Hemocyte monophenol oxidase activity in mosquitoes exposed to microfilariae of Dirofilaria immitis

Monophenol oxidase (MPO) activity in hemocytes collected from Aedes aegypti Liverpool strain and Aedes trivittatus intrathoracically inoculated with saline alone, inoculated with Dirofilaria immitis microfilariae (mff), or from uninoculated mosquitoes was compared using a radiometric tyrosine hydroxylation assay. Hemocyte MPO activity in mff-inoculated (= immune-activated) mosquitoes was significantly increased at 24 hr postinoculation (PI) in A. aegypti and at 6, 12, and 24 hr PI in A. trivittatus as compared with saline-inoculated controls. Baseline and immune-activated levels of hemocyte MPO activity in A. trivittatus were significantly higher compared with those seen in A. aegypti. Baseline hemocyte population levels were similar in both species, but immune activation did not elicit increases in total hemocyte populations in A. trivittatus as has been demonstrated for A. aegypti. Likewise, immune activation by the inoculation of mff did not significantly alter plasma MPO activity in A. trivittatus as compared with uninoculated or saline-inoculated mosquitoes. Plasma MPO activity in A. aegypti, however, appears to constitute a major component of the immune response. The importance of phenol oxidase(s) in the immune response of mosquitoes against mff and the relationship of observed differences in MPO activity to differences in immunological capability between A. aegypti and A. trivittatus are assessed.     

Defense reactions of mosquitoes to filarial worms: potential mechanism for avoidance of the response by Brugia pahangi microfilariae

The melanization response of Aedes trivittatus and the black-eyed Liverpool (LVP) and Rocke-feller (RKF) strains of Aedes aegypti against intrathoracically inoculated Brugia pahangi microfilariae (mff) that previously had penetrated LVP, RKF, or A. trivittatus midguts in vitro was assessed at 1, 3, and 5 days postinoculation (PI). LVP and RKF midgut-derived mff almost totally avoided the melanization response and developed normally in LVP strain A. aegypti, and although over 90% of these mff died by 5 days PI in RKF mosquitoes, the majority of these were not melanized. A. aegypti midgut-derived mff also were able to avoid the response of A. trivittatus in 33–43% of the cases. Penetration through A. trivittatus midguts, however, did not significantly affect the ability of mff to avoid the melanization response in any of the mosquitoes examined. Allogeneic and xenogeneic tissue inplants were accepted by all three mosquito species examined. Data presented support the hypothesis that mff avoid immune recognition in compatible mosquitoes by coating themselves with midgut material(s) during penetration of the midgut in their migration to the hemocoel.     

Hemocyte cell surface changes in Aedes aegypti in response to microfilariae of Dirofilaria immitis

This study involved the assessment of surface changes on hemocytes of Aedes aegypti black-eyed Liverpool strain in association with the melanization response against intrathoracically inoculated Dirofilaria immitis microfilariae (mff). Surface changes on hemocytes were identified using fluorescein-labeled wheat germ agglutinin (WGA). In mosquitoes eliciting a melanization response against inoculated mff, there was a 5-fold increase in the percentages of hemocytes exhibiting WGA binding compared with saline inoculated controls. Relationships of this hemocyte activation in relation to cell-mediated melanization responses of adult mosquitoes against mff are discussed.     

Hemocyte population changes during the immune response of Aedes aegypti to inoculated microfilariae of Dirofilaria immitis

Ultrastructural and lectin-binding studies have established that the melanotic encapsulation reaction of Aedes aegypti Liverpool strain against inoculated Dirofilaria immitis microfilariae (mff) is a hemocyte-mediated reaction. Total hemocyte counts from mff-inoculated (= immune-activated), saline-inoculated, and uninoculated female A. aegypti were determined using a hemocoel perfusion technique. Total hemocyte populations in uninoculated mosquitoes were significantly larger in younger mosquitoes, but no significant change was noted as mosquitoes aged beyond 14 days. Hemocyte populations in immune-activated mosquitoes increased from 1 to 3 days postinoculation (PI) and decreased on days 4 and 5 PI. Hemocyte populations at 1 to 4 days PI were significantly elevated in mff-inoculated A. aegypti as compared with saline-inoculated controls. Saline-inoculated mosquitoes displayed little change in total hemocyte numbers from 1 to 5 days PI, and their hemocyte populations were similar to those seen in uninoculated insects of the same age. Experiments involving the inoculation of [3H]thymidine along with mff or saline alone and studies involving the administration of colchicine suggest that increased hemocyte populations in immune-activated A. aegypti are a result of mitotic division of circulating blood cells.     

Defense reaction of mosquitoes to filarial worms: role of the microfilarial sheath in the response of mosquitoes to inoculated Brugia pahangi microfilariae

The melanization response of Aedes trivittatus and A. aegypti (black-eyed Liverpool strain) against intrathoracically inoculated sheathed and chemically exsheathed Brugia pahangi microfilariae (mff) was assessed daily through 5 days postinoculation (PI). Response of A. aegypti against exsheathed mff was significantly reduced on all days compared with the response against sheathed mff, and a significantly greater percentage of exsheathed mff were alive through 4 days PI than were sheathed mff. The melanization response of A. trivittatus was nearly 100% effective against either sheathed or exsheathed mff by Day 2 PI. When mff were allowed to migrate through A. aegypti midguts in vitro before inoculation into intact A. aegypti, nearly 94% ($\text{120}\text{128}$) of the parasites recovered had avoided the response and were developing. Penetration of A. trivittatus midguts in vitro by mff before inoculation into intact A. trivittatus did not prevent a melanization response. Inoculation of mff into A. trivittatus following A. aegypti midgut penetration, however, resulted in almost 60% ($\text{98}\text{171}$) of the mff avoiding the response and developing as normal L₁ larvae after 5 days PI. The possibility of mff acquiring host antigens during midgut penetration and therefore avoiding recognition as nonself by mosquitoes, and (or) the possibility of the midgut environment modifying or stimulating mff to inhibit the response of mosquitoes are discussed.     

Effect of gamma irradiation on the hemocyte-mediated immune response of Aedes aegypti against microfilariae

The effect of gamma irradiation on the melanotic encapsulation response of Aedes aegypti black eye Liverpool strain against inoculated Dirofilaria immitis microfilariae (mff) was assessed at 1, 2, 3, and 6 days postinoculation (PI). Mosquitoes received 6000 rad from a 137Cs source (Shepard Mark I irradiator) at 3 days postemergence and were inoculated with 15-20 mff 24 hr later. These mosquitoes were compared to nonirradiated controls that also were inoculated with 15-20 mff at 3 days postemergence. The immune response was significantly reduced in irradiated mosquitoes as compared with controls at all days PI. Although the response was significantly inhibited compared with controls, irradiated mosquitoes were still capable of eliciting a response against 69% of recovered mff at 6 days PI. External gamma irradiation did not significantly affect the proliferation of hemocytes associated with the melanotic encapsulation response of A. aegypti. The number of circulating hemocytes increased in irradiated mosquitoes in response to inoculated mff in a manner similar to nonirradiated, inoculated controls. Hemocyte monophenol oxidase activity, however, was significantly reduced in gamma-irradiated mosquitoes at 12 hr PI as compared with controls. The reduced immunological capacity of irradiated mosquitoes might be related to an interference with gene activity required for the synthesis or activation of enzymes that are directly or indirectly involved in the biochemical processes associated with the production of melanotic substances that sequester mff.     

Parasite-induced suppression of the immune response in Aedes aegypti by Brugia pahangi

The melanization response against intrathoracically inoculated Brugia pahangi and Dirofilaria immitis microfilariae (mff) isolated from vertebrate host blood was evaluated in both uninfected Aedes aegypti black-eyed Liverpool strain and in mosquitoes harboring a developing B. pahangi infection. The immune response against inoculated mff of either species was significantly reduced by 28-47% in infected as compared with uninfected mosquitoes. Attempts to passively transfer this suppression factor(s) by inoculating naive mosquitoes with 0.1-0.2 microliter of hemolymph from B. pahangi-infected mosquitoes produced equivocal results. The role this parasite-induced immune suppression might play in aiding parasite survival in compatible vectors is discussed.     

High-pressure liquid chromatographic analysis of hemolymph plasma catecholamines in immune-reactive Aedes aegypti

Tyrosine and catecholamines have been implicated as substrates for the encapsulation reactions involved in the immune response of mosquitoes to microfilariae (mff). Identification and quantitation of tyrosine and catecholamines present in Aedes aegypti hemolymph plasma were accomplished by ion-pair high-pressure liquid chromatography with electrochemical detection at either +650 or +850 mV vs Ag/AgCl. Tyrosine, dopamine, and N-beta-alanyldopamine were detected in the hemolymph plasma of naive A. aegypti. Although no differences in these compounds were observed in hemolymph plasma from A. aegypti inoculated with Dirofilaria immitis mff, the chromatogram showed a single major peak (PI) (65 microM, expressed as dopamine equivalents) that was not present in naive hemolymph plasma. Saline-inoculated controls contained only 5% of the PI in immune reactive hemolymph plasma. A high concentration of PI (127 +/- 39 microM) was also detected after treatment of hemolymph plasma with mild alkaline conditions (pH 9.0), indicating that it is normally present as an electrochemically inert form in naive mosquitoes. High concentrations of PI were also detected in the naive hemolymph plasma from three other mosquito species, but no PI was found in A. trivittatus under any conditions. PI did not cochromatograph with any of the catecholamines commonly thought to be involved in immune responses of dipterans against metazoan parasites, suggesting that it may be a unique substrate for these reactions. The biological relevance of PI was evidenced by its appearance in the hemolymph plasma of two strains of D. immitis-inoculated A. aegypti.     

Ultrastructure of the melanization response of Aedes trivittatus against inoculated Dirofilaria immitis microfilariae

Scanning and transmission electron microscopy revealed that intrathoracically-inoculated microfilariae (mff) of Dirofilaria immitis elicited a rapid and effective immune response in the hemocoel of Aedes trivittatus mosquitoes. Hemocyte lysis and melanization of inoculated mff began immediately following exposure to the hemolymph environment. Initial melanin accumulation occurred at any site along the surface of mff and rapidly increased in thickness. Hemocyte encapsulation generally described for insects did not occur, but hemocytes might be necessary for activation of the melanization response. Although intact hemocytes were never abundant, those that were present seemed to show an active secretion of membrane-bound vacuoles directed toward mff. Activated hemocytes were in close association, but never in direct contact with the parasite, and were most commonly seen in various stages of lysis. Numerous cell remnants were noted throughout the developing melanin capsule. Parasites were completely melanized by 24 hr postinoculation (PI). By about 3 days PI, a membrane began to form around deposited melanin and hemocyte remnants. This developed into a double membrane-like structure of 25-30 nm thickness and resulted in the enclosure and isolation of the mff, melanin deposits, and cellular remnants from hemolymph components. It is suggested that this membrane functions as a boundary to isolate the melanized parasite and prevents additional hemocyte involvement.     

Hemocyte-mediated melanization of microfilariae in Aedes aegypti

The melanization response of adult female Aedes aegypti (black-eyed Liverpool strain) against intrathoracically inoculated Dirofilaria immitis microfilariae (mff) was assessed with transmission electron microscopy. The initial reaction involved the lysis of hemocytes at or near the surface of the parasite prior to the deposition of pigment. Subsequently, melanin formation was noted in the area of lysed cells and appeared to cascade onto the parasite surface. Observations suggest that melanin may be synthesized within certain hemocytes and released by exocytosis or upon cell lysis. Intact and disrupted nuclei and cytoplasmic elements from lysed hemocytes became numerous as mff became completely coated with melanin. A double membrane-like structure formed around the melanized mff and cellular debris during the later stages of the reaction, which eventually isolated the melanin capsule from hemolymph components. Results obtained are discussed in relation to the melanization response previously described for Aedes trivittatus.     

Relationship of hemolymph phenol oxidase and mosquito age in Aedes aegypti.

Monophenol oxidase (MPO) and diphenol oxidase (DPO) activity in hemocytes and cell-free plasma perfused from 7-, 14-, 21-, and 28-day-old Aedes aegypti mosquitoes were compared. A progressive decrease of enzyme activity was detected as mosquito age increased, and this decrease was significant in both hemocytes and cell-free plasma when mosquitoes were 28 days old as compared with that found in 7-day-old mosquitoes. There was no significant difference in total hemolymph protein as mosquito age increased. Although this decreased MPO and DPO activity might be partially responsible for the reduced immune response against filarial worms previously reported for older mosquitoes, other factors undoubtedly play a significant role.     

Defense reactions of mosquitoes to filarial worms: comparative studies on the response of three different mosquitoes to inoculated Brugia pahangi and Dirofilaria immitis microfilariae

The melanization response of Aedes trivittatus and the Rockefeller (RKF) and black-eyed Liverpool (LVP) strains of Aedes aegypti against intrathoracically inoculated Dirofilaria immitis and Brugia pahangi microfilariae (mff) was investigated. All mff of either species were melanized in A. trivittatus following Day 2 postinoculation, and the response of this species was significantly more rapid and effective than either strain of A. aegypti. The refractory RKF strain had a significantly greater response against both D. immitis and B. pahangi than the highly susceptible LVP strain, but data suggest that the increased responsiveness was due to a physiologic incompatibility in RKF A. aegypti, thereby resulting in a greater mortality and subsequent melanization of inoculated mff. Inoculation of large numbers of mff overloaded the defense capabilities of A. aegypti (LVP), but not those of A. trivittatus. The melanization response against D. immitis mff was effectively reduced for up to 4 days in A. aegypti (LVP), but for only 1 day in A. trivittatus, when mosquitoes were maintained on a 0.3 m sucrose diet containing from 0.1 to 1.0% (w/v) phenylthiourea.     

中华按蚊和白纹伊蚊接种马来丝虫微丝蚴后酚氧化酶活性的变化(英文)

酚氧化酶在昆虫抵抗外来异物黑化和成囊的免疫反应中起重要作用。中华按蚊和白纹伊蚊分别经胸内接种马来丝虫微丝蚴和生理盐水后,测定蚊血淋巴中酚氧化酶活性。结果表明:未接种的两种蚊,其1日龄蚊的酚氧化酶活性显著高于3、12和16日龄蚊。1日龄中华按蚊接种微丝蚴24h后,其酚氧化酶活性比未接种蚊和接种生理盐水蚊高2—3倍。1日龄白纹伊蚊接种微丝蚴24h后,其酚氧化酶活性是未接种蚊的7倍。白纹伊蚊酚氧化酶活性的免疫激活水平显著高于中华按蚊。讨论了中华按蚊和白纹伊蚊酚氧化酶活性的差异与其免疫力差异的关系。     

Laminin and a Plasmodium ookinete surface protein inhibit melanotic encapsulation of Sephadex beads in the hemocoel of mosquitoes

In refractory mosquitoes, melanotic encapsulation of Plasmodium ookinetes and oocysts is a commonly observed immune response. However, in susceptible mosquitoes, Plasmodium oocysts develop extracellularly in the body cavity without being recognized by the immune system. Like Plasmodium gallinaceum oocysts, negatively charged carboxymethyl (CM)-Sephadex beads implanted in the hemocoel of Aedes aegypti female mosquitoes were not usually melanized, but were coated with mosquito-derived laminin. Conversely, electrically neutral G-Sephadex beads were routinely melanized. Since mosquito laminin coated both CM-Sephadex beads and P. gallinaceum oocysts, we hypothesized that laminin prevents melanization of both. To test this hypothesis, we coated cyanogen-bromide-activated G-Sephadex beads with laminin, recombinant P. gallinaceum ookinete surface protein (PgS28) or bovine serum albumin (BSA). Beads were implanted into the abdominal body cavity of female Aedes aegypti and retrieved 4 days later. Uncoated controls as well as BSA-coated G-Sephadex beads were melanized in a normal manner. However, melanization of beads coated with mouse laminin, Drosophila L2-secreted proteins or PgS28 was markedly reduced. Fluorescent antibody labeling showed that PgS28-coated beads had adsorbed mosquito laminin on their surface. Thus, mosquito laminin interacting with Plasmodium surface proteins probably masks oocysts from the mosquito's immune system, thereby facilitating their development in the body cavity.     

Immune competence of Aedes trivittatus hemocytes as assessed by lectin binding

Hemocytes were perfused from uninoculated, saline-inoculated, and Dirofilaria immitis microfilariae-inoculated Aedes trivittatus and assessed for their capacity to bind wheat germ agglutinin (WGA). Approximately one-fourth of perfused hemocytes were WGA positive in all groups of mosquitoes at all time periods tested. Results suggest A. trivittatus has a larger inherent population of immune-competent hemocytes as compared with Aedes aegypti and, therefore, is faster and more effective in killing microfilariae by melanotic encapsulation reactions.     

Characterization of the intracellular melanization response in Anopheles quadrimaculatus against subperiodic Brugia malayi larvae.

Intracellular melanization, a defense or an immune response in the thoracic muscle cells, was investigated in a refractory strain of Anopheles quadrimaculatus infected with larvae of Brugia malayi. In mosquitoes fed on B. malayi-infected jirds, intracellular melanization against first-stage larvae (L1) was better expressed when fewer than 40 microfilariae reached the thoracic muscle cells than when more than 40 microfilariae reached the thoracic muscle cells. This result suggests that when large numbers of microfilariae invade the thoracic muscle cells, the immune response of the mosquito may become overloaded. Intracellular melanization response against L1 in the thoracic muscle cells also showed a significant decrease in older females (14-16-day-old) as compared to the younger ones (4-9-day-old). A comparison is made between intracellular and extracellular responses of mosquitoes to filarial larvae. It is significant that in both cases high rate of infection can reduce both the number and percentage of larvae melanized.     

PHENOL OXIDASE ACTIVITY IN ANOPHELES SINENSIS AND AEDES ALBOPZCTUS EXPOSED TO MICROFILARIAE OF BRUGIA MALAYI

Abstract Phenol oxidase (PO activity was investigated in cell-free hemolymph collected from Anopheles sinensis and Aedes albopictlcs female adults intrathoracically inoculated with Brugia dayi microfilariae (mff), inoculated with saline alone, or from uninoculated mosquitoes. The activity of PO from uninoculated 1-day-old mosquitoes was significantly greater than those of mosquitoes on 3, 12 and 16 day. PO activity in mff-inoculated A. sinensis at 24 h postinoculation (PI) was 2–3 times higher as compared with uninoculated or saline-inoculated mosquitoes. Inoculation of B. malayi mff into A. albopictus elicited ?-fold increase in PO activity at 24 h PI as compared with uninoculated mosquitoes. Immune-activated levels of PO activity in A. alboplctus was significantly higher as compared with those seen in A. sinensis. The relationship of observed differences in PO activity to differences in immunological capability between A. sinensis and A. albopictus is discussed.     

Brugia malayi and Brugia pahangi: inherent difference in immune activation in the mosquitoes Armigeres subalbatus and Aedes aegypti

The inherent ability of Brugia malayi and Brugia pahangi (Nematoda) to establish successful relationships with the mosquitoes Armigeres subalbatus and Aedes aegypti Liverpool strain was evaluated. Brugia pahangi microfilariae (mff) avoided the immune response and developed normally in A. subalbatus exposed to the parasite by an infective bloodmeal, whereas nearly 85% of B. malayi were destroyed by the immune response. Because A. aegypti supports the development of both filarial worm species but destroys intrathoracically inoculated B. pahangi isolated from jird blood, blood-isolated B. malayi were inoculated into A. aegypti, and the immune response was compared with that observed against B. pahangi. The response against B. malayi was significantly more rapid and effective than the response against B. pahangi. Similar results were obtained when blood-isolated B. pahangi or B. malayi were inoculated into A. subalbatus. Microfilariae of both species were able to avoid immune destruction in A. aegypti if they were allowed to penetrate the Liverpool midgut in vitro prior to inoculation. Most B. pahangi that had first penetrated an Armigeres midgut prior to inoculation into A. subalbatus were able to avoid the immune response, but by day 3 postinoculation, less than 40% of the B. malayi, treated in the same manner, were able to escape the immune response. Genetic susceptibility of mosquitoes to infection by filarial worms and potential mechanisms of immune evasion/suppression are discussed regarding B. malayi and B. pahangi.     

The cost of immunity in the yellow fever mosquito, Aedes aegypti depends on immune activation

Although host immunity offers the obvious benefit of reducing parasite infection, it is often traded-off with other fitness components. We investigated whether the cost of an immune response in the yellow fever mosquito, Aedes aegypti, is modulated by the antigen that activates the melanization immune response. Thus, one of three different novel antigens were injected into the mosquito's thorax--either a glass bead, a negatively charged (C-25) Sephadex bead, or a neutral (G-25) Sephadex bead--and fecundity and bead melanization were observed. Glass beads are immunologically inert and were therefore used as an inoculation control. The fecundity of mosquitoes inoculated with these beads did not differ from the fecundity of mosquitoes that did not melanize negatively charged or neutral beads. The ability of A. aegypti to melanize negatively charged Sephadex beads was associated with reduced fecundity, showing a clear cost of immunity. In contrast, melanization of the neutral beads was quite strong but had no effect on fecundity. Thus, the cost of what appeared to be the same immune response--melanization of a bead--depended on the type of bead that stimulated the immune system. Such differences might help to explain variation of immune efficacy against different parasites in natural populations.     

Spontaneous flight activity of Aedes trivittatus infected with Dirofilaria immitis

Spontaneous flight activity of Dirofilaria immitis-infected Aedes trivittatus was evaluated by using an acoustic activity system. The activity of mosquitoes infected with low numbers of filarial larvae (1-4) was similar to that of uninfected mosquitoes. However, mosquitoes infected with more than 4 larvae became more active than uninfected mosquitoes 8 days after infection. Peak flight activity (circadian) occurred at the same time in both infected and uninfected mosquitoes, but infected mosquitoes were much more active during normal periods of quiescence. Flight activity of mosquitoes infected with more than 4 larvae was suppressed on days 10 and 14 postinfection, corresponding to times of greatest disruption of the Malpighian tubules by the developing larvae.