Xylella fastidiosa in Olive in Apulia: Where We Stand.

A dramatic outbreak of Xylella fastidiosa decimating olive was discovered in 2013 in Apulia, Southern Italy. This pathogen is a quarantine bacterium in the European Union (EU) and created unprecedented turmoil for the local economy and posed critical challenges for its management. With the new emerging threat to susceptible crops in the EU, efforts were devoted to gain basic knowledge on the pathogen biology, host, and environmental interactions (e.g., bacterial strain(s) and pathogenicity, hosts, vector(s), and fundamental drivers of its epidemics) in order to find means to control or mitigate the impacts of the infections. Field surveys, greenhouse tests, and laboratory analyses proved that a single bacterial introduction occurred in the area, with a single genotype, belonging to the subspecies pauca, associated with the epidemic. Infections caused by isolates of this genotype turned to be extremely aggressive on the local olive cultivars, causing a new disease termed olive quick decline syndrome. Due to the initial extension of the foci and the rapid spread of the infections, eradication measures (i.e., pathogen elimination from the area) were soon replaced by containment measures including intense border surveys of the contaminated area, removal of infected trees, and mandatory vector control. However, implementation of containment measures encountered serious difficulties, including public reluctance to accept control measures, poor stakeholder cooperation, misinformation from some media outlets, and lack of robust responses by some governmental authorities. This scenario delayed and limited containment efforts and allowed the bacterium to continue its rapid dissemination over more areas in the region, as shown by the continuous expansion of the official borders of the infected area. At the research level, the European Commission and regional authorities are now supporting several programs aimed to find effective methods to mitigate and contain the impact of X. fastidiosa on olives, the predominant host affected in this epidemic. Preliminary evidence of the presence of resistance in some olive cultivars represents a promising approach currently under investigation for long-term management strategies. The present review describes the current status of the epidemic and major research achievements since 2013.

Detection of four regulated grapevine viruses in a qualitative, single tube real-time PCR with melting curve analysis.

The detection of the four grapevine viruses (GLRaV-1, GLRaV-3, GFLV and ArMV) regulated in European Union plant material certification, requires sensitive and specific diagnostic tools. A strategy of simultaneous detection in a real-time single tube amplification was developed, based on the EvaGreen binding dye. The melting curve analysis (MCA) of the amplicons allows a qualitative detection of the four different virus targets in multiplex analysis. A plasmid dilution assay calculated an analytical sensitivity with an amplification threshold up to 100 copies of the target sequences. A small cohort of field grapevine samples, with a known status of infection by mixtures of the target viruses or free of them, respectively, was successfully tested for the evaluation of the amplicons Tm.

Genetic Variability of Grapevine Pinot gris virus and Its Association with Grapevine Leaf Mottling and Deformation.

The role of Grapevine Pinot gris virus (GPGV) in the etiology of grapevine leaf mottling and deformation was investigated by biological and molecular assays. A survey on different cultivars from the Trentino Region in Italy showed a widespread distribution of GPGV, which was associated with symptomatic (79%) but also with symptomless (21%) vines. Symptomatic and GPGV-infected 'Pinot gris' vines induced symptoms on grafted vines of healthy Pinot gris or 'Traminer', whereas GPGV-infected but symptomless vines did not. High-throughput sequencing of small RNA (sRNA) populations of two infected Pinot gris accessions confirmed the existence of nearly overlapping viromes in vines with or without symptoms but phylogenetic analyses of the genomes of seven GPGV isolates from Italy and the Czech and Slovak Republics clearly differentiated those infecting symptomatic vines. The involvement of Grapevine rupestris vein feathering virus (GRVFV) in the disease, which was only infecting the symptomatic vine, was ruled out by reverse-transcription polymerase chain reaction studies. Maximum likelihood and Bayesian phylogenetic analysis of two GPGV genomic regions, encompassing part of the movement protein (MP) and coat protein gene sequences and the RNA-dependent RNA polymerase domain of the replicase gene, showed that isolates from symptomatic vines form a lineage distinct from that of symptomless vines. Moreover, the presence or lack of the MP stop codon identified in viral isolates from symptomatic or symptomless vines, respectively, is likely responsible for an MP six amino acids longer in symptomless isolates.

Identification of an RNA-silencing suppressor in the genome of Grapevine virus A.

Higher plants use post-transcriptional gene silencing (PTGS), an RNA-degradation system, as a defence mechanism against viral infections. To counteract this, plant viruses encode and express PTGS suppressor proteins. Four of the five proteins encoded by the Grapevine virus A (GVA) genome were screened using a green fluorescent protein (GFP)-based transient expression assay, and the expression product of ORF5 (protein p10) was identified as a suppressor of silencing. ORF5 p10 suppressed local and systemic silencing induced by a transiently expressed single-stranded sense RNA. This protein was active towards both a transgene and exogenous GFP mRNAs. Ectopic expression of GVA-ORF5 by a Potato virus X vector enhanced symptom severity. The findings that p10 markedly reduces the levels of small interfering RNAs (siRNAs) and that the recombinant protein is able to bind single-stranded and double-stranded forms of siRNAs and microRNAs, suggest the existence of a potential mechanism of suppression based on RNA sequestering.

Isolation of recombinant antibodies (scFvs) to grapevine virus B.

A panel of 15 recombinant single chain antibodies (scFv) specific to grapevine virus B (GVB) were recovered from a human combinatorial scFv antibody library using the phage display technique against purified virus particles. Two selected scFv-encoding genes were expressed in recombinant Escherichia coli cells as dimeric antibodies. Successful detection of GVB in tissues of herbaceous hosts and grapevine was obtained in a direct binding assay using dimeric scFvs. This reagent was also shown to substitute efficiently for a GVB polyclonal serum in standard DAS-ELISA test used routinely for diagnosis.

Cucumber mosaic virus as carrier of a hepatitis C virus-derived epitope.

Cucumber mosaic virus (CMV) is a three component isodiametric plant virus which is common worldwide and has an extremely wide host range. A pseudorecombinant was made, derived from the RNA3 component of the CMV-S strain, carrying the coat protein (CP) gene, and the RNA1,2 components of the CMV-D strain. This system developed mild mosaic and vein clearing in Xanthi tobacco three weeks after inoculation. The CP gene was then engineered in three different positions, to encode a Hepatitis C virus (HCV) epitope. The selected peptide was the so-called R9 mimotope, a synthetic surrogate derived from a consensus profile of many hypervariable region 1 (HVR1) sequences of the putative HCV envelope protein E2. Serum samples from 60 patients with chronic hepatitis C displayed a significant immunoreactivity to crude plant extracts infected with the chimeric CMV. These results suggest that further investigation should be made into a possible vaccine function for the CMV-HCV mimotope system.

Maculavirus, a new genus of plant viruses.

Maculavirus is a new genus of plant viruses typified by Grapevine fleck virus (GFkV). A possible second member is Grapevine redglobe virus (GRGV). Maculaviruses are phloem-limited non-mechanically transmissible viruses with isometric particles c. 30 nm in diameter that have a rounded contour and prominent surface structure. Vectors, if any, are unknown. GFkV preparations contain two centrifugal components, T made up of empty protein shells and B, which contains 35% RNA. The coat protein (CP) has a molecular mass of 24 kDa. The genome is a single-stranded RNA that has c. 50% cytosine residues. It is 7564 nt in size, excluding the poly(A) tail and contains four putative open reading frames (ORF) that encode a 215.4 kDa polypeptide with the conserved motifs of replication-associated proteins of positive-strand RNA viruses (ORF1), the CP (ORF2), and one (GRGV) or two (GFkV) proline-rich polyproteins of 31.4 kDa (ORF3) and 15.9 kDa (ORF4), respectively, with unknown function. Replication-associated proteins and CP are phylogenetically related to those of members of the genera Tymovirus and Marafivirus. GFkV-infected grapevine cells contain vesiculated mitochondria, the possible site of RNA replication. In the natural host, GFkV particles accumulate in great quantity, sometimes in crystalline arrays in phloem cells.

Epitope mapping of Grapevine virus A capsid protein.

Previously characterized monoclonal antibodies (MAbs) to Grapevine virus A (GVA) showed a differential reactivity against intact or partially destabilized virus particles [2]. In the present study, this differential reactivity was confirmed and several peptides reacting with a panel of four different antibodies were identified by the PEPSCAN method of epitope mapping. Oligopeptide sequences comprised between coat protein residues 61 (V) and 72 (T) were recognized by all the antibodies tested. One of these peptides (VGPKASK) was also reactive when expressed on recombinant phage particles as a fusion protein with protein pVIII. The specificity of this sequence for antibody binding was also demonstrated by competitive-ELISA using one of the GVA MAbs. The results of this study suggest that GVA particles carry a highly structured epitope centered on a common peptide region of the coat protein sequence.

Immunodetection and subcellular localization of the proteins encoded by ORF 3 of grapevine viruses A and B.

Polyclonal antisera were raised to Escherichia coli-expressed ORF3 products (putative movement proteins) of Grapevine virus A (GVA) and Grapevine virus B (GVB) (genus Vitivirus), and used for their immunodetection in infected plants. Western blot analysis of subfractionated cellular compartments showed that the distribution of both proteins was comparable to that of plant virus movement proteins, as they were transiently present in a crude membrane fraction and accumulated in a cell wall-enriched fraction. The GVA ORF3-encoded protein, but not the comparable GVB protein, was also present in large amount in a cytoplasmic soluble fraction. Intracellular immunogold labelling localized these proteins in the cell wall and plasmodesmata of infected cells and, especially for GVA, in association with cytoplasmic virus aggregates.

Infectious cDNA clones of two grapevine viruses.

Full-length cDNA copies of the genomes of Grapevine virus A (GVA) and Grapevine virus B (GVB) under the control of bacteriophage T7 promoter have been synthesized, which were refractory to cloning in Escherichia coli. However, both transcribed cDNAs were infectious when mechanically inoculated to Nicotiana plants. A full-length cDNA copy of GVB was engineered in pCass2, a plasmid containing a partially duplicated copy of the Ca35S promoter, but was rather unstable in Escherichia coli. No infection of Nicotiana plants was obtained following mechanical inoculation but detached Nicotiana leaves, inoculated by particle bombardment, supported the multiplication of a GVB isolate seemingly identical to the wild-type used for cloning. Nicotiana seedling inoculated with sap expressed from these leaves became infected showing typical GVB symptoms. Transient transcription of Ca35S driven cDNA clones was also detected by RT-PCR in leaves of the grapevine hybrid LN33 following inoculation by particle bombardment. The availability of infectious cDNA clones of GVA and GVB constitutes a tool for the study of genome expression and pathogenesis, and for the ultimate establishment of the aetiological role of these viruses.

Use of Degenerate Primers for Partial Sequencing and RT-PCR-Based Assays of Grapevine Leafroll-Associated Viruses 4 and 5.

ABSTRACT Double-stranded RNA (dsRNA) was purified from grapevines infected with grapevine leafroll-associated viruses 4 (GLRaV-4) and 5 (GLRaV-5), two putative closteroviruses. Reverse-transcriptase polymerase chain reaction (RT-PCR) was performed on this dsRNA using degenerate oligonucleotides designed to amplify an approximately 550- to 650-nucleotide fragment from the heat shock protein 70 homolog (HSP70) of the known closteroviruses. RT-PCR products of the appropriate molecular weight were gel-isolated and cloned into the plasmid vector pGEM-T. Clones of RT-PCR products generated by using these primers on dsRNA isolated from a plant infected with GLRaV-4 were sequenced. This sequence was used to develop an immunocapture RT-PCR (IC-RT-PCR) detection protocol capable of detecting GLRaV-4. Similar clones were made from dsRNA isolated from a plant infected with GLRaV-5. These clones were also sequenced. The two sequences were compared, and RT-PCR primers were developed that were able to amplify cDNA from both. These experiments demonstrate that degenerate primers that amplify closterovirus HSP70 sequences can be used to successfully generate sequences useful for IC-RT-PCR detection of these viruses. These data also suggest that it is feasible to use HSP70 sequences to design PCR primers capable of more general PCR detection of multiple GLRaV serotypes. Lastly, the presence of closterovirus-like HSP70 sequences in these putative closteroviruses implies that they are indeed members of this taxonomic group.

A spot-PCR technique for the detection of phloem-limited grapevine viruses.

Specific amplification of genomic fragments of grapevine trichovirus A (GVA), grapevine trichovirus B (GVB) and grapevine leafroll-associated closterovirus 3 (GLRaV3) was obtained by reverse transcription-PCR on total nucleic acid solubilized from small pieces of charged nylon membrane, on which a drop of crude infected grapevine sap was spotted (spot-PCR). A thermal treatment (95 degrees for 10 degrees) of spotted sap in a buffered solution improved the release of viral template. Consistent amplification was obtained with three viruses from fragments of the same respective blots up to 1 month after spotting, while a detection threshold limit comparable with standard PCR techniques was found for this method. Duplex PCR (i.e. amplification of different viruses from a mixed-infected grapevine source) was also found to be effective, since GVA and GLRaV3 were amplified by a mixture of specific primers in the same reaction. This rapid and easy sampling technique, using leaf petioles to express crude sap, may have a wide field application for screening grapevine viruses.

Grapevine virus A: nucleotide sequence, genome organization, and relationship in the Trichovirus genus.

The 5' terminal region of the genomic RNA of grapevine virus A (GVA), a tentative member of the Trichovirus genus, encompassing 5466 nucleotides, was sequenced. Evidence was obtained that the RNA is capped. Two putative open reading frames (ORF) were identified: ORF 1 that codes for a 194 kDa polypeptide with conserved motifs of replication-related proteins of positive-strand RNA viruses, and ORF 2 that encodes a 19 kDa polypeptide with no significant homology with protein sequences from databases. This polypeptide, however, showed 44% similarity with the product expressed by a comparable ORF present in grapevine virus B (GVB). GVA genome had the same size and structural organization as that of GVB. It also had the same size of the genome of apple chlorotic leaf spot virus (ACLSV), the type species of the Trichovirus genus, but differed substantially in the number (5 versus 3), size, and order of genes. Differences existed also in the degree of sequence homology between polymerases, which did not cluster together in phylogenetic trees. Definitive (ACLSV, PVT) and tentative (GVA, GVB) trichovirus species differ molecularly, biologically and epidemiologically to an extent that warrants the taxonomic revision of the genus.

The nucleotide sequence and genomic organization of grapevine virus B.

Grapevine virus B (GVB) is a tentative member of the genus Trichovirus. The 5'-terminal region of the RNA genome of GVB comprises 5437 nucleotides and has been sequenced by the dideoxynucleotide chain termination method. Evidence was obtained that the RNA is capped. Two putative open reading frames (ORFs) were identified. ORF 1 coded for a 194.7 kDa polypeptide with conserved motifs of replication-related proteins of positive-strand RNA viruses (i.e. methyltransferase, helicase and RNA-dependent RNA polymerase, in that order from the N to the C terminus). ORF 2 encoded a 20 kDa polypeptide that did not show any significant sequence homology with protein sequences from the databases. The biological function of this polypeptide was not determined. Although the 20 kDa product was expressed as a fusion protein with glutathione S-transferase in Escherichia coli and an antiserum produced, it could not be identified in GVB-infected plant tissue extracts. The GVB genome had the same size as that of apple chlorotic leaf spot virus (ACLSV), the type species of the genus Trichovirus, but differed substantially in the number (five compared to three), size and order of genes. Differences existed also in the extent of sequence homology between polymerases, which did not cluster together in tentative phylogenetic trees. The results of this study show that definitive and tentative trichovirus species differ molecularly to an extent that may warrant a taxonomic revision of the genus.

Nucleotide sequence of the 3' terminal region of the RNA of two filamentous grapevine viruses.

The 3' terminal region of grapevine virus A (GVA) and grapevine virus B (GVB), encompassing 1883 and 2136 nucleotides, respectively, was sequenced by the deoxynucleotide chain termination method. Three putative open reading frames (ORF) were identified in both genomic viral RNAs, denoted 1 to 3 in the 5' to 3' direction. ORF 1 encoded a polypeptide with estimated M(r) of 31 kDa (GVA) and 36.5 kDa (GVB), possessing the G/D motif of the "30 K superfamily" movement proteins, and showing good alignments with putative movement proteins of trichoviruses and capilloviruses. ORF 2 was identified as the coat protein (CP) cistron, coding for polypeptides with an estimated M(r) of 21.5 kDa (GVA) and 21.6 kDa (GVB). These CPs showed substantial sequence homology with one another and with CPs of tricho- and capilloviruses, but not of closteroviruses. ORF 3 potentially coded for two small polypeptides with estimated M(r) of 10 kDa (GVA) and 14 kDa (GVB). The ORF 3 product of GVB (14 K), but not that of GVA, shared some homology with the 3' terminal polypeptides of different plant viruses that exhibit the "zinc finger domain" of proteins with nucleic acid-binding properties. GVA and GVB have many properties in common with trichoviruses but possess an extra open reading frame (ORF 3). Whether this finding may have a bearing on the classification of these viruses is unclear. However, until the taxonomic significance of this difference in genome structure is established, it seems plausible to include GVA and GVB as tentative species in the Trichovirus genus.