Leafhopper Feeding Research Articles

Acylsugars, Nicotine and a Protease Inhibitor Provide Variable Protection for Nicotiana benthamiana in a Natural Setting.

Plants produce an immense diversity of defensive specialized metabolites. However, despite extensive functional characterization, the relative importance of different defensive compounds is rarely examined in natural settings. Here, we compare the efficacy of three Nicotiana benthamiana defensive compounds, nicotine, acylsugars and a serine protease inhibitor, by growing plants with combinations of knockout mutations in a natural setting, quantifying invertebrate interactions and comparing relative plant performance. Among the three tested compounds, acylsugars had the greatest defensive capacity, affecting aphids, leafhoppers, spiders and flies. Nicotine mutants displayed increased leafhopper feeding and aphid colonization. Plants lacking both nicotine and acylsugars were more susceptible to flea beetles and thrips. By contrast, knockout of the serine protease inhibitor did not affect insect herbivory in the field. Complementary experiments under controlled laboratory conditions with caterpillars, grasshoppers and aphids confirmed results obtained in a natural setting. We conclude that the three metabolite groups collectively provide broad-spectrum protection to N. benthamiana. However, there is a gradient in their effects on the interacting invertebrates present in the field. Furthermore, we demonstrate that, even if individual metabolites do not have a measurable defensive benefit on their own, they can have an additive effect when combined with other defensive compounds.

Scavenging H2O2 of plant host by saliva catalase of leafhopper vector benefits viral transmission.

Catalase (CAT) is the main reactive oxygen species (ROS)-scavenging enzyme in plants and insects. However, it remains elusive whether and how insect saliva CAT suppresses ROS-mediated plant defense, thereby promoting initial virus transmission by insect vectors. Here, we investigated how leafhopper Recilia dorsalis catalase (RdCAT) was secreted from insect salivary glands into rice phloem, and how it was perceived by rice chaperone NO CATALASE ACTIVITY1 (OsNCA1) to scavenge excessive H2O2 during insect-to-plant virus transmission. We found that the interaction of OsNCA1 with RdCAT activated its enzymatic activity to decompose H2O2 in rice plants during leafhopper feeding. However, initial insect feeding did not significantly change rice CATs transcripts. Knockout of OsNCA1 in transgenic lines decreased leafhopper feeding-activated CAT activity and caused higher H2O2 accumulation. A devastating rice reovirus activated RdCAT expression and promoted the cosecretion of virions and RdCAT into leafhopper salivary cavities and ultimately into the phloem. Virus-mediated increase of RdCAT secretion suppressed excessive H2O2, thereby promoting host attractiveness to insect vectors and initial virus transmission. Our findings provide insights into how insect saliva CAT is secreted and perceived by plant chaperones to suppress the early H2O2 burst during insect feeding, thereby facilitating viral transmission.

Proteomic Analysis of Salivary Secretions from the Tea Green Leafhopper, Empoasca flavescens Fabrecius.

Saliva plays a crucial role in shaping the compatibility of piercing-sucking insects with their host plants. Understanding the complex composition of leafhopper saliva is important for developing effective and eco-friendly control strategies for the tea green leafhopper, Empoasca flavescens Fabrecius, a major piercing-sucking pest in Chinese tea plantations. This study explored the saliva proteins of tea green leafhopper adults using a custom collection device, consisting of two layers of Parafilm stretched over a sucrose diet. A total of 152 proteins were identified using liquid chromatography-tandem mass spectrometry (LC-MS/MS) following the filter-aided sample preparation (FASP). These proteins were categorized into six groups based on their functions, including enzymes, transport proteins, regulatory proteins, cell structure proteins, other proteins, and unknown proteins. Bioinformatics analyses predicted 16 secreted proteins, which were successfully cloned and transcriptionally analyzed across various tissues and developmental stages. Genes encoding putative salivary secretory proteins, including Efmucin1, EfOBP1, EfOBP2, EfOBP3, Efmucin2, low-density lipoprotein receptor-related protein (EfLRP), EFVg1, and EFVg2, exhibited high expressions in salivary gland (SG) tissues and feeding-associated expressions at different developmental stages. These findings shed light on the potential elicitors or effectors mediating the leafhopper feeding and defense responses in tea plants, providing insights into the coevolution of tea plants and leafhoppers. The study's conclusions open avenues for the development of innovative leafhopper control technologies that reduce the reliance on pesticides in the tea industry.

Leafhopper salivary vitellogenin mediates virus transmission to plant phloem

Salivary effectors of piercing-sucking insects can suppress plant defense to promote insect feeding, but it remains largely elusive how they facilitate plant virus transmission. Leafhopper Nephotettix cincticeps transmits important rice reovirus via virus-packaging exosomes released from salivary glands and then entering the rice phloem. Here, we report that intact salivary vitellogenin of N. cincticeps (NcVg) is associated with the GTPase Rab5 of N. cincticeps (NcRab5) for release from salivary glands. In virus-infected salivary glands, NcVg is upregulated and packaged into exosomes mediated by virus-induced NcRab5, subsequently entering the rice phloem. The released NcVg inherently suppresses H2O2 burst of rice plants by interacting with rice glutathione S-transferase F12, an enzyme catalyzing glutathione-dependent oxidation, thus facilitating leafhoppers feeding. When leafhoppers transmit virus, virus-upregulated NcVg thus promotes leafhoppers feeding and enhances viral transmission. Taken together, the findings provide evidence that viruses exploit insect exosomes to deliver virus-hijacked effectors for efficient transmission.

Colladonus spp. (Hemiptera: Cicadellidae) vectors of X-disease: biology and management in Western United States

Abstract The US cherry and stone fruit industries have periodically experienced devastating outbreaks of X-disease phytoplasma (XDP) since the 1930s, with an ongoing epidemic occurring since 2010. This disease is critically impacting Prunus spp. and the stone fruit industry, causing underdeveloped, bitter, and misshapen fruit on economically important crops, primarily cherries, peaches, and nectarines, making the fruit unmarketable. Trees cannot recover from this disease and eventually die if they are not removed. It takes at least 1 yr for symptoms to appear, postinfection, which hinders disease management efforts. The phytoplasma, Candidatus Phytoplasma pruni, is a phloem-limited intracellular bacterium that is spread by grafting and leafhopper (Hemiptera: Cicadellidae) feeding. Several leafhopper species are known to transmit XDP, of which Colladonus spp. are considered the most important vectors in the Western United States and are native to this region. Colladonus spp. feed and oviposit on a wide variety of broadleaf perennial plants, including mallow, alfalfa, and clover. These plants are also hosts of the phytoplasma. In Western United States, these leafhoppers have 3 periods of adult activity: May–June, late July–August, and October. The highest rates of pathogen transmission likely occur during the last 2 activity periods due to the high abundance of leafhoppers and a postharvest increase of XDP titers in trees. Using known activity periods and host plants of the leafhoppers, growers can monitor and strategically manage the vectors, which, when combined with the removal of infected trees and ground-cover hosts, should help limit the spread of X-disease.

Tea green leafhopper-induced synomone attracts the egg parasitoids, mymarids to suppress the leafhopper.

The tea green leafhopper, Empoasca flavescens is the most important pest of tea plants in China. Mymarid attractants based on herbivore-induced plant volatiles (HIPVs) from leafhopper feeding and oviposition-induced plant volatiles (OIPVs) were formulated and tested as a novel pest control agent against the leafhopper in tea plantations. Results showed that two mymarid species, Stethynium empoascae and Schizophragma parvula, had a reducing effect on leafhopper populations. The HIPVs and OIPVs were identified and bioassayed to screen the key synomones showing strong attraction to the mymarids. They were formulated into different blends, of which Field Attractant 1, comprising linalool, methyl salicylate, (E)-2-hexenal, perillen and α-farnesene at ratio of 1:2:3:58:146 (20 mg/lure), showed the strongest attraction to the mymarids. In field trials with the attractant, the average parasitism rate (60.46 ± 23.71%) of tea leafhoppers by the two mymarids in the attractant-baited area was significantly higher than that (42.85 ± 19.24%) in the CK area. Also, the average leafhopper density (46 ± 30 per 80 tea shoots) in the attractant-baited area was significantly lower than that (110 ± 70 per 80 tea shoots) in the CK area. This study showed that a synthetic blend of key volatiles from HIPVs and OIPVs at an optimal ratio can be formulated into an attractant with the potential to attract and retain wild mymarid populations to suppress leafhopper populations in infested tea plantations, so as to reduce or avoid the spraying of insecticides. © 2023 Society of Chemical Industry.

Does grape leafhopper Arbordia hussaini (Hemiptera: Cicadellidae) effect on chlorophyll content of grape leaves?

The leafhopper Arbordia hussaini is a phloem feeding pest of the grape leaves causing a drop in chlorophyll levels in the grape leaves, which decreases photosynthesis and causes drying of the leaves depend on the population density of insects and found in various grape varieties growing around the world. The direct effects of A. hussaini on biomass dynamics, particularly the chlorophyll content of grapevine leaves, are investigated in this study. the high population of A. hussaini were 19.33 insect adult per grape leave in the first of September, while the low density of A. hussaini was 0.11 insect adult per grape leave at the end of December that trapped in blue sticky trap. The high density of leafhopper was recorded on the variety of Kamali followed by the variety of Halawani and Faranci. Chemical analysis of the chlorophyll content between the uninfested and infested grape leaves with the grape leafhopper showed decreasing of chlorophyll content and has been given 19.03 and 15.11 mg/L of the Halawani variety for the uninfested and infested leaves, respectively. Whereas, th mean of chlorophyll content of uninfested and infested leaves was 24.63 and 18.85 mg/L for Faranci variety, respectively. Moreover, the comparession of chlorophyll content between uninfested and infested Kamali leaf variety was 23.69 and 12.30 mg/L, respectively. Finally, depending on the degree of the attack, the grapevine response to A. hussaini infestation that affects on grape leaves and photosynthesis. This research shows that leafhopper feeding on tree sap has a significant direct impact on the chlorophyll content of grape leaves.

Leafhopper feeding behaviour on three grapevine cultivars with different susceptibilities to Flavescence dorée

Scaphoideus titanus (Ball) is a grapevine-feeder leafhopper, and the most important vector of Flavescence dorée of grapevine (FD), a disease associated with phytoplasmas belonging to ribosomal subgroups 16Sr-V–C and –D. FD is a major constraint to viticulture in several European countries and, so far, its control has relied on roguing of infected plants and insecticide applications against the vector. Detailed knowledge on different levels of the multifaceted phytoplasma-plant-vector relationship is required to envisage and explore more sustainable ways to control the disease spread. In the present work, S. titanus feeding behaviour was described on three grapevine cultivars: Barbera (susceptible to FD), Brachetto, and Moscato (tolerant to FD) using the Electrical Penetration Graph (EPG) technique. Interestingly, no differences were highlighted in the non-phloem feeding phases, thus suggesting that the tested cultivars have no major differences in the biochemical composition or structure of the leaf cuticle, epidermis or mesophyll, that can affect the first feeding activities. On the contrary, the results showed significant differences in leafhopper feeding behaviour in terms of the duration of the phloem feeding phase, longer on Barbera and shorter on Brachetto and Moscato, and of the frequency of interruption-salivation events inside the phloem, higher on Brachetto and Moscato. These findings indicate a possible preference for the Barbera cultivar, a better host for the leafhopper. Scaphoideus titanus feeding behaviour on Barbera correlates with an enhanced FDp transmission efficiency, thus explaining, at least in part, the higher susceptibility of this cultivar to FD. The mechanisms for the possible non-preference for Brachetto and Moscato are discussed, and an antixenosis is hypothesized. We propose that breeding for resistance against FD should take into account both plant traits associated with the response to the phytoplasmas and to the vector.

First report on clover proliferation phytoplasma related strain associated with Matthiola incana floral virescence in Uttar Pradesh, India.

Matthiola incana R. Br. (Fam: Brassicaceae) is an ornamental, commonly known as hoary stock has an extremely fragrant flowers, which blooms in dense clusters in a large variety of colors. During a survey of flower nurseries in March 2019 at Indian Institute of Sugarcane Research campus, Lucknow, floral virescence (MiV) symptoms (Fig. 1 A, B) were observed in M. incana pots with an incidence of over 40%. Leaf yellows symptoms were also observed on a weed Acalypha indica (AiLY) in Matthiola nursery (Fig. 1 C). Nested PCR assays were carried out to detect and identify the possible association of phytoplasmas with MiV and AiLY symptoms. Three each of symptomatic MiV and AiLY samples and two non-symptomatic samples were collected and processed for DNA extraction from the leaf midrib by CTAB method. Hishimonus phycitis (HP) (Hemiptera: Cicadellidae) leafhopper feeding on MiV symptomatic plants was also collected and DNA was extracted. The DNA of 8 symptomatic and 4 non-symptomatic plants and from the 10 leafhopper was used as a template for PCR assays. Phytoplasma specific 16Sr RNA gene specific primers (P1/P7 and 3Far/3Rev; Schneider et al. 1995; Manimekalai et al. 2010) and multilocus genes' specific primer pairs for secA (SecAfor1/SecArev3;SecAfo5r/SecARev2; Bekele et al. 2011), secY (SecYF1(VI)/SecYR1(VI);SecYF2(VI)/SecYR1(VI); Lee et al. 2010) and rp genes (rpFIC/rp(I)R1A; rp(VI)F2/ rp(VI)R2; Martini et al. 2007) were employed as previously described. Amplified products of ~1.3kb, ~600bp, ~1.7kb and ~1.0kb of 16S rRNA, secA, secY and rp genes of phytoplasma were consistently amplified in all the MiV and AiLY samples and in the HP leafhopper. No amplifications were achieved in any of the asymptomatic plant samples. Amplified products of all the four genes of MiV, AiLY and HP isolates were purified, sequenced and submitted in GenBank. Sequence comparison and phylogeny analysis of the sequences of the four genes of MiV, AiLY and HP isolates revealed 99% - 100% sequence identity and clustering with clover proliferation phytoplasma related strains (16SrVI group)(Fig.2 A,B,C and D). The virtual RFLP analysis of 17 restriction endonucleases corresponding to the 16S rDNA sequence of MiV, AiLY and HP phytoplasma strains by pDraw program, assigned them into a novel phytoplasma subgroup strain under 16SrVI group, since its HpaII restriction profile was different to earlier classified 16SrVI subgroups but was very close to16SrVI-E subgroup (GenBank acc. no. AY270156) (Fig 3). Earlier, peanut witches' broom (16SrII-A) phytoplasma was identified associated with M. incana from Italy (Davino et al. 2007). However, the association of clover proliferation phytoplasma (16SrVI) related strain associated with virescence symptom of M. incana is the first report in world. The weed (A. indica) and HP leafhopper were also reported as additional hosts of 16SrVI subgroup related new strain in India, which needs further investigation. The report of a new host and new subgroup of clover proliferation phytoplasma related strain in India is having an epidemiological significance and warrants attention.

Defensive Responses of Tea Plants (Camellia sinensis) Against Tea Green Leafhopper Attack: A Multi-Omics Study.

Tea green leafhopper [Empoasca (Matsumurasca) onukii Matsuda] is one of the most devastating pests of tea plants (Camellia sinensis), greatly impacting tea yield and quality. A thorough understanding of the interactions between the tea green leafhopper and the tea plant would facilitate a better pest management. To gain more insights into the molecular and biochemical mechanisms behind their interactions, a combined analysis of the global transcriptome and metabolome reconfiguration of the tea plant challenged with tea green leafhoppers was performed for the first time, complemented with phytohormone analysis. Non-targeted metabolomics analysis by ultra-performance liquid chromatography quadrupole time-of-flight mass spectrometry (UPLC-QTOF MS), together with quantifications by ultra-performance liquid chromatography triple quadrupole mass spectrometry (UPLC-QqQ MS), revealed a marked accumulation of various flavonoid compounds and glycosidically bound volatiles but a great reduction in the level of amino acids and glutathione upon leaf herbivory. RNA-Seq data analysis showed a clear modulation of processes related to plant defense. Genes pertaining to the biosynthesis of phenylpropanoids and flavonoids, plant-pathogen interactions, and the biosynthesis of cuticle wax were significantly up-regulated. In particular, the transcript level for a CER1 homolog involved in cuticular wax alkane formation was most drastically elevated and an increase in C29 alkane levels in tea leaf waxes was observed. The tea green leafhopper attack triggered a significant increase in salicylic acid (SA) and a minor increase in jasmonic acid (JA) in infested tea leaves. Moreover, transcription factors (TFs) constitute a large portion of differentially expressed genes, with several TFs families likely involved in SA and JA signaling being significantly induced by tea green leafhopper feeding. This study presents a valuable resource for uncovering insect-induced genes and metabolites, which can potentially be used to enhance insect resistance in tea plants.

Discovery of the transantarctic distribution of the genus Metanteon Olmi(Hymenoptera: Dryinidae), with description of a new species from New Caledonia.

Metanteon poirieri sp. nov. (Hymenoptera: Dryinidae: Anteoninae) is described from New Caledonia. The genus Metanteon Olmi, 1984, was known only from the southern region of Argentina and Chile. The unique species attributed previously to this genus is M. aerias (Walker, 1839), collected in Chile by Charles Darwin during his famous trip on the HMS Beagle. M. aerias is associated only with leafhoppers feeding on Southern Beeches (Nothofagus spp.), a genus of Nothofagaceae including species of trees and shrubs native to the southern Hemisphere in southern South America (Argentina, Chile) and Australasia (east and southeast Australia, New Zealand, New Guinea and New Caledonia). Like Nothofagus, Metanteon is a transantarctic organism.

Short-Term Physiological Response of a Native Hawaiian Plant, Hibiscus arnottianus, to Injury by the Exotic Leafhopper, Sophonia orientalis (Hemiptera: Cicadellidae).

Sophonia orientalis (Matsumura), also known as the two-spotted leafhopper, is a widespread exotic pest of many economically important crop plants and ornamental plants in Hawaii. Sophonia orientalis is highly polyphagous and is a major threat to some of the native endemic plants. Despite the successful establishment in Hawaii, interactions of S. orientalis with its host plants remain poorly understood. Previous studies primarily focused on distribution, parasitism, and oviposition of S. orientalis in Hawaii, whereas plant physiological responses to the leafhopper's injury, and, specifically, gas exchange rates in plants, have not yet been described. In this study, we examined a short-term physiological response of a native Hawaiian plant, Hibiscus arnottianus (A. Gray), to injury by S. orientalis. We also explored whether Camellia sinensis (L.) Kuntze, a native host plant of S. orientalis in Asia, exhibits a similar response. We found that H. arnottianus plants demonstrated a rapid (2-d) physiological response to injury accompanied by 40% reduction in rate of photosynthesis and 42% reduction in rate of transpiration, whereas C. sinensis did not exhibit any reduction in gas exchange rates. We did not record any changes in plant chlorophyll levels after plant injury in either species. Our results suggest that H. arnottianus is responding to the leafhopper feeding with a generalized wound response predicted for novel plant-insect herbivore associations. We discuss potential future directions for studies which might focus on host plant responses to S. orientalis in its native versus introduced range.

Physiological and biochemical responses of Camellia sinensis to stress associated with Empoasca vitis feeding

The tea green leafhopper, Empoasca vitis, is the most serious pest in plantations of tea, Camellia sinensis. Beyond physical damage to the leaves, tea yields may be affected if feeding stress causes physiological and biochemical changes in the tea plant, which affected the quality and flavor of the tea. Yet the effect of feeding stress, induced by E. vitis, is largely unknown. We measured the injury index and the physiological and biochemical responses of C. sinensis to stress by E. vitis feeding in a series of laboratory trials. Using 2-year-old C. sinensis plants, we tested the effects of leafhopper feeding at different densities—0, 5, 10, and 20 leafhoppers—and different durations of exposure—1, 4, 7, and 10 days—on potential changes in chlorophyll, tea polyphenols, nutrient content, activities of protective enzymes (peroxidase, POD; superoxide dismutase, SOD; and catalase, CAT), and the lipid peroxidation (MDA). We found that the injury indices for tea leaves increased continuously as the density of E. vitis increased in the same day, and simultaneously, as the time of leafhoppers damage increased, the injury indices for tea leaves also increased. Our results also indicated that feeding by E. vitis caused a considerable decline in chlorophyll a, chlorophyll b, total chlorophyll in tea leaves and soluble carbohydrate content, and an increase in tea polyphenols. Soluble protein content showed a direct increasing relationship with the increasing leafhopper density and the duration of exposure. Throughout the period of E. vitis exposure, there was highly significant difference in the activities of protective enzymes and MDA content. Additionally, POD, SOD, and CAT activities in tea leaves were elevated significantly with the increase of leafhopper density. Lipid peroxidation (MDA) content also increased after the exposure to leafhopper feeding. Overall, our results indicate that although C. sinensis displays a certain level of tolerance to E. vitis feeding stress, higher density of leafhoppers, and longer exposure duration, can cause severe damage to tea leaves and also a decline in plant defense of tea, so as to affect the tea quality.

Genome Sequences of Beet curly top Iran virus, Oat dwarf virus, Turnip curly top virus, and Wheat dwarf virus Identified in Leafhoppers.

ABSTRACTImplementation of a vector-enabled metagenomics approach resulted in the identification of various geminiviruses. We identified the genome sequences of Beet curly top Iran virus, Turnip curly top viruses, Oat dwarf viruses, the first from Iran, and Wheat dwarf virus from leafhoppers feeding on beet, parsley, pumpkin, and turnip plants.

Discovery of the genus Mirodryinus Ponomarenko, 1972 (Hymenoptera, Chrysidoidea, Dryinidae) associated with salt cedar trees in the eastern part of Iran

In 2015 and 2016 a survey was carried out on the parasitoids of leafhoppers (Hemiptera, Cicadomorpha) feeding on salt cedar trees (Tamarix spp.) growing around Hamoon Lake in the Sistan region (Iran). Among the collected material, a series of dryinid specimens belonging to Mirodryinus atlanticus Olmi, 1984 (Hymenoptera, Dryinidae, Bocchinae) was captured on branches of Tamarix aphylla (L.) Karst. and Tamarix stricta Boiss., infested by Opsius versicolor (Distant) (Hemiptera, Cicadellidae). The subfamily Bocchinae and the genus Mirodryinus Ponomarenko, 1972 are new records for Iran. Diagnostic characters and notes on the morphological variability of the newly collected specimens are presented and discussed.

Comparison of tree genotypic diversity and species diversity effects on different guilds of insect herbivores

Although the effects of plant diversity on herbivores are contingent upon herbivore traits and the source of plant diversity (e.g. intra‐ and interspecific), most studies have analyzed these effects separately. We compared the effects of genotypic diversity of big‐leaf mahogany Swietenia macrophylla with that of tree species diversity on two specialist caterpillars (Hypsipyla grandella stem borers and Phyllocnistis meliacella leaf miners) and three generalist leafhoppers (Cicadellidae) feeding on mahogany in a large‐scale (7.2 ha) forest diversity experiment in southern Mexico. The experiment consisted of fifty‐nine 21 × 21‐m plots, with 64 tree saplings each (3‐m spacing between plants). Plots were either mahogany monocultures or species polycultures of four species (including mahogany) and – within each of these two plot types – mahogany was represented by either one or four genotypes. Throughout a five‐month period, beginning six months after planting, we measured mahogany growth and monitored herbivore and predator (spider) abundance. We found no effect of mahogany genotypic diversity on either specialist caterpillars or generalist leafhoppers, and this result was consistent across levels of tree species diversity. In contrast, species diversity had significant effects on both specialists but neither of the generalist herbivores. Specifically, species diversity lowered H. grandella attack at the middle of the sampling season, but increased attack at the end of the season, whereas P. meliacella abundance was consistently reduced. Such effects were not mediated by effects of species diversity on plant growth (of which there were none), but rather through resource heterogeneity. Diversity did not influence spider abundance. This study is one of few to directly compare sources of plant diversity, and uniquely compares such effects among herbivores with contrasting life histories (e.g. diet breadths). Overall, we demonstrate that plant species diversity effects outweigh those of genotypes, and our results suggest that such effects are stronger on specialist than generalist herbivores.

Probing behavior of Empoasca vitis (Homoptera: Cicadellidae) on resistant and susceptible cultivars of tea plants.

Feeding activities of the tea green leafhopper, Empoasca vitis (Gothe) (Homoptera: Cicadellidae), on resistant and susceptible cultivars of tea plants (Camellia sinensis L.) were recorded and analyzed using the direct current electrical penetration graph (EPG) system. Six distinct EPG waveforms characterizing the feeding behavior of the tea green leafhopper, categorized as waveforms A, C, E, S, F, and R, were obtained during the investigation. Duration of passive ingestion, possibly of phloem (E), was the longest among all the probing waveforms on susceptible cultivars, whereas durations of the salivation (S) waveform and stylet work waveform (F) became longer on resistant cultivars. The durations of waveforms S and F on the resistant cultivar Jiandecha were slightly longer than those on the less resistant cultivar Yunguidaye , and both were significantly longer than those on the susceptible cultivars Hangzhoudaye and Zhushan-1 . Waveform E was shorter on the resistant cultivar Jiandecha than on the less resistant cultivars Yunguidaye and was significantly shorter than on the susceptible cultivars ( Hangzhoudaye and Zhushan-1 ). It is suggested that E, S, and F are the important waveforms related to leafhopper feeding behavior and tea plant resistance. Based on the results, the resistance levels of tea cultivars against the tea leafhopper can be evaluated quickly by direct current EPG.

EFFECTS OF SAGE LEAFHOPPER FEEDING DAMAGE ON HERBAGE COLOUR, ESSENTIAL OIL CONTENT AND COMPOSITIONS OF TURKISH AND GREEK OREGANO

SUMMARYTurkish (Origanum onites L.) and Greek oregano (Origanum vulgare L., ssp. hirtum (Link.) Ietswaart) species were investigated to determine herbage colour, essential oil content and composition changes due to sage leafhopper (Eupteryx melissae) (Hemiptera: Cicadellidae) infestation. Sage leafhopper population on both Turkish and Greek oregano did not significantly vary. The sage leafhopper damage was more severe in the lower part of the canopy than the middle and upper parts. Extensive sage leafhopper feeding dramatically reduced essential oil contents, resulting in 28.8 and 34.8% reductions for Greek and Turkish oregano, respectively. Carvacrol, the major essential oil component of both oregano species, did not remarkably vary between leafhopper infested and non-infested plants. With respect to herbage colour, the brightness, redness and yellowness values were significantly different between infested and non-infested plants. Sage leafhopper damage increased brightness and yellowness but decreased greenness of the oregano herbage. To avoid the feeding damage, it is essential to detect the sage leafhopper problem as early as possible and certain control practices are necessary when the infestation is high.

Application of Vascular Puncture for Evaluation of Curtovirus Resistance in Chile Pepper and Tomato

AbstractCurtoviruses cause severe damage to tomatoes and peppers. Functional field resistance to curtoviruses in these plants is desirable but difficult to produce and difficult to screen for because it is time‐consuming and resistance could be achieved by developing resistance either to the virus or to insect feeding. To improve and speed curtovirus resistance testing in tomato (Solanum lycopersicum) and pepper (Capsicum annuum) plants, two puncture methods were developed and compared to leafhopper inoculation and feeding preference assays. The two puncture methods were adapted to introduce a modified Agrobacterium tumefaciens plasmid carrying a recombinant curtovirus into the meristem tissue of tomato plants and into newly germinated chile pepper seedlings. The puncture techniques were used to screen for resistance to curtoviruses in chile pepper and tomato breeding lines and varieties. Similarly, the peppers and tomatoes were assayed for curtovirus resistance using leafhopper inoculation and feeding preference, which was assessed by stylet sheath staining. Virus infection by puncture and leafhopper feeding was monitored using PCR and ELISA. ELISA was performed using an antibody to bacterially expressed coat protein. While pepper cvs Tabasco, NuMex Las Cruces cayenne and New Mexico 6‐4 were infected using both puncture and leafhopper inoculation methods, New Mexico 6‐4 had higher infection rates than the other two cultivars. Stylet sheath staining results suggest that leafhoppers prefer to feed on New Mexico 6‐4 rather than Tabasco and NuMex Las Cruces cayenne. Eight tomato cultivars were infected using meristem removal injection inoculation. Three tomatoes cultivars (CVF‐11, Saladmaster and Supersteak) were infected using leafhopper inoculation, although stylet sheath staining results suggested that the first two cultivars were not preferred by the insect vector. Our results suggest that puncture methods and leafhopper inoculation are successful in resistance screening, and both methods should be used as part of screening, because they assess different types of resistance.

Identification of up-regulated genes in tea leaves under mild infestation of green leafhopper

Transcriptional changes accompany induced resistance of plants against insect feeding, and monitoring transcriptional reorganization triggered in response to herbivory is an essential step for deciphering the molecular basis of the resistance. To isolate up-regulated genes in tea leaves under mild infestation of green leafhopper ( Empoasca vitis Göthe), a subtractive cDNA library was constructed using the suppression subtractive hybridization strategy. Subsequent differential screening, DNA sequencing analyses, and real-time PCR analyses identified 21 unique genes up-regulated by leafhopper feeding from the library. Among the genes likely to be directly involved in defense, those encoding pathogen-related protein and type 2 ribosome-inactivating protein were found in the subtractive library. In addition, genes involved in the CBL (calcineurin B-like)–CIPK (CBL-interacting protein kinases) pathway, cell wall fortification, secondary metabolite synthesis, water transport, and oxidative stress protection were identified in our experiment. Besides, a number of genes that have not been previously associated with defense responses against insects were isolated.