TuMV virions and its viral-like particles (VLPs) to explore the role of the interactions between proteins and RNA in the assembly of the virions. The results show that the CP-RNA interaction is needed for the correct orientation of the CP N-terminal arm, a region that plays as a molecular staple between CP subunits in the fully assembled virion.

Structural basis for the multitasking nature of the potato virus Y coat protein.

Potato virus Y (PVY) is among the most economically important plant pathogens. Using cryoelectron microscopy, we determined the near-atomic structure of PVY's flexuous virions, revealing a previously unknown lumenal interplay between extended carboxyl-terminal regions of the coat protein units and viral RNA. RNA-coat protein interactions are crucial for the helical configuration and stability of the virion, as revealed by the unique near-atomic structure of RNA-free virus-like particles. The structures offer the first evidence for plasticity of the coat protein's amino- and carboxyl-terminal regions. Together with mutational analysis and in planta experiments, we show their crucial role in PVY infectivity and explain the ability of the coat protein to perform multiple biological tasks. Moreover, the high modularity of PVY virus-like particles suggests their potential as a new molecular scaffold for nanobiotechnological applications.

Three heterologous proteins simultaneously expressed from a chimeric potyvirus: infectivity, stability and the correlation of genome and virion lengths.

Three heterologous proteins were simultaneously expressed from a chimeric potyvirus Potato virus A (PVA) in Nicotiana benthamiana. The genes for green fluorescent protein of Aequoria victoriae ("G"; 714 nucleotides, nt), luciferase of Renilla reniformis ("L", 933 nt) and beta-glucuronidase of Escherichia coli ("U", 1806 nt) were inserted into the engineered cloning sites at the N-terminus of the P1 domain, the junction of P1 and helper component protein (HC-Pro), and the junction of the viral replicase (NIb) and coat protein (CP), respectively, in an infectious PVA cDNA. The proteins were expressed as part of the viral polyprotein and subsequently released by cleavage at the flanking proteolytic cleavage sites by P1 (one site) or the NIa-Pro proteinase (other sites). The engineered viral genome (pGLU, 13311 nt) was 39.2% larger than wild-type PVA (9565 nt) and infected plants of N. benthamiana systemically. pGLU was stable and expressed all three heterologous proteins, also following the second infection cycle initiated by sap-inoculation of new plants with the progeny viruses. The gene for GUS showed some inherent instabilities, as also reported in other studies. Accumulation of pGLU in infected leaves was lower by a magnitude as compared to the vector viruses pG0U and p0LU used to express two heterologous proteins. Hence, pGLU may have reached the maximum genome size that can still function and complete the PVA infection cycle. Examination of virions by electron microscopy indicated that the virion lengths of PVA chimera with various numbers of inserts were directly proportional to their genome lengths.

Redox-Immunofunctionalized Potyvirus Nanoparticles for High-Resolution Imaging by AFM-SECM Correlative Microscopy.

We present in this chapter a new experimental approach allowing the high resolution imaging of immune complexes on virus particles. Combined atomic force-electrochemical microscopy (AFM-SECM) is used to image the presence of ferrocene functionalized specific antibodies on the surface of potyvirus particles. For this purpose, potyviruses, flexuous filamentous phytoviruses with a high aspect ratio, have been chosen. This technique allows analysis of the distribution of antibody labeling over the virus population. But, more importantly, it opens up the imaging of immune complexes decorating a single viral particle. Finally, its high resolution allows the characterization in situ of the ultrastructure of a single immune complex on the particle.

Localization of sweet potato chlorotic stunt virus (SPCSV) in synergic infection with potyviruses in sweet potato.

Among diseases reported worldwidely for sweet potato (Ipomoea batatas (L) Lam) crop, one of the most frequent is the Sweet potato virus disease (SPVD), caused by sweet potato chlorotic stunt virus (SPCSV) and sweet potato feathery mottle virus (SPFMV) co-infection. In Argentina, there exists the sweet potato chlorotic dwarf (SPCD), a sweet potato disease caused by triple co-infection with SPCSV, SPFMV and sweet potato mild speckling virus (SPMSV). Both diseases cause a synergism between the potyviruses (SPFMV and SPMSV) and the crinivirus (SPCSV). Up to date, studies carried out on the interaction among these three viruses have not described their localization in the infected tissues. In single infections, virions of the crinivirus genus are limited to the phloem while potyviral virions are found in most tissues of the infected plant. The purpose of this work was to localize the heat shock protein 70 homolog (HSP70h), a movement protein for genus crinivirus, of an Argentinean SPCSV isolate in its single infection and in its double and triple co-infection with SPFMV and SPMSV. The localization was made by in situ hybridization (ISH) for electron microscopy (EM) on ultrathin sections of sweet potato cv. Morada INTA infected tissues. The results demonstrated that viral RNA coding HSP70h is restricted to phloem cells during crinivirus single infection, while it was detected outside the phloem in infections combined with the potyviruses involved in chlorotic dwarf disease.

Potyvirus virion structure shows conserved protein fold and RNA binding site in ssRNA viruses.

Potyviruses constitute the second largest genus of plant viruses and cause important economic losses in a large variety of crops; however, the atomic structure of their particles remains unknown. Infective potyvirus virions are long flexuous filaments where coat protein (CP) subunits assemble in helical mode bound to a monopartite positive-sense single-stranded RNA [(+)ssRNA] genome. We present the cryo-electron microscopy (cryoEM) structure of the potyvirus watermelon mosaic virus at a resolution of 4.0 Å. The atomic model shows a conserved fold for the CPs of flexible filamentous plant viruses, including a universally conserved RNA binding pocket, which is a potential target for antiviral compounds. This conserved fold of the CP is widely distributed in eukaryotic viruses and is also shared by nucleoproteins of enveloped viruses with segmented (-)ssRNA (negative-sense ssRNA) genomes, including influenza viruses.

Identification of prevalent potyvirus on maize and johnsongrass in corn fields of Tehran province of Iran and a study on some of its properties.

During a growing season in 2004, 231 leaf samples of virus infected and mosaic and dwarf mosaic symptoms showing maize (Zea mays L.) plants and 258 leaf samples of mosaic showing johnsongrass (Sorghum halepens L.) plants from various corn fields in Tehran province were collected. Serological tests of DAS-ELISA and DIBA were performed on samples using antisera of sugarcane mosaic virus (SCMV), maize dwarf mosaic virus (MDMV), sorghum mosaic virus (SrMV) and johnsongrasss mosaic virus (JGMV). In both tests performed on leaf samples extractions, all samples reacted strongly with SCMV antiserum and no reaction was seen with other 3 potyviruses antisera. 0.1 M potassium phosphate buffer (pH = 7) containing 2% polyvinyl pyrrolidon (PVP) was used for mechanical inoculation and all isolates were inoculated and propagated on sweet corn cv. Pars 403 and grain sorghum cv. Kimia. In serological tests on the inoculated plants samples also only SCMV was detected. Purification of virus was done using a modified "minipurification" method and the concentration of purified virus was 11.45 mg/ml and ratio of A260/280 = 1.2 was calculated for it. Electron microscopic study using ISEM and decoration method with SCMV antiserum revealed filamentous flexuous particles of SCMV. In SDS-polyachrylamide gel electrophoresis and Western blot test using SCMV antiserum that were performed on infected samples and purified viruses, the molecular weight of the virus coat protein was approximately 37-38 KDa and a difference among the CP weights of various SCMV isolates was not found. Reverse transcription-polymerase chain reaction (RT-PCR) was done using SCMV F3 and SCMV R3 primers and amplified fragments of approximately 900 bp in size were as in expected. The host range study with selected isolates of SCMV showed that the virus isolates were not transmitted by mechanical inoculation on Avena sativa, Panicum miliaceum, Setaria italica, Pennisetum americanum, Hordeum vulgare and Triticum aestivum. The isolates produced red-brown necrotic streaks on sudangrass (Sorghum sudanense) that lately changed in systemic necrosis. In host reaction studies on sorghum (Sorghum bicolor) cultivars, the virus isolates caused severe necrotic and killer reaction on sorghum cultivars Payam, Sepideh and Speed feed, but caused systemic mosaic and non-killer reaction on sorghum cultivars Kimia, KFS2, KFS3 and Jumbo. The present study showed that SCMV is the prevalent potyvirus and the main causal agent of mosaic and dwarf mosaic on maize plants in province. Since the virus is prevalent on johnsongrass plants in marginal areas of corn fields too, it seems that the origin of the virus on corn is from johnsongrass and the virus is a special strain of sugarcane mosaic virus that infects johnsongrass too.

Occurrence of Colombian datura virus in Brugmansia hybrids, Physalis peruviana L. and Solanum muricatum Ait. in Hungary.

Colombian datura virus (CDV) has been found to infect angel trumpets (Brugmansia spp.) frequently and cape gooseberry (Physalis peruviana) and pepino (Solanum muricatum) sporadically in Hungary. A CDV BRG/H isolate was characterized. It had flexuous thread-like virions of about 750 x 12 nm in size. Host range and symptomathological studies revealed its great similarity to authentic CDV isolates. Nicotiana tabacum cultivars and lines resistant to Potato virus Y (PVYN) either genically or transgenically proved highly susceptible to the BRG/H isolate. Tomato (L. esculentum cvs.) was systemically susceptible to this isolate, but some lines of Lycopersicon hirsutum and L. peruvianum turned out to be resistant. Browallia demissa, Ipomoea purpurea, N. megalosiphon and S. scabrum were demonstrated as new experimental hosts of CDV. The BRG/ H isolate proved to be transmissible by the aphid Myzus persicae Sulz. in a non-persistent manner. Potyvirus-specific coat protein (CP) gene sequences of about 1700 bp from angel trumpet, cape gooseberry and pepino plants were amplified by RT-PCR. The cloned BRG/H CP gene showed a 99.12-99.31% identity with other CDV isolates. CDV has been found for the first time to infect naturally cape gooseberry and pepino. Since the botanical genus name of original hosts of CDV has changed from Datura to Brugmansia, we propose to change the virus name from CDV to Angel trumpet mosaic virus (ATMV).

Encapsidation of potyviral RNA in various forms of transgene coat protein is not correlated with resistance in transgenic plants.

Transgenic plants expressing either bean yellow mosaic potyvirus or chimeric potyvirus coat protein (CP) were inoculated with various potyviruses. Antigen-coated plate, indirect enzyme-linked immunosorbent assay and immunoelectron microscopy of virus purified from transgenic plants showed that progeny virions contained from < 1% to as much as 25% transgenic CP. Different levels of transcapsidation may reflect the extent of compatibility between transgene CP and the viral CP.

Expression of Cardamom mosaic virus coat protein in Escherichia coli and its assembly into filamentous aggregates.

Cardamom mosaic virus (CdMV), a member of the genus Macluravirus of Potyviridae, causes a mosaic disease in cardamom. A polyclonal antiserum was raised against the purified virus and IgG was prepared. Electron microscopic studies on the purified virus showed flexuous filamentous particles of approximately 800 nm in length, typical of members of Potyviridae. The coat protein (CP) encoding sequence of the virus was expressed in Escherichia coli and the protein purified by affinity chromatography under denaturing conditions. The viral nature of the expressed CP was confirmed by positive reaction with anti CdMV IgG in a Western blot. The expressed CP aggregated irreversibly upon renaturation at concentrations above 0.07 mg/ml. The expression of the CP led to the formation of filamentous aggregates in E. coli as observed by immuno-gold electron microscopy. The filamentous aggregates were of 100-150 nm in length. Immuno-capture RT-PCR confirmed the absence of coat protein mRNA in the filamentous aggregates. Deletion mutations, which were expected to inhibit virus assembly, were introduced in the core region of the coat protein. However, these mutations did not improve the solubility of the CP in non-denaturing buffers.