Nucleotide sequence and rt-PCR detection of a virus associated with grapevine rupestris stem-pitting disease

A Metagenomic Investigation of the Viruses Associated with Shiraz Disease in Australia

Shiraz disease (SD) is an economically important virus-associated disease that can significantly reduce yield in sensitive grapevine varieties and has so far only been reported in South Africa and Australia. In this study, RT-PCR and metagenomic high-throughput sequencing was used to study the virome of symptomatic and asymptomatic grapevines within vineyards affected by SD and located in South Australia. Results showed that grapevine virus A (GVA) phylogroup II variants were strongly associated with SD symptoms in Shiraz grapevines that also had mixed infections of viruses including combinations of grapevine leafroll-associated virus 3 (GLRaV-3) and grapevine leafroll-associated virus 4 strains 5, 6 and 9 (GLRaV-4/5, GLRaV-4/6, GLRaV-4/9). GVA phylogroup III variants, on the other hand, were present in both symptomatic and asymptomatic grapevines, suggesting no or decreased virulence of these strains. Similarly, only GVA phylogroup I variants were found in heritage Shiraz grapevines affected by mild leafroll disease, along with GLRaV-1, suggesting this phylogroup may not be associated with SD.

Virome of Grapevine Germplasm from the Anapa Ampelographic Collection (Russia)

Grapevine germplasm collections are unique repositories of grape cultivars; therefore, it is necessary to minimize their infection with pathogens, including viruses, and develop various programs to maintain them in a virus-free state. In our study, we examined the virome of the largest Russian grapevine germplasm collection, the Anapa Ampelographic Collection, using high-throughput sequencing of total RNAs. As a result of bioinformatics analysis and validation of its results by reverse transcription PCR (RT-PCR) and quantitative RT-PCR (RT-qPCR), we identified 20 viruses and 3 viroids in 47 libraries. All samples were infected with 2 to 12 viruses and viroids, including those that cause economically significant diseases: leafroll, fleck, and rugose wood complex. For the first time in Russia, we detected Grapevine virus B (GVB), Grapevine virus F (GVF), Grapevine asteroid mosaic-associated virus (GAMaV), Grapevine Red Globe virus (GRGV), Grapevine satellite virus (GV-Sat), Grapevine virga-like virus (GVLV), Grapevine-associated jivivirus 1 (GaJV-1) and Vitis cryptic virus (VCV). A new putative representative of the genus Umbravirus with the provisional name Grapevine umbra-like virus (GULV) was also identified in Russian grape samples.

High-Throughput Sequencing of Small RNAs for Diagnostics of Grapevine Viruses and Viroids in Russia

The use of high-throughput sequencing (HTS) technology has led to significant progress in the identification of many viruses and their genetic variants. In this study, we used the HTS platform to sequence small RNAs (sRNAs) of grapevine to study the virome. Isolation of RNA was performed using symptomatic grapevines collected from commercial vineyards in Krasnodar Krai in 2017-2018. To determine the viromes of vineyards, we used an integrated approach that included a bioinformatic analysis of the results of sRNA HTS and the molecular method RT-PCR, which made it possible to identify 13 viruses and 4 viroids. Grapevine leafroll-associated virus 4 (GLRaV-4), Grapevine Syrah Virus-1 (GSyV-1), Raspberry bushy dwarf virus (RBDV), Australian grapevine viroid (AGVd), and Grapevine yellow speckle viroid 2 (GYSVd-2) were identified for the first time in Russia. Out of 38 samples analyzed, 37 had mixed infections with 4-11 viruses, indicating a high viral load. Analysis of the obtained sequences of fragments of virus genomes made it possible to identify recombination events in GLRaV-1, GLRaV-2, GLRaV-3, GLRaV-4, GVT, GPGV, GRSPaV, GVA, and GFLV. The obtained results indicate a wide spread of the viruses and a high genetic diversity in the vineyards of Krasnodar Krai and emphasize the urgent need to develop and implement long-term strategies for the control of viral grapevine diseases.

Prevalence and Genetic Diversity of Viruses Associated with Rugose Wood Complex in Greek Vineyards

Rugose wood is one of the most important disease syndromes of grapevine, and it has been associated with at least three viruses: grapevine rupestris stem pitting-associated virus (GRSPaV), grapevine virus A (GVA), and grapevine virus B (GVB). All three viruses show a worldwide distribution pattern, and their genetic composition has been the focus of extensive research in past years. Despite their first record in Greece almost 20 years ago, there is a lack of knowledge on the distribution and genetic variability of their populations in Greek vineyards. In this context, we investigated the distribution of GRSPaV, GVA, and GVB in rootstocks, self-rooted vines, and grafted grapevine cultivars originating from different geographic regions that represent important viticultural areas of Greece. Three new reverse transcription-PCR assays were developed for the reliable detection of GRSPaV, GVA, and GVB. Our results indicated that GVA is the most prevalent in Greek vineyards, followed by GRSPaV and GVB. However, virus incidence differed among self-rooted and grafted grapevine cultivars or rootstocks tested. Selected isolates from each virus were further molecularly characterized to determine their phylogenetic relationships. All three viruses exhibited high nucleotide diversity, which was depicted in the constructed phylogenetic trees. Isolates from Greece were placed in various phylogroups, reinforcing the scenario of multiple introductions of GVA, GVB, and GRSPaV in Greece and highlighting the effect of different transmission modes in the evolutionary course of the three viruses.

Grapevine virus T diversity as revealed by full-length genome sequences assembled from high-throughput sequence data

RNASeq or double-stranded RNA based approaches allowed the reconstruction of a total of 9 full-length or near full-length genomes of the recently discovered grapevine virus T (GVT). In addition, datamining of publicly available grapevine RNASeq transcriptome data allowed the reconstruction of a further 14 GVT genomes from five grapevine sources. Together with four GVT sequences available in Genbank, these novel sequences were used to analyse GVT diversity. GVT shows a very limited amount of indels variation but a high level of nucleotide and aminoacid polymorphism. This level is comparable to that shown in the closely related grapevine rupestris stem pitting-associated virus (GRSPaV). Further analyses showed that GVT mostly evolves under conservative selection pressure and that recombination has contributed to its evolutionary history. Phylogenetic analyses allow to identify at least seven clearly separated groups of GVT isolates. Analysis of the only reported PCR GVT-specific detection primer pair indicates that it is likely to fail to amplify some GVT isolates. Taken together these results point at the distinctiveness of GVT but also at the many points it shares with GRSPaV. They constitute the first pan-genomic analysis of the diversity of this novel virus.

Survey for major viruses in commercial Vitis vinifera wine grapes in Ontario

BACKGROUND

In recent years, the Ontario grape and wine industry has experienced outbreaks of viral diseases across the province. Little is known about the prevalence of viruses and viral diseases in Ontario. Since 2015, we have conducted large-scale surveys for major viruses in commercial wine grapes in order to obtain a comprehensive understanding of the prevalence and severity of viral diseases in Ontario.

METHODS

A total of 657 composite leaf samples representing 3285 vines collected from 137 vine blocks of 33 vineyards from three appellations: Niagara Peninsula, Lake Erie North Shore and Prince Edward County. These samples covered six major red cultivars and five major white grape cultivars. Using a multiplex RT-PCR format, we tested these samples for 17 viruses including those involved in all major viral diseases of the grapevine, such as five grapevine leafroll-associated viruses (GLRaV-1, 2, 3, 4, 7), grapevine red blotch virus (GRBV), grapevine Pinot gris virus (GPGV), grapevine rupestris stem sitting-associated virus (GRSPaV), grapevine virus A (GVA), grapevine virus B (GVB), grapevine fleck virus (GFkV), arabis mosaic virus (ArMV), tomato ringspot virus (ToRSV), trapevine fanleaf virus (GFLV), among others.

RESULTS

Fourteen of the 17 viruses were detected from these samples and the predominant viruses are GRSPaV, GLRaV-3, GFkV, GPGV and GRBaV with an incidence of 84.0, 47.9, 21.8, 21.6 and 18.3%, respectively. As expected, mixed infections with multiple viruses are common. 95.6% of the samples included in the survey were infected with at least one virus; 67% of the samples with 2-4 viruses and 4.7% of the samples with 5-6 viruses. The major grape cultivars all tested positive for these major viruses. The results also suggested that the use of infected planting material may have been one of the chief factors responsible for the recent outbreaks of viral diseases across the province.

CONCLUSIONS

This is the first such comprehensive survey for grapevine viruses in Ontario and one of the most extensive surveys ever conducted in Canada. The recent outbreaks of viral diseases in Ontario vineyards were likely caused by GLRaV-3, GRBV and GPGV. Findings from this survey provides a baseline for the grape and wine industry in developing strategies for managing grapevine viral diseases in Ontario vineyards.

Grapevine fanleaf virus affects grape (Vitis vinifera) berry anthocyanin content via the transcriptional regulation of anthocyanin biosynthetic genes

Grapevine fanleaf virus (GFLV) causes grapevine fanleaf degeneration, one of the oldest known viral diseases of grapevines. The virus has been found in all winegrowing regions around the world. In the seasons 2011-12 a comparison between field grown GFLV-infected and healthy grapevines was conducted for the cultivars Schioppettino in North-Eastern Italy and Refošk in South-Western Slovenia. Our research showed that GFLV infection caused a drop of the yield due to reduction of both cluster weight and berry weight. Besides the yield, the berry composition was also affected; in detail, anthocyanin concentration increased in both varieties but significantly only in the case of Schioppettino. Upregulation of the F3'5'H gene and downregulation of F3'H gene in the berries of GFLV infected vines compared with the ones of healthy control vines resulted in modified proportions between di- and tri- hydroxylated or methylated derivatives of anthocyanins. The F3H1 gene was identified to be the most strongly regulated gene of the flavonoid biosynthetic pathway by GFLV infection, indicating its important role in increasing anthocyanin concentration in grapes of GFLV infected vines as compared with healthy controls.

Viral Diversity in Autochthonous Croatian Grapevine Cultivars

A survey was conducted on nine autochthonous grapevine cultivars grown along the Croatian coastal region. In total, 48 vines (44 from germplasm collection, 4 from vineyards) originating from 23 sites were tested for 26 viruses using molecular methods. Results revealed high infection rates with Grapevine leafroll-associated virus 3 (GLRaV-3); Grapevine virus A (GVA, both 91.7%); Grapevine fleck virus (GFkV, 87.5%); and Grapevine rupestris stem pitting-associated virus (GRSPaV, 83.3%). Other detected viruses were: Grapevine fanleaf virus (GFLV); Grapevine leafroll-associated viruses 1, 2, and strains of 4 (GLRaV-1, GLRaV-2, GLRaV-4); Grapevine viruses B, D, F (GVB, GVD, GVF); Grapevine red globe virus (GRGV); Grapevine vein feathering virus (GVFV); Grapevine Syrah virus 1 (GSyV-1); and Grapevine Pinot gris virus (GPGV). No virus-free vine was found. Mixed infections were determined in all vines, the number of viruses in a single vine ranged from three to nine. GLRaV-3 variant typing confirmed presence of group I, II, and III. Four vines with leaf deformation and mottling were positive for GPGV. Seven viruses (GLRaV-4-like group, GVD, GVE, GVF, GRGV, GSyV-1, and GVFV) were detected for the first time in Croatia. This survey confirmed the deteriorated sanitary status of autochthonous Croatian grapevine cultivars.

Analysis of Grapevine rupestris stem pitting-associated virus in Slovakia Reveals Differences in Intra-Host Population Diversity and Naturally Occurring Recombination Events

Grapevine rupestris stem pitting-associated virus (GRSPaV) is a worldwide-distributed pathogen in grapevines with a high genetic variability. Our study revealed differences in the complexity of GRSPaV population in a single host. A single-variant GRSPaV infection was detected from the SK30 grapevine plant. On the contrary, SK704 grapevine was infected by three different GRSPaV variants. Variant-specific RT-PCR detection protocols have been developed in this work to study distribution of the three different variants in the same plant during the season. This study showed their randomized distribution in the infected SK704 grapevine plant. Comparative analysis of fulllength genome sequences of four Slovak GRSPaV isolates determined in this work and 14 database sequences showed that population of the virus cluster into four major phylogenetic lineages. Moreover, our analyses suggest that genetic recombination along with point mutations could play a significant role in shaping evolutionary history of GRSPaV and contributed to its extant genetic diversification.

Biotechnology Applications of Grapevine Viruses

Plant virus genomes are engineered as vectors for functional genomics and production of foreign proteins. The application of plant virus vectors is of potential interest to the worldwide, multibillion dollar, grape and wine industries. These applications include grapevine functional genomics, pathogen control, and production of beneficial proteins such as vaccines and enzymes. However, grapevine virus biology exerts certain limitations on the utility of the virus-derived gene expression and RNA interference vectors. As is typical for viruses infecting woody plants, several grapevine viruses exhibit prolonged infection cycles and relatively low overall accumulation levels, mainly because of their phloem-specific pattern of systemic infection. Here we consider the biotechnology potential of grapevine virus vectors with a special emphasis on members of the families Closteroviridae and Betaflexiviridae.

A highly effective and versatile technology for the isolation of RNAs from grapevines and other woody perennials for use in virus diagnostics

BACKGROUND

Isolation of pure RNA from woody perennials, especially fruit crops such as grapevine rich in complex secondary metabolites, has remained very challenging. Lack of effective RNA isolation technology has resulted in difficulties in viral diagnosis and discovery as well as studies on many biological processes of these highly important woody plants. It is imperative to develop and refine methodologies with which large amounts of pure nucleic acids can be readily isolated from woody perennials.

METHODS

We compared five commonly used RNA isolation kits in isolating total RNA from twelve species of woody perennials. We made modifications to select RNA isolation systems to simplify and improve their efficiency in RNA isolation. The yield and quality of isolated RNAs were assessed via gel electrophoresis and spectrophotometric measurement. We also performed RT-PCR and RT-qPCR to detect several major viruses from grapevines.

RESULTS

Two of the kits were shown to be the best in both the yield and quality of the isolated RNA from all twelve woody species. Using disposable extraction bags for tissue homogenization not only improved the yield without affecting quality, but also made the RNA isolation technology simpler, less costly, and suitable for adoption by many potential users with facility limitations. This system was successfully applied to a wide range of woody plants, including fruit crops, ornamentals and timber trees. Inclusion of polyvinylpyrrolidone in the extraction buffer drastically improved the performance of the system in isolating total RNA from old grapevine leaves collected later in the season. This modification made our system highly effective in isolating quality RNA from grapevine leaves throughout the entire growing season. We further demonstrated that the resulting nucleic acid preparations are suitable for detection of several major grapevine viruses with RNA or DNA genomes using PCR, RT-PCR and qPCR as well as for assays on plant microRNAs.

CONCLUSIONS

This improved RNA isolation system would have wide applications in viral diagnostics and discovery, studies on gene expression and regulation, transcriptomics, and small RNA biology in grapevines. We believe this system will also be useful in diverse applications pertaining to research on many other woody perennials and recalcitrant plant species.

Molecular characterizations of two grapevine rupestris stem pitting-associated virus isolates from China

The complete nucleotide sequences of two isolates of grapevine rupestris stem pitting-associated virus (LSL and JF) collected from grapevine of Xingcheng in Liaoning Province, China, were determined. The genomes of both LSL and JF were found to contain five open reading frames (ORFs). Sequence alignments showed that the genomic sequences of JF were 76.1 %-83.5 % identical to the other ten GRSPaV isolates that have been reported previously and that the nucleotide sequence identity of isolate LSL to other isolates was no more than 78 %. Phylogenetic analysis based on the complete genome sequence indicated that JF belongs to group III and that LSL belongs to a new group (group IV). The average genetic distances of the new genetic lineage from groups I, II and III were 0.34, 0.32 and 0.33, respectively.

Subcellular localization and membrane association of the replicase protein of grapevine rupestris stem pitting-associated virus, family Betaflexiviridae

As a member of the newly established Betaflexiviridae family, grapevine rupestris stem pitting-associated virus (GRSPaV) has an RNA genome containing five ORFs. ORF1 encodes a putative replicase polyprotein typical of the alphavirus superfamily of positive-strand ssRNA viruses. Several viruses of this superfamily have been demonstrated to replicate in structures designated viral replication complexes associated with intracellular membranes. However, structure and cellular localization of the replicase complex have not been studied for members of Betaflexiviridae, a family of mostly woody plant viruses. As a first step towards the elucidation of the replication complex of GRSPaV, we investigated the subcellular localization of full-length and truncated versions of its replicase polyprotein via fluorescent tagging, followed by fluorescence microscopy. We found that the replicase polyprotein formed distinctive punctate bodies in both Nicotiana benthamiana leaf cells and tobacco protoplasts. We further mapped a region of 76 amino acids in the methyl-transferase domain responsible for the formation of these punctate structures. The punctate structures are distributed in close proximity to the endoplasmic reticulum network. Membrane flotation and biochemical analyses demonstrate that the N-terminal region responsible for punctate structure formation associated with cellular membrane is likely through an amphipathic α helix serving as an in-plane anchor. The identity of this membrane is yet to be determined. This is, to our knowledge, the first report on the localization and membrane association of the replicase proteins of a member of the family Betaflexiviridae.

Control of viruses infecting grapevine

Grapevine is a high value vegetatively propagated fruit crop that suffers from numerous viruses, including some that seriously affect the profitability of vineyards. Nowadays, 64 viruses belonging to different genera and families have been reported in grapevines and new virus species will likely be described in the future. Three viral diseases namely leafroll, rugose wood, and infectious degeneration are of major economic importance worldwide. The viruses associated with these diseases are transmitted by mealybugs, scale and soft scale insects, or dagger nematodes. Here, we review control measures of the major grapevine viral diseases. More specifically, emphasis is laid on (i) approaches for the production of clean stocks and propagative material through effective sanitation, robust diagnosis, as well as local and regional certification efforts, (ii) the management of vectors of viruses using cultural, biological, and chemical methods, and (iii) the production of resistant grapevines mainly through the application of genetic engineering. The benefits and limitations of the different control measures are discussed with regard to accomplishments and future research directions.

The triple gene block movement proteins of a grape virus in the genus Foveavirus confer limited cell-to-cell spread of a mutant Potato virus X

Grapevine rupestris stem pitting-associated virus (GRSPaV) is a member of the genus Foveavirus in the family Betaflexiviridae. The genome of GRSPaV encodes five proteins, among which are three movement proteins designated the triple gene block (TGB) proteins. The TGB proteins of GRSPaV are highly similar to their counterparts in Potato virus X (PVX), as reflected in size, modular structure, conservation of critical amino acid sequence motifs, as well as similar cellular localization. Based on these similarities, we predicted that the TGB proteins of these two viruses would be interchangeable. To test this hypothesis, we replaced the entire or partial sequence of PVX TGB with the corresponding regions from GRSPaV, creating chimeric viruses that contain the PVX backbone and different sequences from GRSPaV TGB. These chimeric constructs were delivered into plants of Nicotiana benthamiana through agro-infiltration to test whether they were capable of cell-to-cell and systemic movement. To our surprise, viruses derived from pPVX.GFP(CH3) bearing GRSPaV TGB in place of PVX TGB lost the ability to move either cell-to-cell or systemically. Interestingly, another chimeric virus resulting from pPVX.GFP(HY2) containing four TGB genes (TGB1 from PVX and TGB1-3 from GRSPaV), exhibited limited cell-to-cell, but not systemic, movement. Our data question the notion that analogous movement proteins encoded by even distantly related viruses are functionally interchangeable and can be replaced by each other. These data suggest that other factors, besides the TGB proteins, may be required for successful intercellular and/or systemic movement of progeny viruses. This is the first experimental demonstration that the GRSPaV TGB function as movement proteins in the context of a chimeric virus and that four TGB genes were required to support the intercellular movement of the chimeric virus.

Identification and complete genome analysis of a virus variant or putative new foveavirus associated with apple green crinkle disease

A virus identified as "apple green crinkle associated virus" (AGCaV) was isolated from Aurora Golden Gala apple showing severe symptoms of green crinkle disease. Evidence was obtained of a potential causal relationship to the disease. The viral genome consists of 9266 nucleotides, excluding the poly(A) tail at the 3'-terminus. It has a genome organization similar to that of members of the species Apple stem pitting virus (ASPV), the type species of the genus Foveavirus, family Betaflexiviridae. ORF1 of AGCaV encodes a replicase-complex polyprotein with a molecular mass of 247 kDa; the proteins of ORFs 2, 3, and 4 (TGB proteins) are estimated to be 25.1 kDa, 12.8 kDa, and 7.4 kDa, respectively; and ORF5 encodes the CP, with an estimated molecular mass of 43.3 kDa. Interestingly, AGCaV utilizes different stop codons for ORF1, ORF3, and ORF5 compared to the ASPV type isolate PA66, and between the two viruses, six distinct indel events were observed within ORF5. AGCaV has four non-coding regions (NCRs), including a 5'-NCR (60 nt), a 3'-NCR (134 nt), and two intergenic (IG) NCRs: IG-NCR1 (69 nt) and IG-NCR2 (91 nt). A conserved stable hairpin structure was identified in the variable 5'-NCR of members of the genus Foveavirus. AGCaV may be a variant or strain of ASPV with unique biological properties, but there is evidence that it may be a distinct putative foveavirus.

Construction and biological activities of the first infectious cDNA clones of the genus Foveavirus

Grapevine rupestris stem pitting-associated virus (GRSPaV, genus Foveavirus, family Betaflexiviridae) is one of the most prevalent viruses in grapevines and is associated with three distinct diseases: rupestris stem pitting, vein necrosis and Syrah decline. Little is known about the biology and pathological properties of GRSPaV. In this work, we engineered a full-length infectious cDNA clone for GRSPaV and a GFP-tagged variant, both under the transcriptional control of Cauliflower mosaic virus 35S promoter. We demonstrated that these cDNA clones were infectious in grapevines and Nicotiana benthamiana through fluorescence microscopy, RT-PCR, Western blotting and immuno electron microscopy. Interestingly, GRSPaV does not cause systemic infection in four of the most commonly used herbaceous plants, even in the presence of the movement proteins of two other viruses which are known to complement numerous movement-defective viruses. These infectious clones are the first of members of Foveavirus which would allow further investigations into mechanisms governing different aspects of replication for GRSPaV and perhaps related viruses.

The capsid protein of Grapevine rupestris stem pitting-associated virus contains a typical nuclear localization signal and targets to the nucleus

Grapevine rupestris stem pitting-associated virus (GRSPaV) is a positive strand, ssRNA virus of the genus Foveavirus (family Betaflexiviridae; order Tymovirales). GRSPaV is distributed in table and wine grapes worldwide and comprises a large family of sequence variants. As a newly discovered virus, mechanisms of virus replication and movement of GRSPaV have not been elucidated. We recently revealed the subcellular localization of the proteins encoded by the triple gene block of GRSPaV (Rebelo et al., 2008). However, the subcellular localization and interaction of its capsid protein (CP) have not been explored. We report here that GRSPaV CP contains a nuclear localization signal "KRKR" near its N-terminus, which is conserved among all five strains whose genomes are completely sequenced. Similar sequences were also detected in the CP of two other viruses of the same family: African oil palm ringspot virus and Cherry green ring mottle virus. Using fluorescent protein tagging, we demonstrate that the CP targets to the nucleus in tobacco protoplasts. Mutation to this nuclear localization signal abolished the nuclear localization. Using bi-molecular fluorescence complementation, we show that the capsid protein of GRSPaV engages in homologous interaction. To our knowledge, this is the first report on the nuclear localization of a CP encoded by a RNA plant virus.

Deep sequencing analysis of viral short RNAs from an infected Pinot Noir grapevine

Virus-derived short interfering RNAs (vsiRNAs) isolated from grapevine V. vinifera Pinot Noir clone ENTAV 115 were analyzed by high-throughput sequencing using the Illumina Solexa platform. We identified and characterized vsiRNAs derived from grapevine field plants naturally infected with different viruses belonging to the genera Foveavirus, Maculavirus, Marafivirus and Nepovirus. These vsiRNAs were mainly of 21 and 22 nucleotides (nt) in size and were discontinuously distributed throughout Grapevine rupestris stem-pitting associated virus (GRSPaV) and Grapevine fleck virus (GFkV) genomic RNAs. Among the studied viruses, GRSPaV and GFkV vsiRNAs had a 5' terminal nucleotide bias, which differed from that described for experimental viral infections in Arabidopsis thaliana. VsiRNAs were found to originate from both genomic and antigenomic GRSPaV RNA strands, whereas with the grapevine tymoviruses GFkV and Grapevine Red Globe associated virus (GRGV), the large majority derived from the antigenomic viral strand, a feature never observed in other plant-virus interactions.

Sequence diversity, population genetics and potential recombination events in grapevine rupestris stem pitting-associated virus in Pacific North-West vineyards

Grapevine rupestris stem pitting-associated virus (GRSPaV; genus Foveavirus, family Flexiviridae) is present in many grape-growing regions of the world. A total of 84 full-length coat protein (CP) sequences and 57 sequences representing the helicase-encoding region (HR) of the RNA-dependent RNA polymerase were obtained from wine grape cultivars grown in the Pacific North-West (PNW) of the United States and their molecular diversity was compared with corresponding sequences previously reported from other grape-growing regions. In pairwise comparisons, the CP sequences from PNW isolates showed identities between 80 and 100% at the nucleotide level and the HR sequences showed identities between 79 and 100%. A global phylogenetic analysis of the CP and HR sequences revealed segregation of GRSPaV isolates into four major lineages with isolates from PNW distributed in all four lineages, indicating a lack of clustering by geographical origin. Scion cultivars grafted onto rootstock were found to contain mixtures of more genetic variants belonging to different lineages than own-rooted cultivars. Assessment of population genetic parameters found that the CP was more variable than the HR region. The discordant gene phylogenies obtained for some CP and HR sequences and the identification of potential recombination events involving parents from different lineages provided strong evolutionary evidence for genetic diversity among GRSPaV isolates. These results underscore the highly variable nature of the virus with implications for grapevine health status and distribution of virus-tested planting materials. This study also contributes to an increased understanding of molecular population genetics of viruses infecting deciduous woody perennials.

Subcellular localization of the triple gene block proteins encoded by a Foveavirus infecting grapevines

Grapevine rupestris stem pitting-associated virus (GRSPaV; Foveavirus; Flexiviridae) contains a positive-sense, ssRNA genome. GRSPaV occurs worldwide in grapes and is involved in the Rugose Wood disease complex. The GRSPaV genome contains the triple gene block (TGB), a genetic module present in several genera of plant RNA viruses. TGB encodes three proteins (TGBp1, TGBp2 and TGBp3) that are believed to work together to achieve intra- and inter-cellular transport of virions in infected plants. To reveal the subcellular localization of each TGB protein and to examine the impact that different fusion positions may have on the behavior of the native protein, we made a series of expression constructs and expressed the corresponding protein fusions in Nicotiana tabacum BY-2 cells and protoplasts. We demonstrated that TGBp1 had both a cytosolic and nuclear distribution. Two TGBp1 fusions (GFP fused at the N- or C-terminus) differ in subcellular distribution. Through the use of truncation mutants, we mapped TGBp1 regions responsible for the formation of two distinct types of aggregates. Sequence analyses predicted two and one transmembrane domains in TGBp2 and TGBp3, respectively. GFP fusions at either terminus of TGBp2 revealed identical localization to the ER network and ER-derived structures. In contrast, the two TGBp3 fusions to mRFP differed in localization. This is the first report on the subcellular localization of the viral proteins of a member of the Foveavirus genus.

Genetic diversity analyses of grapevine Rupestris stem pitting-associated virus reveal distinct population structures in scion versus rootstock varieties

Grapevine Rupestris stem pitting-associated virus (GRSPaV) is a member of the genus Foveavirus within the family Flexiviridae. GRSPaV is closely associated with the disease Rupestris stem pitting and is frequently detected in grapevines worldwide. Previous research in several laboratories suggests that GRSPaV consists of a family of sequence variants. However, the genetic composition of GRSPaV variants in viral isolates from scion and rootstock varieties has not been studied extensively. In this report, the genetic diversity and population structure of GRSPaV isolates from scion and rootstock varieties were analysed using two pairs of primers targeting two different genomic regions encoding the helicase domain of the replicase and the capsid protein. In total, 190 cDNA clones derived from 24 isolates were sequenced and analysed. At least four major groups of GRSPaV variants were found to exist in grapevines. Interestingly, the majority of the scion varieties (9/10) that were analysed, regardless of their genetic background and geographical origin, harboured complex viral populations composed of two to four distinct viral variants. In contrast, the viral populations in isolates from rootstock varieties were homogeneous and comprised a single variant. The practice of grafting between scion and rootstock varieties commonly used in modern viticulture, coupled with the frequent regional and international exchange of propagating materials, may have played a major role in the ubiquitous distribution and mixed infections of distinct GRSPaV variants among scion varieties. The possible origin and evolution of GRSPaV are also discussed.

Molecular analysis of a California strain of Rupestris stem pitting-associated virus isolated from declining Syrah grapevines

The sequence of the genome of a Rupestris stem pitting-associated virus (RSPaV) isolated from a declining Syrah grapevine in California, designated the Syrah strain (RSPaV-SY) was determined. The genome of this strain had an overall nucleotide identity of 77% in comparison with RSPaV sequences in GenBank; the coat protein was the most conserved gene among RSPaV sequences and the replicase was the least conserved gene. Phylogenetic analysis of partial coat protein and replicase gene sequences showed RSPaV-SY clustered independently from the majority of RSPaV isolates.

Efficient methods for sample processing and cDNA synthesis by RT-PCR for the detection of grapevine viruses and viroids

Template preparation is important in reverse-transcription polymerase chain reaction (RT-PCR)-based detection methods. A TissueLyser with tungsten carbide beads was used for simultaneous processing of up to 48 samples under the same conditions in the development of a simple and rapid procedure to prepare a plant extract for RT reaction. A sandpaper method was also developed by which wood tissue of dormant cuttings could be macerated easily to process with minimal time and effort. It was also demonstrated that the combination use of random primers and oligo dT primer in an RT reaction was efficient for simultaneous cDNA synthesis of viral and viroid RNAs in plant extracts. These template preparation methods were used for the amplification of Grapevine leafroll-associated virus-1,-2, and -3; Grapevine virus A and B; Grapevine rupestris stem pitting-associated virus; Grapevine fleck virus; and Grapevine fanleaf virus. All these viruses tested in this study were reliably detected up to a 10(3)-fold or higher dilution of the original extract. Besides, Hop stunt viroid and Grapevine yellow speckle viroid 1 were well amplified in the same manner as the template preparation and following PCR for virus detection. These methods would contribute to cost-effective testing of a large number of samples through the year and help to detect viral pathogens in grapevine.

Application of a spotting sample preparation technique for the detection of pathogens in woody plants by RT-PCR and real-time PCR (TaqMan)

An extraction technique for reverse transcription-PCR (RT-PCR) detection of plant pathogens including viruses, bacteria and phytoplasma is described. The total nucleic acid of these plant pathogens was obtained by direct spotting of crude sap derived from infected leaf, petiole or cambial tissue onto two different types of membranes, positively charged Hybond N(+) Nylon and FTA membranes, and processed for use in PCR. Thirteen different plant viruses, Xylella fastidiosa (causal agent of Pierce's disease) and phytoplasmas were included in the experiment. A thermal treatment (95 degrees C for 10 min) of the Hybond N(+) Nylon discs in a buffered solution improved the detection, but for FTA membrane discs the thermal treatment was not required and the discs were directly placed in the PCR reaction cocktail. Specific amplification of genomic or ribosomal RNA fragments of these pathogens was obtained by one-step RT-PCR except for X. fastidiosa in which a fragment of the genomic DNA was used for amplification. The same sample preparation methods also worked well for real-time RT-PCR (TaqMan). The sample preparation techniques reported here could be used to store samples for future PCR test or for long distance shipment to a detection laboratory.

Rupestris stem pitting associated virus isolates are composed by mixtures of genomic variants which share a highly conserved coat protein

Broad spectrum primers were used to amplify a fragment comprising the CP gene and putative ORF6 by RT-PCR from ds-RNA templates originating from 46 Portuguese varieties, totalling 190 samples, including some wild Vitis ssp sylvestris vines, and 2 vines from Slovenia. SSCP analysis was used as a preliminary screen to avoid cloning and sequencing very similar variants. Four groups of variants were recognized. In pair wise comparisons between nucleotide sequences the minimal homology found was 81%. In case of the cultivated varieties, no relationship could be seen between the phylogenetic groups and geographic origin or grape variety. Several isolates were found harbouring mixed infections with genomic variants from different groups, but the mixing did not lead to an extensive recombination between them. The deduced amino-acid sequences revealed a conserved CP subjected to strong purifying selection pressure. Analysis of the selection pressure operating on the putative ORF6 suggests that this ORF does not exist. Previously produced polyclonal antiserum raised against the recombinant CP of RSPaV expressed in Escherichia coli was shown to be able to detect all four groups of variants of RSPaV included in this study, which might enable the diagnosis of the virus on a serological basis.

Complete genome sequences of two new variants of Grapevine rupestris stem pitting-associated virus and comparative analyses

Grapevine rupestris stem pitting-associated virus (GRSPaV), a member of the genus Foveavirus within the family Flexiviridae, is the putative causal agent of the disease Rupestris stem pitting (RSP) of grapevines. GRSPaV comprises a family of variants whose pathological characteristics have not been determined. Recently, many of the indicator "St George" plants (Vitis rupestris) used throughout the world to index RSP tested positive for GRSPaV. This finding questions the validity of past biological indexing results. In this work, a representative genomic region of GRSPaV was first sequenced from ten "St George" plants from two sources and it was demonstrated that nine of them carried a new variant, GRSPaV-SG1. The genomes of GRSPaV-SG1 and GRSPaV-BS from "Bertille Seyve 5563" plants were sequenced, revealing a genome structure identical to that of GRSPaV-1. It was demonstrated experimentally that infection of "St George" plants with GRSPaV-SG1 is asymptomatic and thus it is proposed that GRSPaV-SG1 infection should not have interfered with the outcome of past indicator indexing. This represents the first attempt to link a GRSPaV variant with pathological properties.

Detecção e caracterização biológica e molecular de Rupestris stem-pitting associated virus e seu efeito na fotossíntese de videiras

Rupestris stem pitting associated virus (RSPaV) é o agente causal das "caneluras do tronco de Rupestris" da videira (Vitis spp.). Neste trabalho, um isolado de RSPaV, encontrado em videiras cv. Cabernet Franc no Rio Grande do Sul, foi estudado. O vírus foi detectado biologicamente, por enxertia em videira indicadora cv. Rupestris du Lot, em 26,2% das amostras avaliadas. A seqüência parcial do gene da replicase do RSPaV, isolado sul-brasileiro, com 831 nucleotídeos amplificados por RT-PCR e 276 aminoácidos deduzidos, apresentou maior identidade de nucleotídeos (98,1%) e aminoácidos deduzidos (99,6%), com dois isolados norte-americanos. O RSPaV estudado apresentou baixa homologia (37-41%) com outros vírus do gênero Foveavirus. A maioria das mudas de videira cv. C. Franc infetadas com RSPaV apresentou diminuição no potencial fotossintético (2,68 a 5,12 vezes) e aumento na taxa respiratória no escuro quando comparadas a mudas sadias, salientando os impactos que esse vírus pode proporcionar no potencial produtivo de videiras.

First Detection of Rupestris stem pitting associated virus Particles by Antibody to a Recombinant Coat Protein

Rupestris stem pitting associated virus (RSPaV), a member of the genus Foveavirus, is associated with the Rupestris stem pitting component of the Rugose wood (RW) disease complex of grapevines. Heretofore, particles of RSPaV have not been visualized. In this work, flexuous rod particles approximately 723 nm in length were detected in the sap of infected grapevines by immunosorbent electron microscopy (ISEM), using a polyclonal antiserum produced to a recombinant coat protein of RSPaV. Particles of RSPaV were detected in tissue culture-, greenhouse-, and field-grown grapevines infected with RSPaV, but not in healthy control plants. Detection of virus particles by ISEM corresponded with detection of RSPaV by Western blot, enzyme-linked immunosorbent assay, and reverse transcription-polymerase chain reaction. Virus particles were decorated with the antibodies specific to RSPaV but not with antibodies to Grapevine virus A or Grapevine virus B, two other viruses believed to be associated with RW. This definitive identification of RSPaV particles will help define the etiology of RW.

Antiserum to Recombinant Virus Coat Protein Detects Rupestris stem pitting associated virus in Grapevines

Rupestris stem pitting (RSP) is the most widespread virus disease of grapevines. The genome of Rupestris stem pitting associated virus (RSPaV), the putative causal agent of RSP, was recently sequenced. Until recently, the only method to diagnose RSP was biological indexing on woody indicator plants, a process that takes 2 to 3 years to complete. This study reports on the production of a polyclonal antiserum to a recombinant coat protein of RSPaV. The antiserum was used effectively to detect RSPaV from various genotypes and tissues of grapevines by Western blot and indirect enzyme-linked immunosorbent assay. Virus antigens were consistently detected in the cambium of dormant canes and in actively growing leaves of grapevines. Moreover, plants of Vitis rupestris 'St. George', the standard biological indicator for RSP, tested positive for RSPaV. The serological methods developed in this study are advantageous as compared with biological indexing because they are more rapid, less expensive, as reliable, and more suitable for assays of a large number of samples.

A spot nested RT-PCR method for the simultaneous detection of members of the Vitivirus and Foveavirus genera in grapevine

A reverse transcription (RT) polymerase chain reaction (PCR) assay was developed to allow rapid, and simultaneous detection of Vitivirus and Foveavirus sequences in two steps. The method involved a one-step RT-PCR, in which the combination of degenerate deoxyinosine-substituted primers amplified part of the polymerase region of both genera, followed by a nested PCR amplification that increased specificity and sensitivity of detection. The increase in sensitivity also permitted the use of a simple and rapid template preparation protocol, involving the spotting of plant sap extract on a nylon membrane. Consistent amplification with infected grapevine plants was possible after inclusion of additives for inhibiting polyphenolic compounds during template preparation. This spot nested RT-PCR method can reliably detect virus species of both genera in grapevine allowing simple, fast, and cost-effective analysis of a large number of samples in certification schemes.

RT-PCR Based Detection of Rupestris stem pitting associated virus Within Field-Grown Grapevines Throughout the Year

The presence of Rupestris stem pitting associated virus (RSPaV) can go unnoticed since symptoms appear only if additional viruses are present. Detection by reverse transcription-polymerase chain reaction (RT-PCR) is possible; however, this assay could be unreliable if the tissue that is being tested has detection-interfering compounds, or if the virus has a low titer. This paper reports on (i) use of a recently developed extraction method and internal control to determine which tissues from field-grown grapevines yield extracts that are reliable for virus detection by RT-PCR, and (ii) a survey for RSPaV of different tissues from the Vitis vinifera varieties Riesling, Chardonnay, Cabernet Franc, Merlot, Sauvignon Blanc, Pinot Noir, and Gamay, as well as from the rootstocks 3309 and Riparia, which were harvested in Ontario, Canada, at different times of the year. Amplifiable extracts were obtained from virtually all bud, shoot tip, seed, and cane samples tested. Detectable amounts of RSPaV were generally found in all tissues of infected plants except young buds collected in the summer. A combination of three single buds from dormant canes, less time-consuming than the preparation of cane shavings, was a reliable source for RSPaV detection.

Improved RNA extraction and one-tube RT-PCR assay for simultaneous detection of control plant RNA plus several viruses in plant extracts

A procedure was developed for simultaneous detection of plant RNA viruses and of plant RNA, as a control. RT-PCR amplification with primers designed for the detection of the plant mRNAs encoding malate dehydrogenase (MDH) and the large subunit of ribulose bisphosphate carboxylase oxygenase (RubiscoL) was used for the development of a plant extraction procedure that consistently yields extracts that can be amplified. The control amplification was used successfully on extracts from cane, leaf and/or bud tissues from grapevine, apple, raspberry, strawberry, peach, apricot, plum and wheat. Multiplex RT-PCR conditions were established for the simultaneous detection in grapevine extracts of either arabis mosaic virus, rupestris stem pitting associated virus and malate dehydrogenase mRNA, or grapevine virus A, grapevine virus B, grapevine leafroll associated virus-3, and RubiscoL mRNA.

Impacts of Molecular Diagnostic Technologies on Plant Disease Management

Detection and diagnosis of plant viruses has included serological laboratory tests since the 1960s. Relatively little work was done on serological detection of plant pathogenic bacteria and fungi prior to the development of ELISA and monoclonal antibody technologies. Most applications for laboratory-based tests were directed at virus detection with relatively little emphasis on fungal and bacterial pathogens, though there was some good work done with other groups of plant pathogens. With the advent of molecular biology and the ability to compare regions of genomic DNA representing conserved sequences, the development of laboratory tests increased at an amazing rate for all groups of plant pathogens. Comparison of ITS regions of bacteria, fungi, and nematodes has proven useful for taxonomic purposes. Sequencing of conserved genes has been used to develop PCR-based detection with varying levels of specificity for viruses, fungi, and bacteria. Combinations of ELISA and PCR technologies are used to improve sensitivity of detection and to avoid problems with inhibitors or PCR often found in plants. The application of these technologies in plant pathology has greatly improved our ability to detect plant pathogens and is increasing our understanding of, their ecology and epidemiology.

Biological and Molecular Characterization of a New Carlavirus Isolated from an Aconitum sp

ABSTRACT A new virus was isolated from symptomless Aconitum napellus plants. The virus, for which the name Aconitum latent virus (AcLV) is proposed, has flexuous particles 640 nm in length. The experimental host range was limited to Nicotiana clevelandii. Electron microscopy studies of ultrathin sections of infected A. napellus tissues revealed the presence of elongated virus particles. No inclusion bodies characteristic of potyvirus infection were observed. AcLV was purified from naturally infected A. napellus by cesium chloride step gradient centrifugation. In sodium dodecyl sulfate-polyacrylamide gel electrophoresis of dissociated purified virus preparations, a major protein component with a molecular mass of 35 kDa was observed. Diagnostic antibodies that could specifically bind to virus particles were produced. The 5' terminus (620 nucleotides) of the viral RNA was cloned and sequenced. It comprised 71 nucleotides from the untranslated 5' terminus and 549 nucleotides of an open reading frame encoding 183 amino acids. Comparison of the predicted amino acid sequence with those of other plant viruses revealed 40 to 60% identity with several carlaviruses. Based on particle morphology, absence of inclusion bodies in ultrathin sections, the relative molecular weight of the coat protein, the nucleotide sequence, and predicted amino acid homology, it is suggested that this virus belongs to the carlavirus group.

A strategy for rapid cDNA cloning from double-stranded RNA templates isolated from plants infected with RNA viruses by using Taq DNA polymerase

A fast and efficient cDNA cloning procedure for plant RNA viruses was developed. In this procedure, double-stranded RNA (dsRNA) was used as a template source. Standard cDNA synthesis reagents and random hexamers were then used for making cDNAs. Taq DNA polymerase was used to add additional (A) at the ends of cDNAs, a TA cloning kit to ligate the cDNAs to vectors, and an electroporator to transform the DNAs to E. coli cells. dsRNAs were extracted from grapevine tissues infected with four different viruses and used for cloning. These viruses included grapevine rupestris stem pitting associated virus, grapevine leafroll associated virus 5, and two uncharacterized grapevine viruses, one each closely related to marafivirus and vitivirus groups. Selected cDNA clones were sequenced and PCR primers were developed for RT-PCR detection of these viruses in host plants.