Leafhopper transmission of a virus causing maize wallaby ear disease

A virus causing maize wallaby ear disease was transmitted experimentally by Cicadulina bimaculata to fourteen species of monocotyledonous plants. It was also transmitted by Nesoclutha pallida, and by grafting. The symptoms obtained resemble closely those reported for maize leaf gall disease in the Philippines and maize rough dwarf virus in Italy and Israel. About 85% of C. bimaculata caught in the field carried maize wallaby ear virus (MWEV), and many of their progeny were viruliferous even when not allowed access to infected plants. The proportion of infective individuals in clones bred for nine generations from selected non-transmitting adults decreased from 85% in the first nymphs to less than 1%; such individuals were difficult to rear, as their fecundity and longevity decreased greatly. N. pallida transmitted MWEV after injection with partially purified extracts of infected plants. Spherical particles c. 85 nm in diameter were found in the salivary glands of viruliferous C. bimaculata, but not in those of non-transmitting individuals. The particles occurred in tubules in the cytoplasm and each had a densely stained core c. 50 nm in diameter. Particles similar in size to the core were found in extracts of infected but not uninfected maize, and in extracts of viruliferous but not in non-viruliferous C. bimaculata and N. pallida.     

Transmission by Laodelphax striatellus Fallen of Rice black‐streaked dwarf virus from Frozen Infected Rice Leaves to Healthy Plants of Rice and Maize

Rice black‐streaked dwarf virus (RBSDV) is transmitted naturally to important crops such as rice, maize, barley and wheat in a persistent manner by the planthoppers, Laodelphax striatellus, Unkanodes sapporona and Unkanodes albifascia. Insect vector transmission tests are the basis for identifying viral incidence, evaluating the resistance of varieties and selecting resistance sources for rice and maize breeding. A simple, rapid and reliable method is described by which virus‐free small brown planthoppers (L. striatellus) acquired RBSDV from frozen infected rice leaves and transmitted it to healthy rice and maize plants. After feeding on frozen infected rice leaves, the planthoppers were tested by RT‐PCR for the presence of virus after 10, 15, and 22 days, respectively. The percentages of RBSDV‐containing insects were 0, 25 and 71.43% of L. striatellus fed on frozen infected rice leaves compared to 0, 28.25 and 71.43% of L. striatellus fed on fresh infected rice leaves, respectively. In transmission tests, three of eight rice seedlings (37.5%) and four of eight maize seedlings (50%) were inoculated by the planthoppers that had fed previously on frozen leaves and had allowed a 22 days latent period and showed typical disease symptoms. As a positive control, four of eight rice seedlings (50%) and four of six maize seedlings (66.67%) became infected. All rice and maize plants expressing disease symptoms were identified as virus‐positive by RT‐PCR. These results indicated that the planthoppers acquired RBSDV from frozen infected leaves and transmitted the virus to healthy plants.     

A study of the mode of transmission of maize streak virus by Cicadulina mbila using an enzyme-linked immunosorbent assay

Two batches of Cicadulina mbila were given two distinct acquisition access periods (AAP) (3 h and 50 h) on maize plants infected with maize streak virus (MSV). Infectivity assays on susceptible maize were carried out 1, 3, 10, 17, 26 and 35 days after the AAP. Transmission efficiency was significantly higher for C. mbila subjected to the 50-h AAP. At the same time as the infectivity assays, the amount of MSV in each leafhopper was determined by an indirect double antibody sandwich (IDAS) ELISA. There were more ELISA-positive insects after the 50-h AAP than after the 3-h AAP. In the group given a 3-h AAP, only 7% of the insects tested between day 1 and 35 were found to be positive by ELISA. In contrast, after the 50-h AAP, the majority of C. mbila were positive, yet a decrease in ELISA-positive insects was noticed from day 17 onwards. Using a calibration curve obtained with purified virus, as little as 0.15 ng of MSV per insect could be measured by the IDAS-ELISA. A mean value of 0.36 ng of MSV per C. mbila was found 3 days after the 50–h acquisition, whereas 14 days later there was only 0.20 ng of virus per insect. For comparison, when leafhoppers were kept on infected maize, they displayed substantial accumulation of MSV up to an average of 3.83 ng of MSV per insect after 35 days of continuous acquisition. The amount of virus per insect detected in females was usually greater than the amount detected in males. Our results suggest that MSV does not multiply in C. mbila and contribute to the understanding of the persistence of transmission efficiency in the absence of virus multiplication.     

Host plant dispersion, leaf hopper movement and disease transmission

Abstract.

• 1 The plant-to-plant movement of the corn leafhopper, Dalbulus maidis Delong & Wolcott, and the spread of the leafhopper-borne maize rayado fino virus were investigated in four patterns of maize (Zea mays) dispersion.
• 2 D. maidis was less abundant and the spread of the virus was slower in dense stands of maize than in sparse stands.
• 3 When plant density was held constant, leafhoppers were more abundant in maize stands with relatively equidistant plant spacing (uniform dispersion) than in stands with densely-sown rows (linear dispersion) or double-sown hills (clumped dispersion), but there was no difference in virus incidence among these plant dispersion patterns.
• 4 Leafhoppers were less likely to move to adjacent plants in uniform plant dispersion patterns than in either linear or clumped dispersion patterns. This result may explain the lack of higher virus incidence in uniform stands, despite higher leafhopper abundance.
• 5 Leafhopper movement was consistent with a simple rule: the shorter the distance to the next adjacent plant, the more likely a leafhopper is to move between plants.
• 6 These results demonstrate that host plant dispersion can affect the abundance and behaviour of highly mobile herbivorous insects even when plant density is constant.

     

Host Feeding by an Herbivore Improves the Performance of Offspring

Herbivores have developed diverse strategies to manipulate host plants for their own benefits. The gall induction by the maize orange leafhopper Cicadulina bipunctata is different from that by other gall-inducing insects in that the galls are induced not on feeding sites but appear on distant, newly developing leaves. In addition, adult C. bipunctata are highly mobile and seldom feed on gall tissue that they have induced. These mean that the gall induction by C. bipunctata is unlikely to contribute to the fitness of the inducer itself. The objective of this study was to determine whether manipulation of the host plant by this leafhopper has a subsequent benefit to offspring. Adults feeding on maize seedlings caused a partial change in the glucose content and a remarkable change in the accumulation of free amino acids in the gall tissue. Increases in emergence and developmental rates were observed in nymphs feeding on gall tissue induced by prior adult feeding. Such improvements were not evident in nymphs feeding on a C. bipunctata-resistant variety, which rarely displays galls after C. bipunctata feeding, nor on maize seedlings previously foraged by another leafhopper, Psammotettix striatus. The results indicate that gall tissue induced by adult C. bipunctata contribute to better performance of its offspring through improvement of the nutritional components of host plants.     

Vector and Host-Plant Relationships of the Leafhopper-Borne Maize Yellow Stripe Virus

Maize yellow stripe virus (MYSV), associated with tenuivirus-like filaments, is transmitted in a persistent manner by the leafhopper Cicadulina chinai. In this vector, MYSV acquisition and inoculation threshold times were 30 min each, latent period ranged from 4.5 to 8 days depending on temperature (14-25 °C), and retention periods were as long as 27 days. Up to 26 % of C, chinai collected from maize fields in Giza, Egypt, during September and October 1985 were naturally infective with MYSV. Two symptom-types (fine and coarse stripe) appeared on experimentally infected plants, usually on separate leaves of the same plant. However, these two symptom-types could not be isolated on separate plants through transmission by single C. chinai leafhoppers. MYSV was transmitted by nymphs and adults of C. chinai from maize to maize, wheat and barley, and from wheat to maize plants. Up to 6 % of the wheat plants examined in Naga Hamadi (Southern Egypt) in February 1986, were naturally infected. It is suggested that wheat, barley and possibly graminaceous weeds may serve as winter hosts or reservoirs for MYSV and its leafhopper vector in Egypt.     

Western Flower Thrips (Frankliniella occidentalis) Transmits Maize Chlorotic Mottle Virus

Maize chlorotic mottle virus (MCMV) is one of the co‐infection pathogens that cause corn (maize) lethal necrosis, but the transmission mechanism of MCMV is not yet clear. In order to determine the ability of western flower thrips (Frankliniella occidentalis; WFT) to transmit MCMV, imported maize seeds from Thailand were germinated in an insect‐free greenhouse and the seedlings were tested for the transmission by WFT of chlorotic mottle virus disease. The thrips (WFT), starved for 48 h then allowed to feed for 30 min on maize plants infected with MCMV or asymptomatic maize plants, were transferred to healthy seedlings. After 35 days, the seedlings with WFT from diseased maize plants showed chlorotic mottle symptoms, whereas seedlings with WFT from asymptomatic maize plants remained healthy. A single band of 711 bp was amplified by RT‐PCR using primers MCMV‐F/MCMV‐R from the MCMV‐infected plants and WFT collected from the diseased plants. Sequencing of the amplified product and further sequence comparison indicated that the two viruses from both sources showed 99% similarity of nucleotides and they should be regarded as identical. In addition, isometric particles c. 30 nm in diameter, characteristic of MCMV, were found in the WFT samples from diseased maize plants. Thus, it is concluded that WFT transmits MCMV. Our findings suggest that corn lethal necrosis disease can be controlled or minimized by the eradication of WFT from the field or greenhouses.     

Do assortative mating and immigrant inviability help maintain population genetic structuring of an herbivore on a crop and a wild relative?

Population genetic structuring is common among herbivorous insects and frequently is associated with divergent host plants, such as crops and their wild relatives. Previous studies showed population genetic structuring in corn leafhopper Dulbulus maidis in Mexico, such that the species consists of two sympatric, host plant-associated populations: an abundant and widespread "pestiferous” population on maize (Zea mays mays), and a small and localized "wild" population on perennial teosinte (Zea diploperennis). a maize wild relative with a limited distribution. This study addressed whether assortative mating and immigrant inviability mediate genetic structuring of corn leafliopper by comparing the mating and reproductive successes of pestiferous and wild females that colonize their nonassociated host plants against the successes of females colonizing their associated host plants. Assortative mating was assessed by comparing mating frequencies and premating and mating times among females of each population on each host plant: immigrant inviability was assessed by comparing, across two generations, the fecundity, survival, development time, sex ratio, and population growth rate among leafhopper populations and host plants. Our results showed that on maize, and compared to resident, pestiferous females, wild females were more likely to mate, and greater proportions of their offspring survived to adult stage and were daughters;consequently, the per-generation population growth rate on maize was greater for immigrant, wild leafhoppers compared to resident, pestiferous leafhoppers. Our results suggested that wild leafhoppers emigrating to maize have a fitness advantage over resident, pestiferous leafhoppers, while immigrant pestiferous and resident wild leafhoppers on teosinte have similar fitnesses.     

Transmission of rayado fino virus of maize (Zea mays) by Dalbulus tnaidis

Rayado fino virus (RFV) of maize (Zea mays) was transmitted by the leaf-hopper Dalbulus maidis in a manner characteristic of viruses that multiply in their insect vectors. Individual insects fed on infected plants transmitted the virus after incubation periods of 8–22 days; males had shorter incubation periods than females but died sooner. Insects retained infectivity for 1–20 days. Transmission by most insects was intermittent. Inoculativity by D. maidis decreased with time, but the virus was recovered from insects that had lost their ability to transmit. Extracts of plants infected with RFV and viruliferous insects were injected into healthy insects, which became viruli-ferous. Infectivity of the extracts was not affected by tetracycline hydrochloride (Achromycin). D. maidis was able to transmit simultaneously RFV and the corn stunt agent. Other than maize, Teosinte (Euchlaena mexicana) was the only plant susceptible to the virus, among a number of species of Gramineae tested.     

Priming of Production in Maize of Volatile Organic Defence Compounds by the Natural Plant Activator cis-Jasmone

cis-Jasmone (CJ) is a natural plant product that activates defence against herbivores in model and crop plants. In this study, we investigated whether CJ could prime defence in maize, Zea mays, against the leafhopper, Cicadulina storeyi, responsible for the transmission of maize streak virus (MSV). Priming occurs when a pre-treatment, in this case CJ, increases the potency and speed of a defence response upon subsequent attack on the plant. Here, we tested insect responses to plant volatile organic compounds (VOCs) using a Y-tube olfactometer bioassay. Our initial experiments showed that, in this system, there was no significant response of the herbivore to CJ itself and no difference in response to VOCs collected from unexposed plants compared to CJ exposed plants, both without insects. VOCs were then collected from C. storeyi-infested maize seedlings with and without CJ pre-treatment. The bioassay revealed a significant preference by this pest for VOCs from infested seedlings without the CJ pre-treatment. A timed series of VOC collections and bioassays showed that the effect was strongest in the first 22 h of insect infestation, i.e. before the insects had themselves induced a change in VOC emission. Chemical analysis showed that treatment of maize seedlings with CJ, followed by exposure to C. storeyi, led to a significant increase in emission of the defensive sesquiterpenes (E)-(1R,9S)-caryophyllene, (E)-α-bergamotene, (E)-β-farnesene and (E)-4,8-dimethyl-1,3,7-nonatriene, known to act as herbivore repellents. The chemical analysis explains the behavioural effects observed in the olfactometer, as the CJ treatment caused plants to emit a blend of VOCs comprising more of the repellent components in the first 22 h of insect infestation than control plants. The speed and potency of VOC emission was increased by the CJ pre-treatment. This is the first indication that CJ can prime plants for enhanced production of defensive VOCs antagonist towards herbivores.     

Biological characteristics of grass geminiviruses from eastern Australia

Two serotypes of chloris striate mosaic virus (CSMV), paspalum striate mosaic virus (PSMV) and geminiviruses infecting Bromus catharticus and Digitaria didactyla were investigated. Their field occurrence and experimental hosts are listed. Serial transmission data for CSMV by single Nesoclutha pallida show a minimum latent period of 12–14 h, and regular transmission with occasional breaks for up to 50 days. Cicadulina bimaculata did not transmit any isolates after plant feeding acquisition, but transmitted CSMV inefficiently after insect injection. The vector of PSMV was found to be a specific biotype of N. pallida which bred only on Paspalum spp. The rate of transmission of CSMV with the Chloris biotype of N. pallida and of PSMV with the Paspalum biotype reached c. 50% with single insects, but only when freshly-infected source plants were used. Geminate particles were found in thin sections of leaf tissue infected with all four viruses, and partially purified preparations were made of three of these. In gel diffusion tests, the virus from Microlaena stipoides produced a spur reaction with CSMV, when reacted with CSMV antiserum. The B. catharticus and D. didactyla isolates failed to react serologically with CSMV, maize streak or Vanuatu digitaria streak viruses.     

Beet curly top virus transmission by artificially fed and injected beet leafhoppers (Circulfer tenellus)

The transmission of beet curly top virus (BCTV) by leafhoppers, Circulifer tenellus, fed virus through Parafilm® membranes was compared with their transmission when injected with virus from phloem exudates of Amsinckia douglasiana. Virus uptake from ³²P-labelled test solutions and the resulting virus transmission, as measured by an infectivity index, varied widely. By contrast, insects injected with virus transmitted with similar efficiencies. If insects were fasted for 3, 5, or 7 h before a 6 h acquisition access period on test solutions, their ³²P, and presumably virus uptake, was greater than that of nonfasted insects and their variability in virus transmission decreased. The proportion of insects transmitting curly top virus, after fasting and given a 6 h acquisition access period, was similar to that of insects injected with virus. Maximum liquid uptake by the beet leafhopper occurred with a 12% sucrose solution.     

Inoculation and acquisition of maize bushy stunt mycoplasma by its leafhopper vector Dalbulus maidis

Maize bushy stunt mycoplasma (MBSM), a mycoplasma-like organism, is transmitted in a persistent manner by the corn leafhopper, Dalbulus maidis, to maize (Zea mays). The influence of the duration of acquisition access and inoculation access periods on the transmission of MBSM by D. maidis was investigated. The proportion of plants infected by D. maidis increased significantly from 0 to 0.51 as the inoculation access time to a plant increased from 10 min to 72 h (X²= 101.5, P < 0.001). Likewise, the proportion of insects acquiring MBSM from infected plants increased from 0 to 0.19 as the acquisition access time to the source plant increased from 10 min to 72 h (X²= 53.2, P < 0.001). The data were fitted to a loglinear regression model. No significant association was found between the sex of the insects and vector ability.     

Assessment of yield losses as a result of co-infection by maize streak virus and maize stripe virus in Mauritius

The effect of co-infection by maize streak virus (MSV) and maize stripe virus (MStV) on plant growth and grain yield was investigated in a susceptible variety of maize (Zea mays), ZS 5206, in Mauritius. Under natural conditions MSV, transmitted by the leafhopper Cicadulina mbila, was normally established before MStV, which is vectored by the planthopper Peregrinus maidis; as a result, MStV symptoms were often partially or completely masked by those of MSV, making MStV detection by symptomatology very unreliable. MSV and MStV were diagnosed by ELISA and MStV by a novel method of detecting the MStV-coded non-capsid protein. The maize hybrid ZS 5206 was inoculated with either MSV, MStV or both, at two stages in the growth cycle (3–5 or 7–10 leaf stage). A greater reduction in plant growth was observed in plants inoculated singly with MStV (80% and 29% for first and second stage, respectively) than with MSV (50% and 23%, respectively). No cobs were produced by plants singly infected with MStV at the first stage, or co-infected with MSV and MStV at both stages; however, marginal grain production was recorded in plants singly infected with MSV at the first stage (91% reduction), or infected either with MSV or MStV, at the second stage (65% and 80% reduction, respectively). In maize hybrid ZS 5206, MStV is more virulent than MSV; co-infection by both viruses causes greater reductions in plant growth and grain yield than single infection by either virus at a given stage of plant development. In the event of co-infection by MSV and MStV, yield losses can be erroneously attributed to MSV only if the symptoms of MStV are masked by those of the former and if adequate methods for MStV detection are not used.     

Did maize domestication and early spread mediate the population genetics of corn leafhopper?

Investigating how crop domestication and early farming mediated crop attributes, distributions, and interactions with antagonists may shed light on today's agricultural pest problems. Crop domestication generally involved artificial selection for traits desirable to early farmers, for example, in creased productivity or yield, and enhanced qualities, though invariably it altered the interactions between crops and insects, and expanded the geographical ranges of crops. Thus, some studies suggest that with crop domestication and spread, insect populations on wild crop ancestors gave rise to pestiferous insect populations on crops. Here, we addressed whether the emergence of corn leafhopper (Dalbulus ma id is) as an agricultural pest may be associated with domestication and early spread of maize (Zea mays mays). We used AFLP markers and mitochondrial COI sequences to assess population genetic structuring and haplotype relationships among corn leafhopper samples from maize and its wild relative Zea diploperennis from multiple locations in Mexico and Argentina. We uncovered seven corn leafhopper haplotypes contained within two haplogroups, one haplogroup containing haplotypes associated with maize and the other containing haplotypes associated with Z. diploperennis in a mountainous habitat. Within the first haplogroup, one haplotype was predominant across Mexican locations, and another across Argentinean locations;both were considered pestiferous. We suggested that the divergence times of the maize-associated haplogroup and of the "pestiferous" haplotypes are correlated with the chronology of maize spread following its domestication. Overall, our results support a hypothesis positing that maize domestication favored corn leafhopper genotypes preadapted for exploiting maize so that they became pestiferous, and that with the geographical expansi on of maize farming, corn leafhopper colonized Z. diploperennis, a host exclusive to secluded habitats that serves as a refuge for archaic corn leafhopper genotypic diversity. Broadly, our results help explain the extents to which crop domestication and early spread may have mediated the emergence of today's agricultural pests.     

Efficient Inoculation of Rice black‐streaked dwarf virus to Maize Using Laodelphax striatellus Fallen

Maize rough dwarf disease caused by Rice black‐streaked dwarf virus (RBSDV) is the most important disease of maize in China. Although deploying disease resistant hybrids would be the most effective way to control the disease, development of resistant hybrids has been limited by virus transmission rates that are too low for effective screening. An efficient inoculation technique for RBSDV was developed using Laodelphax striatellus Fallen, in which a virus‐free planthopper colony was developed and viruliferous planthoppers were obtained by allowing a 3‐ to 4‐day acquisition access period on RBSDV‐infected wheat plants. Planthoppers were then allowed a 25‐ to 28‐day latent period on wheat seedlings followed by a 3‐day inoculation access period on two‐to‐three‐leaf stage maize seedlings. By 35 days postinoculation, susceptible hybrid ‘Zhengdan 958’, inbred lines of ‘Ye 107’ and ‘Ye 478’ plants showed 100% RBSDV infection with symptoms of stunting plants, darkening leaves and white waxy swellings on underside of leaves. At tasseling stage, average disease indices were from 96.4 to 100.0%. Enzyme‐linked immunosorbent assays were correlated with the presence of symptoms. The high efficiency of RBSDV transmission obtained using this technique provides a reliable procedure to screen for RBSDV resistance in maize.     

Efficient monitoring of maize orange leafhopper, <Emphasis Type="Italic">Cicadulina bipunctata</Emphasis> (Hemiptera: Cicadellidae), and small brown planthopper, <Emphasis Type="Italic">Laodelphax striatellus</Emphasis> (Hemiptera: Delphacidae), in forage maize fields using yellow sticky traps

The monitoring of insect pests in fields of forage maize is difficult because plants are tall and grow at a high density. We investigated the effectiveness of colored sticky traps and appropriate conditions for monitoring insect pests in forage maize fields. Large numbers of the maize orange leafhopper, Cicadulina bipunctata Melichar (Hemiptera: Cicadellidae), and the small brown planthopper, Laodelphax striatellus Fallen (Hemiptera: Delphacidae), were collected during the experimental period with yellow and blue sticky traps placed in summer crop forage maize fields. A greater number of insects were trapped in yellow traps relative to blue traps. Traps located at a lower height (40 cm above the ground) attracted larger numbers of C. bipunctata, whereas L. striatellus did not demonstrate a height-dependent preference. These results indicated that yellow-colored sticky traps located at low height are effective for collecting C. bipunctata and L. striatellus simultaneously. Seasonal occurrence data obtained by the yellow sticky traps showed clearer seasonal occurrences than that obtained by two previously developed methods, suction and light traps, indicating that sticky traps are effective for monitoring the seasonal occurrence of these two insects in forage maize fields.     

Further studies on the maize and rice leaf galls induced by Cicadulina bipunctella

In the Philippines, plant galls were induced by the feeding of Cicadulina bipunctella (Mats.). Every insect collected in nature, as well as all insects raised on healthy maize, were able to produce leaf galls. Approximately 10 days after exposure to the insects, galls appeared on the next developing young leaf, but not on the leaf that was exposed to the insects. No difference was observed between the effect of feeding by single insects and groups of 10 insects. C. bipunctella-induced galls were compared to similar galls induced by the feeding of C. zeae in Africa, C. pastusae in South America, C. bimaculata in Australia, Dalbulus elimatus in America and Euscelis plebejus in Europe. In addition to experimental findings, worldwide association of leaf galls with feeding of leafhoppers belonging to several related species, favours the view that the galls of maize and rice plants are caused by insect toxins, rather than by plant viruses.

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Zusammenfassung Auf den Philippinen wurden Pflanzengallen durch das Saugen von Cicadulina bipunctella (Mats.) hervorgerufen. Jede dieser im Freien gesammelten Zwergzikaden sowie alle an gesundem Mais gezüchteten Individuen waren fähig, Blattgallen zu erzeugen. Ungefähr 10 Tage nach dem Ansetzen der Zikaden erschienen die Gallen auf dem nächsten sich entwickelnden jungen Blatt, jedoch nicht auf dem Blatt, das den Zikaden ausgesetzt worden war. Es wurde kein Unterschied zwischen der Wirkung des Saugens von einzelnen und Gruppen von 10 Zikaden beobachtet. Die von C. bipunctella hervorgerufenen Gallen wurden mit ähnlichen Gallen verglichen, die durch das Saugen von C. zeae in Afrika, C. pastusae in Südamerika, C. bimaculata in Australien, Dalbulus elimatus in Amerika und Euscelis plebejus in Europa erzeugt werden. In Ergänzung zu den experimentellen Befunden begünstigt die weltweite Verknüpfung von Blattgallen mit dem Saugen von Zwergzikaden, die zu einigen verwandten Arten gehören, die Ansicht, daß die Gallen an Mais-und Reispflanzen eher von Insektentoxinen als von Pflanzenviren hervorgerufen werden.

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An abstract of this paper has been presented at the Annual Meeting of the Eastern Branch, Entomological Society of America, New York City, Nov., 1960.     

Attachment of the Flavescence doree pathogen (MLO) to leafhopper vectors and other insects

Flavescence doree (FD) is an important yellows disease of grapevine, caused by mycoplasma-like-organism (MLO) and is transmitted in the field by the leafhopper Scaphoideus titanus Ball. It can be transmitted in the laboratory between Vicia faba test plants by the leafhopper, Euscelidius variegatus Kbm. A technique to identify a specific attachment system between the MLO and the leafhopper vectors was developed. In this method, called “Double Dot”, extracts of macerated healthy whole insects or organs applied to a support membrane or cryosections of healthy whole leafhoppers, are incubated with a MLO-enriched extract from FD-infected V. faba or FD-infected E. variegatus. Attached MLO cells were identified by immunolabelling using FD-MLO specific monoclonal antibodies. Attachment of MLO cells was obtained on extracts of healthy S. titanus and E. variegatus and on tissues such as salivary glands, hemolymph and alimentary tract. On cryosections, MLO attachment was obtained on acini IV and V of the salivary glands and on some acini III, on the ventriculus of the alimentary tract, and on the abdomen fat bodies. “Double dot” experiments were done using other insect species, and MLO cells attachment was obtained on most MLO-vector insects but also on insects from a few non-vector species.