Brugia pahangi: uptake and incorporation of adenosine and thymidine.

The uptake and incorporation of adenosine and thymidine by infective larvae, 10-day-old juvenile, and adult stages of Brugia pahangi were investigated using scintillation counting and autoradiographic techniques. No evidence of thymidine incorporation by the worm was obtained in this study. Scintillation counting methods demonstrated that ¹⁴C-labeled adenosine was incorporated by all three stages of this filarial worm. Autoradiography, performed on worms incubated in [³H] adenosine from 5 min through 2 hr, revealed that following 5–15 min incubation the greatest degree of adenosine incorporation occurred in the hypodermis and somatic cords. Adenosine incorporation into the deeper body tissues, including the gut, increased significantly with longer periods of incubation. The results obtained further support the concept that nutrient uptake in B. pahangi occurs by a transcuticular route.     

Acknowledgment

The uptake and incorporation in vitro of various nucleic acid precursors by microfilariae, third-stage infective larvae, 10-day-old juveniles and adult worms of Brugia pahangi were investigated using scintillation counting and autoradiographic techniques. A significant uptake of uracil and of purines, including adenine, hypoxanthine, and guanine was demonstrated in this study. No evidence was obtained for the uptake and incorporation of thymine, cytosine, orotate, formate, folate or p-aminobenzoic acid by either micro- or macrofilariae of B. pahangi.     

Brugia pahangi: stage-specific antigens on microfilariae detected by serum from infected jirds or by monoclonal antibodies

Experiments were carried out to determine whether there are stage-specific antigens on microfilariae of Brugia pahangi, using sera from Mongolian jirds infected with B. pahangi and monoclonal antibodies against microfilariae of B. pahangi. These studies showed that microfilariae have both stage-specific and nonspecific antigens. The nonspecific antigens were also present on adult worms and on infective larvae. Among monoclonal antibodies, 6 out of 14 clones produced antibodies against the microfilarial stage-specific antigens, and 8 clones produced antibodies against nonspecific antigens. These monoclonal antibodies could not distinguish between adults, microfilariae, or infective larvae of B. malayi and B. pahangi.     

Induction of host resistance to Brugia pahangi in jirds (Meriones unguiculatus) protected by chemoprophylaxis

Jirds were given a chemoprophylactic inoculation of flubendazole (FMBZ) and then five injections of infective larvae of Brugia pahangi whilst still protected by the FMBZ. When the drug was thought to be non-effective the jirds (and controls) were given a challenge infection of B. pahangi larvae. By comparison with control jirds the treated-infected-challenged jirds had 40% fewer adult worms. The control treated-challenged jirds contained mostly sterile female worms showing that they were still partially protected by FMBZ but worms numbers were not significantly reduced as compared with untreated controls.     

Experimental Brugia pahangi and B. malayi infections of callitrichid primates

The callitrichid primates, Callithrix jacchus jacchus (the marmoset) and Saguinus labiatus (the tamarin) were inoculated with infective larvae of Brugia malayi and B. pahangi. Microfilaraemia at low levels developed in 3 out of 4 C.j. jacchus infected with B. malayi and living or dead adult worms found in all 4. Only one of 4 C.j. jacchus became microfilaraemic (mf + ve) when given B. pahangi and adults were found in two. Of 4 S. labiatus given B. pahangi one became very lightly mf + ve and adults were found in 3. It is concluded that these animals are not suitable hosts for chemotherapeutic experiments.     

Brugia pahangi in nude mice: protective immunity to infective larvae is Thy 1.2+ cell dependent and cyclosporin A resistant

Mechanisms of protective immunity to larvae of Brugia pahangi were studied in congenitally athymic nude C3H/HeN mice and their syngeneic heterozygous littermates. An average 11% of subcutaneous larval inocula was recovered from control nudes 28 days after inoculation. No worms were recovered from nude recipients of viable splenic Thy 1.2+ T lymphocytes from heterozygotes which had killed a priming dose of B. pahangi larvae. Primed T lymphocytes, depleted of either Lyt 1.1+ or Lyt 2.1+ cells or incubated with anti-Thy 1.2 monoclonal antibody and complement, failed to protect nude mice against a larval challenge. Nor were primed B lymphocytes depleted by Thy 1.2+ T cell contaminants protective. Treatment with cyclosporin A (CsA) did not increase the numbers of worms recovered from heterozygotes nor did CsA treatment of heterozygous cell donors abolish the ability of primed Thy 1.2+ T lymphocytes to transfer protection to nude mice. IgG but not IgM antibody titres to B. pahangi antigens were depressed in all CsA-treated mice. CsA treatment of nude mice had no direct effect upon development of B. pahangi larvae. These results show that protective immunity to larvae of B. pahangi in mice depends upon small numbers of Thy 1.2+ T cells which are CsA-resistant.     

Studies with Brugia pahangi 17. The anthelmintic effects of diethylcarbamazine.

Diethylcarbamazine (DEC) was active in vitro against infective larvae and microfilariae of Brugia pahangi but only at high concentrations. When fed to mosquitoes which were infected with B. pahangi it had little or no activity. In jirds it was inactive against B. pahangi microfilariae and adults when administered at 300 mg/kg for 5 days either by the intraperitoneal or oral route. In cats given 25 or 50 mg DEC/kg intraperitoneally on 3 or 5 occasions it was not microfilaricidal, but most of the adult worms died within 30 days of the end of treatment. Although most microfilariae disappeared from the blood of cats immediately (i.e., within an hour) after treatment, they reappeared within a few hours in the same numbers. Microfilarial levels were reduced after treatment but there was no precipitate decline as occurs in human B. malayi patients.     

Electron microscopical studies of Strongyloides ratti infective larvae: loss of the surface coat during skin penetration

Previous indications using radiolabelled larvae that Strongyloides ratti free-living infective larvae lose a surface coat during penetration of the skin were further investigated by transmission electron microscopy of the cuticle of S. ratti infective larvae in the free-living stage, after penetration of mouse skin, and after migration to the lungs. These studies demonstrated the presence of a faint electron-dense surface coat external to the epicuticle on free-living worms which was absent from larvae recovered from the skin and lungs. When free-living infective larvae were incubated in 10% CO2 at 37 C and then examined with phase-contrast microscopy, worms were observed in the process of losing this coat. These observations confirm the hypothesis that S. ratti infective larvae lose a surface coat during penetration of the skin.     

Uptake and utilization of arachidonic acid in infective larvae of Angiostrongylus cantonensis

Infective larvae of Angiostrongylus cantonensis may take up and incorporate exogenous arachidonic acid into their lipid pool. By scintillation counting, uptake and incorporation were determined to be time dependent. Arachidonic acid was mainly incorporated into phospholipid (56.8%) and neutral lipid (22.4%) pools. In the neutral lipids, 64.0% was diglyceride and 36.0% triglyceride. Phosphatidylcholine was the predominant fatty acid in the phospholipid pool. In addition to the release of leukotriene B4, the parasite was found to generate radiolabelled CO2 after incubation with [U-14C]arachidonate. Moreover, enzymatic analysis of crude extracts revealed the presence of acyl-CoA dehydrogenase (short and long chain), thiolase, enoyl-CoA hydratase and 3-hydroxyacyl-CoA dehydrogenase. These findings suggest that infective larvae of A. cantonensis not only take up and incorporate exogenous arachidonic acid into their lipid pool, but may also utilize the fatty acid through a functional β-oxidation pathway.     

Delayed macrofilaricidal activity of diethylcarbamazine against Brugia pahangi in Mongolian jirds

The macrofilaricidal activity of diethylcarbamazine (DEC) was confirmed in jirds infected with Brugia pahangi. Seventy jirds were inoculated subcutaneously with 100 infective larvae. At 20 weeks post-infection, the microfilaraemic jirds were divided into two groups, untreated and treated. For the treated group, 200 mg kg(-1) of DEC was injected intraperitoneally for 5 consecutive days. One, 4, 8, 12, 16 and 27 weeks after the final treatment, 4-7 jirds in each group were sacrificed to measure adult worm burdens. The number of adult worms recovered from treated jirds was comparable to controls at earlier necropsy (1 and 4 weeks post-treatment). However, at late necropsy (8 weeks and later) the recovery rate of adult worms in treated jirds was significantly lower than that in untreated controls, indicating an adultcidal effect of DEC. The present study demonstrates that DEC requires 8 weeks to kill B. pahangi adult worms in jirds and that the Mongolian jird is a useful model for screening antifilarial activity.     

Brugia pahangi: production of a monoclonal antibody reactive with the surface of infective larvae.

Monoclonal antibodies against infective third-stage larvae (L3) of Brugia pahangi were generated from mice immunized with L3 antigens. The monoclonal antibodies were L3 stage-specific or stage-nonspecific. A BpG1 monoclonal antibody (IgG1 subclass) showing L3 stage-specificity was examined in detail. BpG1 recognized the surface of B. pahangi L3 and also reacted with the surface of Brugia malayi L3 but not with the surface of filarial worms of other genera, such as Acanthocheilonema viteae and Litomosoides carinii. BpG1 promoted cellular adhesion to the surface of B. pahangi L3. BpG1 bound on living L3 was shed but the shedding rate was relatively slow. The surface antigen recognized by BpG1 had a molecular weight of 58 kDa. It was stable to heat and periodate treatments but sensitive to trypsin digestion and was released from living L3 by SDS but not by Triton X-100 or CTAB. Preincubation of L3 with BpG1 significantly reduced the recovery rate of worms compared with the preincubation with a monoclonal antibody (IgG1 subclass) against the inner tissues of B. pahangi L3 or control supernatant of P3U1 myeloma cells. This result suggests that the antigen containing the BpG1 epitope may be one of the targets of a protective immune response against Brugia infection.     

Trichinella spiralis: behavior, structure, and biochemistry of larvae following exposure to components of the host enteric environment

Four layers are present on the surface of infective larvae of Trichinella spiralis isolated from host muscle in pepsin-HCl. Trypsin treatment of pepsin-HCl isolated worms caused partial degradation and removal of large patches of the two outer surface layers. Following exposure to bile, only traces of the outer layers remained on the worms surface. These changes in the worm surface were accompanied by a shift from Type I behavior, typical of pepsin-HCl isolated larvae, to Type II behavior, (snakelike) following exposure to either trypsin or bile. Worm behavior was also temperature dependent. Type I behavior was typical of worms maintained at room temperature regardless of treatment, while Type II behavior displayed by worms held at 37 C was treatment dependent. The absorption of in vitro glucose or beta-methyl-D-glucoside was lowest in pepsin-HCl isolated first stage infective larvae, significantly higher in trypsin treated worms and greatest in worms following exposure to bile. Sugar uptake by worms isolated from the host small intestine after 1 hr of enteral infection was similar to that seen in worms isolated from host muscle in pepsin-HCl. Sugar uptake in vitro in worms 2 hr following enteral infection was similar to worms following exposure to bile. The highest levels of sugar absorption in vitro occurred in worms which had resided in the small intestine for 3 hr. The lowest rates of incorporation of label into worm tissues was seen in 1 hr enteral and pepsin-HCl isolated worms. Infective larvae treated with trypsin or bile incorporated significantly greater amounts of label than the two former groups. The highest levels of incorporation of label into worm tissues was seen in 3 hr enteral worms. These findings support the view that trypsin, bile, and temperature serve as environmental cues which lead to alteration of the parasite's behavioral and nutritional status.     

Brugia pahangi in rats: increasing the number of infective larvae inoculated increases the percentage of microfilaremic rats

One hundred Brugia pahangi infective larvae (L3) caused microfilaremic (mf + ve) infection in 56% of inbred PVG rats. Adult worms were recovered consistently from infected rats but worm recovery was very low, only 1-3% of L3 inoculated survived to adulthood and the worms were dispersed in a wide range of anatomical sites. This suggested that lack of microfilaremia may be due to the low probability of male and female worms meeting in the same site and thus may be numerically and topographically based. When the number of infective larvae inoculated was increased to 500, the percentage of mf + ve infections in rats also increased to 94%, corroborating the hypothesis that lack of mf was not due to an immune response. In a further experiment all infected rats had lost both mf and adult worms by day 420. It has yet to be established whether final rejection of the parasite is due to immunity.     

Effects of tetracycline on the filarial worms Brugia pahangi and Dirofilaria immitis and their bacterial endosymbionts Wolbachia

Wolbachia endosymbiotic bacteria have been shown to be widespread among filarial worms and could thus play some role in the biology of these nematodes. Indeed, tetracycline has been shown to inhibit both the development of adult worms from third-stage larvae and the development of the microfilaraemia in jirds infected with Brugia pahangi. The possibility that these effects are related to the bacteriostatic activity of tetracycline on Wolbachia symbionts should be considered. Here we show that tetracycline treatment is very effective in blocking embryo development in two filarial nematodes, B. pahangi and Dirofilaria immitis. Embryo degeneration was documented by TEM, while the inhibition of the transovarial transmission of Wolbachia was documented by PCR. Phylogenetic analysis on the ssrDNA sequence of the Wolbachia of B. pahangi confirms that the phylogeny of the bacterial endosymbionts is consistent with that of the host worms. The possibility that tetracycline inhibition of embryo development in B. pahangi and D. immitis is determined by cytoplasmic incompatibility is discussed.     

Pinocytosis of Ferritin from the Gut Lumen in Larvae of a Sea Star (Patiria miniata) and a Sea Urchin (Lytechinus pictus)

Pinocytosis of macromolecules from the gut lumen is demonstrated for the first time in larval stages of invertebrates. Developing sea stars ( Patiria miniata ) and sea urchins ( Lytechinus pictus ) were incubated in seawater containing ferritin, which was detected in cell organelles by transmission electron microscopy. Pinocytotic uptake of ferritin by gut cells of Patiria could be detected as soon as the larval mouth opened before the esophagus, stomach and intestine could be distinguished from one another; in contrast, no pinocytosis was detected at the comparable developmental stage (the prism larva) of Lytechinus . Pinocytosis was first detected in developing Lytechinus in pluteus larvae, especially in the stomach and intestine. In gut cells of both kinds of echinoderm larvae, the ferritin progressed rapidly from coated pits at the luminal cell membrane to secondary lysosomes (e.g. this progression took only about 10 min in stomach cells of Patiria larvae). Phagocytosis from the gut lumen was never observed after latex beads or starch granules were fed to larvae of Patiria and Lytechinus . Moreover, there was no evidence of pinocytosis of ferritin or phagocytosis of large particles by epidermal cells of larvae of either species.     

Attempted vaccination of jirds (Meriones unguiculatus) against Brugia pahangi with radiation attenuated infective larvae

Jirds were vaccinated by three to five subcutaneous (SC) injections of infective larvae of Brugia pahangi which had been irradiated at 25, 45 or 90 krads from a 60Co source. They were challenged either SC or intraperitoneally. Vaccination with four doses of 50 larvae irradiated with 25 krads produced 49.3% resistance to IP challenge worms and 39.8% against SC challenge worms. Five doses of larvae irradiated with 45 krads produced 62% resistance to SC challenge. Three doses of larvae irradiated with 90 krads produced 74.9% resistance to SC challenge and five doses produced 76.2% resistance. The reasons why irradiated larvae produce resistance whereas normal larvae do not are discussed.     

Dissociation of the protective immune response in the mouse to Strongyloides ratti

The generation of protective immunity by various stages in the life-cycle of Strongyloides ratti and the phases against which resistance is directed has been examined in murine strongyloidiasis. Mice were exposed to natural, complete infections, were treated with thiabendazole (which largely resembles the natural infection), were treated with cambendazole (which restricts infection to the larval stage), or infected directly by oral transfer of adult worms. Mice that were infected with infective larvae alone did not become resistant to infective larvae or the complete infection but were resistant to adult worms implanted directly into the gut. Mice exposed to adult worms alone were resistant to natural infections and adults worms implanted directly but were not resistant to infective larvae. On the other hand, mice that had received prior natural infections showed evidence of resistance to infective larvae, adult worms, and natural, complete infections. It is concluded that there is immunological cross-reactivity between infective larvae and adult worms but that under certain circumstances the infective larvae are able to evade the host's protective immune response.     

The ability of Aedes aegypti mosquitoes to survive and transmit infective larvae of Brugia pahangi over successive blood meals

The mortality of Aedes aegypti mosquitoes increased; immediately following a blood meal containing microfilariae of Brugia pahangi, when infective larvae began to migrate out of the flight muscles and when infective larvae were lost from the mosquitoes during a blood meal. When infective mosquitoes took a second blood meal 86.2% of the infective larvae escaped from their bodies. However, only 50.3% escaped when mosquitoes fed through a thin layer of cotton. Infective larvae in the abdomen of the mosquitoes stood the least chance of escaping from the insects. When infective mosquitoes were offered a third blood meal four days later, the proportion of infective larvae in the head and labium had risen from 56.6% in the control group to 66.0% and 69.4% in the two test groups. At this third feed 54.7% and 75.7% of the infective larvae were lost from mosquitoes with a low and medium pre-feeding worm burden respectively. This suggests that the escape of infective larvae from mosquitoes with only a few worms is less efficient than from mosquitoes with a medium worm burden.     

Alloxan cytotoxicity in vitro. Microscope photometric analyses of Trypan Blue uptake by pancreatic islet cells in suspension.

Suspensions of islet cells were prepared by shaking pancreatic islets from non-inbred ob/ob mice in a Ca2+-free buffer. The cells were incubated with or without 20 mM-alloxan, and subsequently with Trypan Blue. The uptake of Trypan Blue by cell nuclei was analysed by microscope photometry and by counting the frequency of cells appearing stained on visual inspection. Cells classified as stained or unstained by inspection showed no overlap in nuclear absorbance. Suspensions not exposed to alloxan contained 70-80% of unstained cells. Alloxan markedly decreased the frequency of unstained cells, an effect counteracted by 5 or 20 mM-D-glucose. The spectrum of Trypan Blue in islet-cell nuclei was red-shifted by about 20 nm. A similar red-shift was observed on adding the dye to solutions of albumin or histones, but not on mixing the dye with DNA. Binding to basic proteins may explain the concentrative uptake of Trypan Blue in dead cells and contribute to the oncogenic transformation of phagocytotically active cells. Beta-Cells in vitro are killed by alloxan and hence represent a valid model for studying the diabetogenic action of the drug.     

The effects of abdominal irradiation on intestinal transport in the rat as assessed with isolated epithelial cells

The time course of the effect of exposure to sublethal irradiation on transport of several substrates by the intestine has been studied using isolated enterocytes. Rats received a single dose of 6 Gy to the abdomen, and isolated intestinal epithelial cells were prepared 3, 7, and 14 days later. The ability of the cells to take up D-glucose, L-leucine, and glycyl-L-leucine was assessed using 2.5-min incubation periods and was compared with the uptake in control cells. It was found that the protein content of the cells increased after irradiation, and although some of this was the result of increased binding of albumin to the cells there was also a nonspecific increase in most cell proteins. Consequently uptake data were expressed per unit number of cells and not per milligram of cell protein. Comparison of uptake expressed in this way showed that D-glucose and glycyl-L-leucine uptake was elevated 3 days after irradiation while that of L-leucine was unaffected. By 14 days after irradiation the glucose and glycyl-L-leucine uptake had returned to normal but the L-leucine transport was depressed. These data indicate that the effects of irradiation upon substrate transport in the intestines are not uniform and that although the cell population is initially reduced the remaining cells can compensate by increasing their transport capacity.