Brugia malayi and Brugia pahangi: transmission blocking activity of ivermectin and brugian filarial infections in Aedes aegypti

Brugia malayi- or Brugia pahangi-infected, microfilaremic jirds (Meriones unguiculatus) were treated with ivermectin at a single dose of 200 micrograms/kg body weight, administered subcutaneously. After different time intervals, Aedes aegypti mosquitoes were fed on treated or untreated jirds. Sausage stage, L2, and L3 larvae failed to develop in mosquitoes that fed on jirds from 15 to 30 days post-treatment. After 1 month, the numbers of L3 larvae recovered from mosquitoes fed on treated B. pahangi jirds were comparable to controls. However, the number of L3's recovered from mosquitoes fed on B. malayi jirds remained significantly lower than controls, 2 and 3 months after treatment. This reduction suggests that ivermectin may be more effective in blocking transmission of B. malayi than B. pahangi. Ivermectin treatment had no effect on the mean number of circulating microfilariae in treated jirds. Therefore, mosquitoes ingested comparable numbers of microfilariae when compared to those mosquitoes fed on untreated controls. Only in the case of jirds infected with B. malayi did the circulating microfilarial counts fall 30 days after treatment. The failure of microfilariae to develop to the L3 stage in mosquitoes fed on jirds within 30 days of treatment was not due to failure of mosquitoes to ingest microfilariae. Brugia malayi microfilariae also failed to develop to L3 in mosquitoes that were allowed to feed on microfilaremic jird blood treated with ivermectin (50 ng/ml) in vitro, indicating its efficacy at low concentrations. In addition to N-acetyl glucosamine, microfilariae obtained for a period of 15 days from ivermectin-treated but not control jirds showed D-mannose, N-acetyl galactosamine, and L-fucose moieties on the surface of the sheath.(ABSTRACT TRUNCATED AT 250 WORDS)     

In vitro killing of microfilariae of Brugia pahangi and Brugia malayi by eosinophil granule proteins

Eosinophil infiltration and degranulation around the tissue-invasive stages of several species of helminths have been observed. Release of eosinophil granule contents upon the worms is supported by localization of two of the major granule proteins, major basic protein (MBP) and eosinophil peroxidase (EPO), on and around species of trematodes, nematodes, and cestodes. In the case of filarial worms, MBP is deposited on degenerating microfilariae (mf) of Onchocerca volvulus. Here, we performed in vitro assays of the toxicity of four purified eosinophil granule proteins, namely, MBP, EPO, eosinophil cationic protein (ECP), and eosinophil-derived neurotoxin (EDN), for the mf of Brugia pahangi and Brugia malayi. MBP, ECP, and EDN killed these worms in a dose-related manner although relatively high concentrations of EDN were necessary. EPO, in the presence of a H2O2-generating system and a halide, was the most potent toxin on a molar basis; here, the most potent halide was I- followed by Br- and Cl-. Surprisingly, EPO in the absence of H2O2 killed mf at concentrations comparable to those required for MBP and ECP. The toxicity of EPO + H2O2 + halide was inhibited by heparin, catalase, or 1% BSA, whereas the toxicity of EPO alone was inhibited only by heparin. Heparin also inhibited killing by both MBP and ECP. Despite the homology of ECP with certain RNases, placental RNasin, an RNase inhibitor, was unable to inhibit ECP-mediated toxicity. These results indicate that all of the eosinophil granule proteins are toxic to mf and they support the hypothesis that eosinophil degranulation causes death of mf in vivo.     

Time courses of antibody levels in Mastomys natalensis after infections with Litomosoides carinii, Dipetalonema viteae, Brugia malayi or B. pahangi, Determined by ELISA

Using a Litomosoides carinii adult antigen, time courses of antibody levels were followed by an ELISA in L. carinii, Dipetalonema viteae, Brugia malayi and B. pahangi infected Mastomys natalensis. Using various groups of infected animals, periods up to 400 days after infection were covered. In L. carinii infected Mastomys, antibodies were first detected 11 days p.i. and levels increased rapidly until day 40. Temporarily reduced levels about the beginning of patency were followed by increasing values until about 100 days p.i. Then the antibody content of the sera remained more or less constant until about 250 days p.i. although maximum levels were found at day 170. Thereafter, the antibody concentration in the sera declined slowly but high levels were still observed 390 days p.i. The antibody content was usually higher in animals with high microfilariae densities than in those with low microfilariae counts but relations could not be proven statistically. In D. viteae infected Mastomys, maximum antibody values were reached within the beginning of patency. Levels were not altered markedly until about 110 days p.i. Thereafter they decreased slightly but then remained constant until the end of the investigation period 350 days p.i. B. malayi infected animals showed a rapid increase of the antibody content in the sera; a maximum was reached by 20 days after the infection. Thereafter, somewhat constant levels were found for 4--5 months. After 300 days p.i. the antibody levels declined progressively, accompanied with increasing parasitaemia densities; after 380 days the levels reached about 2/3 of the maximum. However, despite this, no relation was found between the levels of parasitaemia and antibody in individual animals. In B. pahangi infections the main prepatent antibody increase occurred during week 5 p.i., when maximum values were observed. The beginning of patency and the early patency were accompanied with slightly declining antibody levels. From 150 days p.i. until the end of the investigation 400 days p.i., the antibody content of the sera was fairly constant.     

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 carbohydrate metabolism of Brugia pahangi microfilariae.

Evidence is presented that the microfilariae of Litomosoides carinii, Dipetalonema viteae and Brugia pahangi have an aerobic requirement for motility, but possibly not for survival. In addition, the data suggest that in an in vitro anaerobic environment, B. pahangi microfilariae ferment glucose only as far as lactate. In an aerobic environment, however, the data are consistent with a portion of glucose being dissimilated via a one step oxidative decarboxylation of pyruvate formed from glycolysis to acetate and CO2. In addition, a low level of complete oxidation, possibly via a tricarboxylic acid cycle pathway, may be occurring. Finally, if B. pahangi microfilariae are immobilized with levamisole in an aerobic atmosphere, the drug appears to alter the aerobic glucose metabolism of the parasite both qualitatively and quantitatively. A decreased glucose utilization occurs, together with a shift to a more nearly homolactate fermentation. It is suggested that the effects of levamisole on the metabolism of the microfilariid are secondary to the observed paralysis.     

Brugia pahangi: granulomatous lesion development in jirds following single and multiple infections

The development of adult worm burdens and microfilaremias were determined in jirds which received 2, 3, or 4 subcutaneous inoculations of 50 Brugia pahangi infective larvae. Parasite burdens in multiply inoculated jirds were compared to those in four different groups of jirds which received single inoculations of 50 infective larvae. One of each of these singly inoculated groups was infected on the same day that one of the inoculations was given to the multiply infected jirds. Thus, the duration of the infections in the four groups of jirds receiving one inoculation was 54, 118, 189, and 254 days. The development of lymphatic lesions and granulomatous hypersensitivity to B. pahangi antigen was assessed in all jirds at necropsy. The percentage recoveries of adult worms and their locations did not differ in the singly inoculated jirds with infections of different durations. A protective resistance to reinfection, as measured by adult worm recovery in multiply infected jirds, did not occur. The lymphatic lesion scores and numbers of intralymphatic thrombi was greatest in singly inoculated jirds examined 54 days after infection. Pulmonary granuloma areas around adult filarial antigen coated beads embolized in the lungs of jirds 3 days prior to necropsy were also greatest in singly inoculated jirds examined 54 days after infection. Using criteria of lesion scores and lymph thrombi numbers to assess lymphatic lesion severity, a decrease in lesion severity as well as pulmonary granuloma size around antigen coupled beads was seen by 118 days after infection in singly inoculated jirds.(ABSTRACT TRUNCATED AT 250 WORDS)     

Synthetic pathways of glycerophospholipids in adult Brugia pahangi and Brugia patei

The pathways of glycerophospholipid syntheses in adult Brugia pahangi and Brugia patei were examined by radioisotopic incorporation and demonstration of the enzymatic steps. Radiolabelling studies showed that l-U-¹⁴C-glycerol-3-phosphate was rapidly incorporated into glycerophospholipids of B. pahangi and B. patei, respectively, with the label distributed in phosphatidylcholine (PC), phosphatidylethanolamine (PE), phosphatidylserine (PS), phosphatidylinositol (PI), phosphatidylglycerol (PG) and cardiolipin (CL) fractions. Crude extracts of these worms were found to contain significant activities of sn-glycerol-3-phosphate acyl-transferase (EC 2.3.1.15), phosphatidic acid phosphatase (EC 3.1.3.4), choline phosphotransferase (EC 2.7.8.2), ethanolamine phosphotransferase (EC 2.7.8.1), PE methyltransferase (EC 2.1.1.17), PS decarboxylase (EC 4.1.1.65), phosphatidylglycerolphosphate synthetase (EC 2.7.8.5), phosphatidylinositol synthetase (EC 2.7.8.11), and base exchange enzymes of ethanolamine, serine and inositol. These findings suggest that filarial worms can synthesize PC by two pathways, PE by three pathways, and PI by two pathways and fabricate PS, PG and CL.     

Qualitative characterization of antibody responses to single and multiple Brugia pahangi infections in jirds

Antibody responses of jirds, singly and multiply inoculated with Brugia pahangi infective larvae (L3), to soluble somatic extracts of adult parasites were characterized by western blot analysis. Forty-two protein bands ranging in molecular weight from 12 to 160 kDa were recognized by sera from infected jirds. Antibody recognition of individual B. pahangi antigen bands in this assay appears to be independent of antibody enzyme-linked immunosorbent assay (ELISA) titers to crude parasite extract, severity of lymphatic lesions, levels of microfilaremia, numbers of L3 inoculated, or numbers of adult parasites in individual jirds. Antibody recognition of protein bands with molecular weights of 37 kDa, 21 kDa, and 17 kDa, however, did temporally correspond with certain parasitological and pathologic events. Antibody against the 37-kDa protein band first was identified at the onset of patency, reaching a 90% prevalence rate by 90 days postinfection (DPI). The prevalence of this antibody remained high. Antibody recognition of the 21-kDa protein band first occurred at 90 DPI and gradually increased in prevalence during the course of infection temporally similar to the increase in microfilaremia. Recognition of the 17-kDa protein band first occurred at 48 DPI, reached a maximum prevalence of 80% at 90 DPI, and decreased to a minimal prevalence by 160 DPI. Prevalence of antibody responses to the 17-kDa protein band corresponded temporally with the kinetics of the rise and fall of numbers of intralymphatic thrombi. The patterns of antibody response to these 3 bands were similar in both singly and multiply inoculated animals.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Dipetalonema viteae and Brugia pahangi transplant infections in gerbils for use in antifilarial screening

Transplanted infections of Dipetalonema viteae and Brugia pahangi have been evaluated as tools for experimental chemotherapy. Attempts were made to establish these filariae in similar pharmacokinetic sites within the same host, so that direct comparisons of in vivo drug susceptibilities could be made. Unfortunately, it was not possible to establish B. pahangi in the subcutaneous tissues, the preferred site of D. viteae. Therefore, intraperitoneal B. pahangi and subcutaneously implanted D. viteae in gerbils were used for the study. D. viteae infections were significantly enhanced by concomitant infections with B. pahangi, while B. pahangi infection rates were unaffected by the presence of D. viteae. Experiments with amoscanate, CGP6140 and Mel W demonstrated the importance of employing both B. pahangi and D. viteae for antifilarial discovery work and the fundamental effect of parasite location on drug efficacy. D. viteae rapidly migrate from the peritoneal cavity of gerbils following implantation; twenty one hours after infection 73% of transplanted worms were found in the subcutaneous tissues. It was shown that the migration response could be used as a stringent parameter for demonstrating antifilarial activity. D. viteae were exposed to antifilarial drugs for 24 hours in vitro, washed and implanted into the peritoneal cavity of gerbils. At autopsy, 5 days later, 10(-8)M ivermectin and milbemycin D had prevented migration; CGP6140, amoscanate, suramin, flubendazole and furapyrimidone were also detected at less than 10(-6)M using this parameter. In all cases the migration response was more sensitive to drugs than parasite kill. Ivermectin's ability to inhibit worm migration through the tissues is discussed, with respect to the role of itinerant males in the reproductive cycle of Onchocerca volvulus.     

Brugia pahangi: inhibition of protein synthesis

The effects of inhibitors of protein synthesis and electron transport on the incorporation of [14C]leucine and [35S]methionine into protein by the filarial worm Brugia pahangi have been investigated. Cycloheximide inhibits the accumulation of both [14C]leucine and [35S]methionine by the worms and their incorporation into protein. In addition, inhibitors of electron transport and some anti-parasitic compounds also significantly inhibit filarial protein synthesis. Antimycin A and cyanide inhibit [14C]leucine incorporation into protein 63 and 72%, respectively, without affecting either motility or lactate production. Interestingly, the anti-malarial compounds chloroquine and quinacrine also significantly inhibit both accumulation and incorporation of [14C]leucine by B. pahangi. In addition, fluorographs of sodium dodecyl sulfate-polyacrylamide gels of homogenates from filariids incubated in [35S]methionine and cycloheximide with and without chloramphenicol indicate that there is a discrete population of proteins, possibly mitochondrial in origin, that are synthesized in the presence of cycloheximide and are not inhibited by chloramphenicol.     

Distribution and development of Brugia malayi in reinfected cats.

At various time periods after an initial exposure to 50 Brugia malayi larvae on one hind foot cats were reexposed to an additional 50 larvae in one of 3 ways: on the previously infected limb only, on the contralateral, uninfected limb only, or on both hind limbs simultaneously. At the time of reexposure uninfected controls were exposed to 50 larvae on one hind foot in a similar manner. From 2 to 4 weeks after reexposure to larvae, the cats were necropsied and the appropriate lymph nodes and vessels examined for adult or developing worms. An existing infection in one limb did not influence early migration or development of larvae introduced into the contralateral leg. Previous infection in the same limb did not consistently result in decreases in the number of developing larvae from the second exposure but did alter the distrubution of larvae. In repeat infections, larvae were consistently located in a moe distal area of the limb than were larvae from an initial infection at a comparable time.     

Rapid Detection and Identification of Wuchereria bancrofti,Brugia malayi,B. pahangi,and Dirofilaria immitis in Mosquito Vectors and Blood Samples by High Resolution Melting Real-Time PCR

A simple, rapid, and high-throughput method for detection and identification of Wuchereria bancrofti, Brugia malayi, Brugia pahangi, and Dirofilaria immitis in mosquito vectors and blood samples was developed using a real-time PCR combined with high-resolution melting (HRM) analysis. Amplicons of the 4 filarial species were generated from 5S rRNA and spliced leader sequences by the real-time PCR and their melting temperatures were determined by the HRM method. Melting of amplicons from W. bancrofti, B. malayi, D. immitis, and B. pahangi peaked at 81.5±0.2℃, 79.0±0.3℃, 76.8±0.1℃, and 79.9±0.1℃, respectively. This assay is relatively cheap since it does not require synthesis of hybridization probes. Its sensitivity and specificity were 100%. It is a rapid and technically simple approach, and an important tool for population surveys as well as molecular xenomonitoring of parasites in vectors.