Strongyloides ratti: Acquired resistance in the rat to the preintestinal migrating larvae

Potential sites for expression of acquired resistance to Strongyloides ratti larvae in rats were investigated. In rats immunized by exposure to a single live infection and challenged 30 to 40 days later, 46 to 98% of the challenge larvae failed to reach the small intestine. Multiply immunized rats nearly completely eliminated migrating challenge larvae. This early killing of migrating larvae occurred during the first 48 hr after challenge infection. Resistance to migrating challenge larvae was also induced by repeated injections with heat-killed infective larvae. That the intestine may also serve as an effective site for worm expulsion was confirmed by intestinal transfers of worms from rats with primary infections into resistant rats.     

Rapid and specific alterations of goblet cell mucin in rat airway and small intestine associated with resistance against Nippostrongylus brasiliensis reinfection

The intestinal parasitic nematode Nippostrongylus brasiliensis is expelled rapidly from the rat in reinfection challenge compared with that of the primary infection owing to the host defense mechanisms raised against the pre-intestinal- and intestinal-stage larvae. We examined the relationship between the mucin alterations in airway and jejunal mucosae and the worm expulsion after third-stage larva reinfection. When rats had been inoculated with fourth-stage larvae and immunized with only the intestinal-stage worms for more than 8 days, the challenge larvae were expelled during the intestinal stage along with a rapid increase of the specific sialomucin in jejunal mucosa, without any effect on the bronchial mucus. When rats had been infected with third-stage larvae and immunized with only the pre-intestinal stage larvae by killing with antihelminthic, the challenge larvae were rejected during the pre-intestinal stage along with marked goblet cell hyperplasia and Muc5AC mucin hyperproduction on the bronchial mucosa, but not as a result of jejunal mucin alteration. Taking these finding together, immunization with pre-intestinal- and intestinal-stage worms independently increases the airway and intestinal goblet cell mucins, respectively, and in both cases, the mucin alterations may contribute to rapid worm expulsion upon reinfection.     

Trichinella spiralis: acquired immunity in swine

The ability of domestic pigs to develop protective immunity to Trichinella spiralis in response to inoculation with different doses of muscle larvae was assessed. Adult worms developing from the inoculations of 112, 500, and 10,000 larvae were expelled from the intestine about 6 weeks after inoculation. Inoculation with 25,000 larvae, however, resulted in more rapid intestinal worms expulsion, indicating that gut expulsion is dose dependent. Secondary expulsion also tended to be dependent upon primary infection level. Pigs initially inoculated with 500 to 10,000 larvae expelled the challenge infection of adult worms after 22 to 25 days; in contrast, infection by inoculation of only 112 larvae failed to induce significant enchanced gut expulsion of the challenge infection intestinal worms. However, all primary infection levels, including inoculation with 112 larvae, induced nearly absolute resistance to the muscle establishment of larvae from challenge adult worms. The fecundity of female worms recovered from immune pigs was reduced 75% in comparison to controls. These results show that, in contrast to some host species, very rapid gut expulsion does not occur in domestic swine. Yet, immune responses at the gut level are important, perhaps responsible for much of the inhibition reflected as reduction in the establishment of muscle larvae.     

Hymenolepis nana: intestinal tissue phase in actively immunized mice.

We investigated the fate of the intestinal cestode Hymenolepis nana in immunized mice. Immunity was induced by infection with the parasite eggs. These immunized animals and unimmunized controls were then challenged with 50,000 H. nana eggs. The mice were killed 4 to 90 hr after challenge, and H. nana in the intestinal tissue were counted. At 4 hr after challenge the unimmunized and immunized animals had approximately equal numbers of oncospheres. By 12 hr there were fewer parasites in the immunized than in the unimmunized animals. At 90 hr, no H. nana were seen in the immunized mice, whereas in the unimmunized animals the median number of cysticercoids was more than 1,000. It appears, therefore, that in mice well immunized to H. nana by infection, challenge oncospheres can burrow into the intestinal tissue before they are killed. The reduced number of oncospheres in the immunized mice 12 hr after challenge, and the accumulation of eosinophils near individual oncospheres still present, indicate that an immune response to the parasite was taking place. Absence of a lymphocyte infiltration near any of the oncospheres suggests that the mechanism of immunity was not lymphocyte mediated; thus, the histopathology of the reaction is consistent with that of humoral immunity.     

Ultrastructural aspects of immune damage to Hymenolepis nana oncospheres in mice

When Hymenoiepis nana eggs were inoculated orally into unimmunized mice, the oncosphere larvae penetrated the intestinal villi and underwent postembryonic development. The ultra-structural changes during the 48 h after infection were characterized by the development of microvillar protrusions on the surface of the epithelium, development of many membranous vesicles in the epithelium, and proliferation of undifferentiated cells in the parenchyma with a rapid disappearance of penetration gland cells and muscle cells. The epithelium of larvae from a challenge infection of mice that had been immunized by oral infection with eggs was severely damaged as shown by the increased electron density, shrinking of the cytoplasm and formation of large empty vacuoles. Development of microvillar protrusions and intraepithelial vesicles were not seen. Changes of internal structure were similar to those changes seen in the larvae of unimmunized mice. It was evident that host immunity, resulting in the ultimate death of challenge larvae during 24 h after challenge, was primarily directed against the epithelium of the larva. Host cells which firmly adhered to the larva in unimmunized mice were monocytes and macrophages with occasional infiltration of eosinophils and plasma cells, whereas the host cells in immunized mice were almost exclusively eosinophils and macrophages. It was suggested that the degeneration of larvae in immunized mice was caused by the action of specific antibody directed against larval epithelium. The cooperative action of antibody and eosinophils or macrophages in killing challenge larvae was also suggested.     

Secretion of anti-parasite substances and leukotrienes from ovine gastrointestinal tissues and isolated mucosal mast cells

The presence of larval migration inhibitory (LMI) compounds in the gastrointestinal mucus of nematode resistant sheep has been shown previously to be associated with increased numbers of gastrointestinal mucosal mast cells (MMC) and globule leukocytes (GL). This experiment was designed to determine if LMI compounds were secreted by MMC/GL in response to nematode antigenic challenge and if so, could secretion account for levels observed in mucus. Rommey sheep were immunized by repeated cycles of infection with Trichostrongylus colubriformis or Haemonchus contortus larvae and anthelmintic treatment. After slaughter, gastrointestinal tissue was taken for examination of histology and mucus anti-parasite activity. Segments of small intestine were ligatured to form sacs which were incubated with exsheathed nematode larvae or larval excretory/secretory antigens. Tissue slices from small intestine or abomasum were also incubated with nematode larvae or antigens. After homologous challenge, levels of leukotrienes secreted into small intestinal tissue sacs were significantly higher than levels in heterologously challenged sacs or unimmunized sheep intestinal sacs challenged with larvae of any nematode species (279.4±33.7, 141.0±27.8 and 39.5±15.2 ng h⁻¹ respectively). Tissue slices gave a similar pattern of leukotriene secretion. LMI activity was also significantly elevated in intestinal sacs from immunized sheep challenged homologously with nematode larvae or antigen (64±10 and 68±14% respectively cf. heterologous challenge 32±10% and unimmunized sheep sacs 15±6%). Histological examination of abomasal and small intestinal sections showed that immunized sheep had significantly greater numbers of MMC/GL than unimmunized sheep. MMC/GL isolated and purified from immunized sheep secreted leukotrienes and compounds having LMI activity when cultured with homologous nematode larvae or antigens. Secretion of leukotrienes and molecules having LMI activity from MMC/GL could account for the levels of these substances observed in small intestinal mucus.     

Demonstration of a range of inflammatory mediators released in trichostrongylosis of sheep.

The levels of inflammatory mediators in the intestinal contents of sheep immunized with Trichostrongylus colubriformis larvae increased in the first 6 days after challenge. These mediators were histamine, leukotriene C4, 6-keto-prostaglandin F1 alpha (from prostacyclin) and thromboxane B2. Leukotriene C4 was released in the greatest quantities. Leukotriene B4 was present but its concentration remained unchanged after challenge. The presence of these particular mediators in the intestinal contents after challenge is consistent with antigen-induced mediator release from the mucosal mast cells found in immune sheep undergoing challenge infection. This is the first sequential analysis of mediator release in sheep that also demonstrates the release of prostacyclin and thromboxane into the intestine during expulsion of a nematode infection.     

Nematospiroides dubius: arrested development of larvae in immune mice.

When immune NIH mice were killed 10 days after a challenge infection with Nematospiroides dubius, approximately 10% of the inoculated larvae were recovered from the intestinal lumen, irrespective of the dose administered. When such mice were treated with cortisone from Day 10 for a period of 8 to 14 days and were subsequently killed for worm counts, it was found that they had significantly more worms than the immune control mice killed on Day 10. During the week following the beginning of treatment with cortisone there was little change in the low worm burdens in immune mice. However, 9 to 11 days after this treatment worm counts indicated that worms were accumulating in the intestinal lumen, and concurrently eggs were recorded in the feces of the mice. These observations indicated that a period of 9 to 11 days was required after the initiation of cortisone treatment on Day 10 for the worms in immune mice to complete their development to the adult lumen-dwelling stage. It is suggested that the larvae in the challenge infection became arrested early in their development in the intestinal wall and that growth resumed only after cortisone treatment. When treatment with cortisone was initiated later after challenge, it was still effective in reactivating arrested worms, but the lower worm recoveries in these mice indicated that the arrested larvae were being slowly rejected by the host. In subsequent experiments it was established that the arrested larvae of N. dubius were insusceptible to the activity of pyrantel embonate, an anthelmintic which is 99% effective against adult worms in the intestinal lumen. The mechanism whereby the larvae of N. dubius became arrested in immune mice and subsequently resumed their development after cortisone treatment is discussed.     

Protective immunity against Brugia malayi infective larvae in mice. II. Induction by a T cell-dependent antigen isolated by monoclonal antibody affinity chromatography and SDS-PAGE

A mAb directed against filarial worm secretory/excretory product and reactive with Brugia malayi larval worm surface was used in conjunction with preparative SDS-PAGE to isolate protective Ag from extracts of adult B. malayi. The IgM mAb OVH bound to a repeating carbohydrate epitope present in adult, infective, and fourth stage larvae and microfilariae of B. malayi, and on the surface of fourth stage larvae. Ag bearing this epitope were also present in the sera of hosts infected with a variety of helminths, including Brugia, Onchocerca, Dirofilaria, and Paragonimus. Affinity chromatography of SDS extract of adult Brugia, using mAb OVH immobilized on agarose beads, isolated several Ag that separated into multiple protein staining bands on SDS-PAGE. In comparing SDS-PAGE-fractionated Ag from the crude SDS extract with fractionated mAb OVH-isolated Ag for the ability to protect BALB/c mice from challenge with B. malayi-infective larvae, it was found that of the mAb OVH-isolated Ag only those at a molecular mass of 26 to 32 kDa were protective while the original SDS extract yielded protective Ag at the following molecular mass: greater than 200, 170 to 200, 40 to 44, 33 to 36, 23 to 28, 20 to 22, and 17 to 19 kDa. Although Ag isolated by mAb OVH were highly protective, they failed to induce high antibody levels against the immunogen or SDS extracts compared to crude SDS extract immunized mouse sera, as determined by immunoblot and ELISA. Transfer of nylon wool non-adherent T cells from BALB/c mice immunized with the 26- to 28-kDa fraction of mAb OVH-isolated Ag to naive mice just before challenge with infective larvae of B. malayi resulted in a 70% reduction in larvae recovered 14 days after challenge.     

Trichinella spiralis: nonspecific resistance and immunity to newborn larvae in inbred mice

The implantation and development of intravenously injected Trichinella spiralis newborn larvae were examined in different strains of inbred mice by determining muscle larvae burden. This was compared to the numbers of muscle larvae that established after a natural infection during which a quantitative assessment of intestinal newborn larvae production was made. In most inbred strains of mice, newborn larvae do not all successfully implant in muscle. Mice of the DBA/1 strain are the most resistant to successful implantation, and C3H mice are the most permissive. This pattern is evident in the strains studied whether newborn larvae are injected intravenously or are produced by intestinal adults. Thus, after a natural infection, 100% of intestinally produced newborn larvae implanted in C3H mice, whereas in NFR 68% and DBA/1 mice 62% successfully matured in muscle. Immunity to newborn larvae could be demonstrated as early as 10 days after exposure to this stage of the life cycle. This immunity was protective against a complete challenge infection given 9 days after newborn larvae had been injected intravenously. Protection against newborn larvae was identical in male and female mice or in mice from 1 to 9 months of age. We conclude that there are two mechanisms by which mice impair newborn larvae establishment or development in muscle. The first appears to be nonimmunological (non-specific resistance), and the second is immunological. Genetically determined variation in strain-specific expression is apparent with both mechanisms. In strains displaying high intrinsic "resistance" (DBA/1), this process is likely to account for most of the 38% reduction in newborn larvae establishment in a primary infection. However, immunity against newborn larvae develops quickly enough to have a significant effect on migratory larvae in primary infections where adults persist in the intestine (e.g., the B10 congenic mice), or when high adult worm burdens delay adult worm rejection. Muscle larvae burden, therefore, reflects systemic nonspecific resistance to newborn larvae as well as immunological processes that occur in the intestine and systemically.     

Brugia malayi: antibody responses to larval antigens in infected and immunized jirds.

Vaccination with irradiated third stage Brugia malayi larvae (L3) has been reported to induce partial protective immunity to L3 challenge in jirds. The purpose of this study was to identify antigens that may be targets of protective immunity in this model. Jirds were immunized by s.c. injection of irradiated L3 and challenged either s.c. or i.p. Necropsy was performed 11 wk after challenge. Partial protection was achieved in s.c. challenged animals; worm recovery was only 41% of that observed in unvaccinated controls, and worms recovered from immunized animals were stunted. Worm recoveries in immunized animals that were challenged i.p. did not differ from those of unimmunized controls. Group differences in parasite antigen levels in sera collected 2-11 wk after larval challenge were consistent with parasitological findings obtained at necropsy. Antibody studies compared prechallenge sera from immunized animals to sera from infected (unimmunized) controls. Antibody responses to L3 surface antigens (assessed by IFA) were much stronger after immunization than after infection. Immunoblot studies showed preferential recognition of several L3 antigens (97, 54, 48, and 40 kDa) by antibodies in sera from immunized animals. Additional studies are needed to determine whether immunization with such preferentially recognized antigens can induce protection to larval challenge comparable to or better than that observed with live vaccines.     

Alterations in the longevity and fecundity of adult Trichinella pseudospiralis related to method of isolation of infective larvae

The infectivity of Trichinella pseudospiralis infective larvae was reduced significantly following exposure to low pH or a combination of 1% pepsin at low pH compared to that for larvae isolated in phosphate-buffered saline (PBS) at pH 7.0. Reduction of host gastric pH by administration to mice of sodium bicarbonate solution in PBS was accompanied by an increase in the infectivity of larvae isolated in 1% pepsin/HCl (P/HCl) compared to that for worms inoculated into hosts given PBS alone. Fewer adult worms developing from larvae isolated in P/HCl became established in the host small bowel than was seen with larvae isolated in PBS; moreover, the fecundity in vitro of adult worms developing from P/HCl-isolated larvae was reduced below that for adults developing from larvae isolated from host muscle in PBS. More adult worms were recovered following infection of immune hosts with PBS-isolated larvae than were recovered from immune mice challenged with larvae isolated in P/HCl. Similar findings were observed in mice immunized by infection with Trichinella spiralis and challenged with T. pseudospiralis larvae isolated in either P/HCl or PBS. Immunization of mice with T. pseudospiralis larvae isolated by either method and challenged with larvae of T. spiralis resulted in recovery of similar percentages of the challenge inoculum.     

Heligmosomoides polygrus (equals nematospiroides dubius): humoral and intestinal immunologic responses to infection in mice

Measurements of serum IgG₁, IgG_2a, IgM, and IgA levels and antibody titers in these immunoglobulin classes were made at intervals after initial infection and challenge infection of mice immunized by two or three previous infections. Identical measurements were made on the content of the small intestine in mice which had been exposed to the same infection schedule. Sections of small intestine taken after initial infection and challenge infection were examined by the fluorescent antibody technique for changes in populations of immunoglobulin-containing cells and by routine histologic procedures for histopathologic changes.In serum, only IgG₁ was consistently increased after initial infection, and antibody in IgG₁ was detected within the first 2 wk of infection. In immunized animals, only IgG₁ and antibody of this class always responded to challenge infection, although antibody in other immunoglobulin classes was detected.IgA concentration of the intestinal content did not differ significantly after initial infection or challenge infection of immunized mice. Immunized mice had about twice the IgG₁ concentration in intestinal content as singly infected animals. No intestinal antibody was detected after initial infection; only IgG₁ antibody was detected in the intestinal content of immunized and challenged mice.Cell infiltrates in the intestinal mucosa and submucosa of immunized animals contained numerous IgG₁-containing cells. Mast cells and globular leukocytes were observed in the intestine of immunized animals.     

Strongyloides ratti: Dissociation of the rat's protective immunity into systemic and intestinal components

Analysis of the early stages of a challenge infection with Strongyloides ratti has shown that protection is expressed against the developing third-stage larval worms (L₃) and prevents the maturation to adulthood of most larvae. Challenge after an immunizing infection that was restricted to the parenteral L₃ migratory phase showed that some 10–40% of overall protection could be ascribed to systemic antilarval immunity. Some larvae were trapped in the skin at the site of injection whereas others failed to migrate to the head and lung of immune rats. Larvae arriving in the intestine at Days 3, 4, and 5 did not persist beyond Day 7 and 8. Studies using [⁷⁵Se]methionine-labeled L₃ showed a significant increase in fecal label in rats immunized by a complete infection. This loss did not occur to the same extent in rats immunized only with parenteral larvae. Significant rejection of worms transplanted to the intestine also indicated intestinal protection. The possible existence of large numbers of worms in a state of “arrested development” was excluded by their failure to appear after cortisone treatment and the absence of worm accumulation in radiolabeling studies. It is concluded that at least two responses operate against larval S. ratti, one is systemic and the other operates in the intestine against larvae in a manner that resembles the “rapid expulsion” rejection of Trichinella spiralis in immune rats.     

Studies on the role of mucus and mucosal hypersensitivity reactions during rejection of Trichostrongylus colubriformis from the intestine of immune sheep using an experimental challenge model.

Nematode-naive sheep and sheep immunised by truncated infections with Trichostrongylus colubriformis were fitted with intestinal cannulae to allow administration of challenge infection and collection of intestinal fluids. Sheep were slaughtered at various times after challenge and the distribution of larvae along the small intestine was determined. Results showed that immune sheep had significantly fewer larvae in their intestines and that some sheep could expel the challenge infection within 2 h. Mucus samples from immune sheep contained increased parasite-specific antibody, histamine and anti-parasite activity as measured by larval migration inhibition assay. Higher levels of antibody and histamine were seen in intestinal fluids of immune sheep after challenge. Immunisation of sheep by truncated infections stimulated serum IgE and resulted in significantly higher numbers of IgE-positive cells in gut tissue sections before challenge and at 2 h and 24 h after challenge. Immune sheep also had greater numbers of mucosal mast cells and globule leucocytes after challenge, compared with naive sheep. When challenge larvae were mixed with mucus from immune sheep and infused back into naive recipient sheep, there was a distinct displacement of the larval population towards the distal part of the intestine, compared with the profile of larval establishment after infusion with mucus from naive sheep. These results are further evidence for an immediate hypersensitivity reaction in the intestine of immune sheep, where challenge larvae are expelled within 2 h and confirm the direct anti-larval properties of mucus. The cannulated-sheep challenge model described here will be a useful tool to unravel the mechanism of larval rejection from immune sheep and could lead to novel therapies.     

Studies of stage-specific immunity against Trichostrongylus colubriformis in sheep: immunization with adult parasites.

Merino sheep immunized by the adoptive transfer of adult T. colubriformis for 8 weeks were significantly protected against a challenge infection of 20,000 larvae. Two additional groups of sheep received a primary infection of 9000 adult worms which were allowed to persist for 14 weeks before one group was drenched. When both groups were challenged 10 days later with 30,000 larvae, serial necropsies of these and naive sheep revealed that worm rejection did not occur until 7-10 days after challenge. By comparison with the rapid rejection of larval challenges from sheep immunized with normal primary infections, the results suggest that the antigens which elicited rejection in these experiments are stage-specific and were only present or synthesized in sufficient quantities when parasites had developed for 1 week.     

Trichinella spiralis: immunization of mice using monoclonal antibody affinity-isolated antigens

An antigen epitope was identified from the excretory-secretory products of Trichinella spiralis first-stage larvae using monoclonal antibodies, and the glycoprotein antigens bearing this epitope (Ts.49 and Ts.53) were isolated from the crude excretory-secretory preparation by affinity chromatography. In immunization experiments carried out in mice, antigen priming with Ts.49 and Ts.53 resulted in a reduction of muscle larvae resulting from a challenge infection at a level comparable to priming with crude excretory-secretory antigens. In addition, antigens Ts.49 and Ts.53 induced an accelerated expulsion of adult worms from the intestines of immunized mice and reduced the fecundity of remaining female worms.     

Ancylostoma ceylanicum: immunization with soluble worm extract and responses to challenge infection of dogs

When dogs were immunized with soluble extract of adult Ancylostoma ceylanicum antigen, they were partially resistant to challenge infection in this model of human hookworm infection. Two immunizing doses, each of 1 mg protein suspended in Freund's complete adjuvant, were administered to one group of animals 1 and 3 weeks prior to infection with 5000 larvae. When compared with control dogs given the same infective dose, fecal egg excretion and intestinal adult worm burden in the immunized animals were reduced by 59 and 74%, respectively. Infection had no significant effect on hemoglobin concentrations, mean red cell volumes, total white cell counts, platelet levels, or spontaneous and phytohemagglutinin-induced lymphocyte transformations in both control and immunized animals. Both groups developed an eosinophilia, and lymphocytes from the immunized dogs responded transiently to stimulation with both larval and adult worm antigens. Specific IgM antibodies were transitory in both groups of dogs following infection. IgG antibodies developed significantly 2 weeks after infection in the immunized group; however, they did not appear until 4 weeks after infection in the control group. Both groups developed IgA antibodies 1 week after infection. They were maintained in the control dogs, in contrast to the levels in immunized animals which subsided rapidly 4 weeks after infection. Therefore, when animals are injected with soluble adult worm antigen prior to infection, specific protective immunity is acquired.     

Onchocerca volvulus: immunization of chimpanzees with X-irradiated third-stage (L3) larvae.

To provide a theoretical basis for the potential development of vaccines against Onchocerca volvulus (Ov) a trial has been conducted to assess the protective efficacy of immunization of chimpanzees with X-irradiated L3 larvae. Approximately 1000 larvae were injected at 0, 1, and 7 months. The immunized animals, and unimmunized controls, were then challenged with 250 live L3. In order to provide possibly protective exposure to the immunologically distinct L4 epicuticle, a radiation dose (45 krad) was chosen which preserved about 50% of the molting ability of unirradiated larvae. Despite the presence of a strong immune response to crude adult worm extracts, and to cloned Ov antigens, at the time of challenge little or no significant protection against patent infection was observed: three of four immunized animals developed patent infection as compared to four of four controls. One immunized animal failed to become patent or to manifest the late antibody response to adult worm antigens seen in both subpatent and patent infections in this model, and may have been protected from infection. The implications of these studies for future attempts to immunize against O. volvulus are discussed.     

Induction of protective immunity against Schistosoma mansoni by a non living vaccine. I. Partial characterization of antigens recognized by antibodies from mice immunized with soluble schistosome extracts

A single intradermal injection of frozen and thawed schistosomula in conjunction with the bacterial adjuvant Mycobacterium bovis strain Bacille Calmette Guerin, Phipps substrain (BCG) induced significant levels of resistance to challenge Schistosoma mansoni infection in C57BL/6 mice. Immunization with the aqueous fraction remaining after 100,000 X G centrifugation of the larval lysate was also protective under these conditions, suggesting that some immunogenic determinants may not be membrane associated. Frozen-thawed cercariae and soluble components of adult worms also protected against challenge infection in these experiments. These observations indicate that soluble immunogens are present in both early and late developmental stages of the parasite, and therefore may be good candidate antigens for an immunochemically defined vaccine against schistosomiasis. Induction of humoral reactivity against soluble or membrane antigens was examined in mice protected against cercarial challenge by prior exposure to frozen-thawed larvae, soluble larval, or soluble adult antigens plus BCG. Animals that were immunized with frozen-thawed larvae produced low but significant levels of antibodies against larval surface antigens when examined by indirect immunofluorescence or by immunoprecipitation of surface-labeled schistosomula. Mice immunized with soluble antigens, however, showed negligible antibody reactivity against surface membrane antigens. Because mice immunized with soluble antigens were resistant to challenge infection, these results strongly suggest that anti-surface membrane reactivity is not required in the mechanism of protective immunity in this model. Sera from mice immunized with either total freeze-thaw larval lysate or soluble schistosome extracts all showed strong reactivity against soluble antigens, as detected by ELISA. Western blot analysis showed these antisera to react with a restricted number of high m.w. antigens that were present both in schistosomula and in adult worms. These antigens are therefore likely to play a major role in the development of resistance in this model as immunogens and/or as targets of protective immune response.