Corn Stunt Spiroplasma in the Leafhopper Euscelidius variegatus

Corn stunt spiroplasma (CSS) multiplied in all leafhoppers Euscelidius variegatus injected with a culture of CSS, reaching titres of over 1x10⁶ colony forming units (cfu) per insect and 2x10⁴ cfu per salivary gland of each insect. CSS could be isolated from the haemolymph and the salivary glands at any time after injection. The growth of CSS in culture was inhibited by insect extract at concentrations greater than the equivalent of 0.1 insect/ml. Transmission of CSS to sterile feeding solution and to broad beans were compared using 24 h feeding periods. A porportion of 1.7 % of injected leafhoppers began to transmit to sterile feeding solution through membranes by the 4th day after injection, and reached a maximum of 30 % by day 14. Similar insects started transmitting to broad bean plants on day 12 (2 %), reaching a maximum of 7.5 % by day 14. The number of spiroplasmas transmitted by each insect to sterile feeding solution increased from 3, cfu on day 4 to a maximum of 80 cfu by day 14. Helices were seen in the haemolymph at any time after injection. However, partially deformed cells were not present until the 1st week and clumps of 3–4 cells and small aggregates until the 3rd week after injection. The salivary glands of injected insects contained membrane-bound “pockets” or “colonies” packed with pleomorphic, filamentous (helical and non-helical) cells and aggregates. Intracellular colonies were always at the periphery of the acini and were easily detectable by fluorescence microscopy after staining with a DNA-binding fluorescent stain. Pleomorphic and filamentous cells were also seen intercellularly in the salivary glands.     

Acquisition and transmission of corn stunt spiroplasma by its leafhopper vector Dalbulus maidis

As the acquisition access period of Dalbulus maidis on infected maize increased from 15 min to 7 days, the incubation period of corn stunt spiroplasma (CSS) in the insect decreased from 27 days to 8 days and the final proportion of transmitting insects increased from 5% to 100%. After 7 days access the median incubation period (IPsO) was 14.3 days (IP₅₀ females = 12.9 days: IP₅₀ males =16.8 days), while the proportion of transmitting insects increased from 4. 3% (9 days after the start of acquisition access) to a maximum of 93% (after 22 days), before decreasing. Females started transmitting significantly earlier and a greater proportion transmitted each day than males, until day 22 when both sexes transmitted equally. Of the insects which transmitted CSS, 29% did so continuously until death; 66% failed to transmit during the last 1–3 days, and 5% transmitted intermittently towards the end of their life. During daily transfer, females were more likely to infect plants consecutively (up to 25) than males, and females infected the higher proportion of test plants. As the transmission access period was increased from 1 h to 72 h, the proportion of transmitting insects increased from 22.5% to 97.3% and the incubation period in maize decreased.     

Multiplication and morphology of Spiroplasma citri in the leafhopper Euscelis plebejus

Spiroplasma citri multiplied in all Euscelis plebejus leaf hoppers injected and sometimes reached titres of over 1 × 10⁷ colony forming units per insect. Spiroplasmas could be isolated from the haemolymph at all times although helices were only apparent for a few days after injection. The salivary glands of injected insects contained membrane bound pockets densely packed with mycoplasma-like bodies. These bodies were frequently infected with virus-like particles similar to those found in cultures of S. citri. Spiroplasmas had little effect on the longevity of the leafhoppers.     

Protein metabolism by the salivary glands and other organs of the larva of the blowfly, Calliphora erythrocephala

Protein metabolism in salivary glands, gut, haemolymph, and fat body during the last larval instar of the blowfly, Calliphora erythrocephala, has been investigated. In salivary glands, protein release, protein synthesis, amylase, and pepsin-like protease activity were maximal in 6 day larvae, this being at a time when the larvae had finished feeding. All these functions declined in glands from the rounded-off white puparial stage (R.O.) while acid phosphatase activity rose throughout the third instar to a maximum at the R.O. stage, Glands from 6 and 7 day larvae released protein which on disk gel electrophoresis separated into four minor bands and two major bands one of the latter possessing protease activity.In the gut, pepsin-like protease activity was maximal in 4 day larvae after which it fell rapidly thus following the feeding pattern of the larva in contrast to that in the salivary glands which did not.In vitro experiments showed that protease was released from 6 day glands through the basal membrane of the cells and not via the duct. A pepsin-like protease was also found in the haemolymph and fat body, the activity in the fat body rising rapidly during the latter part of the third instar, a rise which is attributed to the fat body sequestering protease from the haemolymph. Acid phosphatase activity in the fat body was maximal in 5 day larvae indicating that this enzyme was synthesized early in the third instar. It was shown that fat body sequestered ¹⁴C-labelled protein synthesized by and released from the salivary glands, most of the ¹⁴C activity being associated with a 600 g precipitable, acid-phosphatase rich fraction.It is proposed that in late third instar larvae the salivary glands function as glands of internal secretion, releasing protease into the haemolymph, which is then sequestered by the fat body (and perhaps other tissues) and is subsequently used in the lysis of the tissues at the time of metamorphosis.     

Fate of ingested β-indolyl acetic acid in Creontiades dilutus

The insects were fed with β-indolyl (acetic acid-2-C¹⁴) and amaranth, and the distribution, amount, and chemical status of C¹⁴ in the insects and their excreta was investigated after 24 hr. From the amount of diet ingested (calculated from the amount of dye recovered), between 67 and 80% of the radioactivity was recovered, and between 80 and 95% of this had already been excreted. Up to 0.2% of the C¹⁴ recovered was present in the salivary glands. Most of the ingested IAA was metabolized, however, and the amount of IAA present in the salivary glands was less than 0.01% of that ingested. An insect could produce a maximum volume of less than 0.1 μl saliva, without further feeding, i.e. about the combined volume of the salivary reservoirs. The concentration of IAA in the reservoirs was of the order of 100 times less than that in the ingesta. It is concluded that salivary IAA is unlikely to play a major role in the phytotoxicity of this insect, as long as it feeds consistently on similar plant tissues.     

Transgenerational Transmission of the Glossina pallidipes Hytrosavirus Depends on the Presence of a Functional Symbiome

The vertically transmitted endosymbionts (Sodalis glossinidius and Wigglesworthia glossinidia) of the tsetse fly (Diptera: Glossinidae) are known to supplement dietary deficiencies and modulate the reproductive fitness and the defense system of the fly. Some tsetse fly species are also infected with the bacterium, Wolbachia and with the Glossina hytrosavirus (GpSGHV). Laboratory-bred G. pallidipes exhibit chronic asymptomatic and acute symptomatic GpSGHV infection, with the former being the most common in these colonies. However, under as yet undefined conditions, the asymptomatic state can convert to the symptomatic state, leading to detectable salivary gland hypertrophy (SGH⁺) syndrome. In this study, we investigated the interplay between the bacterial symbiome and GpSGHV during development of G. pallidipes by knocking down the symbionts with antibiotic. Intrahaemocoelic injection of GpSGHV led to high virus titre (10⁹ virus copies), but was not accompanied by either the onset of detectable SGH⁺, or release of detectable virus particles into the blood meals during feeding events. When the F₁ generations of GpSGHV-challenged mothers were dissected within 24 h post-eclosion, SGH⁺ was observed to increase from 4.5% in the first larviposition cycle to >95% in the fourth cycle. Despite being sterile, these F₁ SGH⁺ progeny mated readily. Removal of the tsetse symbiome, however, suppressed transgenerational transfer of the virus via milk secretions and blocked the ability of GpSGHV to infect salivary glands of the F₁ progeny. Whereas GpSGHV infects and replicates in salivary glands of developing pupa, the virus is unable to induce SGH⁺ within fully differentiated adult salivary glands. The F₁ SGH⁺ adults are responsible for the GpSGHV-induced colony collapse in tsetse factories. Our data suggest that GpSGHV has co-evolved with the tsetse symbiome and that the symbionts play key roles in the virus transmission from mother to progeny.     

Effect of allatectomy on ecdysteroid-dependent development of Rhodnius prolixus larvae

the regulation of haemolymph titres of ecdysteroids during larval development of the bloodsucking bug, Rhodnius prolixus was studied. Corpus allatum ablation in 4th-instar larvae 1 day after feeding was reflected in an increase of the intermoult period and in a high level of ecdysial arrest. These effects could be corrected by juvenile hormone and ecdysone therapies. Comparison of the ecdysteroid titres in haemolymph determined in control and allatectomized larvae, at different intervals after feeding, showed that allatectomy drastically depressed the ecdysteroid levels. Juvenile hormone treatment reestablished ecdysteroid titres in the haemolymph of allatectomized insects. Isolated prothoracic glands from allatectomized larvae had a very low production of ecdysteroid-RIA-activity when compared with prothoracic glands from control or allatectomized larvae which received in vivo juvenile hormone treatment. The complexity of the corpus allatum-prothoracic glands interaction in Rhodnius post-embryonic development is discussed.     

Biochemical characterization of α- and β-glucosidases in alimentary canal, salivary glands and haemolymph of the rice green caterpillar, Naranga aenescens M. (Lepidoptera: Noctuidae)

The biochemical properties of ??- and ??-glucosidase in salivary glands, alimentary canal and haemolymph of Naranga aenescens larvae, one of the most damaging pests of the rice crop in Iran, were investigated. The specific activity of ??-glucosidases were 3.88, 2.74 and 1.58 ??mol/min per mg protein in the alimentary canal, salivary glands and haemolymph of last instar larvae, respectively. The specific activity of ??-glucosidases were 1.27, 0.077 and 0.414 ??mol/min per mg protein in the alimentary canal, salivary glands and haemolymph of last instar larvae, respectively. The optimal pH for ??-glucosidases were 6.0, 6.0?C8.0 and 6.0 and the maximum activity for ??-glucosidases were obtained at pH 6.0, 5.0?C7.0 and 5.0 in alimentary canal, salivary glands and haemolymph, respectively. The optimum temperatures for ??-glucosidases were determined at 55°C in alimentary canal, 35?C45°C in salivary glands and 55°C in haemolymph, whereas the ??-glucosidases reached their optimum at 45°C in all three tissues. Effect of metal ions on the activity of ??- and ??-glucosidases showed that K⁺ (20 mM) and Mg²⁺ (10 and 20 mM) increased N. aenescens ??- and ??-glucosidases activities from salivary glands, while Ca²⁺ increased ??- and ??-glucosidases activities in haemolymph. In the presence of Fe²⁺, Mn²⁺, Hg⁺ and Zn²⁺ (10, 20 mM) and Hg²⁺ (20 mM), these enzymes from all tissues were completely inactivated. K _m values were estimated for the ??-glucosidases as 3.96, 0.547 and 3.084 mM and for ??-glucosidases as 1.93, 1.014 and 1.93 mM in the alimentary canal, salivary gland and haemolymph, respectively. The zymogram analyses of N. aenescens crude extracts indicated the presence of at least two isoforms for ??-glucosidase and one isoform for ??-glucosidase.     

Distribution of velvet tobacco mottle virus in its mirid vector and its relationship to transmissibility

Following acquisition by feeding, velvet tobacco mottle virus (VTMoV) was detected in the gut, haemolymph and faeces of the mirid vector, Cyrtopeltis nicotianae, but not in the salivary glands. Virus antigen was detected in the gut and haemolymph for up to nine days following acquisition. Infective virus was detected in the secretions and excretions of the mirids immediately after acquisition and was also detected in the faeces of nymphs after six days. Insoluble nigrosin dye was eliminated intermittently from the gut up to six days after ingestion, in a manner similar to the loss of virus infectivity. Non-infective mirids were able to inoculate plants from infectious sap deposits on the upper epidermis. An ingestion-defecation model of insect transmission in which the salivary glands are not implicated is proposed as one explanation for the persistence of transmission in this mirid-virus association.     

Pharmacokinetics of chlorogenic acid and rutin in larvae of Heliothis zea

Studies using [³H]chlorogenic acid and [³H]rutin demonstrated that the kinetics of uptake of these plant phenolics into the haemolymph of 5th-instar Heliothis zea (Boddie) following actue oral administration is a first-order process. The total quantity of either phenolic present in the haemolymph within 1 hr amounts to 5% or less of the total ingested dose. Based on TLC analyses, 80% or more of the radioactivity in the haemolymph occurs as the parent phenolic. Retention of [³H]-chlorogenic acid or [³H]-rutin in H. zea following chronic feeding from 1st to 3rd-instar larvae is also linearly related to dietary dose. Chlorogenic acid and rutin are both equitoxic and equivalent in bioavailability to H. zea.Loss of [³H]-rutin from the haemolymph of 5th-instar larvae following injection is biphasic. One half of the injected dose is excreted in the frass in the first 6 hr after injection; the other half is thereafter eliminated at 1/20th of the initial rate. Analyses of extracts of frass by thin-layer chromatography indicate that after either chronic or acute feeding 90% of the ingested phenolic is excreted unchanged. Possible sites and modes of action of phenolics in insects are discussed in light of these findings.     

昆虫唾液成分在昆虫与植物关系中的作用

近年来,人们对于植食性昆虫唾液的深入研究,揭示出其在昆虫与植物的相互关系和协同进化中起到非常重要的作用。植食性昆虫唾液中含有的酶类和各种有机成分,能诱导植物的一系列生化反应,而且这些反应有很强的特异性,与为害的昆虫种类甚至龄期有关。鳞翅目幼虫口腔分泌物（或反吐液）中含有的β-葡糖苷酶、葡萄糖氧化酶等酶类和挥发物诱导素等有机成分,已经证明可以诱导植物的反应; 刺吸式昆虫的取食也可以刺激植物产生反应,但其唾液内的酶类,如烟粉虱的碱性磷酸酶, 蚜虫的酚氧化酶、果胶酶和多聚半乳糖醛酸酶, 蝽类的寡聚半乳糖醛酸酶等是否发挥作用,目前还没有直接的证据。寄主植物对昆虫的唾液成分也有很大的影响,可能是昆虫对不同植物营养成分和毒性成分的适应方式。对昆虫唾液蛋白的分析表明,具有同样类型口器、食物类型接近的昆虫,唾液成分有更多的相似性。研究植食性昆虫的唾液成分,对于阐明昆虫和植物的协同进化关系、昆虫生物型的形成机理、害虫的致害机理,以及指导害虫防治等,有着一定的理论和实际意义。     

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.     

Effect of 20-hydroxyecdysone on the salivary glands of the male tick,Amblyomma hebraeum

Female ticks (Acari: Ixodidae) feed only once in the adult stage, dying after laying a large batch of eggs. During the early post-engorgement stage, haemolymph ecdysteroid titre rises, which is probably responsible for autolysis of the salivary glands that takes place at this time. Males, on the other hand, can re-attach and feed numerous times during the adult stage. Males were fed on rabbits for either 7 or 14 days. Haemolymph was collected either the day of removal from the host or 4 days later, and ecdysteroid titre was measured by radioimmunoassay. The approximate titre in all 4 groups was 20 ng of 20-hydroxyecdysone (20-OHE) equivalents/ml haemolymph. Fluid secretory competence in vitro can be used as an index of salivary-gland degeneration. The glands dissected from fed males which had been left off the host for 4 days lost 62% of their fluid secretory competence compared to glands dissected shortly after the males were removed. This loss in fluid secretory competence was reversed by allowing ticks left off the host of 4 days to resume feeding. Male salivary glands lost fluid secretory competence when exposed for 4 days in organ culture to 20-OHE; the effect was maximal at the lowest concentration tested (20 ng/ml). Thus, although male salivary glands were highly sensitive to 20-OHE, it is still not clear whether this hormone causes the tissue to degenerate.     

Alterations in polypeptides pattern in malaria vector Anopheles stephensi, fed upon immunized blood causing fecundity reduction

Changes in polypeptides pattern of haemolymph, midgut, ovary and salivary glands of female mosquito A. stephensi were studied when fed upon anti-mosquito haemolymph antibodies. The expression of almost all polypeptides was reduced in haemolymph and ovary of the immune fed mosquitoes as compared to control. However, there was no significant difference in case of midgut and salivary glands. Seven polypeptides 100, 90, 84, 80, 62, 19 and 12.5 kDa were absent in haemolymph and five 92, 90, 80, 60 and 55 kDa were absent in ovaries. Changes in the polypeptide pattern have been correlated with the fecundity reduction due to immunized blood feeding.     

Variation in vector competency depends on chrysanthemum yellows phytoplasma distribution within Euscelidius variegatus

Phytoplasmas are plant‐pathogenic Mollicutes transmitted by leafhoppers, planthoppers, and psyllids in a persistent propagative manner. Chrysanthemum yellows phytoplasma (CY) is a member of ‘Candidatus Phytoplasma asteris’, 16Sr‐IB, and is transmitted by at least three leafhopper species, Macrosteles quadripunctulatus Kirschbaum, Euscelidius variegatus Kirschbaum, and Euscelis incisus Kirschbaum (all Homoptera: Cicadellidae: Deltocephalinae). Although M. quadripunctulatus transmits CY with very high efficiency (near 100%), 25% of E. variegatus repeatedly fail to transmit CY. The aims of this work were to correlate vector ability with different pathogen distribution in the insect body and to investigate the role of midgut and salivary glands as barriers to CY transmission. Euscelidius variegatus individuals acquired CY by feeding on infected plants or by abdominal microinjection of a phytoplasma‐enriched suspension. Insects were individually tested for transmission on daisy seedlings [Chrysanthemum carinatum Schousboe (Asteraceae)], and thereafter analysed by real‐time polymerase chain reaction (PCR) for CY concentration on whole insects or separately on heads and the rest of the body. Hoppers were classified as early and late transmitters or non‐transmitters, according to the time inoculated plants required for expression of CY symptoms. Similar transmission efficiencies were achieved following feeding or abdominal microinjection, suggesting that salivary glands may be a major barrier to transmission. Following acquisition from infected plants, all transmitters tested positive by PCR, and 60% of non‐transmitters also tested positive although with a significantly lower CY concentration. This indicates that a minimum number of phytoplasma cells may be required for successful transmission. The midgut may have prevented phytoplasma entry into the haemocoel of PCR‐negative non‐transmitters. Results suggest that both midgut and salivary glands may act as barriers. To assess the effect on CY transmission of a specific parasitic bacterium of E. variegatus, tentatively named BEV (Bacterium Euscelidius variegatus), we established a BEV‐infected population by abdominal microinjection of BEV bacteria. The presence of BEV did not significantly alter the efficiency of CY transmission.     

Development of accessory reproductive glands and its control by the corpus allatum in adult male Melanoplus sanguinipes

Changes in the protein content of and the rate at which labelled protein appears in the accessory reproductive glands (ARG), fat body, and haemolymph were studied in normal and allatectomized (CA^?) males of the migratory grasshopper, Melanoplus sanguinipes. In addition, the effects of treatment of CA^? insects with synthetic juvenile hormone (SJH), copulation, and removal of the ARG were examined.In normal males the protein content of the ARG increases linearly during the first 14 days after emergence. Incorporation of label by the ARG is maximal at day 7 and then decreases until, at day 14, it is the same as at day 1. The protein content of the fat body and haemolymph increases up to day 10 then declines, whereas changes in the uptake of label by the fat body and haemolymph parallel those of the ARG.Removal of the corpora allata (CA) prevents the normal increase in protein content of the ARG, but the protein content of the fat body and haemolymph increases steadily throughout the 14 days. Incorporation of label into the ARG, fat body, and haemolymph remained low throughout the experiment. Treatment of CA^? insects with SJH, or copulation, stimulates the uptake of label by the ARG, fat body, and haemolymph and also results in an increase in their protein content.Removal of the ARG leads to an increase in the protein content of the fat body and haemolymph. Uptake of label by the fat body remains low after the operation. Although the rate at which labelled protein appears in the haemolymph is high initially, it declines steadily to day 14.We conclude that the CA regulate ARG development. It is suggested that the fat body, under CA control, synthesizes proteins which are incorporated into secretions of the ARG. Further, it is proposed that the primary effect of copulation is activation of the CA.     

Factors influencing the toxicity of salivary gland extracts of Ixodes holocyclus Neumann

A bioassay using mice was developed to compare the toxin content of extracts of salivary glands of I. holocyclus at various stages of feeding. The quantity of toxin increased rapidly from the third day of feeding. Toxin production continued and increased in ticks removed after 3–5 days on mice and held at 30°C at 92% RH for 24 h, whereas no toxin was detected in the salivary glands of ticks fed for 3 days and treated similarly. It is suggested that major physiological changes occur in the salivary glands of I. holocyclus on the third day, which once stimulated continue independently of feeding. Toxin production in ticks was not suppressed by passively immunizing mice with anti-tick toxin but was in ticks fed upon hosts with a previous experience of tick feeding.Thus, to obtain salivary glands containing high concentrations of toxin for chemical analysis, it is necessary for salivary glands to develop 5 days from the initial attachment of the tick to a host with no previous experience of tick feeding. This can be achieved by passively immunizing mice against toxin, thus enabling the tick to feed 5 days without killing the mouse or by keeping the tick for 24 h at 30°C at 92% RH following the death of the mouse on the fourth day.     

The interaction between Trypanosoma rangeli and the nitrophorins in the salivary glands of the triatomine Rhodnius prolixus (Hemiptera; Reduviidae)

The parasite Trypanosoma rangeli develops in the intestinal tract of triatomines and, particularly in species of the genus Rhodnius, invades the hemolymph and salivary glands, where subsequent metacyclogenesis takes place. Many aspects of the interaction between T. rangeli and triatomines are still unclear, especially concerning the development of the parasite in the salivary glands and how the parasite interacts with the saliva. In this work, we describe new findings on the process of T. rangeli infection of the salivary glands and the impact of infection on the saliva composition. To ensure a complete infection (intestinal tract, hemolymph and salivary glands), 3rd instar Rhodnius prolixus nymphs were fed on blood containing T. rangeli epimastigotes using an artificial feeder. After molt to the 4th instar, the nymphs were inoculated with epimastigotes in the hemolymph. The results showed that the flagellates started to invade the salivary glands by the 7th day after the injection. The percentage of trypomastigotes inside the salivary glands continuously increased until the 25th day, at which time the trypomastigotes were more than 95% of the T. rangeli forms present. The salivary contents from T. rangeli-infected insects showed a pH that was significantly more acidic (<6.0) and had a lower total protein and hemeprotein contents compared with non-infected insects. However, the ratio of hemeprotein to total protein was similar in both control and infected insects. qPCR demonstrated that the expression levels of three housekeeping genes (18S rRNA, β-actin and α-tubulin) and nitrophorins 1–4 were not altered in the salivary glands after an infection with T. rangeli. In addition, the four major nitrophorins (NPs 1–4) were knocked down using RNAi and their suppression impacted T. rangeli survival in the salivary glands to the point that the parasite burden inside the R. prolixus salivary glands was reduced by more than 3-fold. These results indicated that these parasites most likely non-specifically incorporated the proteins that were present in R. prolixus saliva as nutrients, without impairing the biosynthesis of the antihemostatic molecules.