Assessment of Subtractive Hybridization to Select Species and Subspecies Specific DNA Fragments for the Identification of Xylophilus ampelinus by Polymerase Chain Reaction (PCR)

Eighteen Bsp143I digested DNA fragments specific to Xylophilus ampelinus were cloned from a library enriched for X. ampelinus obtained after a subtractive hybridization step. It was also possible to clone specific DNA sequences directly after DNA digestion with Bsp143I probably because X. ampelinus is a unique bacterium. Nucleotidic sequences of four cloned specific fragments were determined. They did not share any homology with other DNA sequences in the EMBL/GeneBank database. Four primer sets were designed and tested for specificity to X. ampelinus. One primer set (Xamp 1.27) was a good candidate for a species-specific reagent in a procedure of identification of X. ampelinus using PCR. One primer set detected only Greek strains isolated from Vitis vinifera cv. Sultana. Genetic diversity within the X. ampelinus species can be used in further epidemiological studies on the bacterial necrosis of grapevine.     

Development of a real-time PCR-based method for detection of Xylophilus ampelinus

A real-time PCR MGB-probe-based detection method specific to Xylophilus ampelinus , the cause of grapevine bacterial blight, was developed. Used in combination with the DNeasy plant mini kit, the sensitivity of X. ampelinus detection was approximately 100 cells from tissue extracts, surpassing the sensitivity of an existing nested PCR method at least tenfold. In field samples a high correlation was observed between real-time PCR cycle threshold (Ct) values obtained and X. ampelinus isolation on artificial media. Isolation was successful from samples with Ct values below 25. Lower concentrations of X. ampelinus , with Ct values up to 36, could also be reliably detected in real-time PCR. The newly developed method offers a reliable and sensitive test for X. ampelinus, suitable as a screening test, complementary to isolation on media or other methods, and could also be used for fast and specific identification of isolated colonies and for relative quantification of X. ampelinus bacteria.     

Development of isolate‐specific markers for Neofusicoccum parvum and N. luteum and their use to study rainwater splash dispersal in the vineyard

Unique bands were identified in single isolates of Neofusicoccum parvum and Neofusicoccum luteum using universally primed polymerase chain reaction (UP‐PCR) analysis of isolates obtained from grapevines and non‐grapevine hosts in New Zealand, Australia, South Africa and the USA. Primers were designed to amplify a 1550 bp portion of the 1573 bp marker band from N. parvum isolate B2141 and a 510 bp portion of the 524 bp marker band from N. luteum isolate G51a2. A PCR‐RFLP assay was developed to distinguish the N. parvum isolate B2141 from other N. parvum isolates, based on a polymorphism found in the marker band using the TaqI restriction endonuclease. For N. luteum isolate G51a2, the designed primers were specific at an annealing temperature of 63°C in the PCR. The sensitivity threshold of the N. parvum and N. luteum isolate‐specific markers was 50 pg and 5 pg, respectively, when used in standard PCR with purified genomic DNA. The sensitivity of the N. parvum isolate‐specific marker was increased to 0·5 pg by nested PCR. The specificity test of both isolate‐specific markers with six other Botryosphaeriaceae spp. showed that they were specific to their respective species and isolates. Both markers were able to detect the conidia of N. parvum and N. luteum marker isolates in rainwater samples collected at different distances from an inoculation point in the vineyard. The results showed that rain splash could disperse the conidia of both of these species up to 2 m from the inoculum point in a single rainfall event.     

Identification of grapevine marker genes for early,non‐destructive Eutypa lata infection diagnosis

Eutypa lata is the causal agent of eutypa dieback, a highly damaging trunk disease affecting all grape‐growing areas, with currently neither an efficient curative treatment nor an early non‐destructive diagnostic method. The present work was carried out to discover grapevine genes expressed in response to the presence of E. lata that could be useful to develop an early (before visible foliar symptoms) and non‐destructive (using grapevine leaves) diagnostic tool. Microarray analyses were carried out from (i) infected plants showing characteristic E. lata foliar and vascular symptoms and positive pathogen recovery from vascular lesions (S⁺R⁺), (ii) infected plants showing no symptoms (S^?R⁺), and (iii) symptomless plants with negative pathogen recovery (S^?R^?). Vineyard and greenhouse‐grown plants, naturally or artificially infected respectively, and uninoculated controls were characterized and leaf RNA was hybridized with 15k operon grapevine oligonucleotide microarrays. Among the grapevine genes differentially expressed between S^?R⁺ and S^?R^? plants in greenhouse and vineyard conditions, 10 were highlighted as robust candidate genes for diagnosis: seven were specifically involved in response to infection and three were associated with symptom absence. Five were confirmed to be effective diagnostic marker genes usable in a qRT‐PCR‐based test performed on RNA extracted from grapevine leaves cultivated in either greenhouse or vineyard conditions. Furthermore, their expression profiles in response to infection with E. lata or other major grapevine fungi (Erysiphe necator, Plasmopara viticola, Botrytis cinerea) could be distinguished. The usefulness of these genes to develop an early and non‐destructive method for diagnosis of E. lata infection is discussed with regard to the advantages and drawbacks of previous E. lata diagnostic studies.     

Development of a real‐time PCR method for the detection of the dagger nematodes Xiphinema index,X. diversicaudatum,X. vuittenezi and X. italiae,and for the quantification of X. index numbers

The ectoparasitic dagger nematodes Xiphinema index and Xiphinema diversicaudatum, often at low numbers in the soil, are vectors of grapevine nepoviruses, which cause huge agronomical problems for the vineyard industry. This study reports a method, based on real‐time PCR, for the specific detection of these species and of the closely related non‐vector species Xiphinema vuittenezi and Xiphinema italiae. Specific primers and TaqMan probes were designed from the ribosomal DNA internal transcribed spacer 1 (ITS1), enabling the specific detection of single individuals of each of the X. index, X. diversicaudatum, X. italiae and X. vuittenezi species whatever the nematode population. The specificity of detection and absence of false positive reaction were confirmed in samples of each species mixed with the three other Xiphinema species or mixed with nematodes representative from other genera (non‐plant‐parasitic Dorylaimida, Longidorus sp., Meloidogyne spp., Globodera spp. and Pratylenchus sp.). The method was shown to be valid for the relative quantification of X. index numbers through its use, from crude nematode extracts of soil samples, in a greenhouse assay of grapevine accessions ranging from highly susceptible to resistant. As an alternative to time‐consuming microscopic identification and counting, this real‐time PCR method will provide a fast, sensitive and reliable diagnostic and relative quantification technique for X. index nematodes extracted from fields or controlled conditions.     

Nested PCR‐RFLP is a high‐speed method to detect fungicide‐resistant Botrytis cinerea at an early growth stage of grapes

BACKGROUND: Grey mould caused by the fungus Botrytis cinerea Pers. ex Fr. is one of the major diseases in grapes. The use of fungicides is a simple strategy to protect grapes against B. cinerea disease. However, phenotypes exhibiting resistance to fungicides have been detected in B. cinerea populations. The variation of fungicide‐resistant B. cinerea isolates renders B. cinerea disease control difficult in grapevine fields. RESULTS: The authors have developed a nested polymerase chain reaction–restriction fragment length polymorphism (PCR‐RFLP) method to detect fungicide‐resistant B. cinerea isolates at an early growth stage of grapes in grapevine fields. The nested PCR‐RFLP method was carried out to detect benzimidazole‐, phenylcarbamate‐ and/or dicarboximide‐resistant B. cinerea isolates from grape berries and leaves at Eichorn–Lorenz growth stage 25 to 29. This method successfully detected fungicide‐resistant B. cinerea isolates at an early growth stage of grapes. In addition, only 8 h was required from tissue sampling to phenotyping of fungicide resistance of the isolates. CONCLUSION: It is proposed that the early diagnosis of fungicide‐resistant B. cinerea isolates would contribute to further improvement of integrated pest management against B. cinerea in grapevine fields, and that the nested PCR‐RFLP method is a high‐speed, sensitive and reliable tool for this purpose. Copyright © 2008 Society of Chemical Industry     

Biological,serological and molecular characterisation of <Emphasis Type="Italic">Raspberry bushy dwarf virus</Emphasis> from grapevine and its detection in the nematode <Emphasis Type="Italic">Longidorus juvenilis</Emphasis>

In 2003, Raspberry bushy dwarf virus was found for the first time in grapevine. Since this was the first report of a non-Rubus natural host, information about it is sparse. During this study the grapevine isolates were characterised biologically, serologically and genetically and compared with known information about Rubus isolates. Infected plant material was used for mechanical inoculation of test plants, and for serological characterisation with monoclonal antibodies. Most of RNA 2 was sequenced and compared with other sequences from the database. Grapevine isolates infected Chenopodium murale systemically, which is not known for raspberry isolates. They were differentiated from Slovenian raspberry isolates with three monoclonal antibodies using TAS-ELISA. Phylogenetic analyses clustered grapevine isolates separately from raspberry isolates. Additionally, the virus was detected using nested RT-PCR in Longidorus juvenilis nematodes collected in an infected vineyard. Grapevine isolates of RBDV are distinct from raspberry isolates.     

The genetic characterization of Xanthomonas arboricola pv. juglandis,the causal agent of walnut blight in Poland

Leaves and fruits of walnut trees exhibiting symptoms of bacterial blight were collected from six locations in Poland. Isolations on agar media resulted in 18 bacterial isolates with colony morphology resembling that of the Xanthomonas genus. PCR using X1 and X2 primers specific for Xanthomonas confirmed that all isolates belonged to this genus. In pathogenicity tests on unripe walnut fruits, all isolates caused typical black necrotic lesions covering almost the entire pericarp. Results of selected phenotypic tests indicated that characteristics of all isolates were the same as described for the type strain of Xanthomonas arboricola pv. juglandis. Genetic analyses (PCR MP, ERIC‐, BOX‐PCR and MLSA) showed similarities between the studied isolates and the reference strain of X. arboricola pv. juglandis CFBP 7179 originating from France. However, reference strains I‐391 from Portugal and LMG 746 from the UK were different. MLSA analysis of partial sequences of the fyuA, gyrB and rpoD genes of studied isolates and respective sequences from GenBank of pathotype strains of other pathovars of X. arboricola showed that the X. arboricola pv. juglandis isolates consisted of different phylogenetic lineages. An incongruence among MLSA gene phylogenies and traces of intergenic recombination events were proved. These data suggest that the sequence analysis of several housekeeping genes is necessary for proper identification of X. arboricola pathovars.     

Detection of Botryosphaeriaceae species within grapevine woody tissues by nested PCR, with particular emphasis on the Neofusicoccum parvum/N. ribis complex

Several species of Botryosphaeriaceae and Phaeomoniella chlamydospora are common agents of grapevine decline worldwide. Currently, the use of culture independent PCR based techniques for detection of Botryosphaeriaceae within grapevine tissues has been limited to Botryosphaeria dothidea. In the present study, two Botryosphaeriaceae specific nested PCR assays were developed. One with a narrow target range, to detect Neofusicoccum parvum and the closely related species complex (Neofusicoccum parvum/N. ribis sensu Pavlic et al. Molecular Phylogenetics and Evolution 51:259–268, 2009) and another, with a wider range, to detect all 17 species of Botryosphaeriaceae which have been reported as potential wood pathogens of grapevine. The effectiveness of these assays was validated in vivo on naturally infected wood samples collected from standing vines and dormant grafted rooted cuttings commercialized in Italy by different nurseries in different years. All samples were also screened by means of a previously published nested PCR assay specific for Phaeomoniella chlamydospora. It was found that: 1) propagation material may play an important role as source of primary inoculum, not only of Phaeomoniella chlamydospora, as previously reported, but also for members of the Botryosphaeriaceae, among which Neofusicoccum parvum, Botryosphaeria dothidea and Diplodia seriata are the most common, and 2) multiple infections by different species belonging to Botryosphaeriaceae and/or Phaeomoniella chlamydospora occur frequently both in standing vines and propagation material. This last finding supports the hypothesis that at least some of the non-specific symptoms of grapevine decline may be due to the presence of different pathogens within host tissues.     

Detection of Xylophilus ampelinus in grapevine cuttings using a nested polymerase chain reaction

A sensitive and specific assay was developed to detect bacterial blight of grapevine caused by Xylophilus ampelinus (Panagopoulos, 1969) comb. nov. in grapevine cuttings. The 16S−23S rDNA intergenic spacer region of X. ampelinus was sequenced and pathogen-specific primers were designed from a region in the spacer between the tRNA (Ala) and the 23S genes. A nested PCR (n-PCR) reaction was applied with a first-stage PCR using universal primers within the ends of the 16S and 23S genes, followed by a second-stage PCR with nested primers specific to the X. ampelinus spacer region. A 277-bp fragment was amplified from 38 Xylophilus strains tested, but not from saprophytes associated with grapevine or phylogenetically related phytobacteria. The 277-bp product was shown to be derived from the X. ampelinus spacer region by restriction with Dra I, Sau 3AI, Taq I and Msp I, Southern hybridization and genomic DNA dot blots. When the (n-PCR) procedure was applied in the absence of nontarget DNA, the limit of detection was less than 10 colony-forming units (CFU) per µ L. The same number of  X. ampelinus CFU could be detected in the presence of 1·5 × 10⁵ CFU  µ L⁻¹ of Erwinia herbicola cells using the n-PCR procedure.     

Molecular characterization of a new isolate of phytoplasma associated with malformation and twisting of floral spikes of <Emphasis Type="Italic">Gladiolus</Emphasis> in India

In 2007–2009, severe virescence, malformation and twisting of flower spikes and yellowing of entire plants were observed in various Gladiolus cultivars growing in the gardens of the National Botanical Research Institute, Lucknow, India. The disease symptoms were very similar to symptoms in Gladiolus caused by the Aster yellows phytoplasma identified from Poland. Disease incidence was low (1.1–3.4%), but the severity of symptoms was high. A phytoplasma infection was detected in nine of 13 cultivars by PCR followed by nested PCR using universal phytoplasma primers P1/P6 or R16F2n/R16R2, respectively. An amplicon of ~1.2 kb obtained from the nested PCR was cloned and sequenced. Sequence analysis of the PCR amplicon revealed high (94–98%) identities and the closest phylogenic relationships with several isolates of Aster yellows phytoplasma of ‘Candidatus Phytoplasma asteris’ (16SrI group). Thus, the phytoplasma isolate of Gladiolus was identified as a new isolate of ‘Ca. P. asteris’ (16SrI group). In silico analysis of the phytoplasma isolate clearly indicated that the isolate was distinct from other Indian isolates of this phytoplasma.     

Detection of a Phytoplasma Associated with Grapevine Flavescence dorée in Clematis vitalba

About 40 different species of wild herbaceous and woody plants were collected in underbrush close to a vineyard where Flavescence dorée (FD) has been reported for several years. Polymerase chain reaction assays were carried out using DNA extracted from leaves of each species for the detection of the presence of phytoplasmas. Only samples of Clematis vitalba were found to be infected with phytoplasmas. Restriction fragment length polymorphism and sequencing data of the 16S ribosomal RNA gene and of a non-ribosomal DNA fragment FD9 revealed that the phytoplasma isolate was identical to that causing FD in the nearby vineyard. The isolate identified in the clematis is the same as the FD-C phytoplasma found in grapevine in north-east Italy.     

Rapid method for detecting resistance to a QoI fungicide in Plasmopara viticola populations

BACKGROUND: The increasing occurrence of Qo inhibitor (QoI)‐fungicide‐resistant Plasmopara viticola (Berk. & MA Curtis) Berl. & DeToni populations is becoming a serious problem in the control of grapevine downy mildew worldwide. RESULTS: The authors have developed a rapid method for detecting resistance to a QoI fungicide, azoxystrobin, in P. viticola populations using the nested PCR‐RFLP method. With this method, a glycine‐to‐alanine substitution was discovered at codon 143 in the cytochrome b gene of P. viticola populations found in Japan. CONCLUSION: It is proposed that the nested PCR‐RFLP method is a high‐speed, sensitive and reliable tool for detecting azoxystrobin‐resistant P. viticola populations. Copyright © 2009 Society of Chemical Industry     

Recent research progress on Xanthomonas ampelina1

Bacterial blight of grapevine (caused by Xanthomonas ampelina) occurs in Greece, France, Spain, Italy, Turkey, Portugal, USSR and South Africa. It is a serious, chronic vascular disease which is widespread in some areas of grape production, affecting commercially important cultivars. There is evidence that the disease is presently spreading into new areas in some countries. The actual distribution of blight may be much wider, since its symptoms may be confused with those of other diseases. It is therefore essential to confirm the presence of X. ampelina by isolation and identification. X. ampelina is an anomalous member of the genus Xanthomonas which is readily distinguished on the basis of a few tests. The pathogen may also be rapidly detected in grapevine sap using the indirect immunofluorescence technique. The susceptibility of shoots to infections, under Cretan conditions, is highest from November to late January and very low during February and March. It has been found that up to 50% of apparently healthy canes obtained from diseased vineyards were latently infected. Transmission of the pathogen through soil and roots during the control of Daktulosphaira vitifolii or frost damage by flooding has been demonstrated in France. Several of the more widely grown cultivars were found to be very susceptible to the pathogen while no completely resistant cultivar has been detected. Control trials based on four sprays with a number of chemicals were unsuccessful. Control policy should be directed: (a) to preventing spread of the disease, by exclusive use of certified material; (b) to minimizing the disease in affected areas by suitable sanitary, cultural and preventive measures.     

Association between genetic variability and titre of Grapevine Pinot gris virus with disease symptoms

The present work was carried out in order to verify the possible association between a new grapevine disease, characterized by leaf mottling and deformation, and the genetic variability and concentration of Grapevine Pinot gris virus (GPGV), a recently identified virus tentatively associated with the pathology. After vineyard surveys and the establishment of real‐time qPCR assays, characterization of GPGV isolates and evaluation of GPGV titre were assessed in more than 100 samples of grapevine Glera, collected from plants regardless of whether or not they showed the symptomatology. Results showed that there was an important association between the GPGV variants and manifestation of the symptoms, and that grapevines with symptoms harboured significantly higher GPGV titre than symptomless vines. Moreover, an interesting relationship among the phylogenetic clustering of the isolates originating from plants with symptoms and some epidemiological characteristics of the disease was found. The current study confirmed the role of GPGV in the emergent disease characterized by grapevine leaf mottling and deformation.     

High genotypic and virulence diversity in Ilyonectria liriodendri isolates associated with black foot disease in New Zealand vineyards

A total of 57 Ilyonectria liriodendri isolates were identified by a combination of species‐specific PCR and DNA sequencing from a collection of 174 Ilyonectria‐like isolates recovered from 101 diseased grapevine samples. These samples were representative of the national vineyard, comprising material contributed by 49 grape growers across seven grape growing areas. This species was predominant, representing 33% of the recovered isolates, and has been reported as a major pathogen of grapevines in other countries. The genetic diversity of the 57 New Zealand isolates was compared to that of isolates from Australia and South Africa using universally primed polymerase chain reaction (UP‐PCR). A total of 66 informative loci distinguished 52 genotypes, of which five contained up to four clonal isolates. Four main clades were identified in a neighbour‐joining (NJ) tree. The international isolates (Australia and South Africa) were placed in a clade that did not include New Zealand isolates. There was a high level of intra‐ and inter‐vineyard genetic variation indicating the free movement of isolates between regions. A subset of nine isolates from different branches of the NJ tree produced two vegetative compatibility groups and hyphal fusion was observed between non‐self pairings. Pathogenicity tests using isolates from different genetic groups inoculated onto either detached roots or 1‐year‐old potted vines showed variability in virulence; however, no correlations were detected.     

A combined agar-absorption and BIO-PCR assay for rapid, sensitive detection of Xylella fastidiosa in grape and citrus

Application of the polymerase chain reaction (PCR) to disease diagnosis is limited in part by the presence of PCR inhibitors. Inhibition can be overcome and sensitivity increased by culturing bacteria on agar media prior to PCR (termed BIO-PCR). However, Xylella fastidiosa grows slowly, requiring 10–14 days for visible colonies to appear. In this study an agar-absorption BIO-PCR method for detecting X. fastidiosa in grape and citrus plants was developed. Optimum lengths of time for absorption of inhibitors by the agar medium or enrichment of bacteria on the medium were determined for Pierce's disease of grape and citrus variegated chlorosis. When petioles of grape and citrus leaves with symptoms were spotted onto agar media, the spots washed after various time intervals and assayed for X. fastidiosa by real-time PCR, 97% (31 out of 32) and 100% (six out of six) of spots were positive after 2 days and 4 h for grape and citrus, respectively. With direct PCR, only 12·5% (four out of 32) and 33% (two out of six) of spots were positive, respectively, and visible X. fastidiosa colonies were evident after 10 and 14 days, respectively. In a separate experiment with samples from a different vineyard, 46% (13 out of 28) of the grape samples (agar spots) were positive after 1 day and 93% (26 out of 28) after 5 days using agar-absorption PCR. In contrast, all samples were negative by direct PCR. Viable X. fastidiosa were recovered from all samples after 14 days. Further tests with eight randomly selected grape petioles from three Texas vineyards known to have Pierce's disease resulted in 50% being positive by a simple 24 h agar-absorption PCR assay, whereas none was positive by direct PCR. Overall, 10 out of 16 (63%) vines from five vineyards (two in California and three in Texas) were positive after the 24 h agar-absorption PCR assay. In contrast, only one vine was positive by direct PCR. This simple agar absorption-based PCR assay protocol should prove useful for the routine detection of X. fastidiosa and other slow-growing bacteria in the presence of PCR inhibitors.     

Eradication of black rot (Guignardia bidwellii) from grapevines by drastic pruning

A drastic pruning strategy was developed to eradicate the fungal disease black rot (Guignardia bidwellii), which is exotic in Australia, from grapevines, while minimizing the economic cost of returning an affected vineyard to its previous quality and production levels. The protocol involved cutting off vines at the top of the trunk, removing debris from the ground beneath and between vines, mulching the vineyard floor, removing low watershoots during vine regrowth and applying a targeted fungicide programme. The protocol was initially evaluated and consequently modified in Australia using an endemic grapevine disease, black spot or anthracnose (Elsinoe ampelina), as an analogous model system. Then, it was validated in a black‐rot‐infested vineyard in New York, USA. Following two seasons of disease‐conducive weather conditions, no black rot was detected on treated vines, whereas leaf and fruit infections developed on the untreated control vines. These results confirmed the efficacy of the protocol for eradicating black rot from vineyards while allowing vines to return quickly to previous yield and quality levels without replanting. The protocol may have applicability to disease eradication protocols for other perennial crops as well. Evidence is also presented on the efficacy and potential pitfalls of burning infected grapevine material to eradicate E. ampelina.     

High genetic and virulence diversity detected in Neofusicoccum luteum and N. australe populations in New Zealand vineyards

Genotypic and virulence diversity of Neofusicoccum luteum and N. australe isolates recovered from grapevines displaying symptoms of dieback and decline in New Zealand were investigated. The universally primed PCR (UP‐PCR) method was used to investigate the genetic diversity of 40 isolates of N. luteum and 33 isolates of N. australe. Five UP‐PCR primers produced a total of 51 loci from N. luteum and 57 from N. australe with a greater number of polymorphic loci produced in N. australe (86%) compared with N. luteum (69%). Analysis of UP‐PCR data showed both species found in New Zealand vineyards were genetically diverse at both the inter‐ and intra‐vineyard levels with only a single pair of clonal isolates in N. luteum. Cluster analysis of UP‐PCR data produced four genetic groups in N. luteum and 10 in N. australe (P < 0.05). For both species, there was no relationship between the genetic groups and the origin of isolates. The mean genetic diversity (H) of N. luteum was less than for N. australe, being 0.1791 and 0.2417, respectively. Pathogenicity assays of both species using isolates from either the same or different genetic groups inoculated onto either green shoots or grapevine trunks, showed virulence diversity within the population; however, no correlation was identified between genetic groups and virulence.     

Spatial and temporal stolbur population structure in a cv. Chardonnay vineyard according to vmp1 gene characterization

Bois noir is a grapevine disease caused by the stolbur phytoplasma. It is widespread in all European and Mediterranean viticultural areas, and it can induce severe damage to the quality and quantity of production. The recent disease recrudescence has encouraged studies on the use of molecular markers to assess the genetic diversity of stolbur strains. The aim of this study was to evaluate the presence of Bois noir symptoms and to monitor the spatial genetic structure of the stolbur population according to vmp1 genotypes, through 2011 and 2012 in a cv. Chardonnay vineyard. In both years, there were increased vines with symptoms from July to September. The analysis of dispersal indices showed that the spatial distribution was uniform in the vineyard. However, the two‐dimensional contour maps show that Bois noir severity was higher in plants located on the borders than in the central parts of the vineyard. Stolbur population was composed of two prevalent vmp genotypes (V14, V12) across both years, along with other minor haplotypes (V3, V4, V9, V11, V15, V18, in 2011; V3, V18 in 2012). The data indicate that the vmp1 gene is an efficient marker to study the population structure of stolbur phytoplasma, to track the movement of the pathogen, and to identify the inoculum source, which will all serve in the planning of control strategies.