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.     

Cloning, expression analysis, and sequence diversity of genes encoding two different immunodominant membrane proteins in poinsettia branch-inducing phytoplasma (PoiBI)

Poinsettia branch-inducing phytoplasma (PoiBI) is a phytopathogenic bacterium that infects poinsettia, and is associated with the free-branching morphotype (characterized by many axillary shoots and flowers) of many commercially grown poinsettias. The major membrane proteins of phytoplasmas are classified into three general types, that is, immunodominant membrane protein (Imp), immunodominant membrane protein A (IdpA), and antigenic membrane protein (Amp). These membrane proteins are often used as targets for the production of antibodies used in phytoplasma detection. Herein, we cloned and sequenced the imp and idpA genes of PoiBI strains from 26 commercial poinsettia cultivars. Although the amino acid sequences of the encoded IdpA proteins were invariant, those of the encoded Imp varied among the PoiBI isolates, with no synonymous nucleotide substitution. Western blotting and immunohistochemical analyses revealed that the amount of Imp expressed exceeded that of IdpA, in contrast to the case of a related phytoplasma-disease, western X-disease, for which the major membrane protein appears to be IdpA, not Imp. These results suggest that even phylogenetically close phytoplasmas express different types of major membrane proteins.     

Characterization of putative membrane protein genes of the 'Candidatus Phytoplasma asteris', chrysanthemum yellows isolate

To characterize potentially important surface-exposed proteins of the phytoplasma causing chrysanthemum yellows (CY), new primers were designed based on the conserved regions of 3 membrane protein genes of the completely sequenced onion yellows and aster yellows witches' broom phytoplasmas and were used to amplify CY DNA. The CY genes secY, amp, and artI, encoding the protein translocase subunit SecY, the antigenic membrane protein Amp and the arginine transporter ArtI, respectively, were cloned and completely sequenced. Alignment of CY-specific secY sequences with the corresponding genes of other phytoplasmas confirmed the 16S rDNA-based classification, while amp sequences were highly variable within the 'Candidatus Phytoplasma asteris'. Five CY partial sequences were cloned into the pRSetC expression vector, and 3 of the encoded protein fragments (Amp 64/651, Amp 64/224, ArtI 131/512) were expressed as fusion antigens for the production of CY-specific polyclonal antibodies (A416 against Amp 64/224; A407 against ArtI 131/512). A416 recognized, in Western blots, the full-length Amp from CY-infected plants (periwinkle, daisy) and insect vectors (Euscelidius variegatus, Macrosteles quadripunctulatus). A416 also reacted to European aster yellows, to primula yellows phytoplasmas, to northern Italian strains of 'Ca. Phytoplasma asteris' from lettuce and gladiolus, but it did not react to American aster yellows phytoplasma.     

Identification of a Conserved Core Genome with Group‐Specific Genes from Comparative Genomics of Ten Different Candidatus Phytoplasma Strains

Plant pathogenic phytoplasmas can infect hundreds of plant species and lead to enormous economic loss. To understand the interactions between phytoplasmas and their hosts, genome sequencing plays an important role. To date, ten phytoplasma genomes from five phylogenetic groups have been released. A comparative genomics analysis showed 170 common conserved genes existing in these ten genomes. Genes involved in translation, ribosomal structure and biogenesis (75 genes) are the largest proportion. Interestingly, the predicted secreted proteins were not found in our core set, suggesting that these genes were diverse. In addition, a highly stringent strategy was taken to mine the group‐specific genes among the five groups. Although the largest part was the hypothetical proteins, some putative secreted proteins (potential effectors) were identified. TENGU was selected to be one of the 16SrI group‐specific genes. This may partly account for the diverse pathogenicity in different 16Sr groups. In addition, our results revealed that Amp and Imp had great potentials of being group specific. Above all, based on the conserved genes, our results provide new insights for the phytoplasma genome assembly, identification and functional genomics.     

Molecular biology and pathogenicity of phytoplasmas

Phytoplasmas are a large group of plant‐pathogenic wall‐less, non‐helical, bacteria associated with diseases, collectively referred to as yellows diseases, in more than a thousand plant species worldwide. Many of these diseases are of great economic importance. Phytoplasmas are difficult to study, in particular because all attempts at culturing these plant pathogens under axenic conditions have failed. With the introduction of molecular methods into phytoplasmology about two decades ago, the genetic diversity of phytoplasmas could be elucidated and a system for their taxonomic classification based on phylogenetic traits established. In addition, a wealth of information was generated on phytoplasma ecology and genomics, phytoplasma–plant host interactions and phytoplasma–insect vector relationships. Taxonomically, phytoplasmas are placed in the class Mollicutes, closely related to acholeplasmas, and are currently classified within the provisional genus ‘Candidatus Phytoplasma’ based primarily on 16S rDNA sequence analysis. Phytoplasmas are characterised by a small genome. The sizes vary considerably, ranging from 530 to 1350 kilobases (kb), with overlapping values between the various taxonomic groups and subgroups, resembling in this respect the culturable mollicutes. The smallest chromosome, about 530 kb, is known to occur in the Bermuda grass white leaf agent ‘Ca. Phytoplasma cynodontis’. This value represents the smallest mollicute chromosome reported to date. In diseased plants, phytoplasmas reside almost exclusively in the phloem sieve tube elements and are transmitted from plant to plant by phloem‐feeding homopteran insects, mainly leafhoppers and planthoppers, and less frequently psyllids. Most of the phytoplasma host plants are angiosperms in which a wide range of specific and non‐specific symptoms are induced. Phytoplasmas have a unique and complex life cycle that involves colonisation of different environments, the plant phloem and various organs of the insect vectors. Furthermore, many phytoplasmas have an extremely wide plant host range. The dynamic architecture of phytoplasma genomes, due to the occurrence of repetitive elements of various types, may account for variation in their genome size and adaptation of phytoplasmas to the diverse environments of their plant and insect hosts. The availability of five complete phytoplasma genome sequences has made it possible to identify a considerable number of genes that are likely to play major roles in phytoplasma–host interactions. Among these, there are genes encoding surface membrane proteins and effector proteins. Also, it has been shown that phytoplasmas dramatically alter their gene expression upon switching between plant and insect hosts.     

Dramatic transcriptional changes in an intracellular parasite enable host switching between plant and insect

Phytoplasmas are bacterial plant pathogens that have devastating effects on the yields of crops and plants worldwide. They are intracellular parasites of both plants and insects, and are spread among plants by insects. How phytoplasmas can adapt to two diverse environments is of considerable interest; however, the mechanisms enabling the "host switching" between plant and insect hosts are poorly understood. Here, we report that phytoplasmas dramatically alter their gene expression in response to "host switching" between plant and insect. We performed a detailed characterization of the dramatic change that occurs in the gene expression profile of Candidatus Phytoplasma asteris OY-M strain (approximately 33% of the genes change) upon host switching between plant and insect. The phytoplasma may use transporters, secreted proteins, and metabolic enzymes in a host-specific manner. As phytoplasmas reside within the host cell, the proteins secreted from phytoplasmas are thought to play crucial roles in the interplay between phytoplasmas and host cells. Our microarray analysis revealed that the expression of the gene encoding the secreted protein PAM486 was highly upregulated in the plant host, which is also observed by immunohistochemical analysis, suggesting that this protein functions mainly when the phytoplasma grows in the plant host. Additionally, phytoplasma growth in planta was partially suppressed by an inhibitor of the MscL osmotic channel that is highly expressed in the plant host, suggesting that the osmotic channel might play an important role in survival in the plant host. These results also suggest that the elucidation of "host switching" mechanism may contribute to the development of novel pest controls.     

Screening potential insect vectors in a museum biorepository reveals undiscovered diversity of plant pathogens in natural areas

Phytoplasmas (Mollicutes, Acholeplasmataceae), vector‐borne obligate bacterial plant parasites, infect nearly 1,000 plant species and unknown numbers of insects, mainly leafhoppers (Hemiptera, Deltocephalinae), which play a key role in transmission and epidemiology. Although the plant–phytoplasma–insect association has been evolving for >300 million years, nearly all known phytoplasmas have been discovered as a result of the damage inflicted by phytoplasma diseases on crops. Few efforts have been made to study phytoplasmas occurring in noneconomically important plants in natural habitats. In this study, a subsample of leafhopper specimens preserved in a large museum biorepository was analyzed to unveil potential new associations. PCR screening for phytoplasmas performed on 227 phloem‐feeding leafhoppers collected worldwide from natural habitats revealed the presence of 6 different previously unknown phytoplasma strains. This indicates that museum collections of herbivorous insects represent a rich and largely untapped resource for discovery of new plant pathogens, that natural areas worldwide harbor a diverse but largely undiscovered diversity of phytoplasmas and potential insect vectors, and that independent epidemiological cycles occur in such habitats, posing a potential threat of disease spillover into agricultural systems. Larger‐scale future investigations will contribute to a better understanding of phytoplasma genetic diversity, insect host range, and insect‐borne phytoplasma transmission and provide an early warning for the emergence of new phytoplasma diseases across global agroecosystems.     

Detection and seed transmission of Bermudagrass phytoplasma in maize in Turkey

During 2017, maize cultivation areas in the provinces of Adana and Kahramanmara? (Turkey) were surveyed to inspect maize plants with symptoms similar to those associated with of phytoplasma disease, that is, yellowing, short internodes and small corncobs. Thirty fields were inspected and two hundred samples from symptomatic and asymptomatic plants were collected, together with insects considered as potential vectors of phytoplasmas. All samples were assayed by polymerase chain reaction (PCR) and subsequently analysed by restriction fragment length polymorphism and sequencing to identify the phytoplasmas detected in the plant material and insects. Results of laboratory assays and phylogenetic analyses showed that the Bermudagrass white leaf phytoplasma ('Candidatus Phytoplasma cynodontis') was present in both maize plants and seeds, showing 99% sequence identity with other reported phytoplasma strains from GenBank, whereas no PCR amplifications were obtained from tested insects. The seeds of infected plants, sown in an insect‐proof screenhouse, produced plantlets that were found PCR‐positive for the Bermudagrass white leaf phytoplasma, indicating its seed transmission.     

A plasmid from a non-insect-transmissible line of a phytoplasma lacks two open reading frames that exist in the plasmid from the wild-type line

Two novel rolling circle replication (RCR) plasmids, pOYM (3932 nt) and pOYNIM (3062 nt), were isolated from a mildly pathogenic variant line (OY-M) and a mildly pathogenic plus non-insect-transmissible line (OY-NIM), respectively, of onion yellows (OY) phytoplasma, a plant and insect endocellular mollicute. OY-M was isolated from an original wild-type line (OY-W) after regular maintenance using alternate plant/insect infections, while OY-NIM was further isolated from OY-M after maintenance by plant grafting without insect vectors. The RCR-initiator proteins (Rep) of both plasmids, which have a characteristic structure with both plasmid- and virus-like domains, were highly homologous to that of a previously described OY-W plasmid, pOYW (3933 nt), and were expressed in OY-M- and OY-NIM-infected plants, indicating that this replicon is stably maintained in the phytoplasma. Interestingly, pOYNIM lacked two ORFs that exist in both pOYW and pOYM, which encode a single-stranded DNA binding protein (SSB) and an uncharacterized putative membrane protein, indicating that these two proteins are not necessary for the phytoplasma to live in plant cells. These are the first candidates as phytoplasma proteins possibly related to host specificity.     

植原体遗传多样性研究现状与展望

植原体是引起众多植物病害的一类重要的无细胞壁的原核致病菌, 其寄主种类多、危害面积广, 对经济、环境等影响严重。大量研究表明植原体存在丰富的遗传多样性。本文就植原体遗传多样性研究现状作一概要评述, 并对植原体遗传变异的研究技术、产生机制、与致病性关系等今后可能的研究方向作一展望。对已完成的5个植原体全基因组序列分析发现, 它们在大小、结构和功能等方面皆存在显著差异, 缺少很多标准代谢所需的基因。不同植原体中质粒的数量、大小和功能等也存在一定差异。植原体含有2个核糖体RNA编码基因, 其序列在不同株系中的变异奠定了现今植原体分类鉴定的基础。对植原体蛋白编码基因如核糖体蛋白编码基因(rp)、蛋白延伸因子基因(tuf、fusA)、转运蛋白基因(secY、secA)、效应子及非编码区序列如启动子、假基因等的深入研究可进一步揭示植原体更丰富的遗传变异特征。由于植原体分离培养困难, 人们对其形态特征、生理代谢等了解甚少, 因而全基因组测序、多位点序列分析等现代分子生物学技术将会成为植原体遗传变异研究的主要手段。植原体遗传多样性研究进展有助于从分子水平上系统地阐明植原体遗传变异规律、系统进化特征及其与寄主(植物和昆虫)、生态环境间的互作和适应关系, 并产生新的认识。这对于提高植原体的分类鉴定、致病机制、流行预测及病害防治等研究水平具有重要的作用和意义。     

The Development of Monoclonal Antibodies to the secA Protein of Cape St. Paul Wilt Disease Phytoplasma and Their Evaluation as a Diagnostic Tool

Partial recombinant secA proteins were produced from six different phytoplasma isolates representing five 16Sr groups and the expressed, purified recombinant (partial secA) protein from Cape St. Paul wilt disease phytoplasma (CSPWD, 16SrXXII) was used to immunise mice. Monoclonal antibodies (mAbs) were selected by screening hybridoma supernatants for binding to the recombinant proteins. To characterise the binding to proteins from different phytoplasmas, the antibodies were screened by ELISA and western blotting, and epitope mapping was undertaken. Eight different mAbs with varying degrees of specificity against recombinant proteins from different phytoplasma groups were selected. Western blotting revealed that the mAbs bind to proteins in infected plant material, two of which were specific for phytoplasmas. ELISA testing of infected material, however, gave negative results suggesting that either secA was not expressed at sufficiently high levels, or conformational changes of the reagents adversely affected detection. This work has shown that the phytoplasma secA gene is not a suitable antibody target for routine detection, but has illustrated proof of principle for the methodology.     

Cloning and expression analysis of Phytoplasma protein translocation genes

Genes encoding SecA and SecY proteins, essential components of the Sec protein translocation system, were cloned from onion yellows phytoplasma, an unculturable plant pathogenic bacterium. The secA gene consists of 2,505 nucleotides encoding an 835 amino acid protein (95.7 kDa) and shows the highest similarity with SecA of Bacillus subtilis. Anti-SecA rabbit antibody was prepared from a purified partial SecA protein, with a histidine tag expressed in Escherichia coli. Western blot analysis confirmed that SecA protein (approximately 96 kDa) is produced in phytoplasma-infected plants. Immunohistochemical thin sections observed by optical microscopy showed that SecA is characteristically present in plant phloem tissues infected with phytoplasma. The secY gene consists of 1,239 nucleotides encoding a 413 amino acid protein (45.9 kDa) and shows the highest similarity with SecY of B. subtilis. These results suggest the presence of a functional Sec system in phytoplasmas. Because phytoplasmas are endocellular bacteria lacking cell walls, this system might secrete bacterial proteins directly into the host cytoplasm. This study is what we believe to be the first report of the sequence and expression analysis of phytoplasma genes encoding membrane proteins with a predicted function.     

Euscelis incisus (Cicadellidae,Deltocephalinae), a natural vector of 16SrIII‐B phytoplasma causing multiple inflorescence disease of Cirsium arvense

We investigated multiple inflorescence disease of Cirsium arvense (CMI) and its association with phytoplasmas of the 16SrIII‐B subgroup, potential natural vector(s) and reservoir plant(s). From five locations in northern Serbia, 27 plants of C. arvense, 1 C. vulgare and 3 Carduus acanthoides with symptoms of multiple inflorescences (MIs) were collected and tested for 16SrIII group phytoplasmas. All symptomatic plants were found to be infected. Tentative reservoir plants and insect vectors were collected at a Dobanovci site where the continuous presence of CMI disease was recorded. Among the 19 most abundant plant species submitted to phytoplasma testing, all symptomless, the presence of the 16SrIII group was detected only in two legumes: Lathyrus tuberosus (2/5) and L. aphaca (1/5). Among 19 insect species from six families of Auchenorrhyncha, the deltocephalid leafhopper Euscelis incisus was the only insect carrying a 16SrIII phytoplasma (10% of analysed individuals). Transmission trials were performed with naturally infected E. incisus adults of the summer generation and with a laboratory population reared on red clover. After an acquisition period of 48 h on C. arvense symptomatic for MIs and a latent period of 28 days, 83% of the E. incisus adults (300/360) were infected with CMI phytoplasma. In two transmission tests, the leafhoppers successfully transmitted the phytoplasma to exposed plants (C. arvense and periwinkle), proving its role as a natural vector. Test plants of C. arvense infected with the 16SrIII‐B phytoplasma expressed typical symptoms similar to those observed in the field, such as MIs or the absence of flowering, shortened internodes and plant desiccation. Typical symptoms in infected periwinkles were virescence and phyllody. The molecular characterisation of the CMI phytoplasma isolates from diseased and asymptomatic field‐collected plants, vectors, and test plants was performed by sequence analyses of the 16S rRNA, rpl22‐rps3 and rpl15‐secY genes. Phylogenetic analyses of other members of the 16SrIII group of phytoplasmas indicated closest relatedness with clover yellow edge phytoplasma (CYE) of the 16SrIII‐B subgroup.     

Universal and group-specific real-time PCR diagnosis of flavescence dorée (16Sr-V), bois noir (16Sr-XII) and apple proliferation (16Sr-X) phytoplasmas from field-collected plant hosts and insect vectors

Three real‐time PCR–based assays for the specific diagnosis of flavescence dorée (FD), bois noir (BN) and apple proliferation (AP) phytoplasmas and a universal one for the detection of phytoplasmas belonging to groups 16Sr‐V, 16Sr‐X and 16Sr‐XII have been developed. Ribosomal‐based primers CYS2Fw/Rv and TaqMan probe CYS2 were used for universal diagnosis in real‐time PCR. For group‐specific detection of FD phytoplasma, ribosomal‐based primers fAY/rEY, specific for 16Sr‐V phytoplasmas, were chosen. For diagnosis of BN and AP phytoplasmas, specific primers were designed on non‐ribosomal and nitroreductase DNA sequences, respectively. SYBR^® Green I detection coupled with melting curve analysis was used in each group‐specific protocol. Field‐collected grapevines infected with FD and BN phytoplasmas and apple trees infected with AP phytoplasma, together with Scaphoideus titanus, Hyalesthes obsoletus and Cacopsylla melanoneura adults, captured in the same vineyards and orchards, were used as templates in real‐time PCR assays. The diagnostic efficiency of each group‐specific protocol was compared with well‐established detection procedures, based on conventional nested PCR. Universal amplification was obtained in real‐time PCR from DNAs of European aster yellows (16Sr‐I), elm yellows (16Sr‐V), stolbur (16Sr‐XII) and AP phytoplasma reference isolates maintained in periwinkles. The same assay detected phytoplasma DNA in all test plants and test insect vectors infected with FD, BN and AP phytoplasmas. Our group‐specific assays detected FD, BN, and AP phytoplasmas with high efficiencies, similar to those obtained with nested PCR and did not amplify phytoplasma DNA of other taxonomic groups. Melting curve analysis was necessary for the correct identification of the specific amplicons generated in the presence of very low target concentrations. Our work shows that real‐time PCR methods can sensitively and rapidly detect phytoplasmas at the universal or group‐specific level. This should be useful in developing defence strategies and for quantitative studies of phytoplasma–plant–vector interactions.     

Phytoplasmas: bacteria that manipulate plants and insects

TAXONOMY: Superkingdom Prokaryota; Kingdom Monera; Domain Bacteria; Phylum Firmicutes (low-G+C, Gram-positive eubacteria); Class Mollicutes; Candidatus (Ca.) genus Phytoplasma. HOST RANGE: Ca. Phytoplasma comprises approximately 30 distinct clades based on 16S rRNA gene sequence analyses of approximately 200 phytoplasmas. Phytoplasmas are mostly dependent on insect transmission for their spread and survival. The phytoplasma life cycle involves replication in insects and plants. They infect the insect but are phloem-limited in plants. Members of Ca. Phytoplasma asteris (16SrI group phytoplasmas) are found in 80 monocot and dicot plant species in most parts of the world. Experimentally, they can be transmitted by approximately 30, frequently polyphagous insect species, to 200 diverse plant species. DISEASE SYMPTOMS: In plants, phytoplasmas induce symptoms that suggest interference with plant development. Typical symptoms include: witches' broom (clustering of branches) of developing tissues; phyllody (retrograde metamorphosis of the floral organs to the condition of leaves); virescence (green coloration of non-green flower parts); bolting (growth of elongated stalks); formation of bunchy fibrous secondary roots; reddening of leaves and stems; generalized yellowing, decline and stunting of plants; and phloem necrosis. Phytoplasmas can be pathogenic to some insect hosts, but generally do not negatively affect the fitness of their major insect vector(s). In fact, phytoplasmas can increase fecundity and survival of insect vectors, and may influence flight behaviour and plant host preference of their insect hosts. DISEASE CONTROL: The most common practices are the spraying of various insecticides to control insect vectors, and removal of symptomatic plants. Phytoplasma-resistant cultivars are not available for the vast majority of affected crops.     

Biological and molecular evidence for the transmission of aster yellows phytoplasma to French marigold (Tagetes patula) by the flatid planthopper Metcalfa pruinosa

Aster yellows (AY) phytoplasmas (Candidatus Phytoplasma asteris) are associated with a number of plant diseases throughout the world. Several insect vectors are responsible for spreading AY diseases resulting in wide distribution and low host specificity. Because the role of sucking insects as vectors of phytoplasmas is widely documented, and the citrus flatid planthopper Metcalfa pruinosa is a phloem feeder, it has been incriminated as a possible vector of phytoplasmas. However, its ability to transfer phytoplasma has not been confirmed. The present work shows that M. pruinosa (Hemiptera: Flatidae), a polyphagous planthopper, is able to vector Ca. P. asteris to French marigold (Tagetes patula). Transmission experiments were conducted in 2017 and 2018 in central Hungary by two approaches: (a) AY-infected M. pruinosa were collected from an area with severe incidence of the disease on T. patula and caged on test plants for an inoculation-access period of 2 weeks, and (b) presumably phytoplasma-free insects were collected from apparently healthy grapevines (Vitis vinifera L.) and fed on AY-infected T. patula plants for 2 weeks prior to being caged on test plants. AY disease symptoms developed on 4 out of 10 and 10 out of 15 test plants, respectively. All phytoplasma-positive marigold and M. pruinosa samples showed identical RFLP patterns and shared 100% 16S rDNA sequence identity with each other and with the aster yellows phytoplasma strain AJ33 (GenBank accession number MK992774). These results indicated that the phytoplasma belonged to the phytoplasma subgroup 16SrI-B Ca. P. asteris. Therefore, the work presented here provides experimental evidence that M. pruinosa is a vector of a 16SrI-B subgroup phytoplasma to T. patula.     

Development of molecular markers and a diagnostic tool for investigation of coinfections by and interactions between potato purple top and potato witches'‐broom phytoplasmas in tomato

Columbia Basin potato purple top (PPT) phytoplasma and Alaska potato witches'‐broom (PWB) phytoplasma are two closely related but mutually distinct pathogenic bacteria that infect potato and other vegetable crops. Inhabiting phloem sieve elements and being transmitted by phloem‐feeding insect vectors, both pathogens are affiliated with ‘Candidatus Phytoplasma trifolii’ and are members of the clover proliferation phytoplasma group (16SrVI). The polyphagous nature and wide geographic distribution of their insect vectors make mixed infection inevitable. In this study, we experimentally constituted a simultaneous PPT and PWB phytoplasma infection in tomato (Solanum lycopersicum) and developed a sensitive diagnostic tool to investigate mixed infections by and in planta interactions of the two phytoplasmas. The distribution and relative abundance of the two co‐infecting phytoplasmas were monitored over a 45‐day post‐infection time course and for three serial passages in planta. Our results revealed that dual infections of the two phytoplasmas induce a new symptom unseen in infection by either phytoplasma alone. Our results also raised an interesting question as to whether the two phytoplasmas differ in ability of competitive dominance under co‐infection conditions. The molecular markers and the diagnostic tool devised in this study should be useful for further investigations of the interactions between the two closely related phytoplasmas in their hosts.     

Differential acquisition of chrysanthemum yellows phytoplasma by three leafhopper species

Chrysanthemum yellows (CY) phytoplasma has been transmitted with three leafhopper species: Euscelidius variegatus (Kirschbaum), Macrosteles quadripunctulatus (Kirschbaum) and Euscelis incisus (Kirschbaum): the first two species are reported as CY phytoplasma vectors for the first time. Leafhoppers were allowed to acquire the pathogen from the following source plants: Apium graveolens L., Catharanthus roseus L., Chrysanthemum carinatum Schousboe L. and C. frutescens L. DNA extracted from healthy or inoculative leafhoppers-exposed plants were analyzed by dot-blot and Southern hybridizations with a molecular probe constructed onto a fragment of European aster yellows phytoplasma DNA. The three leafhopper species were able to transmit CY phytoplasma after acquisition on chrysanthemum, but only M. quadripunctulatus and E. variegatus transmitted after feeding on periwinkle, and none acquired it from celery. All plant species tested were susceptible to CY, but while chrysanthemum and periwinkle were suitable for both inoculation and acquisition, celery did not seem to be a good source of phytoplasma for further inoculations. It is concluded that host plants influence leafhoppers' vectoring ability, possibly due to the different feeding behaviour of the insects on diverse plant species. Since CY, like several other phytoplasmas, can be transmitted by different insect species, it is likely that a close transmission specificity probably does not exist between phytoplasmas and their leafhopper vectors.     

New 16Sr subgroups and distinct single nucleotide polymorphism lineages among grapevine Bois noir phytoplasma populations

Bois noir (BN) is an insect-transmitted grapevine yellows disease caused by phytoplasmas belonging to the stolbur subgroup 16SrXII-A. In Italy, increasing prevalence of stolbur phytoplasma strains in vineyards suggests progressive spread of the disease and potential for heavy impacts on the wine industry. In this study, we investigated the genetic diversity of stolbur phytoplasma strains in BN phytoplasma populations. Nucleotide sequences of 16S rRNA genes from stolbur phytoplasma strains affecting vineyards in the Lombardy region of Italy and stolbur phytoplasma 16S rDNA sequences retrieved from GenBank were subjected to virtual restriction fragment length polymorphism analysis. Calculation of virtual restriction similarity coefficients revealed the presence of new subgroups in group 16SrXII (stolbur phytoplasma group). Representative strains of confirmed new subgroups 16SrXII-F (XII-F) and XII-G and tentative new subgroups XII-A1 through XII-A19, XII-H, XII-I, and XII-J as well as known subgroup XII-A were from grapevines; strains representing three additional tentative new subgroups (XII-K, XII-L and XII-M) were from other plant hosts. Nucleotide sequence alignments identified no less than nine genetically distinct 16S rDNA single nucleotide polymorphism lineages from grapevine, indicating a high degree of genetic heterogeneity within BN phytoplasma populations. The findings open new opportunities for in-depth studies of the distribution of grapevine-associated 16SrXII phytoplasma strains in weeds, insect vector populations and grapevines from vineyards located in different geographic areas.