Protection against virus infection in tobacco plants expressing the coat protein of grapevine fanleaf nepovirus

Summary Grapevine fanleaf nepovirus (GFLV) is responsible for the economically significant court-noué disease in vineyards. Its genome is made up of two single-stranded RNA molecules (RNA1 and RNA2) which direct the synthesis of polyproteins P1 and P2 respectively. A chimeric coat protein gene derived from the C-terminal part of P2 was constructed and subsequently introduced into a binary transformation vector. Transgenic Nicotiana benthamiana plants expressing the coat protein under the control of the CaMV 35S promoter were engineered by Agrobacterium tumefaciens-mediated transformation. Protection against infection with virions or viral RNA was tested in coat protein-expressing plants. A significant delay of systemic invasion was observed in transgenic plants inoculated with virus compared to control plants. This effect was also observed when plants were inoculated with viral RNA. No coat protein-mediated cross-protection was observed when transgenic plants were infected with arabis mosaic virus (ArMV), a closely related nepovirus also responsible for a court-noué disease.Abbreviations GFLV-F13 grapevine fanleaf virus F13 isolate - ArMV arabis mosaic virus - CP coat protein - MS Murashige and Skoog - NPTII neomycin phosphotransferase II - CaMV cauliflower mosaic virus - ELISA enzyme linked immunosorbent assay - VPg genome linked viral protein - TMV tobacco mosaic virus - PVX potato virus X - PVY potato virus Y - TRV tobacco rattle virus - +CP CP expressing - -CP control plant, not expressing CP - CPMP coat protein-mediated protection - CPMCP coat crotein-mediated cross protection     

Transient expression of artificial microRNAs targeting Grapevine fanleaf virus and evidence for RNA silencing in grapevine somatic embryos

Grapevines are affected worldwide by viruses that compromise fruit yield and quality. Grapevine fanleaf virus (GFLV) causes fanleaf degeneration disease, a major threat to grapevine production. Transgenic approaches exploiting the RNA silencing machinery have proven suitable for engineering viral resistance in several crop species. However, the artificial microRNA (amiRNA)-based strategy has not yet been reported in grapevine. We developed two amiRNA precursors (pre-amiRNAs) targeting the coat protein (CP) gene of GFLV and characterised their functionality in grapevine somatic embryos. To create these pre-amiRNAs, natural pre-miR319a of Arabidopsis thaliana was modified by overlapping PCR in order to replace miR319a with two amiRNAs targeting different regions of the CP gene: amiR^CP-1 or amiR^CP-2. Transient expression of these two pre-amiRNA constructs was tested in grapevine somatic embryos after co-cultivation with Agrobacterium tumefaciens. Expression of amiR^CP-1 and amiR^CP-2 was detected in plant tissues by an endpoint stem-loop RT-PCR as early as 1?day after a 48-h co-cultivation, indicating active processing of pre-amiRNAs by the plant machinery. In parallel, GUS-sensor constructs (G^CP-1 and G^CP-2) were obtained by fusing the target sequence of amiR^CP-1 or amiR^CP-2 to the 3?? terminus of the GUS gene. Co-transformation assays with GUS-sensors and the pre-amiRNA constructs provided evidence for in vivo recognition and cleavage of the 21-nt target sequence of GUS-sensors by the corresponding amiRNA. This is the first report of amiRNA ectopic expression in grapevine. The constructs we developed could be useful for engineering GFLV-resistant grapes in the future.     

Transformation of five grape rootstocks with plant virus genes and a virE2 gene from Agrobacterium tumefaciens

Summary To facilitate the development of transgenic grapevines that are resistant to grapevine fanleaf virus (GFLV), grapevine leafroll-associated closterovirus (GLRaV-3) and crown gall diseases, we developed a rapid system for regenerating root-stocks: Couderc 3309, Vitis riparia ‘Gloire de Montpellier’, Teleki 5C, Millardet et De Grasset 101-14, and 110 Richter via somatic embryogenesis. Embryo culture and grape regeneration were accomplished with four media. Embryogenic calluses from anthers were induced in the initiation medium [MS basic medium containing 20 g sucrose per L, 1.1 mg 2,4-dichlorophenoxyacetic acid (2,4-D) per L, 0.2 mg N⁶-benzyladenine (BA) per L, and 0.8% Noble agar). The percentage of anthers that developed into embryogenic calli ranged from 2 to 16.3% depending on the rootstock. Calluses with early globular stage embryos were cocultivated with Agrobacterium tumefaciens strain C58Z707 containing the gene constructs of interest. The genes were sense-oriented translatable and antisense coat protein genes from GFLV and GLRaV-3, a truncated HSP90-related gene of GLRaV-3 (43K), and a virE2 del B gene from A. tumefaciens strain C58. Twenty independent transformation experiments were performed on five rootstocks. After 3–4 mo. under kanamycin selection, secondary embryos were recovered on differentiation medium (1/2 MS salts with 10 g sucrose per L, 4.6 g glycerol per L, and 0.8% Noble agar). Embryos that were transformed were regenerated on a medium containing MS salts with 20 g sucrose per L, 4.6 g glycerol per L, 1 g casein hydrolysate per L, and 0.8% Noble agar. Elongated embryos were then transferred to a rooting medium supplemented with 0.1 mg BA per L, 3 g activated charcoal per L, 1.5% sucrose, and 0.65% Bacto agar. A total of 928 independent putative transgenic plants were propagated in the greenhouse. All plants were tested for neomycin phosphotransferase II expression by enzyme-linked immunosorbent assay (ELISA). The presence of transgenes was assessed by polymerase chain reaction and Southern analysis. ELISA revealed various levels of expression of GFLV coat protein in transgenic plants of Couderc 3309. The transgenic rootstocks that have been generated are being screened to determine whether transgenes have conferred resistance to the virus and crown gall diseases.     

Cross-protection between arabis mosaic virus and grapevine fan leaf virus isolates in Chenopodium quinoa

Cross-protection experiments were performed in Chenopodium quinoa using arabis mosaic virus (ArMV) and grapevine fanleaf virus (GFLV) isolates. Two factors were specially studied, namely the time interval and the distance between the two inoculations, respectively, with the hypovirulent isolate and with the hyper virulent challenge isolale. ArMV-S clearly protected C. quinoa from a super infection with GFLV-F13 as shown by a diminution, or even suppression, of the synthesis of the coat protein and the nucleic acids of the GFLV-F13 isolate. In the homologous interaction between GFLV isolates (GH and F13), protection was also observed. In the interaction between GFLV-GH and ArMV-862, by contrast, symptoms were typical of the hyper virulent ArMV-862 and the amount of coat protein of ArMV-862 was normal.     

An Unusual Feature at the N-terminal end of the Coat Protein of Maize dwarf mosaic virus isolated in Hungary

Maize dwarf mosaic is the most widespread virus disease affecting corn production in Hungary. In attempts to identify the causal virus by test plant reactions, enzyme‐linked immunosorbent assay (ELISA) and polymerase chain reaction (PCR), only Maize dwarf mosaic virus (MDMV) was detected. To further characterize Hungarian isolates of MDMV, one isolate from each of the sweet corn varieties Dallas, Royalty and GH23‐85 was selected for sequence analysis of its coat protein (CP) gene. The three Hungarian isolates shared CP amino acid sequence similarities of 95–98% not only with one another but also with MDMV isolates from other countries. However, the N‐terminus of the CP of the ‘Dallas’ isolate was unusual in containing a stretch of 13 additional amino acids. This is the first report of variation in the size of the N‐terminus of the MDMV CP.     

Molecular characterization of grapevine plants transformed with GFLV resistance genes: I

The Grapevine FanLeaf Virus-Coat Protein (GFLV CP) gene was inserted through Agrobacterium-mediated transformation in Vitis vinifera ‘Nebbiolo’, ‘Lumassina’ and ‘Blaufränkisch’. Two plasmids were used: pGA-CP+ (full-length GFLV CP gene with an introduced start codon) and pGA-AS (same gene in antisense orientation). Forty-three transgenic lines were regenerated. As several lines in Southern blots share same hybridization patterns, eight independent line groups resulted for ‘Nebbiolo’, one for ‘Lumassina’, and two for ‘Blaufränkisch’. Inserted T-DNA copies ranged from one to three; one line probably contains an incomplete copy of T-DNA. Except for one ‘Nebbiolo’ line, no evidence for methylation of the transgene at cytosine residues was found by Southern analyses. Specific mRNA was present at variable expression levels; some lines accumulated the coat protein while in others the protein was not detectable by ELISA.     

Structural insights into viral determinants of nematode mediated Grapevine fanleaf virus transmission

Many animal and plant viruses rely on vectors for their transmission from host to host. Grapevine fanleaf virus (GFLV), a picorna-like virus from plants, is transmitted specifically by the ectoparasitic nematode Xiphinema index. The icosahedral capsid of GFLV, which consists of 60 identical coat protein subunits (CP), carries the determinants of this specificity. Here, we provide novel insight into GFLV transmission by nematodes through a comparative structural and functional analysis of two GFLV variants. We isolated a mutant GFLV strain (GFLV-TD) poorly transmissible by nematodes, and showed that the transmission defect is due to a glycine to aspartate mutation at position 297 (Gly297Asp) in the CP. We next determined the crystal structures of the wild-type GFLV strain F13 at 3.0 Å and of GFLV-TD at 2.7 Å resolution. The Gly297Asp mutation mapped to an exposed loop at the outer surface of the capsid and did not affect the conformation of the assembled capsid, nor of individual CP molecules. The loop is part of a positively charged pocket that includes a previously identified determinant of transmission. We propose that this pocket is a ligand-binding site with essential function in GFLV transmission by X. index. Our data suggest that perturbation of the electrostatic landscape of this pocket affects the interaction of the virion with specific receptors of the nematode''s feeding apparatus, and thereby severely diminishes its transmission efficiency. These data provide a first structural insight into the interactions between a plant virus and a nematode vector.     

Expression of Potato Virus Y Coat Protein Gene in Transgenic Potato

Potato virus Y (PVY) N coat protein (CP) coding sequence was cloned into a plant expression vector pMON316 under the CaMV 35S promoter. Leaf discs of potato (Solanum tuberosum) were used to Agrobacterium-mediated gene transfer. A large number of regenerated putative transgenic plants were obtained based on kanamycin resistance. Using total DNA purified from transgenic plants as templates and two oligonucleotides synthesized from 5' and 3' of the PVY coat protein gene as primers, the authors carried out polymerase chain reaction (PCR) to check the presence of this gene and obtained a 0. 8 kb specific DNA fragment after 35 cycles of amplification. Southern blot indicated that the PCR product was indeed PVY CP gene which had been integrated into the potato genome. Enzyme-linked immunosorbent assay (ELISA) of our transgenic plants showed that CP gene was expressed in at least some transgenic potato plants.     

Grapevine fanleaf virus (GFLV)-specific antibodies confer GFLV and Arabis mosaic virus (ArMV) resistance in Nicotiana benthamiana

Grapevine fanleaf virus (GFLV) is one of the most destructive pathogens of grapevine. In this study, we generated monoclonal antibodies binding specifically to the coat protein of GFLV. Antibody FL₃, which bound most strongly to GFLV and showed cross-reactivity to Arabis mosaic virus (ArMV), was used to construct the single-chain antibody fragment scFvGFLVcp-55. To evaluate the potential of this single-chain variable fragment (scFv) to confer antibody-mediated virus resistance, transgenic Nicotiana benthamiana plants were generated in which the scFv accumulated in the cytosol. Recombinant protein levels of up to 0.1% total soluble protein were achieved. The T₁ and T₂ progenies conferred partial or complete protection against GFLV on challenge with the viral pathogen. The resistance to GFLV in transgenic plants was strictly related to scFvGFLVcp-55 accumulation levels, confirming that the antibody fragment was functional in planta and responsible for the GFLV resistance. In addition, transgenic plants conferring complete protection to GFLV showed substantially enhanced tolerance to ArMV. We demonstrate the first step towards the control of grapevine fanleaf degeneration, as scFvGFLVcp-55 could be an ideal candidate for mediating nepovirus resistance.     

Display of whole proteins on inner and outer surfaces of grapevine fanleaf virus‐like particles

Virus‐like particles (VLPs) derived from nonenveloped viruses result from the self‐assembly of capsid proteins (CPs). They generally show similar structural features to viral particles but are noninfectious and their inner cavity and outer surface can potentially be adapted to serve as nanocarriers of great biotechnological interest. While a VLP outer surface is generally amenable to chemical or genetic modifications, encaging a cargo within particles can be more complex and is often limited to small molecules or peptides. Examples where both inner cavity and outer surface have been used to simultaneously encapsulate and expose entire proteins remain scarce. Here, we describe the production of spherical VLPs exposing fluorescent proteins at either their outer surface or inner cavity as a result of the self‐assembly of a single genetically modified viral structural protein, the CP of grapevine fanleaf virus (GFLV). We found that the N‐ and C‐terminal ends of the GFLV CP allow the genetic fusion of proteins as large as 27 kDa and the plant‐based production of nucleic acid‐free VLPs. Remarkably, expression of N‐ or C‐terminal CP fusions resulted in the production of VLPs with recombinant proteins exposed to either the inner cavity or the outer surface, respectively, while coexpression of both fusion proteins led to the formation hybrid VLP, although rather inefficiently. Such properties are rather unique for a single viral structural protein and open new potential avenues for the design of safe and versatile nanocarriers, particularly for the targeted delivery of bioactive molecules.     

Primary structure and location of the genome-linked protein (VPg) of grapevine fanleaf nepovirus

The genome linked protein VPg covalently linked to the RNAs of grapevine fanleaf nepovirus has been sequenced. The VPg (Mr = 2931) composed of 24 residues is linked by its N-terminal Ser beta-OH group to the viral RNAs. The VPg mapped from residues 1218 to 1241 of the 253K polyprotein encoded by GFLV RNA1.     

Production of transgenic soybean lines expressing the bean pod mottle virus coat protein precursor gene

Soybean (Glycine max. Merrill. cv. Fayette) cotyledonary nodes were transformed with bean pod mottle virus (BPMV) coat protein precursor (CP-P) gene via Agrobacterium-mediated transformation. The transformation rate was low, and only five primary transformants derived from five different cotyledons were obtained from 400 original cotyledons. Southern blot hybridization verified the integration of the BPMV CP-P gene. Inheritance and expression of this gene in R₁ plants were also demonstrated. About 30% of R₂ plants derived from one transgenic line showed complete resistance to BPMV infection, as assessed by symptomatology and ELISA, suggesting that homozygous, but not hemizygous, plants exhibit the resistant phenotype.Abbreviations BAP 6-benzyladenine phosphate - BPMV bean pod mottle virus - CP-P coat protein-precursor - CTAB hexadecyltrimethylammonium bromide - DAS-ELISA double antibody sandwich-enzyme-linked immunosorbent assay - IBA indole-butyric acid - kbp kilobase pairs - MES 2-(N-Morpholino)ethanesulfonic acid - NOS nopaline synthase - NPTII neomycin phosphotransferase II - NTP nucleoside triphosphate - PBS phosphate-buffered saline - PCR polymerase chain reaction - PVP polyvinyl pyrrolidone - VPg viral genome-linked protein