Kinetics of primary and secondary infections with Strongyloides ratti in mice

Dawkins H. J. S. and Grove D. I. 1981 Kinetics of primary and secondary infections with Strongyloides ratti in mice. International journal for Parasitology11: 89–96. The kinetics of infection with S. ratti were quantitated in normal and previously exposed C57B1 /6 mice. In primary infections, larvae penetrated the skin rapidly and were seen in peak numbers 12 h after infection. By 24 h after infection, larval numbers had declined appreciably and there was a slow decrease in numbers thereafter. Larvae were first observed in the lungs at 24 h and maximal recovery occurred at 48 h. It is thought that larval migration through the lungs is rapid. Worms were first seen in the intestines two days after infection. Maximum numbers were seen on the fifth day and worm expulsion was complete by day 10. Two moults took place in the small intestine during days 3 and 4 after infection. Rhabditiform larvae were first noted on the fourth day after infection. Mice exposed to S. ratti four weeks previously had significantly less larvae in the skin 4 and 12 h after infection but by 24 h there was no difference when compared with mice with primary infections. Peak recovery of larvae from the lungs occurred 24 h after infection; significantly less larvae were recovered on days 2 and 3 when compared with normal mice. There was a marked reduction in the adult worm burden in the gut; the number of worms recovered was less than one fifth of that seen in primary infections. Those worms which did mature were less fecund and were expelled from the intestines within 7 days of infection. It is suggested that in previously exposed animals, the migration of larvae from the skin is hastened, many of these larvae are destroyed in the lungs and that expulsion of worms which do mature in the intestines is accelerated.     

Nippostrongylus brasiliensis: effects of immunity on the pre-intestinal and intestinal larval stages of the parasite

Nippostrongylus brasiliensis: effects of immunity on the pre-intestinal and intestinal larval stages of the parasite. International journal for Parasitology4: 183–191. Migration of the pre-intestinal larval stages of N. brasiliensis was studied in rats undergoing either primary or challenge infections. In rats undergoing a primary infection, more than 67 percent of larvae successfully migrated from the skin to the oesophagus by 70 h after infection, and subsequently over 90 per cent of these larvae became established in the small intestine as sexually mature adults. In immune rats undergoing a second infection, 46 per cent of larvae completed migration to the oesophagus by 70 h and of these, only 1·6 per cent became established in the intestine to produce eggs. These inhibitory effects on the pre-intestinal and intestinal larval stages were even more pronounced in immune rats undergoing a third or fourth infection and in addition, there was a prolonged sojourn and substantial retention of larvae in their lungs. There was no evidence that the immune response had an adverse effect on oesophageal fourth stags larvae as these organisms (obtained from immune donors) were able to establish and develop to maturity when transferred per os to normal animals.Syngeneic transfer of immune mesenteric lymph node cells to normal recipients, caused expulsion of parasites from the intestine but failed to effect migration of pre-intestinal larval stages. The implications of these findings are discussed in the context of current knowledge of the mechanisms of immunity to helminths.     

The occurrence of Strongyloides ratti in the tissues of mice after percutaneous infection

The migration of infective larvae of Strongyloides ratti has been examined in C57Bl/6 mice after percutaneous infection of the anterior abdominal wall. Lateral migration of larvae through the skin and subcutaneous tissues was not seen. Large numbers of larvae were recovered from the muscles between 2 and 24 hours after infection and larvae were seen in the cerebrospinal fluid 24 and 48 hours after infection. Insignificant numbers of larvae were seen in the blood, serosal cavities, liver, spleen, kidneys, brain or nasopharynx. Larvae arrived in the lungs between 24 and 72 hours after infection and worms were first noted in the small intestines at 48 hours. It is concluded that larvae migrate preferentially to the muscles and CSF before passing to the lungs, but the exact mode of travel is uncertain.     

Venestatin from parasitic helminths interferes with receptor for advanced glycation end products (RAGE)-mediated immune responses to promote larval migration

Parasitic helminths can reside in humans owing to their ability to disrupt host protective immunity. Receptor for advanced glycation end products (RAGE), which is highly expressed in host skin, mediates inflammatory responses by regulating the expression of pro-inflammatory cytokines and endothelial adhesion molecules. In this study, we evaluated the effects of venestatin, an EF-hand Ca²⁺-binding protein secreted by the parasitic helminth Strongyloides venezuelensis, on RAGE activity and immune responses. Our results demonstrated that venestatin bound to RAGE and downregulated the host immune response. Recombinant venestatin predominantly bound to the RAGE C1 domain in a Ca²⁺-dependent manner. Recombinant venestatin effectively alleviated RAGE-mediated inflammation, including footpad edema in mice, and pneumonia induced by an exogenous RAGE ligand. Infection experiments using S. venezuelensis larvae and venestatin silencing via RNA interference revealed that endogenous venestatin promoted larval migration from the skin to the lungs in a RAGE-dependent manner. Moreover, endogenous venestatin suppressed macrophage and neutrophil accumulation around larvae. Although the invasion of larvae upregulated the abundance of RAGE ligands in host skin tissues, mRNA expression levels of tumor necrosis factor-α, cyclooxygenase-2, endothelial adhesion molecules vascular cell adhesion protein-1, intracellular adhesion molecule-1, and E-selectin were suppressed by endogenous venestatin. Taken together, our results indicate that venestatin suppressed RAGE-mediated immune responses in host skin induced by helminthic infection, thereby promoting larval migration. The anti-inflammatory mechanism of venestatin may be targeted for the development of anthelminthics and immunosuppressive agents for the treatment of RAGE-mediated inflammatory diseases.     

Histopathological appearances in primary and secondary infections with Strongyloides ratti in mice

Dawkins H. J. S., Muir G. M. & Grove D. I. 1981. Histopathological appearances in primary and secondary infections with Strongyloides ratti in mice. International Journal for Parasitology11: 97–103. The histological appearances of the skin, lungs and small intestines of mice with primary and secondary infections with S. ratti are described. When the skins of mice with a primary infection were examined, larvae were seen scattered throughout the dermis. An inflammatory reaction of neutrophils and eosinophils was first noted around larvae 12 h after infection. By 48 h, mononuclear cells were prominent. The intensity of the inflammatory reaction gradually increased to a maximum on the fifth day and the larvae were destroyed. Very few larvae were seen in the lungs; those observed were located in the alveolar spaces and were not surrounded by an inflammatory infiltrate. Worms in the small intestines were found mostly in the crypts of Leiberkuhn, and were probably located within the epithelial layer; there was no significant villous atrophy or cellular infiltration. Marked differences were found in the tissues of mice with secondary infections. In the skin, oedema and neutrophils and eosinophils were seen around worms as early as 2 h after infection. By 24 h after infection, there was a mixed inflammatory infiltrate and worms were undergoing disintegration. Larvae in the lungs were surrounded by polymorphonuclear and mononuclear cells 48 h and 72 h after infection and the engulfed larvae were undergoing lysis. Only a few worms were seen in the intestines of mice with a secondary infection; the histological appearances were similar to that found in animals with primary infections. It is suggested that the rapid development of an oedematous reaction in the skins of immune mice may facilitate the entry of larvae into the bloodstream and that inflammatory cells destroy many larvae in the lungs of immune mice.     

Experimental infection of mice with Toxocara canis larvae obtained from Japanese quails

The migration and distribution of Toxocara canis larvae in the tissues of Japanese quails, infected orally with 5 x 10(3) infective eggs, were studied, as well as the re-infectivity of these larvae in mice, inoculated with 50 larvae obtained from the liver of these quails. Post-infection, the highest concentrations of larvae were found to be present in the liver of quails while only a few migrated to other tissues like lungs, heart, muscle and brain. The migration and distribution of the larvae in the tissues of mice were studied by necropsy on days 6 and 12 post-infection. On both days the highest number of larvae, 11 and 10, were recovered from the carcase followed by six and seven from the leg muscles and four and eight from the brain, respectively. A few larvae were recovered from the liver, lungs and viscera. This implies that the larvae had a special affinity for the muscle and brain tissue of mice, unlike in the quails. The role of these larvae in relation to paratenism is discussed.     

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.     

The location of parasites within their hosts: the behavioural component in the larval migration of Nippostrongylus bras1l1ensis in the tissues of the rat

The role of larval behaviour in successful completion of tissue migration is briefly discussed and it is related to the passive carriage of larvae along the ‘pipes and tubes’ of the host. Larvae of N. brasiliensis were injected into selected portions of the circulatory system and following periods of 5–60 min they were recovered from the blood, liver and lungs. Larvae were also immobilised in 0·4% piperazine, a dosage which permitted recovery in about 60 min. The dispersion of treated larvae was compared with that untreated controls. It was found that larvae were carried very rapidly in the blood stream and that they became lodged in the first capillary bed that they entered. They could not pass through capillary beds without movements (and/or secretions). A decreased number of adults developed after larvae were introduced via a series of routes which required the larvae to pass through an increasing number of ‘hurdles’ to migration.     

Schistosoma mansoni: histological localization of gelatinase in the preacetabular glands of cercariae

Proteolytic activity was demonstrated in secretions from the preacetabular glands of cercariae of Schistosoma mansoni. Thin gelatin film substrates were lysed by living cercariae stimulated to penetrate by application on the films of skin surface lipid. Lysis was directly related to number of cercariae, time, and temperature of incubation and pH of the medium. Gelatinase activity in unfixed frozen sections of cercariae incubated on the gelatin films was in the preacetabular glands which are the source of the secretion emptied into skin during penetration. Protease activity, therefore, appears to be related to penetration. The schistosome larvae which made the penetration attempt satisfied the accepted criteria for schistosomules, and therefore appeared to have transformed into schistosomules even though they did not successfully penetrate anything.     

Optimization of the Agar-gel Method for Isolation of Migrating Ascaris suum Larvae From the Liver and Lungs of Pigs

Experiments on use of an agar-gel method for recovery of migrating Ascaris suum larvae from the liver and lungs of pigs were conducted to obtain fast standardized methods. Subsamples of blended tissues of pig liver and lungs were mixed with agar to a final concentration of 1% agar and the larvae allowed to migrate out of the agar-gel into 0.9% NaCl at 38°C. The results showed that within 3 h more than 88% of the recoverable larvae migrated out of the liver agar-gel and more than 83% of the obtained larvae migrated out of the lung agar-gel. The larvae were subsequently available in a very clean suspension which reduced the sample counting time. Blending the liver for 60 sec in a commercial blender showed significantly higher larvae recovery than blending for 30 sec. Addition of gentamycin to reduce bacterial growth during incubation, glucose to increase larval motility during migration or ice to increase sedimentation of migrated larvae did not influence larvae recovery significantly.     

Longevity of Toxocara cati Larvae and Pathology in Tissues of Experimentally Infected Chickens

This study was conducted to determine the distribution patterns and duration of stay of Toxocara cati larvae in organs of chickens and to investigate chronic phase and potential zoonotic risk of toxocariasis in chickens. Chickens were orally infected with 1,000 embryonated T. cati eggs and necropsied 240 days post-infection. Organs of the chickens were examined at gross and microscopic levels; tissues were digested to recover larvae. Peribronchiolitis with infiltration of lymphocytes, and hyperplasia of bronchiolar associated lymphatic tissues (BALT) and goblet cells, were evident in the lungs of infected chickens. There were mild hemorrhages and infiltration of lymphocytes and a few eosinophils in the meninges. Larvae were recovered from 30% of the exposed chickens. Larvae recovery indicated that T. cati larvae stay alive for at least 240 days in the chicken brain. Therefore, chickens may potentially act as a paratenic host in nature and transfer T. cati larvae to other hosts.     

Brugia pahangi: infections and their effect on the lymphatic system of Mongolian jirds (Meriones unguiculatus)

Brugia pahangi has been found to be primarily a lymphatic-dwelling parasite in jirds when infections are induced by the subcutaneous injection of infective larvae or by allowing infected Aedes aegypti to feed.Migration to the regional lymphatics occurred as early as 1–4 days. Although some injected larvae remained in the skin for as long as 30 days and some became localized in the heart, lungs, pleural cavity, or peritoneal cavity, about three-fourths of the recovered filariae were found in the regional lymphatics. In contrast, when larvae were injected peritoneally they remained largely in the peritoneal cavity for at least 30 days.The relevant lymphatics and their drainage patterns in jirds have been described.The major pathological changes noted in jirds involved the regional lymphatic vessels and nodes, which were severely affected when they contained dead worms. Pulmonary granulomas due to dead microfilariae and occasionally to dead larvae or adult worms were noted.Observations are included on the susceptibility and course of B. pahangi infections in jirds.     

Influences of Nano-TiO2 on the chloroplast aging of spinach under light

The aim of this study was to investigate the biochemical effects of niacin and chromium(III)-chloride on serum lipid peroxidation, uric and sialic acids, and the extent of lipid peroxidation and glutathione levels in skin and lung tissues of hyperlipidemic rats. In this study, female Swiss albino rats, 12 mo old, were used. They were randomly divided into four groups. Group I animals were fed with a standard pellet diet and water ad libitium. Group II rats were fed with a standard pellet diet and were treated with a dose of 250 μg/kg body weight CrCI₃·6H₂O and 100 mg/kg body weight niacin, for 45 d, by the gavage technique. Group III rats were fed a lipogenic diet in which 2% cholesterol, 0.5% cholic acid, and 20% sunflower oil were added to the pellet chow. In addition, the animals in this group drank water containing 3% ethanol. This regime was maintained for 60 d. The rats in group IV were maintained in the same food and drink regime as the animals in group III. After 2 wk, the animals showed symptoms of hyperlipemia and they were treated with 250 μg/kg body weight CrCI₃·6H₂O and 100 mg/kg body weight niacin, by gavage, for 45 d. On d 60, the blood and the skin and lungs samples were taken from animals. In the hyperlipemic groups, a reduction of the lung glutathione level and an increase in serum, lung, and skin lipid peroxidation levels and in serum sialic and uric acid were observed. In rats treated with a combination of niacin and Cr(III), the skin and serum lipid peroxidation and the sialic and uric acid levels decreased while showing an increase of lung glutathione activity. These results suggest that niacin and Cr(III), when administered in combination, have a protective effect against skin and lung tissues damage as a result of hyperlipidemia.     

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.     

Comparison of fatty acid composition in total lipid of diapause and non-diapause larvae of Cydia pomonella （Lepidoptera： Tortricidae）

Seasonal changes in the fatty acid composition of the total lipid extracted from the whole body of Cydia pomonella L. larvae were determined by gas chromatography. The six most abundant fatty acids in both non-diapause and diapause larvae of codling moth were oleic （35%-39%）, palmitic （23%-33%）, linoleic （16%-30%）, palmitoleic （5%-10%）, stearic （1.5%-3.0%） and linolenic acids （1.0%-2.5%）. This represents a typical complement of Lepidopteran fatty acids. The fatty acid composition of total lipid of C. pomonella larvae was related to diapause. In similarity to most other reports, the proportion of unsaturated fatty acids increased in diapause initiation state. The total lipid of diapause larvae contained more linoleic acid （25.8% vs. 16.1%） and less palmitic acid （24.7% vs. 33.4%）, than that of non-diapause larvae. The weight percentage of linoleic acid （C 18：2） increased from 16% to 26% from early-August through early-September during transition to diapause, while palmitic acid （C16：0） decreased from 33% to 25% at the same time. These changes resulted in an increase in the ratio of unsaturated to saturated fatty acids （UFA/SFA） from 1.72 in non-diapause larvae to 2.63 in diapause larvae.     

Pathology of pulmonary parasitic migration: morphological and bronchoalveolar cellular responses following Nippostrongylus brasiliensis infection in rats

Nippostrongylus brasiliensis has an obligatory migratory phase through the lungs during its development in rats. This migration is associated with marked tissue damage and pronounced cellular reaction. Given that cells from the lower respiratory tract, especially alveolar macrophages, can adhere to and kill larvae of N. brasiliensis in vitro, we studied the time course of morphological changes associated with parasitic migration. Compared to a primary infection, a secondary infection resulted in significant changes in the pulmonary tissue characterized by an early acute inflammation leading to granulomatous reaction in the parenchyma and a leucocytosis in the bronchoalveolar lavage fluids with an anamnestic increase in absolute numbers of neutrophils, alveolar macrophages, eosinophils, and lymphocytes. Scanning electron microscopy showed that inflammatory cells, especially alveolar macrophages, granulocytes, lymphocytes, erythrocytes, and platelets, adhered to the larvae following secondary infection and this adhesion was associated with disruption of cuticular surface in some larvae. Secondary infection also resulted in retention of larvae in granulomatous lesions in the lungs even up to 21 days postinfection. There was mast cell and type II pneumocyte hyperplasia and these cells appeared to be activated. Thus, the histopathological changes in lungs correlated with the bronchoalveolar cellular responses and further document the inflammatory and immunological reactions during the migration of N. brasiliensis larvae.     

Tissue-specific mechanisms control the retention of IL-8 in lungs and skin

Chemokines are a group of structurally related peptides that promote the directed migration of leukocytes in tissue. Mechanisms controlling the retention of chemokines in tissue are not well understood. In this study we present evidence that two different mechanisms control the persistence of the CXC chemokine, IL-8, in lungs and skin. (125)I-labeled IL-8 was injected into the airspaces of the lungs and the dermis of the skin and the amount of (125)I-labeled IL-8 that remained at specified times was measured by scintillation counting. The (125)I-labeled IL-8 was cleared much more rapidly from skin than lungs, as only 2% of the (125)I-labeled IL-8 remained in skin at 4 h whereas 50% of the (125)I-labeled IL-8 remained in lungs at 4 h. Studies in neutropenic rabbits showed that neutrophils shortened the retention of (125)I-labeled IL-8 in skin but not lungs. A monomeric form of IL-8, N-methyl-leucine 25 IL-8, was not retained as long in lungs as recombinant human IL-8, indicating that dimerization of IL-8 is a mechanism that increases the local concentration and prolongs the retention of (125)I-labeled IL-8 in lungs. These observations show that the mechanisms that control the retention of IL-8 in tissue include neutrophil migration and dimerization, and that the importance of these varies in different tissues.     

Lipid Metabolism of Caddisfly Larvae at Low pH

The influence of low pH (5.0 and 4.0) on lipid metabolism of caddisfly larvae Hydropsyche contubernalis L. (Trichoptera) was studied in 48 h toxicity experiments. The results were correlated with lipid composition of caddisfly larvae directly isolated from natural water. Phospholipids, cholesterol, mono-, di-, triacylglycerols, and fatty acids were detected by thin-layer and liquid chromatography. Minimal environmental changes were shown to initiate the biochemical adaptation mechanisms strengthening the cellular membranes through their condensation due to additional phospholipid and cholesterol synthesis. In the natural medium the adaptation processes are more active than in the artificial medium. More serious changes, such as pH decrease to 4.0, suppress the adaptation processes in the first medium and terminate them in the second one.     

Larval migration in oral and parenteral Toxocara pteropodis infections and a comparison with T. canis dispersal in the flying fox, Pteropus poliocephalus

When eggs of T. pteropodis were fed in large doses to juveniles of a definitive host, Pteropus poliocephalus, larvae hatched throughout the gastrointestinal tract. The majority penetrated the mucosa of the distal half of the intestine, to reach the liver via the portal circulation. A few entered the lymphatics to eventually reach the liver by passing through the lungs and migrating tracheally or continuing in the systemic circulation. Patent infections did not develop. Eggs inoculated subcutaneously also hatched and larvae again reached the liver, travelling via the circulation through the lungs and often other tissues; again, some underwent tracheal migration. Infective larvae of T. canis, identical in size with T. pteropodis, passed through the liver and lungs and dispersed mainly to skeletal muscles, but with time gradually accumulated in the brain. These findings indicate that Toxocara larval distribution is not primarily influenced by larval dimensions but reflects goal-directed behaviour.