Stylet penetration activities linked to the acquisition and inoculation of Candidatus Liberibacter solanacearum by its vector tomato potato psyllid

The tomato potato psyllid (TPP), Bactericera cockerelli (Sulc) (Hemiptera: Triozidae), is the main vector of the bacterium Candidatus Liberibacter solanacearum (Lso), a major disease of solanaceous crops. Feeding of TPP is associated with Lso transmission. However, very little is known about the stylet penetration activities linked to acquisition and inoculation of Lso. The electrical penetration graph (EPG)‐DC system was used to monitor stylet penetration activities during acquisition and inoculation of Lso by individual TPP on tomato [Solanum lycopersicum L. (Solanaceae)]. Female TPP from Lso‐free and Lso‐infected colonies were used in acquisition and inoculation tests, respectively. In the acquisition tests, TPP were tested for Lso after EPG recording of their stylet penetration activities on Lso‐infected tomato shoots. In the inoculation tests, samples from the tomato plants on which the stylet penetration of Lso‐infected TPP had been recorded were tested for Lso infection. The relationships between qPCR results and the EPG waveforms (C, G, D, E1, and E2) representing the main stylet penetration activities performed by individual insects in inoculation and acquisition tests were investigated. Results confirmed that a single adult TPP is capable of infecting a plant with Lso. Our data suggest that acquisition of the bacteria occurs during phloem ingestion (E2), and inoculation is likely associated with salivation into the phloem sieve elements (E1). The durations of EPG parameters were not significantly different between Lso‐infected and Lso‐free TPP (later shown by qPCR) in acquisition tests. In inoculation tests, the durations of E1 or E2 recorded from TPP on Lso‐infected and Lso‐free plants that were later shown by qPCR were not significantly different. However, C was shorter on Lso‐infected plants than on Lso‐free plants, where TPP performed phloem activities. The minimum plant access period required for Lso transmission by a single TPP was estimated to be ca. 2 h, with an acquisition threshold of about 36 min.     

Feeding behavior of Diaphorina citri and its transmission of ‘Candidatus Liberibacter asiaticus’ to citrus

Huanglongbing (HLB), also known as citrus greening, is currently the most destructive disease of citrus, responsible for huge economic losses in the world's major citrus production areas. The Asian citrus psyllid, Diaphorina citri Kuwayama (Hemiptera: Liviidae), transmits ‘Candidatus Liberibacter asiaticus’ (Clas), the pathogen responsible to cause HLB. Understanding of vector, pathogen, and host plant interactions is important for the management of this vector‐disease complex. We used the direct‐current electrical penetration graph (DC‐EPG) system to evaluate feeding behavior of Clas‐infected D. citri adults, and their potential to transmit the pathogen to healthy citrus, Citrus reticulata Blanco cv. Sunki (Rutaceae), following a 24‐h inoculation access period. Plants were tested for the presence of Clas by qPCR 6 months after inoculation. Findings suggest that inoculation was associated with salivation into the phloem sieve elements (waveform E1). The minimum feeding time for successful transmission by a single adult was 88.8 min, with a minimum E1 duration of 5.1 min. Regression analysis indicated a significant relationship between E1 duration and transmission efficiency. The adults successful in transmitting Clas to healthy citrus were able to penetrate and feed in the phloem much earlier than those which did not transmit. The minimum duration of E1 for a female was shorter than that of a male, but transmission was higher. However, durations of other EPG parameters were not significantly different between male and female. Feeding by single Clas‐infected D. citri adults on 6‐month‐old plants (Sunki) resulted in 23% HLB‐positive plants 6 months after inoculation. Multiple nymphs or adults could transmit the pathogen more efficiently than individual adults in the field, and further enhance the severity of the disease. Effective tactics are warranted to control D. citri and disrupt transmission of Clas.     

Characterization of the electrical penetration graphs of the psyllid Bactericera trigonica on carrots

The psyllid Bactericera trigonica Hodkinson (Hemiptera: Triozidae) is a carrot and celery pest recently described as a vector of the plant pathogenic bacterium Candidatus Liberibacter solanacearum (Lso) on Apiaceae. Detailed information on vector stylet penetration activities is essential in the study of Lso transmission. In this study we used the electrical penetration graph (EPG) technique, characterized waveforms produced during the various stylet penetration activities in carrot leaves, and correlated them with stylet tracks and salivary sheath termini on plant tissues as well as with Lso inoculation. In addition, the effect of Lso in B. trigonica on the stylet penetration activities was tested. The EPG waveforms identified were: waveforms C1 and C2 detected in the mesophyll, waveforms D, E1, and E2 near or in the phloem sieve elements, and waveform G in the xylem vessels. A waveform pattern not previously reported for psyllids was the ‘pseudo‐potential drop’ (pseudo‐pd), characterized by sudden voltage dips similar to potential drops. However, the lowered voltage appeared to be inverted when the plant voltage is negative, indicating that it is caused by an increased resistance period and not due to a cell puncture. A direct correlation is shown between the waveform E1 and salivation into phloem sieve elements by B. trigonica as the inoculation of Lso occurred in a period as short as 30 s of E1; Lso transmission occurred in 17 of 35 plants (48%). Stylet activities during waveforms C or D had no consequences on the inoculation of Lso. In conclusion, Lso infection directly affects the probing behaviour of B. trigonica by increasing the total duration of C and D waveforms, but not variables related to phloem salivation (Lso inoculation) or ingestion (Lso acquisition). The reported information here is fundamental for identifying the psyllid vector traits of behaviour associated with transmission of Lso to Apiaceae.     

Use of Electrical Penetration Graph Technology to Examine Transmission of ‘Candidatus Liberibacter solanacearum’ to Potato by Three Haplotypes of Potato Psyllid (Bactericera cockerelli; Hemiptera: Triozidae)

The potato psyllid, Bactericera cockerelli (Šulc) (Hemiptera: Triozidae), is a vector of the phloem-limited bacterium ‘Candidatus Liberibacter solanacearum’ (Lso), the putative causal agent of zebra chip disease of potato. Little is known about how potato psyllid transmits Lso to potato. We used electrical penetration graph (EPG) technology to compare stylet probing behaviors and efficiency of Lso transmission of three haplotypes of potato psyllid (Central, Western, Northwestern). All haplotypes exhibited the full suite of stylet behaviors identified in previous studies with this psyllid, including intercellular penetration and secretion of the stylet pathway, xylem ingestion, and phloem activities, the latter comprising salivation and ingestion. The three haplotypes exhibited similar frequency and duration of probing behaviors, with the exception of salivation into phloem, which was of higher duration by psyllids of the Western haplotype. We manipulated how long psyllids were allowed access to potato (“inoculation access period”, or IAP) to examine the relationship between phloem activities and Lso transmission. Between 25 and 30% of psyllids reached and salivated into phloem at an IAP of 1 hr, increasing to almost 80% of psyllids as IAP was increased to 24 h. Probability of Lso-transmission was lower across all IAP levels than probability of phloem salivation, indicating that a percentage of infected psyllids which salivated into the phloem failed to transmit Lso. Logistic regression showed that probability of transmission increased as a function of time spent salivating into the phloem; transmission occurred as quickly as 5 min following onset of salivation. A small percentage of infected psyllids showed extremely long salivation events but nonetheless failed to transmit Lso, for unknown reasons. Information from these studies increases our understanding of Lso transmission by potato psyllid, and demonstrates the value of EPG technology in exploring questions of vector efficiency.     

Sugarcane white leaf phytoplasma in tissue culture: long-term maintenance,transmission, and oxytetracycline remission

Sugarcane white leaf (SCWL)-diseased sugarcane plants collected from Udornthani Province, in north-eastern Thailand, were the source for tissue culture experiments. Explants from axillary buds, meristem tips, and leaves grew optimally in Murashige-Skoog medium containing 0.5 mg/l -naphthaleneacetic acid, 0.5 mg/l 6-benzylaminopurine, and 15% coconut water. Callus development and shoot/root proliferation were more rapid in cultures from diseased than from healthy plants. Disease symptoms continued for 6 years after culture initiation, and SCWL phytoplasma persisted, as confirmed by polymerase chain reaction using both 16S rDNA and 16S-23S rDNA primers. Phytoplasmas in the cultured plantlets were transmissible by grafting to sugarcane and periwinkle, and by feeding of the leafhopper vector Matsumuratettix hiroglyphicus to sugarcane. Although 50% of the plantlets were killed by oxytetracycline at 500 mg/ml, 70–100% of plantlets grown with 200–500 mg/ml oxytetracycline showed symptom remission through 5–8 subcultures. Typical phytoplasma-like bodies, visible by electron microscopy in sieve tubes of untreated diseased plantlets, were absent in antibiotic-treated plantlets. Thus, tissue culture provides a convenient and reliable in vivo system for investigation of SCWL phytoplasma. A preliminary report of this study was presented at the Eighth International Congress of Plant Pathology, Christchurch, New Zealand, 2–7 February 2003     

Identification of ‘Candidatus Phytoplasma solani’ Associated with Tree Peony Yellows Disease in China

Tree peony (Paeonia suffruticosais) plants with yellowing symptoms suggestive of a phytoplasma disease were observed in Shandong Peninsula, China. Typical phytoplasma bodies were detected in the phloem tissue using transmission electron microscopy. The association of a phytoplasma with the disease was confirmed by polymerase chain reaction (PCR) using phytoplasma universal primer pair R16mF2/R16mR1 followed by R16F2n/R16R2 as nested PCR primer pair. The sequence analysis indicated that the phytoplasma associated with tree peony yellows (TPY) was an isolate of ‘Ca. Phytoplasma solani’ belonging to the stolbur (16SrXII) group. This is the first report of a phytoplasma associated with tree peony.     

Dispersal of the leafhoppers <Emphasis Type="Italic">Matsumuratettix hiroglyphicus</Emphasis> and <Emphasis Type="Italic">Yamatotettix flavovittatus</Emphasis> (Homoptera: Cicadellidae), vectors of sugarcane white leaf disease

Sugarcane white leaf disease is a serious problem in many Asian Countries. The leafhoppers Matsumuratettix hiroglyphicus (Matsumura) and Yamatotettix flavovittatus Matsumura are the main vectors of sugarcane white leaf disease phytoplasma. Gaining a better understanding of the dispersal behavior of such insect vectors is essential for both disease epidemiology and vector control. The dispersal distances of M. hiroglyphicus and Y. flavovittatus in a sugarcane field were estimated by means of mark–release–recapture experiments. Adult leafhopper vectors collected from the fields were marked using fluorescent dye powder and released at a central release point in a sugarcane field. The marking method did not have a significant effect on the survival or flight activity of the leafhopper vectors. The overall release–recapture rates of M. hiroglyphicus and Y. flavovittatus within 50 m were 10.1 and 13.4 %, respectively. The estimated natural mean dispersal distances for M. hiroglyphicus and Y. flavovittatus were 162.1 and 387.5 m, respectively. Wind appears to be the main factor influencing the leafhopper dispersal direction.     

Plant penetration activities by the flatid planthopper Metcalfa pruinosa (Hemiptera: Fulgoroidea): an electrical penetration graph‐histology analysis

The citrus flatid planthopper, Metcalfa pruinosa Say (Hemiptera: Flatidae), is a very polyphagous native insect in North America and currently a serious pest in Europe and South Korea. To understand the feeding behaviour of M. pruinosa, stylet penetration behaviour of M. pruinosa was investigated with an electrical penetration graph (EPG) system. This study reports seven EPG waveforms related to M. pruinosa feeding behaviour: np (no stylet penetration), Mp1 (initiation of stylet penetration), Mp2 (stylet movement and salivation), Mp4 (phloem feeding), Mp4‐H (honeydew excretion), Mp5 (xylem feeding) and Mp6 (unknown). To determine respective feeding behaviour related to the Mp4 and Mp5 waveforms, stylets were cut with a laser beam, and the location of the stylet tip within plant tissue was examined. We found plant sap was exuded from the severed stylets only when the Mp4 waveform was observed, suggesting phloem sap ingestion. The stylet tip was located in the xylem region, indicating xylem‐feeding activity, when the Mp5 waveform was observed. The analysis of 24 different EPG parameters suggests that M. pruinosa stylets reached the vascular bundle of a plant within ca. 5 min and spend ca. 70% of the time feeding on xylem and phloem feeding. This is the first study that reports seven distinctive EPG waveforms with respect to the feeding behaviour of M. pruinosa which could help determine host specificity and host plant susceptibility.     

An analysis of the feeding behavior of three stages of Toxoptera citricida by DC electrical penetration graph waveforms

With the purpose of studying the feeding behavior of the brown citrus aphid pest, Toxoptera citricida (Kirkaldy) (Hemiptera: Aphididae), we compared stylet probing behaviors of third and fourth instars and adults on Citrus unshiu Marc (Rutaceae) seedlings using the electrical penetration graph (EPG) technique. EPG waveforms exhibited the full suite of stylet behaviors – stylet pathway, intracellular stylet puncture, phloem salivation (E1), sieve ingestion (E2), and xylem sap ingestion activities, plus the non‐penetration (Np) waveform. Before the phloem phase, the number of probes was significantly higher for third‐instar nymphs than for adults. Overall duration of Np events by adults was significantly lower than the duration of third and fourth instars. The number of short probes of the fourth instars was significantly higher than that of the adults. In the phloem phase, adults made more frequent and longer E1 events than the third and fourth instars. Third instars made more frequent but shorter E2 events, whereas adults made fewer but longer events. These results showed adults gained nutrients by increasing feeding time during phloem ingestion. Thus, the probability of phloem‐associated virus acquisition and transmission of T. citricida was higher in adults than in nymphs.     

Barley yellow dwarf virus transmission and feeding behaviour of Rhopalosiphum padi on Hordeum bulbosum clones

A Hordeum bulbosum L. (Poaceae) clone A17 was identified, which showed complete resistance to Barley yellow dwarf virus (BYDV) and Cereal yellow dwarf virus (CYDV). It was not possible to infect plants of A17 with BYDV‐PAV, ‐MAV, or with CYDV‐RPV by the aphid vectors Rhopalosiphum padi (L.) or Sitobion avenae (Fabricius) (both Hemiptera: Aphididae). Plants of the A17 clone and of the BYDV‐susceptible H. bulbosum clone A21 revealed some resistance to R. padi compared to the susceptible winter barley cultivar Rubina [Hordeum vulgare L. (Poaceae)]. The development time to the imago was longer and the number of nymphs was reduced on both clones compared with cv. Rubina. The probing and feeding behaviour of R. padi on plants of the H. bulbosum clones was studied over 12 h and compared with that on plants of the barley cv. Rubina. Principal component analysis of the results of the feeding behaviour revealed a clear separation of the H. bulbosum genotypes from Rubina. On H. bulbosum the number of penetrations was higher but total feeding time was shorter. Significant differences were mainly found in the phloem feeding parameters for plants of both clones in comparison to Rubina, with the virus resistant A17 clone having the strongest effect and the susceptible A21 clone being intermediate. Most significant differences were found in parameters of the phloem salivation phase. On A17, an average of less than one (0.9) E1 phase per plant was observed (3.3 on A21 and 5.7 on Rubina) and its duration was reduced to less than 1 min (0.9 min) in comparison to 2.4 min on A21 and 5.7 min on Rubina. Also, the phloem feeding (E2) phase was clearly reduced on A17 plants with 0.5 E2 phases per test and a mean duration of 1.1 min in contrast with 2.9 and 3.5 E2 phases per test and 34.1 and 421.3 min for A21 and Rubina, respectively. These results point towards a phloem‐localized factor for aphid resistance in H. bulbosum, i.e., on A17 plants the phloem salivation time is too short for a successful infection by BYDV leading to vector resistance.     

Mixed Infection and Natural Spread of ‘Candidatus Phytoplasma asteris’ and Mungbean Yellow Mosaic India Virus Affecting Soya Bean Crop in India

Suspected phytoplasma and virus‐like symptoms of little leaf, yellow mosaic and witches’ broom were recorded on soya bean and two weed species (Digitaria sanguinalis and Parthenium hysterophorus), at experimental fields of Indian Agricultural Research Institute, New Delhi, India, in August–September 2013. The phytoplasma aetiology was confirmed in symptomatic soya bean and both the weed species by direct and nested PCR assays with phytoplasma‐specific universal primer pairs (P1/P6 and R16F2n/R16R2n). One major leafhopper species viz. Empoasca motti Pruthi feeding on symptomatic soya bean plants was also found phytoplasma positive in nested PCR assays. Sequencing BLASTn search analysis and phylogenetic analysis revealed that 16Sr DNA sequences of phytoplasma isolates of soya bean, weeds and leafhoppers had 99% sequence identity among themselves and were related to strains of ‘Candidatus Phytoplasma asteris’. PCR assays with Mungbean yellow mosaic India virus (MYMIV) coat‐protein‐specific primers yielded an amplicon of approximately 770 bp both from symptomatic soya bean and from whiteflies (Bemisia tabaci) feeding on soya bean, confirmed the presence of MYMIV in soya bean and whitefly. Hence, this study suggested the mixed infection of MYMIV and ‘Ca. P. asteris’ with soya bean yellow leaf and witches’ broom syndrome. The two weed species (D. sanguinalis and P. hysterophorus) were recorded as putative alternative hosts for ‘Ca. P. asteris’ soya bean Indian strain. However, the leafhopper E. motti was recorded as putative vector for the identified soya bean phytoplasma isolate, and the whitefly (B. tabaci) was identified as vector of MYMIV which belonged to Asia‐II‐1 genotype.     

Ultrastructure of compatible and incompatible interactions in phloem sieve elements during the stylet penetration by cotton aphids in melon

Resistance of the melon line TGR‐1551 to the aphid Aphis gossypii is based on preventing aphids from ingesting phloem sap. In electrical penetration graphs (EPGs), this resistance has been characterized with A. gossypii showing unusually long phloem salivation periods (waveform E1) mostly followed by pathway activities (waveform C) or if followed by phloem ingestion (waveform E2), ingestion was not sustained for more than 10 min. Stylectomy with aphids on susceptible and resistant plants was performed during EPG recording while the stylet tips were phloem inserted. This was followed by dissection of the penetrated leaf section, plant tissue fixation, resin embedding, and ultrathin sectioning for transmission electron microscopic observation in order to study the resistance mechanism in the TGR. The most obvious aspect appeared to be the coagulation of phloem proteins inside the stylet canals and the punctured sieve elements. Stylets of 5 aphids per genotype were amputated during sieve element (SE) salivation (E1) and SE ingestion (E2). Cross‐sections of stylet bundles in susceptible melon plants showed that the contents of the stylet canals were totally clear and also, no coagulated phloem proteins occurred in their punctured sieve elements. In contrast, electron‐dense coagulations were found in both locations in the resistant plants. Due to calcium binding, aphid saliva has been hypothesized to play an essential role in preventing/suppressing such coagulations that cause occlusion of sieves plate and in the food canal of the aphid's stylets. Doubts about this role of E1 salivation are discussed on the basis of our results.     

Comparative Molecular Analyses of Phytoplasmas infecting Sophora japonica cv. golden and Robinia pseudoacacia

Phytoplasmas were detected in Sophora japonica cv. golden and Robinia pseudoacacia with diseased branches of witches'‐broom collected in Haidian district, Beijing, China. Phytoplasma cells were observed in phloem sieve elements of symptomatic S. japonica cv. golden by transmission electron microscopy. The presence of phytoplasmas was further confirmed by sequence determination of partial gene sequences of 16S rDNA, rp (ribosomal protein) and secY. Phylogenetic trees and virtual restriction fragment length polymorphism (RFLP) analyses indicated that the phytoplasmas causing S. japonica cv. golden witches'‐broom (SJGWB) and R. pseudoacacia witches'‐broom (RPWB) belong to the 16SrV (elm yellows) group, and they are most closely related to subgroup 16SrV‐B, rpV‐C and secYV‐C jujube witches'‐broom (JWB) phytoplasma. Comparative analyses indicated that the phytoplasma of RPWB was closer to the JWB and that R. pseudoacacia might serve as an alternative host plant of JWB phytoplasma.     

Aster Yellows Subgroup 16SrI‐C Phytoplasma in Rhododendron hybridum

Symptoms of unknown aetiology on Rhododendron hybridum cv. Cunningham's White were observed in the Czech Republic in 2010. The infected plant had malformed leaves, with irregular shaped edges, mosaic, leaf tip necrosis and multiple axillary shoots with smaller leaves. Transmission electron microscopy showed phytoplasma‐like bodies in phloem cells of the symptomatic plant. Phytoplasma presence was confirmed by polymerase chain reaction using phytoplasma‐specific, universal and group‐specific primer pairs. Restriction fragment length polymorphism analysis of 16S rDNA enabled classification of the detected phytoplasma into the aster yellows subgroup I‐C. Sequence analysis of the 16S‐23S ribosomal operon of the amplified phytoplasma genome from the infected rhododendron plant (1724 bp) confirmed the closest relationship with the Czech Echinacea purpurea phyllody phytoplasma. These data suggest Rhododendron hybridum is a new host for the aster yellows phytoplasma subgroup 16SrI‐C in the Czech Republic and worldwide.     

Feeding by sugarcane aphid,Melanaphis sacchari,on sugarcane cultivars with differential susceptibility and potential mechanism of resistance

Feeding behavior of Melanaphis sacchari Zehntner (Hemiptera: Aphididae) was studied on sugarcane, Saccharum spp. (Poaceae), cultivars HoCP 91‐555 (resistant), LCP 85‐384 (moderately resistant), and L 97‐128 (susceptible) using the electrical penetration graph (EPG) technique. Constitutive concentrations of total phenolics and available carbohydrates, water potential at the whole‐leaf tissue level, and free amino acids (FAAs) in phloem sap extracts, and in honeydew produced by aphids fed on L 97‐128 and HoCP 91‐555 were determined. Cultivar did not influence time for M. sacchari to access phloem sieve elements. Total time in sieve elements was ca. two‐fold greater on L 97‐128 than on HoCP 91‐555, whereas it did not differ from LCP 85‐384 in either cultivar. The mean duration of individual events associated with phloem sap ingestion was ca. 50% shorter on both HoCP 91‐555 and LCP 85‐384 than on L 97‐128. Although cultivar effects were not detected for levels of total phenolics, available carbohydrates, and water potential, two free essential amino acids, histidine and arginine, were absent from phloem sap in HoCP 91‐555. Two free essential amino acids, leucine and isoleucine, and two free non‐essential amino acids, tyrosine and proline, were absent from honeydew of aphids fed on HoCP 91‐555. These results suggest that despite apparent biosynthesis of some FAAs, the absence of important FAAs in the phloem sap of HoCP 91‐555 and the inability of M. sacchari and its endosymbionts (e.g., Buchnera) to derive specific free essential and non‐essential amino acids from other ingested molecules, possibly along with other unidentified factors, underlie the pest's decreased phloem sap ingestion and consequently reduced growth potential on HoCP 91‐555.     

The Significance of Napier Grass Stunt Phytoplasma and Its Transmission to Cereals and Sugarcane

Production of Napier grass, Pennisetum purpureum, the most important forage crop in Africa, is severely constrained by Napier grass stunt (NGS) disease. Wild grasses have been identified as alternative hosts for NGS, but there is no record regarding the ability of this phytoplasma to infect cultivated food crops. To assess this threat, six crop species were placed around phytoplasma‐infected Napier grass with the vector Maiestas banda (Hemiptera: Cicadellidae) in transmission cages for a period of 30 days. The crop plants were observed for 3 months after removal from the cages for disease development. Polymerase chain reaction based on the conserved 16S gene, primed by P1/P6‐NapF/NapR nested primer sets, was used to diagnose phytoplasma in test plants, before and after transmission experiments. Pennisetum purpureum showed the highest infection level (81.3%), followed by Saccharum officinarum (56.3%), Eleusine coracana (50%), Sorghum bicolor (43.8%), Oryza sativa (31.3%) and Zea mays (18.8%). All the test plants remained symptomless except sugarcane that exhibited mild to moderate symptoms comprising yellow leaves and bright white or yellow midribs. Napier grass, however, was stunted with small yellow leaves. The study showed that food crops could be infected, suggesting their possible role as sources of inoculum for NGS and their contribution in the spread of the disease in regions where these crops are cultivated. This implies an additional disease cycle could occur for NGS disease, highlighting the challenges to development and implementation of management strategies for the disease.     

First Report of a 16SrI‐C Phytoplasma Infecting Celery (Apium graveolens) with Stunting,Bushy Top and Phyllody in the Czech Republic

Apium graveolens L. plants showing stunting, purplish/whitening of new leaves, flower abnormalities and bushy tops were observed in South Bohemia (Czech Republic) during 2011 and 2012. Transmission electron microscopy observations showed phytoplasmas in phloem sieve tube elements of symptomatic but not healthy plants. Polymerase chain reactions with universal and group‐specific phytoplasma primers followed by restriction fragment length polymorphism analyses and sequencing of 16S rDNA enabled classification of the detected phytoplasmas into the aster yellows group, ribosomal subgroup 16SrI‐C. Identical analyses of the ribosomal protein genes rpl22 and rps3 were used for further classification and revealed affiliation of the phytoplasmas with the rpIC subgroups. This is the first report of naturally occurring clover phyllody phytoplasma in A. graveolens in both the Czech Republic and worldwide.     

Preliminary survey on putative insect vectors for Rubus stunt phytoplasmas

Phytoplasmas are cell wall‐less phytopathogenic bacteria which are associated with a disease in Rubus species known as Rubus stunt. Symptoms range from stunting, witches’ broom, small leaves, short internodes, enlarged sepals, phyllody and flower proliferation to fruit malformations. Phytoplasmas can be spread by vegetative propagation and by phloem‐feeding insect vectors. However, little is known about the spectrum and distribution of putative Rubus stunt insect vectors. In this study, a screening of putative insect vectors of Rubus stunt in raspberry plantations in southern and northern Germany was carried out during two successive years (2014 and 2015) with multiple sampling dates throughout the growing seasons. A total of 2,891 hemipteran insects were sorted, identified to family, genus or species level when possible, and a subset of 319 DNA samples containing a sum of 932 selected individuals representing all identified species, sampling locations and sampling dates were tested for phytoplasma DNA using qPCR. Altogether, eight DNA samples were positive for phytoplasma DNA, among them species from the genera Euscelidius, Macrosteles, Euscelis, Anaceratagalliaand Psammotettix. These data will form the basis for choosing and timing appropriate control measures against Rubus stunt and also for potential insect vector transmission experiments.     

New insights in phytoplasma‐vector interaction: acquisition and inoculation of flavescence dorée phytoplasma by Scaphoideus titanus adults in a short window of time

The leafhopper Scaphoideus titanus is able to transmit 16SrV phytoplasmas agents of grapevine's flavescence dorée (FD) within 30–45 days, following an acquisition access period (AAP) of a few days feeding on infected plants as a nymph, a latency period (LP) of 3–5 weeks becoming meanwhile an adult, and an inoculation access period (IAP) of a few days on healthy plants. However, several aspects of FD epidemiology suggest how the whole transmission process may take less time, and may start directly with adults of the insect vector. Transmission experiments have been set up under lab condition. Phytoplasma‐free S. titanus adults were placed on broad bean (BB) plants (Vicia faba) infected by FD‐C (16SrV‐C) phytoplasmas for an AAP = 7 days. Afterwards, they were immediately moved onto healthy BB for IAP, which were changed every 7 days, obtaining three timings of inoculation: IAP 1, IAP 2 and IAP 3, lasting 7, 14 and 21 days from the end of AAP, respectively. DNA was extracted from plants and insects, and PCR tests were performed to identify FD phytoplasmas. Insects were dissected and fluorescence in situ hybridisation was made to detect the presence of phytoplasmas in midguts and salivary glands. The rate of infection in insects ranged 46–68% without significant differences among IAPs. Inoculation in plants succeeded in all IAPs, at a rate of 16–23% (no significant differences). Phytoplasma load was significantly higher in IAP 3 than IAP 1–2 for both plants and insects. Phytoplasmas were identified both in midgut and salivary glands of S. titanus at all IAP times. The possible implications of these results in the epidemiology of flavescence dorée are discussed.