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.     

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.     

Inhibition of Dirofilaria immitis in gregarine-infected Aedes aegypti: preliminary observations.

This study examined some of the effects of Ascocystis culicis infections in Aedes aegypti mosquitoes and on the development of dog heartworm, Dirofilaria immitis, in A. culicis-infected A. aegypti. Infections of 100 or more gregarines had an adverse effect on mosquito larvae and the resulting pupae weighed 1 to 2 mg less than the gregarine-free stock mosquitoes. Intensity of gregarine-induced pathology of adult mosquitoes was best estimated by counting the cells of the Malpighian tubules. Larvae infected with approximately 100 gregarines per larva had at least half the number of cells in their tubules destroyed, and development of D. immitis was greatly reduced. Thus, gregarine infections may be useful in reducing populations of aedine mosquitoes and, in areas endemic for heartworm, may interrupt transmission of D. immitis.     

Physiological basis of host susceptibility of Florida mosquitoes to Dirofilaria immitis.

Young females of seven species of Florida mosquitoes were fed a meal of dog blood infected with Dirofilaria immitis to repletion to study the physiological mechanisms which control susceptibility and resistance in these mosquitoes. Various species of mosquitoes showed different grades of susceptibility. In all mosquitoes, microfilariae reached the midgut immediately after ingestion. Their movement from midgut to the specific host tissue—the Malpighian tubules—was either facilitated or inhibited depending on the presence or absence of anticoagulins in the salivary glands of these mosquitoes. In Anopheles quadrimaculatus, Aedes taeniorhynchus, and Aedes sollicitans, microfilariae move freely from the midgut to the Malpighian tubules, because of the presence of substantial amounts of anticoagulins in their salivary glands, and 30 to 60 mf/female developed normally to an infective stage. Very few microfilariae reached the tubules of Mansonia titillans as most of them were defaecated within a very short time after ingestion. In Aedes aegypti, Culex nigripalpus, and Culex pipiens quinquefasciatus movement of microfilariae from the midgut to the Malpighian tubules was obstructed by the coagulation of blood soon after ingestion. Coagulation of blood was followed by formation of oxyhaemoglobin crystals in C. nigripalpus and C. p. quinquefasciatus. It is suggested that secretions from symbiotic bacteria in the midgut of these mosquitoes lyse ingested red blood cells, and the released haemoglobin is oxidized to oxyhaemoglobin crystals which hinder the further movement of microfilariae and kill them.Microfilariae developed normally in A. quadrimaculatus, thus making them potentially the most susceptible mosquitoes, even though these mosquitoes did not survive to be effective potential vectors. A few microfilariae or their later developmental stages were melanized in the tubules of most A. sollicitans and A. taeniorhynchus, but the numbers of melanized stages were too few to affect the vectoring potentials of these species. In 20 per cent of A. sollicitans, 60 per cent of M. titillans, and ca. 80 per cent A. aegypti substantial numbers of the microfilariae after reaching the Malpighian tubules did not advance beyond the prelarval stage, and very few microfilariae developed successfully in the remaining mosquitoes. Very few microfilariae reached the Malpighian tubules of a small percentage of C. nigripalpus and C. p. quinquefasciatus and developed normally. The vectoring potentials of A. sollicitans, M. titillans, A. aegypti, and both Culex species were greatly hampered. These studies suggested that host-specificity of mosquitoes to D. immitis infection is controlled by the presence or absence of secondary physiological factors in their digestive tracts or in the Malpighian tubules.     

The effect of infection with Dirofilaria immitis (dog heartworm) on fluid secretion rates in the Malpighian tubules of the mosquitoes Aedes taeniorhynchus and Anopheles quadrimaculatus

Dirofilaria immitis, the parasitic nematode causing the disease dog heartworm, is transmitted by female mosquitoes. During their development, larval nematodes reside in the cells of the Malpighian tubules of these mosquitoes for approx 13 days. We have examined the effect of the presence of these large intracellular parasites on the main physiological function of the Malpighian tubules, i.e. fluid secretion. Rates of fluid secretion were examined in vitro using both normal and infected tubules of the mosquito species Aedes taeniorhynchus and Anopheles quadrimaculatus. Tubules of A. quadrimaculatus show changes in trasport rate during the reproductive cycle. Those of A. taeniorhynchus do not. Infection with larvae of D. immitis had no effect on the rate of fluid secretion in tubules of A. quadrimaculatus. In A. taeniorhynchus by contrast, the tubules show decline in transport with time following infection. The reduction in transport capacity is proportional to the number of worms infecting the tubule. The present paper and separate ultrastructural studies demonstrate that parallel changes in microvillar ultrastructure and epithelial transport rates occur in response to infection by the parasite. In both species examined, the survival of the mosquitoes and their vector potential are determined by factors other than the transport capacities of the infected Malpighian tubules.     

The effect of Brugia pahangi infection on survival of susceptible and refractory species of the Aedes scutellaris complex

Life table statistics were used to examine the survival functions of filarial susceptible and refractory species of the Aedes scutellaris (Walker) group of mosquitoes, following infection with high and moderate doses of Brugia pahangi (Buckley & Edeson). Survivorship curves and hazard function curves were generated, and the median survival times and the proportions of mosquitoes surviving beyond the extrinsic incubation period of the parasite were determined. In the susceptible populations of Aedes polynesiensis Marks, Ae. pseudoscutellaris (Theobald) and Ae.tabu Ramalingam & Belkin a dose-response relationship was detected between parasite load and mortality. This relationship was characterized by a significant reduction in the proportions of infected female mosquitoes surviving at days 1 and 9 postinfection, reduction in the median survival times and an increase in the hazard rates as the infectious dose increased. The survival of the refractory species, Ae.alcasidi Huang and Ae.katherinensis Woodhill was not significantly affected by the infection. A positive correlation between microfilaraemia in the vertebrate host and parasite load in the susceptible mosquito populations was also observed. Regression analysis of the number of parasites recovered from susceptible mosquitoes at the time of death showed that mosquitoes at highest risk of dying harboured from 11.6 to 19.4 infective larvae when fed on a gerbil with sixty-five microfilariae per 20 microliters blood; this resulted in 34.4-40.2% mortality by day 9 postinfection. A mean number of 32.6-46.9 infective larvae was observed when these populations were exposed to a gerbil with a microfilaraemia of 150 mf/20 microliters and resulted in 72.8% to 80% mortality in these populations. Viable infective larvae were recovered from infected mosquitoes up to 50 days postinfection.     

Hemolymph volume of noninfected and Plasmodium berghei-infected Anopheles stephensi.

The hemolymph volume of Anopheles stephensi adult female mosquitoes was determined by a radioisotope dilution technique. [carboxy-¹⁴C]Inulin was injected into the hemocoels of mosquitoes with a calibrated capillary needle. After sufficient time for thorough mixing, the labeled hemolymph was collected from groups of 50 mosquitoes by a centrifugation technique. Total hemolymph volume was calculated by a conventional formula for radioisotope dilution. The mean hemolymph volume of the newly emerged adult female mosquitoes was 336 nl/mosquito. The ratio of hemolymph volume to body weight was 0.25 μl/mg body wt. By 14 days after emergence, hemolymph volume had dropped to 190 nl/mosquito. Infection of mosquitoes with the rodent malaria parasite, Plasmodium berghei, had no significant effect on hemolymph volume of the mosquito.     

Activation of Akt Signaling Reduces the Prevalence and Intensity of Malaria Parasite Infection and Lifespan in Anopheles stephensi Mosquitoes

Malaria (Plasmodium spp.) kills nearly one million people annually and this number will likely increase as drug and insecticide resistance reduces the effectiveness of current control strategies. The most important human malaria parasite, Plasmodium falciparum, undergoes a complex developmental cycle in the mosquito that takes approximately two weeks and begins with the invasion of the mosquito midgut. Here, we demonstrate that increased Akt signaling in the mosquito midgut disrupts parasite development and concurrently reduces the duration that mosquitoes are infective to humans. Specifically, we found that increased Akt signaling in the midgut of heterozygous Anopheles stephensi reduced the number of infected mosquitoes by 60–99%. Of those mosquitoes that were infected, we observed a 75–99% reduction in parasite load. In homozygous mosquitoes with increased Akt signaling parasite infection was completely blocked. The increase in midgut-specific Akt signaling also led to an 18–20% reduction in the average mosquito lifespan. Thus, activation of Akt signaling reduced the number of infected mosquitoes, the number of malaria parasites per infected mosquito, and the duration of mosquito infectivity.     

Filarial worms reduce Plasmodium infectivity in mosquitoes

Background

Co-occurrence of malaria and filarial worm parasites has been reported, but little is known about the interaction between filarial worm and malaria parasites with the same Anopheles vector. Herein, we present data evaluating the interaction between Wuchereria bancrofti and Anopheles punctulatus in Papua New Guinea (PNG). Our field studies in PNG demonstrated that An. punctulatus utilizes the melanization immune response as a natural mechanism of filarial worm resistance against invading W. bancrofti microfilariae. We then conducted laboratory studies utilizing the mosquitoes Armigeres subalbatus and Aedes aegypti and the parasites Brugia malayi, Brugia pahangi, Dirofilaria immitis, and Plasmodium gallinaceum to evaluate the hypothesis that immune activation and/or development by filarial worms negatively impact Plasmodium development in co-infected mosquitoes. Ar. subalbatus used in this study are natural vectors of P. gallinaceum and B. pahangi and they are naturally refractory to B. malayi (melanization-based refractoriness).

Methodology/Principal Findings

Mosquitoes were dissected and Plasmodium development was analyzed six days after blood feeding on either P. gallinaceum alone or after taking a bloodmeal containing both P. gallinaceum and B. malayi or a bloodmeal containing both P. gallinaceum and B. pahangi. There was a significant reduction in the prevalence and mean intensity of Plasmodium infections in two species of mosquito that had dual infections as compared to those mosquitoes that were infected with Plasmodium alone, and was independent of whether the mosquito had a melanization immune response to the filarial worm or not. However, there was no reduction in Plasmodium development when filarial worms were present in the bloodmeal (D. immitis) but midgut penetration was absent, suggesting that factors associated with penetration of the midgut by filarial worms likely are responsible for the observed reduction in malaria parasite infections.

Conclusions/Significance

These results could have an impact on vector infection and transmission dynamics in areas where Anopheles transmit both parasites, i.e., the elimination of filarial worms in a co-endemic locale could enhance malaria transmission.     

Transovarial Transmission of Chikungunya Virus by Aedes albopictus Mosquitoes Ingesting Microfilariae of Dirofilaria immitis under Laboratory Conditions

Female Aedes albopictus mosquitoes of the Miki strain were experimentally fed on defibrinated sheep blood containing 5× 10⁷ PFU of chikungunya virus and 20,000 microfilariae of Dirofilaria immitis per milliliter. Fully engorged mosquitoes transmitted the virus to a small percentage of the F1 progeny, but females of the F1 generation did not transmit the virus to the F2 progeny. The control mosquitoes that ingested the virus without microfilariae did not transmit the virus to their eggs, larvae, or pupae in the F1 or F2 generations. These results showed that A. albopictus of this strain that concurrently ingested the virus and microfilariae transmitted the virus by the transovarial route under experimental conditions.     

Periodicity exhibited by Dirofilaria immitis microfilariae identified in dogs of Korea

Microfilarial periodicity of Dirofilaria immitis (the dog heartworm) was determined at two hr intervals for 72 consecutive hrs in 10 naturally infected war dogs, 3-9 years old, in Korea to facilitate harvest of the microfilariae for possible use in laboratory works and to elucidate further the periodicity of the microfilaria depending on geographic location. Although the periodicity had been observed as being low-grade nocturnal, maximal microfilarial counts were found at 21:00 hr and minimal at 11:00 hr, giving rise to an evident peak in fluctuation of the larval counts. This is the first record of the periodicity of the microfilariae identified as D. immitis in Korea.     

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.     

Mosquito mortality and the evolution of malaria virulence

Abstract Several laboratory studies of malaria parasites (Plasmodium sp.) and some field observations suggest that parasite virulence, defined as the harm a parasite causes to its vertebrate host, is positively correlated with transmission. Given this advantage, what limits the continual evolution of higher parasite virulence? One possibility is that while more virulent strains are more infectious, they are also more lethal to mosquitoes. In this study, we tested whether the virulence of the rodent malaria parasite P. chabaudi in the laboratory mouse was correlated with the fitness of mosquitoes it subsequently infected. Mice were infected with one of seven genetically distinct clones of P. chabaudi that differ in virulence. Weight loss and anemia in infected mice were monitored for 16–17 days before Anopheles stephensi mosquitoes were allowed to take a blood meal from them. Infection virulence in mice was positively correlated with transmission to mosquitoes (infection rate) and weakly associated with parasite burden (number of oocysts). Mosquito survival fell with increasing oocyst burden, but there was no overall statistically significant relationship between virulence in mice and mosquito mortality. Thus, there was no evidence that more virulent strains are more lethal to mosquitoes. Both vector survival and fecundity depended on parasite clone, and contrary to expectations, mosquitoes fed on infections more virulent to mice were more fecund. The strong parasite genetic effects associated with both fecundity and survival suggests that vector fitness could be an important selective agent shaping malaria population genetics and the evolution of phenotypes such as virulence in the vector.     

Xenomonitoring of Different Filarial Nematodes Using Single and Multiplex PCR in Mosquitoes from Assiut Governorate,Egypt

Wuchereria bancrofti, Dirofilaria immitis, and Dirofilaria repens are filarial nematodes transmitted by mosquitoes belonging to Culex, Aedes, and Anopheles genera. Screening by vector dissection is a tiresome technique. We aimed to screen filarial parasites in their vectors by single and multiplex PCR and evaluate the usefulness of multiplex PCR as a rapid xenomonitoring and simultaneous differentiation tool, in area where 3 filarial parasites are coexisting. Female mosquitoes were collected from 7 localities in Assiut Governorate, were microscopically identified and divided into pools according to their species and collection site. Detection of W. bancrofti, D. immitis, and D. repens using single PCR was reached followed by multiplex PCR. Usefulness of multiplex PCR was evaluated by testing mosquito pools to know which genera and species are used by filarial parasites as a vector. An overall estimated rate of infection (ERI) in mosquitoes was 0.6%; the highest was Culex spp. (0.47%). W. bancrofti, D. immitis, and D. repens could be simultaneously and differentially detected in infected vectors by using multiplex PCR. Out of 100 mosquito pools, 8 were positive for W. bancrofti (ERI of 0.33%) and 3 pools each were positive for D. immitis and D. repens (ERI 0.12%). The technique showed 100% sensitivity and 98% specificity. El-Nikhila, El-Matiaa villages, and Sahel Seleem district in Assiut Governorate, Egypt are still endemic foci for filarial parasites. Multiplex PCR offers a reliable procedure for molecular xenomonitoring of filariasis within their respective vectors in endemic areas. Therefore, it is recommended for evaluation of mosquito infection after lymphatic filariasis eradication programs.     

Avian malaria infection intensity influences mosquito feeding patterns

Pathogen-induced host phenotypic changes are widespread phenomena that can dramatically influence host–vector interactions. Enhanced vector attraction to infected hosts has been reported in a variety of host–pathogen systems, and has given rise to the parasite manipulation hypothesis whereby pathogens may adaptively modify host phenotypes to increase transmission from host to host. However, host phenotypic changes do not always favour the transmission of pathogens, as random host choice, reduced host attractiveness and even host avoidance after infection have also been reported. Thus, the effects of hosts’ parasitic infections on vector feeding behaviour and on the likelihood of parasite transmission remain unclear. Here, we experimentally tested how host infection status and infection intensity with avian Plasmodium affect mosquito feeding patterns in house sparrows (Passer domesticus). In separate experiments, mosquitoes were allowed to bite pairs containing (i) one infected and one uninfected bird and (ii) two infected birds, one of which treated with the antimalarial drug, primaquine. We found that mosquitoes fed randomly when exposed to both infected and uninfected birds. However, when mosquitoes were exposed only to infected individuals, they preferred to bite the non-treated birds. These results suggest that the malarial parasite load rather than the infection itself plays a key role in mosquito attraction. Our findings partially support the parasite manipulation hypothesis, which probably operates via a reduction in defensive behaviour, and highlights the importance of considering parasite load in studies on host–vector–pathogen interactions.     

A correlated response of a parasite’s virulence and life cycle to selection on its host’s life history

We demonstrate a correlated response of the virulence and the mode of transmission of the microsporidian parasite Edhazardia aedis to selection on the age at pupation of its host, the mosquito Aedes aegypti. We selected three lines of mosquitoes each for early or late pupation and exposed the larvae after zero, two and four generations of selection to a low and a high concentration of the parasite’s spores. Before selection the parasites induced a similar level of mortality in the six lines; after four generations of selection mortality was higher in the mosquitoes selected for late pupation than in those selected for early pupation. Overall, parasite-induced mortality was positively correlated with the mean age at pupation of the matching uninfected line. When they died, mosquitoes selected for early pupation harboured mostly binucleate spores, which are responsible for vertical transmission. Mosquitoes selected for late pupation were more likely to harbour uninucleate spores, which are responsible for horizontal transmission. The parasite enhanced this tendency for horizontal transmission by prolonging the larval period in the lines selected for late pupation, but not in the ones selected for early pupation. These results suggest that the genetic basis of the mosquito’s age at pupation helps to determine the parasite’s mode of transmission: parasites in rapidly developing mosquitoes are benign and transmit vertically, while parasites in slowly developing mosquitoes are virulent and transmit horizontally. Thus, as the host’s life history evolves, the parasite’s performance changes, because the host’s evolution changes the environment in which the parasite develops.     

Observations on the basal follicle numbers developed per female of two strains of Aedes aegypti after being fed on hosts with different levels of microfilariae of Brugia pahangi

Results indicate that there is a significant correlation between the density of Brugia pahangi microfilariae on which Aedes aegypti feed, the mean number of infective larvae produced per mosquito, and the mean number of basal follicles developed per female. When the density of microfilariae in cat's blood was high, the mean number of basal follicles developed per female was proportionally lower. It is concluded that the infected mosquitos show a significant drop in numbers of basal follicles produced per female. Both in the susceptible and refractory mosquito strains infected with B. pahangi, there was a negative linear correlation between parasite load and the number of basal follicles developed per female following their infecting blood meal.     

Massive microfilaremia in a dog subclinically infected with Acanthocheilonema dracunculoides

Canine filarioids are worldwide distributed nematodes transmitted by arthropods with variable virulence depending on the species. Dirofilaria immitis is the most virulent and serological antigen tests are commonly employed to detect it. This study reports on the heaviest cavity filariasis recorded so far in a dog, which showed no apparent clinical signs of infection. The 6-year-old male was positive to a D. immitis antigen test. Blood samples collected and analyzed with the modified Knott's test for microfilariae revealed 264,367 microfilariae/ml. In a post-mortem examination 791 adult filarial nematodes were found in the dog's thoracic and peritoneal cavities. Morphological and molecular analysis identified the nematode as Acanthocheilonema dracunculoides and no other species were present. This is evidence that massive A. dracunculoides infections in dogs may not be clinically evident, they may cause serologic cross-reaction with D. immitis infection and become a life-threatening condition if dogs are treated with a microfilaricidal treatment without previously performing an adequate diagnosis.     

The Plasmodium bottleneck: malaria parasite losses in the mosquito vector

Nearly one million people are killed every year by the malaria parasite Plasmodium. Although the disease-causing forms of the parasite exist only in the human blood, mosquitoes of the genus Anopheles are the obligate vector for transmission. Here, we review the parasite life cycle in the vector and highlight the human and mosquito contributions that limit malaria parasite development in the mosquito host. We address parasite killing in its mosquito host and bottlenecks in parasite numbers that might guide intervention strategies to prevent transmission.     

Brugia pahangi and Dirofilaria immitis: experimental infections in the ferret, Mustela putorius furo.

Ferrets were inoculated with 160 third-stage larvae of the filarial nematode Brugia pahangi, followed 23 days later by 15 larvae of another filarial nematode, Dirofilaria immitis. Other ferrets received only one of these species. Microfilaremia developed in some ferrets with single infections of each species and in some ferrets with dual infections. The nature of the experiment did not permit a thorough study of microfilaremia, but B. pahangi microfilariae were found in numbers as high as 15,650/ml. At necropsy, approximately 8 months after inoculation, adult B. pahangi were recovered from the lymphatic vessels of all 8 ferrets inoculated only with that species, the recovery rate (based on 6 animals only) varying from 2 to 50% of the inoculum (mean 25%). Adult D. immitis were recovered from the heart of all three ferrets inoculated only with that species, the recovery rate being 7, 47, and 60% (mean 38%) of the inoculum. All 5 ferrets inoculated with both species yielded both adult B. pahangi (6 to 23%, mean 16% of inoculum) and adult D. immitis (13 to 67%, mean 37% of inoculum). It is concluded that the ferret is highly susceptible to both species and that concurrent infections with both species may readily be established.