Molecular Diagnosis of Phytoplasmas

Phytoplasmas are wall-less prokaryotes associated with diseases in numerous plant species worldwide. In nature they are transmitted by phloem-sucking insects. Yellowing, decline, witches’ broom, leaf curl, floral virescence and phyllody are the most conspicuous symptoms associated with phytoplasmas, although infections are sometimes asymptomatic. Since phytoplasmas cannot be cultured in vitro, molecular techniques are needed for their diagnosis and characterization. The titer of phytoplasma cells in the phloem of infected plants may vary according to the season and the plant species, and it is often very low in woody hosts. Different DNA extraction procedures have therefore been tried out to obtain phytoplasma DNA at a concentration and purity high enough for effective diagnosis. DNA/DNA hybridization methods were reported in the nineties to be appropriate for the detection of phytoplasmas, but at present PCR is considered the most suitable. Universal and group-specific primers have been designed on the rRNA operon of the phytoplasma genome and on plasmid sequences. RFLP analysis of the obtained amplicons has classified these pathogens into major 16Sr RNA groups. Group-specific primers have also been designed on other genomic sequences. PCR is a very sensitive technique, but due to the low titre of phytoplasmas a further increase in sensitivity may be required for accurate diagnosis. This is routinely obtained with a second round of PCR (nested PCR). The drawback of nested PCR is that there is a greater chance of obtaining false positives due to contamination. Many authors have therefore developed protocols based on hybridization (PCR/dot blot) or serological approaches (PCR/ELISA) to increase the sensitivity and specificity of the direct PCR, reducing the risks due to nested PCR. Real time PCR protocols may also improve the sensitivity and specificity of the direct PCR assay

Identification and ecology of alternative insect vectors of ‘Candidatus Phytoplasma solani’ to grapevine

Bois noir, a disease of the grapevine yellows complex, is associated with 'Candidatus Phytoplasma solani' and transmitted to grapevines in open fields by the cixiids Hyalesthes obsoletus and Reptalus panzeri. In vine-growing areas where the population density of these vectors is low within the vineyard, the occurrence of bois noir implies the existence of alternative vectors. The aim of this study was to identify alternative vectors through screening of the Auchenorrhyncha community, phytoplasma typing by stamp gene sequence analyses, and transmission trials. During field activities, conducted in Northern Italy in a vineyard where the bois noir incidence was extremely high, nine potential alternative insect vectors were identified according to high abundance in the vineyard agro-ecosystem, high infection rate, and harbouring phytoplasma strains characterized by stamp gene sequence variants found also in symptomatic grapevines. Transmission trials coupled with molecular analyses showed that at least eight species (Aphrodes makarovi, Dicranotropis hamata, Dictyophara europaea, Euscelis incisus, Euscelidius variegatus, Laodelphax striatella, Philaenus spumarius, and Psammotettix alienus/confinis) are alternative vectors of 'Candidatus Phytoplasma solani' to grapevines. These novel findings highlight that bois noir epidemiology in vineyard agro-ecosystems is more complex than previously known, opening up new perspectives in the disease management

The Major Antigenic Membrane Protein of “Candidatus Phytoplasma asteris” Selectively Interacts with ATP Synthase and Actin of Leafhopper Vectors

Phytoplasmas, uncultivable phloem-limited phytopathogenic wall-less bacteria, represent a major threat to agriculture worldwide. They are transmitted in a persistent, propagative manner by phloem-sucking Hemipteran insects. Phytoplasma membrane proteins are in direct contact with hosts and are presumably involved in determining vector specificity. Such a role has been proposed for phytoplasma transmembrane proteins encoded by circular extrachromosomal elements, at least one of which is a plasmid. Little is known about the interactions between major phytoplasma antigenic membrane protein (Amp) and insect vector proteins. The aims of our work were to identify vector proteins interacting with Amp and to investigate their role in transmission specificity. In controlled transmission experiments, four Hemipteran species were identified as vectors of “Candidatus Phytoplasma asteris”, the chrysanthemum yellows phytoplasmas (CYP) strain, and three others as non-vectors. Interactions between a labelled (recombinant) CYP Amp and insect proteins were analysed by far Western blots and affinity chromatography. Amp interacted specifically with a few proteins from vector species only. Among Amp-binding vector proteins, actin and both the α and β subunits of ATP synthase were identified by mass spectrometry and Western blots. Immunofluorescence confocal microscopy and Western blots of plasma membrane and mitochondrial fractions confirmed the localisation of ATP synthase, generally known as a mitochondrial protein, in plasma membranes of midgut and salivary gland cells in the vector Euscelidius variegatus. The vector-specific interaction between phytoplasma Amp and insect ATP synthase is demonstrated for the first time, and this work also supports the hypothesis that host actin is involved in the internalization and intracellular motility of phytoplasmas within their vectors. Phytoplasma Amp is hypothesized to play a crucial role in insect transmission specificity

Are grapevine plants recovered from Flavescence dorée susceptible to new infections of this phytoplasma?

Woody plants can eventually recover from phytoplasma infection; this phenomenon is of growing interest because it can be exploited for the management of phytoplasma diseases in fruit growing and viticulture. Moreover, in apricot trees, plants recovered from ESFY phytoplasmas, have shown a remarkable resistance to re-infections of this pathogen. Grapevine can be affected by several phytoplasma diseases and, among them, Flavescence dorée is probably the most epidemic and dangerous in Europe, where it affects many viticultural areas in several countries. The aim of this work was to ascertain if grapevine plants obtained from propagative material derived from FD-recovered plants show resistance/tolerance to new FD infections. To this purpose, potted grapevines of the cv Barbera and Glera (from FD-recovered or from healthy plants never infected) were exposed to FD-infected Scaphoideus titanus leafhoppers and then transplanted in the field. Their infection status was confirmed the following year by molecular detection and symptom observation. No difference in susceptibility to FD inoculation was recorded between grapevine cuttings derived from recovered and healthy plants of the same variety. More than 90% of Barbera plants exposed to vector inoculation, compared to 30% of Glera ones, became infected, showing a very high susceptibility of Barbera cv to FD. The relevance of these findings for FD management is discusse