Angiostrongylus costaricensis and experimental infection of Sarasinula marginata II: elimination routes

Angiostrongylus costaricensis intermediate hosts are terrestrial mollusks mostly belonging to the Veronicellidae family. In the present investigation we focused on the mechanisms of larval expulsion from Sarasinula marginata infected with A. costaricensis. Twenty-five mollusks were individually infected with 5000 L1 and sacrificed at 30 min and 1, 2, 4, 6, and 8 h post-infection and at days 1, 2, 4, 5, 6, 8, 10, 11, 12, 14, 15, 16, 20, 21, 22, 25, 26, 28, and 30 post-infection; the mollusks were then fixed and stained. Diverse organs involved throughout the course of the migratory routes of larvae from oral penetration on were specified and the mechanisms of larval access to the fibromuscular layer through the kidney, rectum, and vascular system were defined. The elimination of L3, derived from oral and/or cutaneous infections, appears to depend on granulomas located close to the excretory ducts of mucous cells.     

Angiostrongylus costaricensis: complete redescription of the migratory pathways based on experimental Sigmodon hispidus infection

Angiostrongylus costaricensis lives in the cecal and mesenteric arteries of its vertebrate hosts, and causes an inflammatory disease in humans. To investigate unknown aspects of the abdominal angiostrogyliasis pathogenesis, infected Sigmodon hispidus were sequentially studied in different times of infection. The study revealed that L3 goes alternatively through two migratory courses during its development into an adult worm: lymphatic/venous-arterial and venous portal pathways. The former is considered the principal one, because it is used by most of the larvae. Like other metastrongylides, A. costaricensis passes over the pulmonary circulation to migrate from the lymphatic system to the arterial circulation, where they circulate during some days before reaching their definitive habitat. The oviposition by mature females began on 15th day. Eggs and L1 were detected mainly in the intestine and stomach, surrounded by inflammatory reaction constituted by macrophages, monocytes, and eosinophils. They were also spread to the lungs, mesenteric lymph nodes, pancreas, spleen, and kidneys. The larvae (L1) exhibited the centripetal capacity to invade the lymphatic and venous vessels of the intestine and mesentery. Adult worms that developed in the venous intrahepatic pathway migrated downstream to reach the mesenteric veins and laid eggs that embolized in the portal hepatic vessels.     

Trichinella spiralis: site selection by the larva during the enteral phase of infection in mice

Mice, belonging to two strains, were infected by the oral route with muscle larvae of Trichinella spiralis. Host animals were killed at various times up to 48 hr after administration of larvae, and the infected small intestines were fixed immediately in 10% neutral formalin. Sections of infected gut, embedded in paraffin and cut at 5 μm, or in methacrylate and cut at 0.5 μm, revealed that all stages (i.e., 1 to 4) of T. spiralis were embedded between the lamina propria and the columnar epithelium. First-stage muscle larvae occupied this niche as early as 10 min after introducing them into the host by the oral route.     

Studies on resistance in snails. 4. Induction of ventricular capsules and changes in the amebocyte-producing organ during sensitization of Biomphalaria glabrata snails.

Formation of an amebocyte aggregate in the ventricular cavity of Biomphalaria glabrata can be induced 30 hr or more after a single infection by irradiated or (less frequently) by normal Echinostoma lindoense miracidia. The resulting amebocyte mass frequently encapsulated and destroyed the developing E. lindoense sporocysts within the ventricle. The constituent amebocytes of the capsule correspond in vitro and by staining characteristics to circulating amebocytes of uninfected snails, but with additional inclusion bodies, increased mucopolysaccharide, acid phosphatases, and lipid-positive staining reactions. Mitotic activity, rapid growth, and later regression of the amebocyte-producing organ (located between the posterior mantle epithelium and anterior pericardial endothelium) follow the growth and regression sequence of the ventricular capsule. Though peripheral foci of secondary amebocyte production have been found and were previously known, the amebocyte-producing organ appears to be the primary amebocyte source responsible for the snails' rapid intraventricular sporocyst encapsulation.     

Detection of the acute phase of abdominal angiostrongyliasis with a parasite-specific IgG enzyme linked immunosorbent assay

Angiostrongylus costaricensis may cause intestinal lesions of varied severity when it accidentally infects man in Central and South America. First-stage larvae have never been detected in stools. Therefore, a parasite-specific IgG ELISA was evaluated for the determination of the acute phase of infection. The specificity and the sensitivity of the immunoassay was shown to be 76.2% and 91.1%, respectively. Eight serum samples taken from patients with histopathological diagnosis, at different time points (3 to 15 months) after surgical treatment, showed a sharp and early decline in antibody reactivity. The titration of anti-A. costaricensis antibodies has proved to be a useful method for the diagnosis of acute abdominal angiostrongyliasis.     

Abdominal angiostrongyliasis in rodent experimental infection: evidence for systemic circulation of first stage larvae

Eggs of Angiostrongylus costaricensis embrionate and hatch in the course of their migration in the intestinal wall, and first stage larvae (L1) are released in feces. Aiming to investigate the possible systemic circulation of L1, we inoculated mice and, four weeks later, examined their peritoneal cavities and several organs for the presence of L1. A total of 65 larvae were found in extra-intestinal organs (kidney, heart, spleen, liver, lungs). No larvae were found in blood or in the peritoneal cavity. 320 and 578 L1 were found in intestinal wall and intestinal contents, respectively. The experiment was repeated and it confirmed that the metastrongylid larvae found in several organs were larval stages of A. costaricensis. Ten Oligoryzomis sp. rodents, a natural host for A. costaricensis, were also infected and in three animals L1 could be recovered from several organs as well as from bronchoalveolar lavage (BAL) in one of them. These data indicate that systemic circulation and bronchial elimination of L1 may represent an alternative route for release of L1 of A. costaricensis into the environment for transmission to the intermediate host.     

Heligmosomoides polygyrus: Simple recovery of post-infective larvae from mouse intestines

Mice infected orally with third-stage larvae of Heligmosomoides polygyrus were killed at various times after infection. Their small intestines were removed, tied at each end and incubated at 37 C in dilute culture medium. When intestines were taken from mice infected for a period of between 1 and 7 days, a number of developing larvae comprising up to 20% of the infective dose emerged within 60 min through the intestinal wall into the medium. The recovery of emergent larvae was highest using intestines from mice infected 36 to 120 hr previously. The proportion of parasites emerging from the intestines of 48-hr-infected mice was similar for doses of 100 to 2400 larvae. Significantly fewer larvae emerged from the intestines of mice resistant to reinfection and challenged with third-stage larvae 36–72 hr before necropsy.     

Trichinella spiralis: modifications of the cuticle of the newborn larva during passage through the lung.

A scintigraphic method was developed to study the distribution of radioactivity after iv injection of 131I-labeled Trichinella spiralis newborn larvae into normal rats. It was found that the radioactivity was immediately retained in the lungs and thereafter slowly released, with a mean transit time in excess of 9 hr, as calculated by image analysis. At various times after iv injection of newborn larvae into normal mice, the lungs were removed and parasites were recovered and counted. Fifty to seventy percent of the larvae injected were recovered after 30 sec, between 10 and 30% after 1 min, and less than 4% at 15 min. These results indicate that during the very rapid passage of newborn larvae through the lungs, labeled components of the cuticle are detached and retained. It is suggested that the modifications produced in the cuticle of the newborn larva during its passage through the lung may increase its resistance to the nonspecific defense mechanisms of the host.     

Trichinella spiralis: vascular recirculation and organ retention of newborn larvae in rats

The recirculation of Trichinella spiralis newborn larvae was studied in inbred AO rats. Newborn larvae collected after in vitro incubation of adult T. spiralis worms for 2 or 24 hr were injected into rats through the tail vein or hepatic portal vein. Blood samples from the femoral vein, hepatic portal vein, and abdominal aorta were collected at intervals from 1 min to 24 hr after larval injection. Newborn larvae of both ages (24 hr or 2 hr old) persisted in femoral vein blood for less than or equal to 5 hr after injection, but they could be detected in portal vein blood by 24 hr after injection. The injection of larvae into a tail vein or the portal vein did not influence the pattern of larval circulation, although there was a 1-5 min delay in newborn larval appearance time after injection into the portal vein. Transcapillary migration through tissue and back to the circulation was evident in the appearance of newborn larvae in the thoracic duct lymph up to 24 (occasionally 48) hr after tail vein injection of newborn larvae. During the course of a natural primary infection, no evidence for trapping of larvae in the mesenteric lymph node could be found despite direct larval migration through this organ. Injected newborn larvae were retained in the lungs, and small numbers could be recovered 24 hr after intravenous injection. We conclude that a proportion of newborn larvae recirculates within the vasculature for several hours; a smaller population extravasates but can reenter the circulatory system via the lymphatics. Furthermore, some newborn larvae are found in organs rich in capillaries up to 24 hr after their entry into the blood.     

Observations on the routes of infection of Oswaldocruzia filiformis (Nematoda: Trichostrongylidae) in amphibia

The oral, percutaneous and subcutaneous routes of infection of Oswaldocruzia filiformis were investigated in amphibia. Tadpoles of Bufo bufo and Rana temporaria can be infected with O. filiformis when kept temporarily in a suspension of infective larvae in water. Larval stages and subadults were found in tadpoles. All stages of the parasite, including egg-producing females, were found after metamorphosis of the host. However, under natural circumstances infection of tadpoles seems unlikely. Oral infections in metamorphosed hosts of both species were successful in 97.5% of the host animals used. The first eggs appeared 29 days after infection in the faeces. The oral route seems to be normal for O. filiformis in amphibia. Experiments on percutaneous infections did not reveal actual penetration of larvae in or through the skin nor a subsequent migration through host tissues. Sometimes a few larvae were found in the stomach and intestine, but in these particular cases the experimental conditions did not totally exclude the possibility of oral infections. Consequently, the percutaneous route of infection is not plausible for O. filiformis. Subcutaneous inoculation of infective larvae seems to be a possible way of establishing experimental infections. Erratic localisation of the parasite in the enlarged gall bladder of the host was observed.     

Trichinella spiralis: effect of high temperature on infectivity in pork

Twenty gram samples of homogenized Boston shoulder from swine experimentally infected with Trichinella spiralis were sealed in plastic pouches, pressed to a uniform thickness of 2 mm, and subjected to water bath temperatures of 49, 52, 55, 60, and 63 +/- 0.5 C for intervals of 2 min to 6 hr, especially within the interval of 0 to 15 min. These times included a period of about 1 min at the start and a period of about 1 min at the end for temperature equilibration. Treated samples were rapidly chilled to 25 C and then digested in a 1% pepsin-HCl solution at 37 C for 18 hr to recover T. spiralis larvae. The recovered larvae were suspended in 2 ml saline; 1 ml of this suspension was introduced into the stomach of each of two rats. The linear equation, log (time) = 17.3 -0.302 (temperature), was calculated from the time required at each temperature for the inactivation of T. spiralis larvae. The correlation coefficient for that relationship was r = -0.994. Larvae heated in the meat to 55 C for 4 min retained their infectivity, but were rendered noninfective after 6 min at 55 C. At 60 C, larvae were not infective after only 2 min (zero dwell time); whereas at 52 C, 47 min were required to render the larvae noninfective. Larvae in meat heated to 49 C were infective after 5 hr but not after 6 hr. These data demonstrate that the destruction of infectivity of T. spiralis is time-temperature related.     

Low susceptibility of Achatina fulica from Brazil to infection with AngioIylus costaricensis and A. cantonensis

Introduction of Achatina fulica in Brazil has led to serious concerns about its role as vector for metaIylid worms: AngioIylus costaricensis and A. cantonensis. Experimental infection with both parasites was performed to evaluate the potential risk for their transmission by the giant African snail. Groups of 5 animals, both wild and bred at captivity were exposed at different inocula: 1, 5, and 10 x 10(3) L1 of A. costaricensis and A. cantonensis. In all groups, few snails got infected and parasitic burden was low. Two different ways of infection were tested: ingestion produced higher numbers of L3 than the inoculation through an artificial hole in the shell. We also report the parasitological examination of 6 batches of wild A. fulica from Florianópolis, state of Santa Catarina, Brazil: only 1 out of 244 animals were infected with metaIylid larvae. Taken together these data indicate that the giant African snail occurring in Southern Brazil is not a permissive host for both AngioIylus species and does not represent a significant risk for transmission of these parasites.     

Immunocytolocalization of two protection-inducing antigens of Trichinella spiralis during its enteral phase in immune and non-immune mice

Monoclonal antibodies (mAb) recognizing epitopes on the 48K (beta stichocyte specific) and the 50/55K antigen (alpha stichocyte specific) were used as first ligands for immunocytolocalization on de-paraffinized sections of infected gut tissue of non-immune and immune CFW strain mice. The enteral phase was studied at 6, 14, 23, 30 hr and 7 days after initiation of infection via the oral route, times corresponding in worm development to the first (L1), second (L2), and third (L3) stage larva and adult. No change in the intensity of the immune reaction with either mAb was noted in parasites developing within immune or non-immune mice for any of the time-points studied. The 48K and the 50/55K antigens were present within the stichocytes at 6 hr. Enterocytes adjacent to some worms also stained positive for both epitopes at this time. Throughout worm development, the amount of each antigen within the worm diminished, until almost none was left at 30 hr. At day 7, the 48K antigen was present within a few stichocyte cells, the canalicular tree, and within the lumen of the midgut. The 50/55K antigen at this time point was localized within only a few stichocyte granules and on the lining of the worm's gut. Embryo stages did not possess either the 48K or 50/55K epitopes. A marked increase in cells bearing IgG in the lamina propria was noted in immune mice when compared with their non-immune counterparts.     

Thermal conditioning of fifth-instar Cydia pomonella (Lepidoptera: Tortricidae) affects HSP70 accumulation and insect mortality

Abstract.  Levels of HSP70 protein of fifth-instar codling moth [ Cydia pomonella (L.) (Lepidoptera: Tortricidae)] are determined after conditioning at 35 °C for different times and also after recovery at 22 °C. Protein samples from larvae conditioned for different times are separated by sodium dodecyl sulphate-polyacrylamide gel electrophoresis electrophoresis. Sub-lethal thermal conditioning at 35 °C for 40 min, 2, 6 and 18 h induces new protein bands in the extracts from treated codling moth larvae. Immunodetection with an antibody to a heat-inducible HSP70 indicates a stronger reaction after 35 °C for 2, 6 and 18 h than after 35 °C for 40 min or control and, during the recovery period at 22 °C, the level of heat shock protein decreases. Conditioning of fifth-instar codling moths at 35 °C also induces thermotolerance in the insects and necessitates longer times at a lethal temperature to ensure mortality. Thermotolerance is correlated with the accumulation of heat inducible HSP70 protein.     

Strongyloides ratti: migration study of third-stage larvae in rats by whole-body autoradiography after 35S-methionine labeling.

In order to clarify the migration pathway of Strongyloides ratti, Wistar rats were given 5,000 35S-labeled infective larvae subcutaneously and killed at 10, 15, 20, 25, 30, 40, and 50 hr postinfection. Prior to inoculation, the specific radioactivity level was assessed in the labeled larvae using a scintillation counter. The frozen rat specimens were sectioned at 50 microm, and the sections were freeze-dried and mounted on X-ray film in darkness. The labeled larvae appeared as dark spots on the film after 14 days of exposure. The infected larvae remained at the inoculated site (lower abdomen) until 10 hr after infection. Some larvae were found in the head portion, whereas others existed sporadically in the skin, liver, and lungs at 15 hr. After 20 and 25 hr, the majority of larvae had accumulated in the head portion. Many larvae appeared in the cranial and nasal cavities; however, no larvae were found in any other organs or tissues. At 30 hr, most larvae had begun to accumulate in the ethmoid region again. At 40 and 50 hr, some larvae were recognized in the ethmoid region, and most had already reached the small intestine. This suggests that the larvae directly move to the nasofrontal portion through the subcutis, rather than migrating to the head through either the viscera, ascending vessels, or the foramen occipital magnum.     

Absorption of intraarticularly injected horseradish peroxidase in synoviocytes of rat synovial membrane: an ultrastructural-cytochemical study

The ability of type A and type S synoviocytes to absorb horseradish peroxidase (HRP) and the intracellular fate of this tracer were studied by electron microscopic cytochemistry. Different concentrations of HRP (0.1-5 mg/ml) were injected into the left knee joint of rats and at intervals ranging from 1 min to 24 hr after injection the synovial membrane was fixed and incubated for HRP. Type A synoviocytes showed a striking ability to absorb HRP at low concentrations. At 1 and 5 min after injection reaction product was localized in coated pits and coated vesicles (110 nm) as well as in smooth-walled vesicles, vacuoles, and tubules. At 15 min to 4 hr postinjection the lysosomal system became increasingly loaded with reaction product. At 24 hr after injection reaction product had disappeared. At higher concentrations of HRP similar observations were made in the A cells, but reaction product was still apparent in lysosomes at 24 hr postinjection. With respect to type S synoviocytes no reaction product was detected within these cells at any time interval after injection of low concentrations of HRP. However, at 5 min after injection of higher concentrations of HRP reaction product was localized in smooth vesicles and vacuoles mainly restricted to the large cytoplasmic processes facing the joint cavity. At 30 min to 4 hr postinjection the lysosomal system became progressively more loaded with HRP reaction product. At 24 hr after injection reaction product still remained in the lysosomal system. The present findings that type A and type S synoviocytes showed major differences with respect to endocytic capacity and cellular structures involved in absorption of HRP support the interpretation that the A and S cells represent two distinct types of cells and further suggest that endocytosis in these two types of cells serve different functions.     

Histopathology of a nuclear polyhedrosis infection in Aedes epactius with observations in four additional mosquito species

Aedes epactius larvae were utilized to study the infection sequence of the nuclear polyhedrosis virus (NPV) from Aedes sollicitans. From 30 min to 6 hr postinoculation, polyhedra and many free virions were observed in the larval midgut lumen. Penetration of the midgut cells by virions was not observed. The first infected nuclei were observed 12 hr postinoculation. Nucleocapsids initially exhibited electron translucent cores which became electron dense before the nucleocapsids acquired an envelope. Envelope acquisition occurred through a process of de novo membrane morphogenesis. Occlusion of the singly embedded virions began by 18 hr postinoculation with the mature rough-surfaced polyhedra averaging approximately 1 by 2 μm. Unusually long nucleocapsids (approximately two or three times the length of other nucleocapsids) were only observed in late infection period nuclei. There was no evidence that long nucleocapsids represented an early developmental stage for nucleocapsids of standard length. Infection was restricted to midgut nuclei and gastric caecae cells. Infected early instar A. epactius larvae became moribund 36 to 40 hr postinoculation and infected midgut nuclei were observed to undergo lysis. The late stages of NPV infection were observed in larvae of A. annandalei, Wyeomyia smithii, Toxorhynchites brevipalpus, and Eretmapodites quinquevittatus. Virion development and occlusion in these species was basically identical to the sequence observed in A. epactius larvae.     

Oral immunization with Escherichia coli K-12 of the fifth instar larvae of the silkworm, Bombyx mori, reared on an artificial diet under completely aseptic conditions.

1. Effect of oral administration of live or formalin-treated Escherichia coli (E. coli) K-12 to the fifth instar, days 1 and 3 larvae of the silkworm, Bombyx mori, on induction of antibacterial activity in the haemolymph was investigated using the silkworms reared on an artificial diet under completely aseptic conditions. 2. When live E. coli was administered to the male day 1 larvae, low but significant antibacterial activity of 3.8 mm was detectable in the haemolymph of one individual at 48 hr after immunization. The proportion of the larvae to express antibacterial activity increased thereafter and at 120 hr after immunization, all three individuals showed antibacterial activity. In day 3 male larvae, activity was detectable at 48 and 72 hr after immunization. 3. When formalin-treated E. coli was orally administered to days 1 and 3 male larvae, no activity was detectable at any time post-immunization. 4. In the second experiment, when day 1 larvae, females and males were orally immunized with live E. coli, only females showed antibacterial activity in the haemolymph, beginning from 24 hr after immunization and up to 96 hr. 5. Removal of an antibiotic, chloramphenicol, from ingredients of an artificial diet was required for induction of antibacterial activity with oral administration of live E. coli. 6. When live E. coli that grows at pH 9.0 was selected and used for oral immunization, antibacterial activity was induced both in females and males at 72 hr after immunization and the activity was observed at 96 hr. 7. These results suggest that establishment of oral immunization with live E. coli in the silkworm larvae requires multiplication of E. coli in the midgut lumen and possibly its colonization on the luminal surface.     

Development of Bacillus thuringiensis in Galleria mellonella larvae exposed to gamma radiation

A suspension of Bacillus thuringiensis was inoculated at 24 and 72 hr into the oral cavity of Galleria mellonella larvae following exposure to 20, 50, and 70 Kr of gamma radiation, respectively. The cytopathology was conducted after B. thuringiensis had developed for 3, 5, and 7 hr and after radiation damage had developed for 27, 29, 31, 75, 77, and 79 hr in the larvae exposed to 20, 50, and 70 Kr, respectively.B. thuringiensis spores appeared in the midgut lumen from 3 to 7 hr after inoculation of 20 Kr irradiated larvae. At 7 hr after B. thuringiensis infection, and 79 hr after 20 Kr irradiation, the following changes were seen: B. thuringiensis rods appeared adsorbed onto the walls of epithelial cells, a few spores appeared in hemolymph, epithelial cells developed vacuoles, and villi appeared detached from the basement membrane.Within a period ranging from 3 to 5 hr after infection, B. thuringiensis rods attacked vacuolated epithelial cells of most of the 50 and 70 Kr irradiated larvae. At 7 hr after infection and at 31 hr after 70 Kr irradiation, the spores reached the interior of some epithelial cells and were also seen concentrated near the basement membrane.In general, the midgut epithelial cells of the 70 Kr-irradiated groups of larvae appeared highly vacuolated, badly disrupted, and in most cases undistinguishable as a result of attack of B. thuringiensis.In short, B. thuringiensis did not show a characteristic pattern of pathology on 20 and 50 Kr-irradiated midgut cells. The problem of permeability of B. thuringiensis toxin into the irradiated cells needs further investigation.     

Thermal treatments to increase acoustic detectability of Sitophilus oryzae (Coleoptera: Curculionidae) in stored grain.

Hidden infestations of stored-product insect larvae are detected most rapidly by acoustic techniques when the larvae are highly active. Larval activity is periodic, however, and it tends to decrease after the larvae are disturbed or cooled. Because of the practical need for rapid inspection of grain at commercial elevators, several heat treatments were tested as potential methods of increasing larval activity and improving the speed and reliability of acoustic detection under adverse conditions. Samples of grain infested with 4th instars of Sitophilus oryzae (L.) were exposed to different radiant and convective heat treatments after they had been conditioned at 11 degrees C, 17 degrees C, or room temperature for 12-24 h. Relative activity levels were evaluated over periods of 0-12 h based on the mean levels in a 15-min interval, 2 h after the beginning of a trial. In comparisons among treatments with precooled larvae, relative activity levels 5-10 min after brief heat pulses were 2-30 times higher than activity levels in precooled controls exposed only to ambient temperatures (25 degrees C). After 15-25 min, the relative activity levels of these heated larvae remained 2-5 times higher than those of the ambient controls. Brief movement disturbances inhibited activity for approximately 20 min at any temperature. These results suggest that, in general, larval detectability is enhanced if cool grain samples are warmed and all samples are left undisturbed for 15-20 min before inspection.