Occurrence and characterization of plum pox virus strain D isolates from European Russia and Crimea.

Numerous plum pox virus (PPV) strain D isolates have been found in geographically distant regions of European Russia and the Crimean peninsula on different stone fruit hosts. Phylogenetic analysis of their partial and complete genomes suggests multiple introductions of PPV-D into Russia. Distinct natural isolates from Prunus tomentosa were found to bear unique amino acid substitutions in the N-terminus of the coat protein (CP) that may contribute to the adaptation of PPV-D to this host. Serological analysis using the PPV-D-specific monoclonal antibody 4DG5 provided further evidence that mutations at positions 58 and 59 of the CP are crucial for antibody binding.

Characterization of sour cherry isolates of plum pox virus from the Volga Basin in Russia reveals a new cherry strain of the virus.

Plum pox virus (PPV) is the causal agent of sharka, the most detrimental virus disease of stone fruit trees worldwide. PPV isolates have been assigned into seven distinct strains, of which PPV-C regroups the genetically distinct isolates detected in several European countries on cherry hosts. Here, three complete and several partial genomic sequences of PPV isolates from sour cherry trees in the Volga River basin of Russia have been determined. The comparison of complete genome sequences has shown that the nucleotide identity values with other PPV isolates reached only 77.5 to 83.5%. Phylogenetic analyses clearly assigned the RU-17sc, RU-18sc, and RU-30sc isolates from cherry to a distinct cluster, most closely related to PPV-C and, to a lesser extent, PPV-W. Based on their natural infection of sour cherry trees and genomic characterization, the PPV isolates reported here represent a new strain of PPV, for which the name PPV-CR (Cherry Russia) is proposed. The unique amino acids conserved among PPV-CR and PPV-C cherry-infecting isolates (75 in total) are mostly distributed within the central part of P1, NIa, and the N terminus of the coat protein (CP), making them potential candidates for genetic determinants of the ability to infect cherry species or of adaptation to these hosts. The variability observed within 14 PPV-CR isolates analyzed in this study (0 to 2.6% nucleotide divergence in partial CP sequences) and the identification of these isolates in different localities and cultivation conditions suggest the efficient establishment and competitiveness of the PPV-CR in the environment. A specific primer pair has been developed, allowing the specific reverse-transcription polymerase chain reaction detection of PPV-CR isolates.

Family-based linkage and association mapping reveals novel genes affecting Plum pox virus infection in Arabidopsis thaliana.

Sharka is a devastating viral disease caused by the Plum pox virus (PPV) in stone fruit trees and few sources of resistance are known in its natural hosts. Since any knowledge gained from Arabidopsis on plant virus susceptibility factors is likely to be transferable to crop species, Arabidopsis's natural variation was searched for host factors essential for PPV infection. To locate regions of the genome associated with susceptibility to PPV, linkage analysis was performed on six biparental populations as well as on multiparental lines. To refine quantitative trait locus (QTL) mapping, a genome-wide association analysis was carried out using 147 Arabidopsis accessions. Evidence was found for linkage on chromosomes 1, 3 and 5 with restriction of PPV long-distance movement. The most relevant signals occurred within a region at the bottom of chromosome 3, which comprises seven RTM3-like TRAF domain-containing genes. Since the resistance mechanism analyzed here is recessive and the rtm3 knockout mutant is susceptible to PPV infection, it suggests that other gene(s) present in the small identified region encompassing RTM3 are necessary for PPV long-distance movement. In consequence, we report here the occurrence of host factor(s) that are indispensable for virus long-distance movement.

Narrowing down the apricot Plum pox virus resistance locus and comparative analysis with the peach genome syntenic region.

Sharka disease, caused by the Plum pox virus (PPV), is one of the main limiting factors for stone fruit crops worldwide. Only a few resistance sources have been found in apricot (Prunus armeniaca L.), and most studies have located a major PPV resistance locus (PPVres) on linkage group 1 (LG1). However, the mapping accuracy was not sufficiently reliable and PPVres was predicted within a low confidence interval. In this study, we have constructed two high-density simple sequence repeat (SSR) improved maps with 0.70 and 0.68 markers/cm, corresponding to LG1 of 'Lito' and 'Goldrich' PPV-resistant cultivars, respectively. Using these maps, and excluding genotype-phenotype incongruent individuals, a new binary trait locus (BTL) analysis for PPV resistance was performed, narrowing down the PPVres support intervals to 7.3 and 5.9 cm in 'Lito' and 'Goldrich', respectively. Subsequently, 71 overlapping oligonucleotides (overgo) probes were hybridized against an apricot bacterial artificial chromosome (BAC) library, identifying 870 single BACs from which 340 were anchored onto a map region of approximately 30-40 cm encompassing PPVres. Partial BAC contigs assigned to the two allelic haplotypes (resistant/susceptible) of the PPVres locus were built by high-information content fingerprinting (HICF). In addition, a total of 300 BAC-derived sequences were obtained, and 257 showed significant homology with the peach genome scaffold_1 corresponding to LG1. According to the peach syntenic genome sequence, PPVres was predicted within a region of 2.16 Mb in which a few candidate resistance genes were identified.

Analysis of the epitope structure of Plum pox virus coat protein.

Typing of the particular Plum pox virus (PPV) strain responsible in an outbreak has important practical implications and is frequently performed using strain-specific monoclonal antibodies (MAbs). Analysis in Western blots of the reactivity of 24 MAbs to a 112-amino-acid N-terminal fragment of the PPV coat protein (CP) expressed in Escherichia coli showed that 21 of the 24 MAbs recognized linear or denaturation-insensitive epitopes. A series of eight C-truncated CP fragments allowed the mapping of the epitopes recognized by the MAbs. In all, 14 of them reacted to the N-terminal hypervariable region, defining a minimum of six epitopes, while 7 reacted to the beginning of the core region, defining a minimum of three epitopes. Sequence comparisons allowed the more precise positioning of regions recognized by several MAbs, including those recognized by the 5B-IVIA universal MAb (amino acids 94 to 100) and by the 4DG5 and 4DG11 D serogroup-specific MAbs (amino acids 43 to 64). A similar approach coupled with infectious cDNA clone mutagenesis showed that a V74T mutation in the N-terminus of the CP abolished the binding of the M serogroup-specific AL MAb. Taken together, these results provide a detailed positioning of the epitopes recognized by the most widely used PPV detection and typing MAbs.

Interaction of plum pox virus with specific colloidal gold-labeled antibodies and development of immunochromatographic assay of the virus.

Two monoclonal antibodies (mABs) raised against plum pox virus (PPV) were shown to recognize its D, M, and C strains. Conjugates of the antibodies with colloidal gold (CG) nanoparticles averaging 26 nm in diameter were synthesized. The binding constants of PPV with both the native and conjugated mABs were determined using a Biacore X device. The complexes between the CG-mAB conjugates and plum pox virions were examined by means of transmission electron and atomic force microscopy. Using the conjugates with optimal component ratio, an express immunochromatographic assay of PPV was developed with a detection limit of 3 ng/ml and duration of 10 min. The assay was tested for PPV detection in samples of stone fruit tree leaves and demonstrated a good compatibility with the data obtained by "sandwich"-ELISA. The developed assay can be used in the field and applied for monitoring viral infection and for quarantine purposes.

Use of Luminex xMAP-derived Bio-Plex bead-based suspension array for specific detection of PPV W and characterization of epitopes on the coat protein of the virus.

A panel of monoclonal antibodies (MAbs) directed against the N-terminus region of the coat protein (CP) of strain PPV W (isolate 3174) was generated by immunizing mice with recombinant peptides. The best performing MAbs were identified as 2C3 and 10G7. MAb 2C3 was selected for comparison of a standard TAS-ELISA protocol with a Luminex xMAP technology-derived bead-based suspension array system described as a triple antibody sandwich-microsphere immunoassay (TAS-MIA). TAS-MIA was as sensitive as TAS-ELISA for the specific detection of PPV W in herbaceous and woody hosts. It was completed in 4h, and used less reagents. Epitope recognition analysis was carried out using a set of overlapping synthetic pin-bound peptides (Mimotopes). Peptides (2)DEEDD(6) and (46)MFNPV(50) were the epitopes recognized most commonly by the best performing MAbs. Linear epitope prediction of B-cell recognition sites confirmed that both peptides fall within highly antigenic and accessible regions. The second glutamic acid residue of the epitope is crucial for MAb recognition, and the context of the epitope is as important as the sequence of the epitope. The results obtained in ELISA, Western blot, and TAS-MIA correlated with B-cell recognition prediction. This is an effective approach to identify suitable antigenic epitopes that generate antibodies for use in reliable diagnostic procedures. This is the first report of the detection of a plant virus using the Luminex xMAP bead-based suspension array system.

Partial sequence analysis of an atypical Turkish isolate provides further information on the evolutionary history of Plum pox virus (PPV).

A variety of techniques, such as typing with subgroup-specific monoclonal antibodies, restriction length polymorphism (RFLP) analysis or subgroup-specific RT-PCR are available for the discrimination of Plum pox virus (PPV) isolates. However, the existence of PPV isolates showing abnormal typing properties has been observed in the past [Candresse, T., Cambra, M., Dallot, S., Lanneau, M., Asensio, M., Gorris, M.T., Revers, F., Macquaire, G., Olmos, A., Boscia, D., Quiot J.B., Dunez, J., 1998. Comparison of monoclonal antibodies and polymerase chain reaction assays for the typing of isolates belonging to the D and M serotypes of Plum pox potyvirus. Phytopathology 88, 198-204.]. In an effort to understand the molecular mechanisms underlying such anomalous serological and molecular typing characteristics, partial 3' (1449 nt) and 5' (3706 nt) sequences have been determined for an atypical Turkish PPV isolate (Abricotier Turquie or Ab-Tk). The results obtained indicate that its unusual typing behaviour is caused by point mutations affecting key restriction sites and epitopes and confirm that this isolate represents a divergent member of the PPV-M subgroup. In addition, analysis of the partial Ab-Tk genomic sequences demonstrated that the 5' region of the genome of this isolate has a mosaic structure resulting from recombination event(s), shedding new light on the evolutionary history of Plum pox virus.

An apricot (Prunus armeniaca L.) F2 progeny linkage map based on SSR and AFLP markers, mapping plum pox virus resistance and self-incompatibility traits.

A genetic linkage map of apricot ( Prunus armeniaca L.) was constructed using AFLP and SSR markers. The map is based on an F(2) population (76 individuals) derived from self-pollination of an F(1) individual ('Lito') originated from a cross between 'Stark Early Orange' and 'Tyrinthos'. This family, designated as 'Lito' x 'Lito', segregated for two important agronomical traits: plum pox virus resistance (PPV) and self-incompatibility. A total of 211 markers (180 AFLPs, 29 SSRs and two agronomic traits) were assigned to 11 linkage groups covering 602 cM of the apricot genome. The average distance (cM/marker) between adjacent markers is 3.84 cM. The PPV resistance trait was mapped on linkage group G1 and the self-incompatibility trait was mapped on linkage group G6. Twenty two loci held in common with other Prunus maps allowed us to compare and establish homologies among the respective linkage groups.

Identification of immunogenic hot spots within plum pox potyvirus capsid protein for efficient antigen presentation.

PEPSCAN analysis has been used to characterize the immunogenic regions of the capsid protein (CP) in virions of plum pox potyvirus (PPV). In addition to the well-known highly immunogenic N- and C-terminal domains of CP, regions within the core domain of the protein have also shown high immunogenicity. Moreover, the N terminus of CP is not homogeneously immunogenic, alternatively showing regions frequently recognized by antibodies and others that are not recognized at all. These results have helped us to design efficient antigen presentation vectors based on PPV. As predicted by PEPSCAN analysis, a small displacement of the insertion site in a previously constructed vector, PPV-gamma, turned the derived chimeras into efficient immunogens. Vectors expressing foreign peptides at different positions within a highly immunogenic region (amino acids 43 to 52) in the N-terminal domain of CP were the most effective at inducing specific antibody responses against the foreign sequence.

The production of a genus-specific recombinant antibody (scFv) using a recombinant potyvirus protease.

A single chain variable fragment antibody (scFv; anti-NIa scFv102) was selected from a synthetic human antibody library by using a NIa protease of Plum pox virus (PPV) as an antigen, which was expressed in bacteria. The NIa protease forms the nuclear inclusion body A and acts as the major protease in the cleavage of the viral polyprotein into functional proteins. The NIa protein was detected with anti-NIa scFv102 after expression in Escherichia coli cells as well as from PPV-infected Nicotiana benthamiana plants. Furthermore, the scFv102 has the ability to identify not only PPV from infected plants but also can detect other infections with members of the potyviruses. Nineteen different potyviruses were recognized by the scFv102 in various infected plants tested through dot blot assays. Therefore, the antibody scFv102 has the potential of becoming a general tool to detect potyvirus infections in different plant species.

Protection of rabbits against rabbit hemorrhagic disease virus by immunization with the VP60 protein expressed in plants with a potyvirus-based vector.

A new plum pox potyvirus (PPV)-based vector has been constructed for the expression of full-length individual foreign proteins. The foreign sequences are cloned between the NIb replicase and capsid protein (CP) cistrons. The heterologous protein is split from the rest of the potyviral polyprotein by cleavage at the site that originally separated the NIb and CP proteins and at an additional NIa protease recognition site engineered at its amino-terminal end. This vector (PPV-NK) has been used to clone different genes, engendering stable chimeras with practical applications. We have constructed a chimera expressing high levels of jellyfish green fluorescent protein, which can be very useful for the study of PPV molecular biology. The VP60 structural protein of rabbit hemorrhagic disease virus (RHDV) was also successfully expressed by making use of the PPV-NK vector. Inoculation of extracts from VP60-expressing plants induced a remarkable immune response against RHDV in rabbits, its natural host. Moreover, these animals were protected against a lethal challenge with RHDV.

Biotechnological aspects of plum pox virus.

Plum pox potyvirus (PPV), the causal agent of a devastating disease that affects stone fruit trees, is becoming a target of intense studies intended both to fight against viral infection and to develop practical applications based on the current knowledge of potyvirus molecular biology. This review focuses on biotechnological aspects related to PPV, such as novel diagnostic techniques that facilitate detection and typing of virus isolates, strategies to implement pathogen-derived resistance through plant transformation, the potential use of genetic elements derived from the virus, and the recent development of PPV-based expression vectors.

The use of transgenic fruit trees as a resistance strategy for virus epidemics: the plum pox (sharka) model.

Sharka or plum pox, caused by Plum pox virus (PPV: genus Potyvirus; Family Potyviridae), is the most serious disease of Prunus. Most cultivated Prunus species are highly susceptible and conventional breeding has not produced highly resistant and commercially acceptable varieties. Success in developing virus-resistant herbaceous crops through genetic engineering led us to investigate this approach for resistance to PPV. Our programme aims to develop a biotechnological approach to PPV control that is effective and shown to be environmentally safe. The programme began with the cloning of the PPV coat protein (CP) gene and the development of a transformation system for plum (Prunus domestica). The CP construct was first tested in Nicotiana benthamiana in which it proved effective in producing transgenic plants with varying levels of CP expression. Some of these plants, particularly low PPV CP expressers, were resistant to PPV, or recovered from initial infection. Based on these results plum was transformed using the Agrobacterium tumefaciens system and both low and high PPV CP-expressing transgenic plum lines were obtained. These were inoculated with PPV by bud grafts in the greenhouse. Line C-5 proved to be highly resistant. It contained multiple copies of the insert, produced low levels of PPV CP mRNA, no detectable CP and the insert appeared to be methylated. These characteristics all suggest that the resistance of the C-5 clone is based on post-transcriptional gene silencing (PTGS). Field tests of C-5 and other transgenic lines in Poland, Romania and Spain have demonstrated that such trees when inoculated by bud-grafts allow a low level of PPV multiplication, from which they rapidly recover. C-5 plants exposed to natural infection for 3 years did not become infected, whereas control trees were infected in the first year. Hybrid plums having the C-5 PPV CP insert inherited from C-5 are virus-resistant, demonstrating the usefulness of C-5 as a parent in developing new PPV-resistant plum varieties. Research is in progress on the biorisks of PPV CP transgenic plants. Gene constructs that either produce no CP or CP that cannot be transmitted by aphids have been developed, tested in N. benthamiana and transferred to plum. Studies have begun on the potential for synergistic interactions between the PPV CP gene and the other common viruses of Prunus spp. In the future we will be participating in investigating the toxicity or/and the allergenicity of transgenic fruit products and, more importantly, transgenic lines will be developed that express transgenes only in vegetative parts of the plant and not in the fruit.

Preparation of diagnostic monoclonal antibodies against two potyviruses.

Diagnostic monoclonal and polyclonal antibodies against bean yellow mosaic virus (BYMV) and plum pox virus (PPV) were prepared, characterized and used for detection of these viruses in infected plants by enzyme-linked immunosorbent assay (ELISA), immunoblot analysis and tissue print immunoblot assay (TPIBA).

Ultrastructural localization of nonstructural and coat proteins of 19 potyviruses using antisera to bacterially expressed proteins of plum pox potyvirus.

Antisera to the bacterially expressed nonstructural proteins (NSP) HC-Pro, CI, NIa, and NIb and the coat protein (CP) of plum pox potyvirus (PPV) were used for analysing the composition of virus-induced cytoplasmic and nuclear inclusions by electron microscopy. The antisera reacted with NSP and CP of PPV on immunogold-labelled ultrathin sections. Antiserum to CP reacted with virions of seven out of 18 other potyviruses. CP was distributed throughout the cytoplasm of infected cells. Antisera to PPV NSP specifically reacted with virus-specific cytoplasmic and/or nuclear inclusions induced by 17 different potyviruses. NSP were furthermore localized in confined cytoplasmic areas in between complex accumulations of virus-specific inclusions. Cylindrical inclusions induced by the potyviruses were proven to consist of CI protein. Most other cytoplasmic or nuclear inclusions were shown to be composed of two or more NSP. An unexpected composition of virus-induced inclusions was observed for the crystalline nuclear inclusions of tobacco etch virus. Here, in addition to the expected presence of NIa and NIb, HC-Pro could be demonstrated. Furthermore, amorphous cytoplasmic inclusions induced by papaya ringspot virus contained the expected HC-Pro but additionally NIa, NIb and CI. Beet mosaic virus-induced nuclear inclusions ('satellite bodies') contained in their electron-dense matrix NIa, NIb, Hc-Pro and CI and in their lacunae CP in bundles of virion-like filaments. The results indicate that all cytoplasmic or nuclear inclusions of potyviruses have to be regarded as deposition sites of excessively produced viral NSP.

Development of an antigen presentation system based on plum pox potyvirus.

The development of an antigen presentation system based on the plum pox potyvirus (PPV) is here described. The amino-terminal part of PPV capsid protein was chosen as the site for expression of foreign antigenic peptides. Modifications in this site were engineered to avoid the capability of natural transmission by aphids of this PPV vector. As a first practical attempt, different forms of an antigenic peptide (single and tandem repetition) from the VP2 capsid protein of canine parvovirus (CPV) were expressed. Both chimeras are able to infect Nicotiana clevelandii plants with similar characteristics to wild-type virus and remain genetically stable after several plant passages. The antigenicity of purified chimeric virions was demonstrated, proving the suitability of this system for diagnostic purposes. Moreover, mice and rabbits immunized with chimeric virions developed CPV-specific antibodies, which showed neutralizing activity.

Production of a monoclonal antibody specific to the El Amar strain of plum pox virus.

Plum pox virus (PPV) isolates are grouped into three clusters differentiated by biological, serological, molecular and epidemiological characteristics: Marcus (M), Dideron (D) and Cherry (C). The El Amar (EA) isolate that does not fit any of the above groups is also known. Monoclonal antibodies (MAbs) that specifically recognize M, D, and C strains of PPV are already available. To complete the set of PPV strain-specific serological reagents, MAbs against the EA isolate were raised by immunizing BALB/c mice and fusing their spleen cells with NS0/1 myeloma cells. After a preliminary characterization by double-antibody sandwich enzyme-linked immunosorbent assay (DAS-ELISA), 1 of 13 selected MAbs proved to be EA strain-specific. This MAb (EA24) reacted equally well with a homologous antigen and several PPV isolates from Egyptian apricot trees, supporting the hypothesis of an additional specific PPV group. MAb EA24 did not react either with about a hundred PPV isolates belonging to the D and M groups or with PPV-SwC and PPV-SoC isolates belonging to the C group. The strain specificity of MAb EA24 was confirmed by Western blot analysis and immunoelectron microscopy. We conclude that there is now available a set of MAbs which are highly specific to the four currently known groups of PPV strains.

Detection and serotyping of Mediterranean plum pox virus isolates by means of strain-specific monoclonal antibodies.

Plum pox virus (PPV) is a major threat to the expanding Mediterranean stone fruit industry. In order to control the plum pox disease it is of utmost importance to detect early PPV foci and to identify the PPV isolates involved. A survey was therefore carried out in Albania, Cyprus, Egypt, Greece, Italy and Turkey by a double-antibody sandwich enzyme-linked immunosorbent assay (DAS-ELISA) with the following monoclonal antibodies (MAbs): 5B (universal), 4DG5 (PPV-D-specific), AL (PPV-M-specific), TUV and AC (PPV-C-specific), and EA24 (PPV-El Amar-specific). A hundred and seventy Mediterranean PPV isolates were tested for strain type. PPV-M was detected in Albania, Cyprus, Greece, Italy, and Turkey; PPV-D was detected in Albania and Italy, whereas samples with natural mixtures of both strains were found in a couple of orchards in Albania. Seven PPV isolates from apricots in two Egyptian localities were recognized only by MAb EA24. In conclusion, DAS-ELISA with a combination of the universal MAb5B and the MAbs specific to the four PPV serotypes currently known (M, D, C and El Amar) is an efficient tool for a simple, sensitive and routine detection of PPV and discrimination of its serotypes.