Genetic Diversity of Flavescence Dorée Phytoplasmas at the Vineyard Scale

Rossi, Marika; Pegoraro, Mattia; Ripamonti, Matteo; Abbà, Simona; Beal, Dylan; Giraudo, Alessia; Veratti, F.; Malembic-Maher, Sylvie; Salar, Pascal; Bosco, Domenico; Marzachı̀, Cristina

doi:10.1128/aem.03123-18

Cited by 25 publications

(42 citation statements)

References 26 publications

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“…It was also the most prevalent genotype detected in D. europaea and C. vitalba collected in Serbia and Montenegro [43]. M51 was not detected in Italy during the present survey but was previously detected in Tuscany [23] and later on in Switzerland [44] and northwestern Italy [42]. On one hand, our data show evidence that M51 may have emerged from C. vitalba in Balkans and subsequently propagated westward to Italy where a secondary diversification into M12, M6 and M3 may have occurred possibly as a result of the presence of established S. titanus populations that migrated from France.…”

Section: Possible Multiple Emergences From Wild Environment In Europesupporting

confidence: 48%

“…In early 2000s, M50 represented 15% of the FD cases in France [24], and in this study M50 was detected in FD outbreaks of Tuscany. M50 was also sporadically detected in Croatia [40], Switzerland [41] and in C. vitalba of Eastern Italian region of Veneto [23] and in north-western Italy [42], but was absent in the current alder and grapevine samples from Serbia. As shown by MLSA, the M50s detected in France, Veneto and Croatia were genetically different [23,40], and we therefore cannot exclude multiple independent emergences of M50 from alders.…”

Section: Possible Multiple Emergences From Wild Environment In Europementioning

confidence: 99%

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When a Palearctic bacterium meets a Nearctic insect vector: Genetic and ecological insights into the emergence of the grapevine Flavescence dorée epidemics in Europe

et al. 2020

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Flavescence doré e (FD) is a European quarantine grapevine disease transmitted by the Deltocephalinae leafhopper Scaphoideus titanus. Whereas this vector had been introduced from North America, the possible European origin of FD phytoplasma needed to be challenged and correlated with ecological and genetic drivers of FD emergence. For that purpose, a survey of genetic diversity of these phytoplasmas in grapevines, S. titanus, black alders, alder leafhoppers and clematis were conducted in five European countries. Out of 132 map genotypes, only 11 were associated to FD outbreaks, three were detected in clematis, whereas 127 were detected in alder trees, alder leafhoppers or in grapevines out of FD outbreaks. Most of the alder trees were found infected, including 8% with FD genotypes M6, M38 and M50, also present in alders neighboring FD-free vineyards and vineyard-free areas. The Macropsinae Oncopsis alni could transmit genotypes unable to achieve transmission by S. titanus, while the Deltocephalinae Allygus spp. and Orientus ishidae transmitted M38 and M50 that proved to be compatible with S. titanus. Variability of vmpA and vmpB adhesin-like genes clearly discriminated 3 genetic clusters. Cluster Vmp-I grouped genotypes only transmitted by O. alni, while clusters Vmp-II and-III grouped genotypes transmitted by Deltocephalinae leafhoppers. Interestingly, adhesin repeated domains evolved independently in cluster Vmp-I, whereas in clusters Vmp-II and-III showed recent duplications. Latex beads coated with various ratio of VmpA of clusters II and I, showed that cluster

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Section: Possible Multiple Emergences From Wild Environment In Europesupporting

confidence: 48%

Section: Possible Multiple Emergences From Wild Environment In Europementioning

confidence: 99%

When a Palearctic bacterium meets a Nearctic insect vector: Genetic and ecological insights into the emergence of the grapevine Flavescence dorée epidemics in Europe

et al. 2020

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“…The isolate was obtained from infective S. titanus adults that were collected in 2015 from an experimental vineyard in Piedmont and allowed to feed on V. faba in the laboratory. This FD phytoplasma isolate was genetically identified as member of 16SrV‐D subgroup based on DNA sequence analysis (Rossi et al ). FD‐Dp was then routinely maintained under controlled conditions with sequential transmissions from broad beans to broad beans by the experimental vector E. variegatus , continuously reared under laboratory conditions on oat.…”

Section: Methodsmentioning

confidence: 99%

Evidence suggesting interactions between immunodominant membrane protein Imp of Flavescence dorée phytoplasma and protein extracts from distantly related insect species

et al. 2019

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Aims In this study, binding between the immunodominant membrane protein Imp of the 16SrV‐D phytoplasma associated with Flavescence dorée disease (FD‐Dp) and insect proteins of vectors and non‐vectors of FD‐Dp was tested. Methods and Results Six Auchenorrhyncha species, from distantly related groups were selected: Scaphoideus titanus, Euscelidius variegatus, Macrosteles quadripunctulatus, Zyginidia pullula (Cicadomorpha), Ricania speculum and Metcalfa pruinosa (Fulgoromorpha). The vector status of each species was retrieved from the literature or determined by transmission trials in this study. A His‐tagged partial Imp protein and a rabbit polyclonal antibody were synthesized and used for Western and Far‐Western dot Blot (FWdB) experiments. Total native and membrane proteins (MP) were extracted from entire bodies and organs (gut and salivary glands) of each insect species. FWdB showed decreasing interaction intensities of Imp fusion protein with total proteins from entire bodies of S. titanus, E. variegatus (competent vectors) and M. quadripunctulatus (non‐vector), while no interaction signal was detected with the other three species (non‐vectors). A strong signal detected upon interaction of FD‐D Imp and MP from guts of closely related insects supports the role of this organ as the first barrier to ensure successful transmission. Conclusions Our results showed that specific Imp binding, correlated with vector status, is involved in interactions between FD‐Dp and insect proteins. Significance and Impact of the Study Integrating knowledge on host–pathogen protein–protein interactions and on insect phylogeny would help to identify the actual range of vectors of phytoplasma strains of economic importance.

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“…The isolate was obtained from infective S. titanus adults that were collected in 2015 from an experimental vineyard located at the CREA research institute (Asti, Piedmont) and allowed to feed on V. faba in the laboratory. This FDp isolate was genetically identified as D strain on dnaK gene (MH547710.1) and mixed profile on malG gene (malG_1 MH547713, malG_3 MH547715, malG_6 MH547718, malG_16 MH547728, malG_34 MH547746), according to (Rossi et al 2019). FDp was then routinely maintained under controlled conditions by sequential transmissions from V. faba to V. faba by the experimental vector E. variegatus, continuously reared under laboratory conditions on Avena sativa (oats) as described in Rashidi et al (2014).…”

Section: Phytoplasma Isolate Insects and Host Plantsmentioning

confidence: 99%

“…DNAKf/DNAKr primers, flanking FDp dnaK gene portion (MH547710.1), were used to detect FDp presence in R. speculum samples, by conventional PCR under standard reaction conditions with an annealing temperature of 55°C (Rossi et al 2019). The corresponding dnaK PCR products obtained from positive samples were purified with DNA Clean & Concentrator kit (Zymo Research) and Sanger sequenced by BMR Genomics (Padova, Italia), to confirm the identity of FDp strain.…”

Section: Phytoplasma Detection Characterization and Relative Quantifmentioning

confidence: 99%

Potential role of the alien planthopper Ricania speculum as vector of Flavescence dorée phytoplasma

et al. 2019

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Ricania speculum is an Asian planthopper that was accidentally imported into Europe from the Far East. The planthopper was first observed in Italy in 2009 (Genoa province, Liguria) and is now considered established. The current range of R. speculum in Italy includes Liguria, Tuscany, Veneto, Piedmont and Latium. Ricania speculum is polyphagous and has been observed on wild and cultivated plants that are herbaceous or woody. This phloem feeder frequently feeds on Vitis spp. (cultivated and wild grapevines) and Clematis vitalba plants that are hosts of Flavescence dorée phytoplasma (FDp), a quarantine phloem-limited bacterial pathogen and a major threat to viticulture of several European regions. The aim of this work was to assess if R. speculum could act as a vector of FDp, thereby affecting disease epidemiology. To explore the role of R. speculum in FDp transmission, nymphs were allowed to feed on FDp-infected Vicia faba plants to estimate acquisition efficiency and successively transferred onto Vitis vinifera, V. faba and C. vitalba test plants to determine transmission ability. Ricania speculum was unable to transmit FDp; some individuals acquired the phytoplasma but supported a very low level of pathogen multiplication, compared with the competent vector. Consistent with transmission results, FDp was detected only in one out of 51 tested salivary gland samples. According to our results, the role of R. speculum in FD epidemiology is expected to be negligible.

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Genetic Diversity of Flavescence Dorée Phytoplasmas at the Vineyard Scale

Cited by 25 publications

References 26 publications

When a Palearctic bacterium meets a Nearctic insect vector: Genetic and ecological insights into the emergence of the grapevine Flavescence dorée epidemics in Europe

When a Palearctic bacterium meets a Nearctic insect vector: Genetic and ecological insights into the emergence of the grapevine Flavescence dorée epidemics in Europe

Evidence suggesting interactions between immunodominant membrane protein Imp of Flavescence dorée phytoplasma and protein extracts from distantly related insect species

Potential role of the alien planthopper Ricania speculum as vector of Flavescence dorée phytoplasma

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