Taenia solium: immunity in hogs to the Cysticercus

Protection was induced in hogs against Taenia solium cysticercosis using an immunogenic complex obtained from its larval "bladder worm" form, Cysticercus cellulosae. Immunoelectrophoresis revealed that this complex contained at least eight antigens. In immunized hogs a total of 71 (mean 11.8) cysticerci were found, whereas in the control animals 397 (mean 74.9) were found. Histopathological studies showed that more than 40% of larvae obtained from immunized hogs were completely destroyed and the others were seen in various stages of degeneration. Eosinophils and mononuclear cells were observed infiltrating the internal structures of the larvae. Intense granulomatous reactions of eosinophils, lymphocytes, macrophages, epithelioid cells, plasma cells, and fibroblasts surrounded the larvae. Larvae from control hogs were intact and surrounded by a small inflammatory reaction. The cellular response was measured by the macrophage migration inhibition test, which was higher in immunized hogs when compared with control animals, either before the infection with T. solium eggs or before slaughter. No significant difference was found in the humoral response of immunized and control hogs.     

Ultrastructural aspects of early immune damage to Taenia crassiceps metacestodes

Siebert, A. E. Jr., Good A. H. and Simmons J. E. 1978. Ultrastructural aspects of early immune damage to Taenia crassiceps metacestodes. International Journal for Parasitology8: 45–53. Changes in the ultrastructure of the tegument and subtegumental cells of intraperitoneally implanted Taenia crassiceps metacestodes were studied by transmission electron microscopy over a 4-week period. Death of metacestodes without involvement of host inflammatory cells is indicated initially by vacuolization of the larval tegument followed by loss of the tegument and subsequent death of the larvae. Changes in the tegument involve loss of the glycocalyx, reduction in the numbers of mitochondria and microtriches present, and loss of secretory capacity. Subtegumental cells show an accumulation of secretory vacuoles and marked disruption of nuclear morphology. Tegument damage is attributed to a complement-mediated lysis of the outer tegument membrane and death of the larvae probably results from loss of tegument function.     

Inflammatory reaction to the human bot-fly,Dermatobia hominis,in infested and reinfested mice

Two groups of mice were infested with first stage larvae of the human bot-fly, Dermatobia hominis (Linnaeus Jr) (Diptera: Oestridae). In the first group, skin biopsies were carried out 1, 3, 5, 7, 10 and 18 days after infestation. The second group was also infested but had all the larvae removed 5 days after infestation. The mice in the latter group were reinfested 4 weeks later and skin biopsies were carried out 1, 3, 5, 7, 10 and 18 days after reinfestation. In the first group, an inflammatory reaction began slowly, the neutrophils being the main inflammatory cells, eosinophils being scarce. The reaction progressed with time, developing a necrotic halo around the larvae containing inflammatory cells surrounded by fibroblasts. The inflammation invaded the adjacent tissue. In the second group, the inflammatory reaction was intense on the day immediately after reinfestation, the pattern being changed by the presence of a large number of eosinophils. Activated fibroblasts surrounding the necrotic area around the larvae appeared 3 days after reinfestation in the second group and 7 days after infestation in the first group. The results demonstrated that the previous contact with the antigens elicited the early arrival of eosinophils, probably through the chemotactic factors liberated by mast cells in the anaphylactic reaction.     

Role of IL-5 in innate and adaptive immunity to larval Strongyloides stercoralis in mice

Protective immunity to Strongyloides stercoralis infective larvae in mice has been shown to be dependent on IL-5 based on mAb depletion studies. The goal of this study was to determine the functional role of IL-5 during the innate and adaptive immune response to larval S. stercoralis in mice. In these studies, three strains of mice were used: wild-type C57BL/6J (WT), IL-5 knockout (KO), and IL-5 transgenic (TG). Innate responses to the larvae indicated that there was enhanced survival in the KO animals and decreased survival in the TG animals compared with WT. Furthermore, killing of larvae in TG mice was associated with eosinophil infiltration and degranulation. In studying the adaptive immune response, it was observed that immunization of KO mice did not lead to the development of protective immunity. Experiments were then performed to determine whether KO mice reconstituted with Abs or cells could then develop protective immunity. KO mice displayed protective immunity via a granulocyte-dependent mechanism following injection of purified IgM from immune wild-type animals. Immunity in KO mice could also be reconstituted by the injection of eosinophils at the time of immunization. These eosinophils did not participate in actively killing the challenge infection, but rather were responsible for the induction of a protective Ab response. We conclude that IL-5 is required in the protective immune response for the production of eosinophils, and that eosinophils were involved in larval killing during innate immunity and in the induction of protective Abs in the adaptive immune response.     

Damage and early destruction of Taenia taeniaeformis larvae in resistant hosts, and anomalous development in susceptible hosts: a light microscopic and ultrastructural study

Bortoletti G., Conchedda M. and Ferretti G. 1985. Damage and early destruction of Taenia taeniaeformis larvae in resistant hosts, and anomalous development in susceptible hosts: a light microscopic and ultrastructural study. International Journal for Parasitology15: 377–384. Taenia taeniaeformis larvae in resistant C57 mice have been studied from 5th to 15th day post-infection (L5–L15) both at the light and electron microscopic level. L5 stages were already damaged and total destruction occurred by approx. 15 days post-infection. In stage L5, unlike fertile larvae from C3H mice, the perilarval amorphous layer (PAL) was generally absent, and the host's cells were in close contact with the parasite surface. At this stage eosinophils were already present together with neutrophils and macrophages. Larvae were seen increasing in volume between stages L6 and L8, but remained constant from stages L9 to L14, while both the tegumental distal cytoplasm (TDC) and the subtegumental cellular layer (SCL) gradually decreased. In stages L10–L14 only a narrow TDC separated the larval cavity from host cells. After the larval tegument had been reduced in thickness the eosinophil lytic enzyme release onto the parasite surface contributed to produce a ‘hole’ in the TDC where host cells penetrated and gradually filled the larval cavity of L15, destroying the parasitic residues. Therefore anomalous small larvae (L50 and more) from C3H mice (susceptible host) have been studied: in these the scolex anlagen was absent or greatly reduced; the TDC was very narrow and the SCL greatly damaged. Outside the larva the ‘host tissue’ appeared as an unidentifiable amorphous material. These larvae cannot be considered ‘dead’ but are defined as sterile.     

Schistosoma mansoni: peripheral and tissue eosinophilia in infected rats.

Peripheral eosinophilia is induced in Sprague-Dawley rats following infection with cercariae of Schistosoma mansoni. Beginning 3 weeks after infection, peripheral eosinophil levels rise above the baseline range; they reach peak values during the fifth week. Following a decline from peak values, peripheral eosinophil levels remain elevated and are observed to fluctuate for the next 5 months. The magnitudes of both the initial peak response at 5 weeks and the subsequent chronic level of peripheral eosinophils are dependent upon dose of cercariae. The initial peak response phase of peripheral eosinophilia coincides in time with the period of adult worm elimination (Weeks 4–6) in the schistosome-infected rat. Histological examination of the liver at 5 weeks after infection reveals eosinophil-rich inflammatory reactions associated with both live and dead worms residing in the portal blood vessels. Around live worms the inflammatory cells are localized in a perivascular arrangement; around dead worms these cells are in the vascular lumen in contact with destroyed worms. The chronic phase of peripheral eosinophilia is associated, in part, with inflammatory reactions surrounding eggs deposited in the liver by the few worm pairs which survive more than 6 weeks and remain within the liver. Histological examination during this period reveals granulomatous lesions within the liver surrounding eggs and dead worms. The granulomas are predominately monocytic (lymphocytes, macrophages) at 11 and 16 weeks. The initial peak response phase of peripheral eosinophilia appears to be a marker for tissue-localized reactions of eosinophils with worms. There are relationships between inflammatory reactions and survival of adult worms.     

Morphological studies on the early development of Taenia taeniaeformis larvae in susceptible mice

Bortoletti G. and Ferretti G. 1985. Morphological studies on the early development of Taenia taeniaeformis larvae in susceptible mice. International Journal for Parasitology15: 365–375. Taenia taeniaeformis larvae which develop into infective strobilocerci in C3H mice have been studied from the 5th to the 15th day of development (L5–L15), both at light and electron microscope level. The L5 were initially compact, without a central cavity but then become vacuolized. Until stages L7–L8 they were surrounded by a perilarval amorphous layer (PAL) made up of a finely granular material which prevented the host cells from making contact with the larval tegument. The larval volume increased considerably between stages L6 and L8, remained unchanged from L9 to L13, but continued to increase thereafter. The larval cellular layer, which appeared as a single, large ‘syncitial system’, grow until stages L14–L15 when the scolex anlagen began to form. The tegument was initially incompletely organized and was covered by microvilli. These were completely replaced by microtriches from stage L8 onward. Sometimes both microvilli and microtriches were together observed in stage L7. Microvilli fragments, sometimes beaded, could be observed at L5 within the damaged cytoplasm of host cell debris. Very often they were branched at different heights, especially in stages L5–L7. In L10–L15 all undamaged microtriches increased in density and formed bundles which invaded the host cells. In stages L5–L8 and in some L9, muscular bundles started to become organized inside the tegumental distal cytoplasm (TDC), and after become independent in the subtegumental cellular layer (SCL). Until L8–L9 the larvae were surrounded by host cells debris. From stages L8–L10 onwards the adjacent host cells were less damaged though the larval microtriches penetrated them deeply. In stages L5–L7 neutrophils together with macrophages and some damaged hepatocytes were detected, while eosinophils were present only from L8 onward. In the other stages neutrophils clearly diminished in numbers, whereas macrophages had increased. No mastcells and few plasma cells were observed.     

Experimental skin lesions from larvae of the bot fly Dermatobia hominis

Skin biopsies from larvae of Rattus norvegicus, experimentally infested with Dermatobia hominis (Linnaeus Jr) (Diptera: Cuterebridae), were processed for histopathological studies. Two days after infestation, the first-stage larvae (L1) were located deep in the dermis, surrounded by an inflamed area infiltrated predominantly by neutrophils. On the fourth day a thin necrotic layer could be seen close to the larvae, surrounded by large numbers of neutrophils, lymphocytes, macrophages with a few eosinophils and mast cells. A small warble was formed after the fourth day, increasing in size until the seventh day, when the L1 moulted to the second-stage larva (L2). The inflammatory process continued with increasing numbers of neutrophils, macrophages, lymphocytes, eosinophils and mast cells invading the area, as well as the proliferation of fibroblasts and endothelial cells and the appearance of a few localized haemorrhages. After 18-20 days, the L2 moulted to the third-stage larva (L3), when a few plasma cells could be seen in the inflamed area. At 25-30 days there was a reduction in the necrotic layer, as well as in the number of neutrophils and lymphocytes, although large amounts of eosinophils, plasma cells, and collagen fibres were seen. The L3 usually left the host after 30 days. Two days later, the larval cavity was reduced, mast cells infiltrated the region and collagen fibre production were increased. After 7 days, an intense infiltration of plasma cells and scattered necrotic areas could be seen. A scar formed after 10 days. This study showed the laboratory rat to be a suitable model for studies of D. hominis infestation.     

Eosinophils mediate SIgA production triggered by TLR2 and TLR4 to control Ascaris suum infection in mice

Human ascariasis is the most prevalent but neglected tropical disease in the world, affecting approximately 450 million people. The initial phase of Ascaris infection is marked by larval migration from the host’s organs, causing mechanical injuries followed by an intense local inflammatory response, which is characterized mainly by neutrophil and eosinophil infiltration, especially in the lungs. During the pulmonary phase, the lesions induced by larval migration and excessive immune responses contribute to tissue remodeling marked by fibrosis and lung dysfunction. In this study, we investigated the relationship between SIgA levels and eosinophils. We found that TLR2 and TLR4 signaling induces eosinophils and promotes SIgA production during Ascaris suum infection. Therefore, control of parasite burden during the pulmonary phase of ascariasis involves eosinophil influx and subsequent promotion of SIgA levels. In addition, we also demonstrate that eosinophils also participate in the process of tissue remodeling after lung injury caused by larval migration, contributing to pulmonary fibrosis and dysfunction in re-infected mice. In conclusion, we postulate that eosinophils play a central role in mediating host innate and humoral immune responses by controlling parasite burden, tissue inflammation, and remodeling during Ascaris suum infection. Furthermore, we suggest that the use of probiotics can induce eosinophilia and SIgA production and contribute to controlling parasite burden and morbidity of helminthic diseases with pulmonary cycles.     

Experimental Haemonchus contortus infections in guinea pigs

Approximately 40% of exsheathed Haemonchus contortus larvae administered to guinea pigs established in the stomach and developed into fourth stage larvae. Most worms were then lost between 5 and 7 days after infection and the guinea pigs were resistant to a second infection. Haemorrhage, oedema and infiltration with inflammatory cells, especially eosinophils, developed in the stomach wall of infected guinea pigs and reactive hyperplastic changes occurred in the gastric lymph node. H. contortus infection of guinea pigs has some potential as a model for study of the pathology, immunology and chemotherapy of gastric nematodiasis.     

Pathological and haematological responses of cats experimentally infected with Toxocara canis larvae

Responses of eight adult cats to one or two infections with larvae of Toxocara canis were studied up to 39 days post infection (DPI). Clinically, all cats remained normal throughout the study. The major necropsy finding was multifocal, white to grey nodules mainly within the liver, lungs and kidneys; live larvae were found in liver nodules. Histologically, the nodules were eosinophilic granulomas. Granulomas containing a larval section were observed mainly within the liver. All infected cats had variably severe, eosinophilic arteritis and bronchiolitis and medial hypertrophy and hyperplasia of the pulmonary arteries. No inflammatory eye lesions were detected. Circulating eosinophil levels increased in all infected cats; peak values of 15,790 and 10,050 eosinophils microliters-1 were observed at 25 or 32 DPI in cats receiving a single or double infection, respectively. Bone marrow of all infected cats exhibited marked eosinophilic hyperplasia which did not correlate with the level of circulating eosinophilia. Thus, infection of cats by the larvae of T. canis causes disseminated eosinophilic and granulomatous disease with marked pulmonary artery and airway lesions.     

Eosinophils and Trichinella infection: toxic for the parasite and the host?

Peripheral blood and tissue eosinophilia characterize trichinellosis in humans, and present in addition to the increased total IgE levels that occur in many helminth infections. Both processes are the consequence of T-helper 2 activation. Blood and tissue eosinophilia begins with eosinophilopoiesis in the bone marrow, which is followed by the migration of eosinophils through the circulatory system, the eosinophil infiltration of tissues at the inflammatory foci and, finally, degranulation and cell death. Recently, some aspects of eosinophilia caused by Trichinella spiralis infection have been elucidated; however, the protective role of this population of cells against Trichinella parasites remains controversial. Furthermore, when eosinophils are numerous, they can be toxic for host tissues. This review discusses these issues in both human and rodent infection models.     

Ultrastructural aspects of the host cellular immune response to Taenia crassiceps metacestodes.

When three Taenia crassiceps metacestodes were injected intraperitoneally into C3H mice primed by previous subcutaneous inoculation of metacestodes, larvae which were resistant to early immune damage by the humoral response were encapsulated by host cells and rejected. Initially, normal larvae were encapsulated primarily by eosinophils and macrophages. In the early stages of encapsulation, both cell types showed severe degenerative changes and disruption of cell membranes, but there was no evidence of tegumental damage to the encapsulated larvae. Later, mast cells appeared in the capsules surrounding the larvae. After mast cells became common, all of the cell types present were normal, and damage to the larval Tegument became apparent. Ultimately, interaction of eosinophils, mast cells, macrophages, and lymphocytes resulted in death of the encapsulated larvae. These results suggest that larvae may secrete substances toxic to host cells, and that mast cells are necessary for rejection of larvae.     

Do eosinophils have a role in the killing of helminth parasites?

Eosinophils have been shown to be potent effector cells for the killing of helminth parasites in in vitro cultures. However, an in vivo role for eosinophils has been more difficult to establish. Early data showed close associations between eosinophils and damaged or dead parasites in histological sections, and significant correlations between resistance to parasites and the capacity to induce eosinophilia after infection. However, more recent studies, using mice that have reduced or increased eosinophil levels through targeting of the eosinophil-specific cytokine interleukin 5, have not unanimously supported an in vivo role for eosinophils in resistance to parasites. Here, Els Meeusen and Adam Balic review these studies and suggest a major role for the innate immune response in unnatural mouse-parasite models to explain some of the findings. They conclude that the data so far are consistent with a role for eosinophils in the killing of infective larval stages, but not adults, of most helminth parasites.     

IL-5-overexpressing mice exhibit eosinophilia and altered wound healing through mechanisms involving prolonged inflammation

Leucocytes are essential in healing wounds and are predominantly involved in the inflammatory and granulation stages of wound repair. Eosinophils are granulocytic leucocytes and are specifically regulated by interleukin-5 (IL-5), a cytokine produced by T helper 2 (Th2) cells. To characterize more clearly the role of the IL-5 and eosinophils in the wound healing process, IL-5-overexpressing and IL-5-deficient mice were used as models of eosinophilia and eosinophil depletion, respectively. Our results reveal a significantly altered inflammatory response between IL-5-overexpressing and IL-5 knockout mice post-wounding. Healing was significantly delayed in IL-5-overexpressing mice with wounds gaping wider and exhibiting impaired re-epithelialization. A delay in collagen deposition was observed suggesting a direct effect on matrix synthesis. A significant increase in inflammatory cell infiltration, particularly eosinophils and CD4(+) cells, one of the main cell types which secrete IL-5, was observed in IL-5-overexpressing mice wounds suggesting that one of the main roles of IL-5 in wound repair may be to promote the infiltration of eosinophils into healing wounds. Healing is delayed in IL-5-overexpressing mice and this corresponds to significantly increased levels of eosinophils and CD4(+) cells within the wound site that may contribute to and exacerbate the inflammatory response, resulting in detrimental wound repair.     

Toxocara canis: interaction of human blood eosinophils with the infective larvae

This study was carried out to investigate the nature of the immunological responses which took place in a child who had recently recovered from toxocariasis. She had developed a marked eosinophilia and had high titers of toxocara antibodies. Experiments were performed to examine whether Toxocara canis infective larvae could be killed in the presence of her serum and human eosinophils. Eosinophils with human complement, or this patient's serum, adhered to the surface of the larvae within 10 min. By 40 min, using both light and electron microscopy, it was shown that the cells had flattened against the cuticle and degranulated. However, by 3 hr, eosinophils had begun to detach, and the larvae remained alive for at least 1 week afterward. Further addition of serum or of eosinophils, which were shown to be able to immobilize T. spiralis infective larvae, failed to kill the T. canis larvae. It was concluded that, in this patient, the development of an inflammatory response to a T. canis infection was not associated with the appearance of antibodies capable of inducing eosinophil dependent toxicity to the larvae in vitro. Eosinophil dependent killing mechanisms may be less important than other components of the immune response, in immunity to this parasite in humans.     

The intensity and duration of primary Heligmosomoides polygyrusinfection in TO mice modify acquired immunity to secondary challenge

The effect of dose and duration of immunizing infections of Heligmosomoides polygyrus on protection against homologous challenge was studied in female TO mice. Primary infections were terminated at various levels with pyrantel embonate (adult infections) or ivermectin (larval infections) and mice were then challenged with 500 infective larvae (L3). The level of protection to secondary challenge positively correlated with the intensity of the primary immunizing infection but truncation of larval infection produced significantly better protection than termination of the adult nematode infection. The duration of the primary larval infection (1-6 days) positively correlated with the level of protection to secondary challenge, antibody responses and the proportion of circulating eosinophils. Histological changes in the gastrointestinal tract, peripheral leucocytic changes and antibody responses of the mice to H. polygyrus adult somatic antigens indicate both a cellular and humoral basis of host immunity to secondary challenge. Although the TO mice are slow responders in that they harbour chronic infections, immunization by intramucosal killing of the larval stage produced strong protection against secondary challenge infection. The presence of dead immunogenic larval stages within the intestinal wall may well be an important factor, since it exposes the host to stage specific antigens at an appropriate location. The implications of the findings for the control of gastrointestinal nematode infections are also discussed.     

Artificial immunization of pigeons against Argas polonicus (Ixodoidea, Argasidae)

Two subcutaneous injections of salivary gland antigen (SGA) or larval homogenate (LH) at 2-week intervals induced a resistance in pigeons to Argas (Argas) polonicus Siuda, Hoogstraal, Clifford and Wassef larvae and induced anti-tick antibodies. The number of larvae rejected after LH immunization was significantly higher compared to SGA immunization but lower than the number of larvae rejected after two natural infestations at 2-week intervals. The antibody titre reached a peak on day 6 following the first inoculation of LH, and 11-13 days after SGA inoculation. The maximum antibody titre was recorded 6 days after a second challenge for both antigens. The highest antibody titre was reached after the first inoculation with LH but only after the second inoculation with SGA. The sera of pigeons immunized either with SGA or LH cross-reacted with the other antigen as demonstrated by ELISA. SDS-PAGE and immunoblot studies demonstrated several differences in the protein profiles of these antigens, the presence of 34 and 35 kdal proteins in SGA and their absence in LH.