Protection against Trichinella spiralis induced by a monoclonal antibody that promotes killing of newborn larvae by granulocytes

To B or not to B: B cells and the Th2-type immune response to helminths

Similar T helper (Th)2-type immune responses are generated against different helminth parasites, but the mechanisms that initiate Th2 immunity, and the specific immune components that mediate protection against these parasites, can vary greatly. B cells are increasingly recognized as important during the Th2-type immune response to helminths, and B cell activation might be a target for effective vaccine development. Antibody production is a function of B cells during helminth infection and understanding how polyclonal and antigen-specific antibodies contribute should provide important insights into how protective immunity develops. In addition, B cells might also contribute to the host response against helminths through antibody-independent functions including, antigen presentation, as well as regulatory and effector activity. In this review, we examine the role of B cells during Th2-type immune response to these multicellular parasites.

Identification and characterisation of a cDNA sequence encoding a glutamic acid-rich protein specifically transcribed in Trichinella spiralis newborn larvae and recognised by infected swine serum

Presently, little is known of the mechanism by which Trichinella penetrates and modulates reprogramming of muscle cells. In light of evidence demonstrating strong protective characteristics of antigens derived from this stage, understanding this process may shed light on potential targets for effective abatement of infection. To this end, a PCR-derived cDNA expression library was constructed using 0.5 micro g of total RNA from Trichinella spiralis newborn larvae. The library consisted of >125000 insert-containing clones. Approximately 40-50 x 10(3) clones were screened immunologically using sera from pigs experimentally infected with 7000 Trichinella L1. Multiple clones reacting positively with the swine infection serum and encoding portions of a glutamic acid-rich protein were identified. Northern and Southern blots indicated at least two distinct genes that encoded the glutamic acid-rich proteins and that these genes were transcribed specifically in the newborn larvae stage. cDNA sequence data predicted open reading frames of 1497 and 1,716 bp generating proteins of 498 amino acids and 571 amino acids, respectively. Both sequences consisted of approximately 39% glutamic acid and 16% serine residues, and differed by the presence of a 219 bp fragment present in the 1716 bp sequence that was absent from the 1497 bp sequence. PCR data indicated that additional isoforms exist within this gene family that are different in length from those described above. In addition, it was found that more than one isoform can exist within a single worm and that this pattern can vary between individual worms within a population. Mouse antibodies to recombinant antigen localised the glutamic acid-rich proteins to the periphery of the developing stichocyte cells within the newborn larvae consistent with the hypothesis that the newborn larval antigens are secreted.

Cloning and preliminary characterization of a novel cuticular antigen from the filarial parasite Dirofilaria immitis

We have described here the cloning and partial characterization of a cDNA encoding a cuticular antigen of Dirofilaria immitis. A 48-h third-stage larval D. immitis cDNA library was immunoscreened with sera raised in mice against third-stage larval cuticles (mouse anti-L3 cuticle antisera). A strongly immunoreactive clone (L3MC4) was isolated. Sequence analysis of L3MC4 showed that it was a partial length cDNA. The missing 5' end of the clone was amplified by PCR from D. immitis adult female first-strand cDNA using the nematode 22-base splice leader sequence and a L3MC4-specific antisense primer. The composite cDNA sequence comprised 616 bases (nDiL3MC4) encoding a full-length protein of 146 amino acids (DiL3MC4). GenBank analysis showed that DiL3MC4 shared some homology to an unknown C. elegans gene product (31%) at the amino acid level. However, there were no related filarial expressed sequence tags in the current GenBank database. Antibodies to recombinant DiL3MC4 (rDiL3MC4) identified a 19-kDa native antigen in the adults and in the L3 and L4 larval stages of D. immitis. In addition, the antibodies bound to the cortical layers of the L3 cuticle, as revealed by immuno-gold electron microscopy. The native protein was not detected in larval and adult excretory-secretory products. Immunoblot analysis showed that serum from a rabbit that was repeatedly injected with a small number of D. immitis third stage larvae reacted with rDiL3MC4. Thus, DiL3MC4 is a novel cuticular antigen of a filarial parasite.

Advances in the immunobiology of eosinophils and their role in disease

Eosinophils play a protective role in host immunity to infections by parasitic worms and, detrimentally, are involved in the pathophysiology of asthma and other allergic diseases. Airway inflammation is central to the pathology of asthma and is characterized by infiltration of the bronchial mucosa by large numbers of proinflammatory cells, amongst which the eosinophil is prominent despite being a minority constituent of circulating leukocytes. Crucial steps in eosinophilic inflammation include augmented production of eosinophils in the bone marrow, their increased release into the circulation, and their selective accumulation in the conducting airways. The eosinophil has a potent armory of proinflammatory mediators, including cytotoxic granule proteins, cytokines and lipid mediators with considerable potential to initiate and sustain an inflammatory response. Thus there is much interest in the elucidation of the mechanisms responsible for eosinophil accumulation, persistence, activation and ultimate fate. This article reviews our current understanding of the role of the eosinophil in human disease and the immunobiology of this important proinflammatory cell.

Isotype-specific antibody responses to the surface-exposed antigens of adult and larval stages of Dictyocaulus viviparus in infected and vaccinated calves

The antibody responses to the surface-exposed antigens of living larval and adult Dictyocaulus viviparus were measured by quantitative immunofluorescence using sera from calves infected with, or vaccinated against, the parasite. In infected animals, the surface of the sheath of the third-stage larvae (L3) (retained cuticle of second-stage larvae (L2)) proved highly immunogenic despite the fact that it is thought to be shed prior to parasite penetration of the host intestine. When responses to the surface of exsheathed larvae (L3 cuticle) were measured, a high level of heterophile IgM antibody was detected in the serum of animals that had not been previously exposed to the parasite and, following infection, a specific IgG response was detected against the exsheathed L3 surface. The antibody response, however, was less marked than that observed against the intact L3 sheath. Responses of patently infected animals to the adult surface showed an initial IgM response that was superseded with time by IgG1 and IgG2 responses. Vaccinated animals showed only low level responses to the surfaces of the L3 sheath, L3 cuticle and adult stages following immunisation with two doses of irradiated larvae. The immunised animals produced a strong antibody response to the larval surface antigens following challenge with infective larvae but they failed to produce antibody to the surface of adult parasites. These results show that the surfaces of all the stages of D. viviparus examined are immunogenic in infected calves and, depending on the developmental stage, infection regime, or time of infection, high levels of parasite-specific IgG1 or IgM are stimulated. It has previously been shown that significant levels of protective immunity can be obtained in naive animals following passive transfer of serum from infected calves. Thus, the antibody responses detected in the work reported here may be of relevance in protective immunity against dictyocaulosis.

Blocking anti-Trichinella spiralis antibodies in chronically infected rats

Specific anti-newborn larva antibodies present in the serum of rats chronically infected with Trichinella spiralis were incapable of inducing killing of newborn larvae by activation of normal peritoneal cells. These late antibodies blocked the cytotoxic reaction induced by early antibodies produced a few weeks after infection. Passive transference of late serum to normal mice failed to induce protective immunity against infection by newborn T. spiralis larvae. When late immunoserum was fractionated by gel filtration, blocking activity was found only in the fraction containing IgG subclasses. By indirect immunofluorescence assay and cytotoxic reaction it was shown that blocking antibodies were specific for newborn larvae and could not be adsorbed with muscle larvae. It is concluded that the synthesis of anti-newborn larva antibodies is modulated in the course of a chronic infection: early antibodies developing shortly after infection are cytotoxic, whereas blocking antibodies predominate in the late population. Furthermore, the results suggest that during a chronic infection, resistance to reinfection may be modified.

The production and characterisation of monoclonal antibodies to Lucilia cuprina larval antigens

A panel of murine monoclonal antibodies was produced against three Lucilia cuprina larval preparations that are unlikely to be exposed to the sheep's immune system during a normal infection. Antibodies were successfully produced against a crude third instar midgut homogenate preparation (MG), and Sodium dodecyl sulphate (SDS) and Triton X-114 (TX) detergent extracts of first instar larvae. Characterisation of the relevant antigens was performed using 1- and 2D gel electrophoresis and immunoblotting, immunoperoxidase histological studies and in vitro larval growth cultures. All the mAbs were of the IgM isotype. Common recognition of bands at 40, 50 and 80 kDA was evident on 1D blots of larval organ preparations by most mAbs while recognition of antigens in the 2D blots appeared to be more specific. Immunohistological studies suggested that a number of the antibodies specifically bound to intracellular structures within the midgut epithelium. However, antibodies derived from one clone also recognised the epithelium of Malpighian tubules, oenocytes and muscle fibres. None of the antibodies raised against TX extracts were observed to bind to larval structures. Results of larval cultures suggested that certain antibodies could significantly inhibit larval survival and growth in vitro.

Immune killing of newborn Trichinella larvae by human leucocytes

The capacity of human leucocytes from normal donors to kill the newborn larvae of the nematode Trichinella spiralis in vitro, in the presence of serum from infected individuals, was studied using newborn larvae (NBL) less than 2 h of age or NBL that had been maintained in culture at 37 degrees C for 20 h. Neutrophils and monocytes attached to newborn Trichinella larvae and killed them, regardless of their age. When eosinophils were used, 20 h old NBL were killed whereas 2 h old NBL were not. Complement was essential in the cytotoxic effect of leucocytes. These results indicate that host defence against T. spiralis in humans may be a complex mechanism in which different cell types can be involved. They also show that the age of maturation of the NBL is of paramount importance in the antibody-dependent cellular cytotoxicity reaction.

Biochemistry of the nematode cuticle: relevance to parasitic nematodes of livestock

The cuticle of nematodes is a thin, flexible outer covering composed primarily of protein with trace amounts of lipid and carbohydrate. There has been considerable recent interest in the biochemistry, immunology and molecular biology of the cuticle of parasitic nematodes because of its role as an interface between parasite and host. The cuticle consists of: (1) collagen-like proteins that form the medial and basal layers; (2) non-collagen proteins that form the epicuticular and external cortical regions; (3) non-structural proteins associated with the external surface. The collagen-like proteins are solubilized by reducing agents, have molecular weights of 30-120 kDa and exhibit stage and species variations. Nematode collagen genes, however, code only for proteins with molecular weights of 30 kDa. The non-collagenous proteins, referred to as cuticlin, exhibit unusual chemical properties as indicated by their resistance to solubilization even under strongly denaturing conditions. Recent studies of Ascaris suum have demonstrated the presence of tyrosine-derived cross-links, dityrosine and isotrityrosine, that may form the linkage between subunits in assemblage of the collagenous and noncollagenous structural components of the cuticle. A peroxidase enzyme has been implicated in the synthesis of these cross-links. Recent 125I labeling studies of Haemonchus contortus have identified and characterized stage-specific proteins on the cuticular surface.

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: a 76-kDa excretory/secretory larval antigen identified by a monoclonal antibody

Spleen cells from BALB/c mice were fused with myeloma cells following infection of the mice with Trichinella spiralis larvae and an ip booster injection with larval homogenate antigen. A monoclonal antibody (Mab), designated as TS 3G6 which did not react with sera or tissue extracts from noninfected mice, rats, and guinea pigs, was selected for further studies because of its high activity and specificity. When tested in ELISA TS 3G6 did not cross-react with Ascaris suum, A. lumbricoides, Toxocara canis, E. granulosus (larvae), Trichiuris suis, or T. ovis. Western blot analysis showed that Mab 3G6 recognized an antigen of 76 kDa located in the stichosome of the larvae as well as on the surface of the larval cuticle. Digestion of a larval extract with different enzymes suggests that the Mab TS 3G6 corresponding epitope is a polypeptide. The TS 3G6 antigen was detected in culture supernatants of Trichinella muscle larvae and in sera of experimentally infected animals using a sensitive ELISA assay. This secretory antigen also seemed to induce a specific immune response in the host since sera from infected animals could block the binding of Mab TS 3G6 to its target antigen when tested in a competitive ELISA.

Trichinella spiralis: major histocompatibility complex-associated elimination of encysted muscle larvae in swine

A heretofore undescribed host-mediated reactivity against encapsulated muscle larvae (ML) of the nematode Trichinella spiralis is reported. Inbred miniature swine (NIH minipigs) of three independent SLA phenotypes, which received a primary oral dose of 300 T. spiralis ML, successfully resisted a secondary infection of 10,000 ML; however, only pigs of the SLAa/a phenotype exhibited an unusual and highly significant reduction in the numbers of encysted ML from the primary infection (P less than 0.0003). This initial anti-encysted ML reactivity was confirmed in subsequent trials by comparing the prechallenge ML burdens with the reduced ML numbers in primary-infected aa pigs after challenge. Analyses of inbred strains of mice, selected for major histocompatibility type and for resistance or susceptibility to infection with T. spiralis, showed no such anti-encysted ML response. Because elimination of encysted T. spiralis ML had been accomplished previously only through selected drug regimens, our demonstration of a nonpharmacological, host-mediated reactivity against this stage of the parasite in swine highlights the importance of MHC genes in regulating disease resistance in a livestock species.

Haemonchus contortus: a simple procedure for purifying surface proteins from third- and fourth-stage larvae

Surface proteins were solubilized from exsheathed third (XL3)- and fourth (L4)-stage larvae of Haemonchus contortus by a one-step extraction procedure involving brief heat treatment of the worms in the presence of buffer and 100 mM sodium chloride. Surface proteins also could be preferentially extracted from XL3s, but not from L4s, by heating the worms briefly in 1% sodium dodecyl sulfate. The major proteins extracted by these procedures were similar in molecular weight to those detected by surface-labeling live worms with 125Iodine. Both extraction procedures solubilized a single, major protein with an apparent molecular weight of 68-97 kDa from XL3s. In contrast, extraction of L4s with 100 mM sodium chloride yielded four major proteins with relative molecular weights of 27, 29, 78, and 200 kDa. Antibodies raised in rabbits to surface proteins prepared by the sodium chloride procedure reacted with the surfaces of live worms in indirect immunofluorescence assays. The anti-XL3 surface protein serum was stage specific in immunofluorescence experiments using live worms and in immunoprecipitation experiments using 125Iodine-labeled XL3 and L4 surface proteins. The overall amino acid composition of the surface proteins is hydrophilic. Twenty-six percent of the amino acid residues of the XL3 surface proteins, which consist predominantly of the 68-97 kDa species, are glutamate or glutamine.

Identification and preliminary characterization of cuticular surface proteins of Haemonchus contortus

Cuticular surface antigens of the XL3 and L4 stages of Haemonchus contortus have been studied by surface labeling and immunological techniques. Live worms were labeled with 125I and extracted with sodium dodecyl sulfate (SDS) followed by SDS + 2-mercaptoethanol. The SDS-soluble surface proteins of XL3s and L4s were found to consist of relatively few major species. The pattern of labeled polypeptides was distinctive for each developmental stage. These proteins are refractory to digestion by bacterial collagenase. Several of the proteins are glycosylated. Further extraction of labeled worms with SDS + 2-mercaptoethanol solubilized additional labeled proteins that appeared to be primarily collagens. Rabbit antisera prepared against native XL3 and L4-cuticles reacted strongly with the surfaces of live worms in immunofluorescence assays. In contrast, antisera prepared against SDS-extracted cuticles reacted weakly or not at all with live worms in similar experiments. Rabbit antisera prepared against adult cuticles failed to react with live XL3s or L4s. These studies suggest that the major surface antigens of XL3s and L4s are solubilized by SDS and that there are different antigens present on the cuticular surfaces of XL3s, L4s and adults. Stage-specificity in cuticular surface proteins may contribute to the successful parasitic lifestyle of this nematode.

Antigens of parasitic helminths in diagnosis, protection and pathology

A thorough study of parasitic helminth antigens is a pre-requisite for control programmes based on accurate immunochemical diagnosis, protection by vaccination and perhaps immune modulation to diminish pathological sequelae. Studies should be directed at the identification of those stage- or age-specific surface, secreted and somatic antigens which are involved in the host-parasite interactions responsible for immunity and/or pathology. Current methods of diagnosis of parasitic infections often fail to detect low-level patent infections, which incurs the risk of having a reservoir capable of perpetuating infections. There is, then, an urgent requirement for accurate immunochemical diagnosis, to be used in association with, and for the evaluation of, drug treatment and vector elimination, in parasite control programmes. Given the high sensitivity of current immunoassay technology, the only bar to establishing the necessary immunological tests is the choice of suitably specific antigen/antibody systems. Assays designed to detect parasite products or antigens are a major priority, as they indicate current infection, whereas those which detect antibody only indicate exposure to infection, which may or may not be current. Surface and secreted antigens are the most likely targets for protective immune responses and thus form a logical focus for vaccine design. The cestodes, which present such strong evidence for immunity following natural infection, are likely to yield effective vaccines by modern procedures. Certain antigens must, however, stimulate the humoral and/or cellular responses which are responsible for the undesirable immunopathological consequences of many helminthic diseases. The nematodes and trematodes furnish some extreme examples of such pathology. The ultimate objective in identifying these particular antigens is to utilize them in the appropriate down-regulation of the immune response responsible for such pathology. As an illustration, we have presented an interesting correlation between one particular clinical condition of onchocerciasis (Sowda) and the serological response, defined both in terms of the parasite antigens and an immunoglobulin class-restricted antibody response. Finally, the complexity of these parasite systems and the host response to the parasite should not be underestimated. Modern analytical techniques allow their detailed analysis in terms of the humoral antibody responses and afford the possibility of the future development of control and disease management procedures tailored to each individual host-parasite system. However, novel systems are required to complete the analysis of the cellular components of the immune response to parasite antigens, and functional studies are needed to determine the role that these parasite antigens play in the complex interaction between parasite and host.

Protection against Trichinella spiralis induced by purified stage-specific surface antigens of infective larvae

The stage-specific surface antigens of the infective larvae of Trichinella spiralis, isolated using an affinity column of monoclonal antibody (Mab) NIM-M1, consisted of four components with molecular weights of 72, 65, 52, and 47 kDa, respectively. These four components may have unique as well as shared structural features and appear to be products of the stichosome. When injected i.p. as an emulsion in complete Freund's adjuvant, the purified antigens induced protection against infection of BALB/c mice with T. spiralis, as assessed by reductions in both the muscle larvae load and the number of adult intestinal worms.

Antibody-mediated in-vivo cytotoxicity to Trichinella spiralis newborn larvae in immune rats

The antibody-dependent cell-mediated larvicidal response of AO rats against Trichinella spiralis newborn larvae was studied in vivo. Rats were immunized with 2000-3000 muscle larvae orally and then challenged 6-20 days later with 10,000-20,000 newborn larvae intraperitoneally. Newborn larvae recovery from the peritoneal cavity decreased significantly and was accompanied by cuticular cell adherence and killing of newborn larvae by day 9 of infection. Similar effects were observed when newborn larvae were incubated with blood obtained from immunized rats. The cell adherence and larvicidal responses reached their peak by day 16 of the primary infection. Passive transfer experiments demonstrated that newborn larvae infectivity was substantially impaired once cell adherence occurred. Cuticular adherence took place in vitro only when immune serum was added to the incubation medium. Complete destruction of newborn larvae in vivo after passive transfer, as measured by muscle larvae burden was only evident after exposure to both immune serum and immune cells, not to either alone. Non-specific stimulation of the peritoneal cavity with a sterile intestinal infection failed to induce cuticular adherence or larval killing in these rats. We conclude that a stage-specific antibody-dependent cell-mediated larvicidal response is rapidly generated in vivo after the host is exposed to newborn larvae. It is a systemic response which impairs the infectivity of newborn larvae and can destroy them before they reach muscle tissue.

Excretory-secretory products of helminth parasites: effects on host immune responses

Parasitic helminths excrete or secrete (ES) a variety of molecules into their mammalian hosts. The effects of these ES products on the host's immune responses are reviewed. Investigations into the source of antigenic or immunoregulatory ES products have identified the cuticular and tegumental surfaces of some nematodes and trematodes respectively as being important sources of ES products; other ES molecules are released through specialized excretory or secretory organs. It is proposed that the active shedding of surface antigens may serve as an important source of parasite antigens available to the immune system in a form in which they can be taken up and processed by antigen-presenting dendritic cells, macrophages and certain B cells for presentation to T helper cells. The ES products of nematodes, trematodes and cestodes contribute to immune evasion strategies of the parasites through mechanisms including shedding of surface-bound ligands and cells, alteration of lymphocyte, macrophage and granulocyte functions and modulation of complement and other host inflammatory responses. Immunopathology may be induced by ES products as in the development of granulomas around entrapped schistosome eggs. In some host-parasite systems ES antigens may induce host-protective immune responses and this source of protective antigens has been utilized in the successful vaccination against helminth infections, particularly against infection with trichurid nematodes and the metacestode stage of cestode parasites. The use of ES antigens in immunodiagnosis of helminth infection is also briefly discussed.

Antibody-dependent in-vitro cytotoxicity of newborn Trichinella spiralis larvae: nature of the cells involved

The cytotoxic reaction of normal peritoneal mouse cells, containing less than 3% eosinophils, against newborn Trichinella spiralis larvae, in the presence of antibody, was studied using newborn worms less than 2 h of age, or newborn worms that had been maintained in culture at 37 degrees C for 20 h. Newborn worms 2 h old were killed, whereas 20 h newborn worms were not. The cells that initially adhered to the larvae were examined by electron microscopy. Only eosinophils adhered to 2 h newborn worms and only macrophages to 20 h ones. The attached eosinophils degranulated and died after a few hours. The macrophages that adhered to, but did not kill the 20 h newborn worms were morphologically in good state and no lysis of the larvae was observed. These results suggest that different antibody classes are involved in eosinophil and macrophage adherence, and strongly support the hypothesis that eosinophils mediate larval destruction. They also show that rapid changes are taking place after birth in the structure of the larval cuticle and that the age of Trichinella newborn worms is a major factor in the antibody-dependent cellular cytotoxicity reaction.

Trichinella spiralis: immunocytochemical localization of surface and intracellular antigens using monoclonal antibody probes

A panel of immunologically and biochemically defined monoclonal antibody probes has been used in conjunction with immunocytochemical techniques to localize target antigens in sections of different life-cycle stages of Trichinella spiralis. Monoclonals that immunoprecipitate surface components from adult worms, show reactivity with the surface but not with internal tissues of sectioned parasites. Reagents that immunoprecipitate radio-isotope labelled stage-specific surface components of muscle-stage larvae, however, react with the stichosome and gut lining of sectioned larvae, as well as with the surface. Monoclonal antibody probes that do not stain the surfaces of live, intact muscle larvae in immunofluorescence assays, but which immunoprecipitate solubilized surface glycoproteins, also show reactivity with cuticular and stichosomal antigens of sectioned larvae. The more powerful resolution provided by electron microscopy has localized the surface antigens to the epicuticle and the intestinal antigens to the brush-border microvilli. Of particular interest was the finding that antigens of muscle-stage larvae, known to confer protection upon recipient mice, also exist in the stichosome of adult parasites. This observation may shed some light on the fact that mice immunized with antigens from muscle-stage larvae show, in addition to reduced muscle larva burden, accelerated expulsion of adult worms. The implications of these data for stage specificity of immune responses to trichinosis are discussed.

Trichinella spiralis: immunization of pigs with newborn larval antigens

The potential of crude Trichinella spiralis newborn larval antigens for pig immunization was investigated. A preparation of whole newborn larvae killed by freezing and thawing, and combined with Freund's complete adjuvant, induced a high level of protection against challenge (78%), compared to a 40% resistance level in pigs immunized with excretory secretory antigens of muscle larvae. Sera from pigs immunized with newborn larvae contained antibodies which bound to the surface of the newborn larvae, as determined by immunofluorescence. In a second trial, the freeze thawed newborn larvae preparation was compared with a soluble and insoluble fraction prepared by sonication of whole newborn larvae. Pigs receiving whole newborn larvae or the insoluble fraction developed strong immunity to challenge (88.2 and 85.5%, respectively); the soluble fraction was ineffective. Immunization with all preparations induced antibody to newborn larval antigens, but not to adult or muscle larvae excretory secretory antigens. Polyacrylamide gel electrophoresis of the soluble and insoluble fractions indicated that sonication was ineffective in solubilizing the larger molecular weight components. These results demonstrate that newborn larval antigens are highly protective in pigs, but that their further development as a vaccine will require more efficient procedures for antigen solubilization and large-scale production.

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.

Trichinella spiralis: antifecundity and antinewborn larvae immunity in swine

The development of antifecundity and antinewborn larvae immunity in swine infected with Trichinella spiralis was investigated. In primary infections, adult female worm fecundity dropped sharply after 3 weeks, although adults could be recovered from the small intestine for at least 7 weeks after infection. In challenge infections of pigs infected previously, adult female worm fecundity was depressed up to 51% and the adults were expelled within 3 weeks. Since immune pigs are almost completely resistant to the secondary establishment of muscle larvae, this suggested the existence of immune effector mechanisms also acting on the newborn larvae. This was supported by observations, using an indirect fluorescent antibody assay, that pig antibody bound to the surface of the newborn larvae. Passive transfer of immune pig serum resulted in a large reduction in muscle larvae burden in both infected pig and rat recipients. Adult female worm fecundity in such immune serum recipients was reduced only by 20% and worm survival in the intestine was unaffected. These results indicate that immunity to the newborn larvae, in addition to antifecundity effects, are responsible for the high levels of acquired resistance to T. spiralis in swine.

Immunoglobulin class specific responses to biochemically defined antigens of Trichinella spiralis

A comparison of the humoral response to resistant (NIH) and susceptible (C3H) strains of mice, which reject adult worms at different rates during a primary infection, was made following infection with Trichinella spiralis. The serum concentration of immunoglobulins of the heavy chain classes IgM, IgG1, IgG2, IgG3 and IgA were determined by single radial immunodiffusion. Antibodies of the same immunoglobulin isotypes to biochemically defined, stage specific surface and secreted components of three stages of parasite development were also determined using an isotype specific immuno-coprecipitation assay. Independent variation of the responses of each immunoglobulin isotype was observed. The specific anti-parasite response did not reflect total serum immunoglobulin levels in all immunoglobulin classes, and this is discussed in relation to basic mechanisms of immunoglobulin class switching. Finally a close correlation was observed in resistant (NIH) mice between the production of IgA antibody to surface components of adult worms and accelerated expulsion of this stage of the worm from the gastrointestinal tract. The possible relevance of this IgA response is further indicated by the failure of susceptible mice to synthesise IgA antibodies to the same surface antigens.

Biotechnology in the development of vaccines for animal parasites

Attempts to develop vaccines for protozoan and helminth parasites of livestock have been generally unproductive. Difficulties have been encountered in identifying antigens which induce protective immune responses and in obtaining sufficient quantities of antigens for vaccine trials. Use of monoclonal antibody and genetic engineering technologies provides the necessary tools to overcome these problems. Application of these technologies in animal parasitology should provide for significant breakthroughs in vaccine development.

Antigens of gastrointestinal nematodes

Nematodes occupying the gastrointestinal (GI) tract of man shed an as yet undefined array of chemicals into their environment. To combat effectively the potentially debilitating disease caused by infection with these organisms we must (a) define the parasite products chemically, (b) determine their ability to induce protective immunity (or to counter a protective immune response), and (c) establish their potential for the diagnosis of infection. Whilst it has become clear that "antigens" can be derived from within the parasite and from the turnover of external cuticular components (the term "ES" must include both), further work is necessary to establish the significance of these molecules to the survival of the parasite. In this context, a number of questions will be answered in the near future. For example, how important is the hookworm protease to parasite nutrition? Can vaccination using the genetically engineered and purified enzyme generate protective immunity? Will the stichocyte secretions of Trichuris trichiura prove to be as immunogenic as those of Trichinella spiralis? (Surprisingly, little has been published with regard to the presence of enzymes in stichocyte secretions.) Are GI nematodes on the way out?

Antigen stripping from the nematode epicuticle using the cationic detergent cetyltrimethylammonium bromide (CTAB)

The cuticular antigens of adult Nematospiroides dubius were selectively removed using the cationic detergent cetyltrimethylammonium bromide (CTAB). Nonionic, zwitterionic or anionic detergents were ineffective in comparison. The biochemical profile of the antigens removed by detergent was identical to that of surface antigens removed by homogenization, with the added advantage that detergent-stripped antigens lacked many of the background antigens (excretory/secretory--ES and somatic) seen in homogenates. In addition, the detergent was shown to act in a non-invasive manner as electron micrographs failed to reveal any gross damage to the nematode outer cuticle. The observed selective release of significant quantities of relatively clean nematode surface antigen by CTAB in a non-invasive or destructive manner provides the impetus for definitive studies on the relevance of surface antigens (in the absence of ES or somatic antigens) to the overall immunogenicity of this and other parasites.

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.

Stage-specific antigens of Trichinella spiralis

Infective larvae, adults and newborn larvae of Trichinella spiralis were surface labelled with radioactive iodine, and the surface material was solubilized in the mild detergent sodium deoxycholate. The radio-isotope labelled products were stage-specific glycoproteins that were few in number (2-4 components) and antigenic in infected mice and rats. Antibodies synthesized in infected animals against these biochemically defined surface antigens may or may not interact with the surface of the living worm. The latter type of antibody is unlikely to be involved in the initial phase of parasite rejection and is therefore another example of a non-protective host antibody response. The stimulus for its synthesis must be the observed release of surface antigen. A monoclonal antibody to a surface glycoprotein of newborn larvae protected against infection, and also promoted eosinophil killing in vitro. This observation emphasizes the importance of surface antigens in protection against infection, suggests a role for granulocytes in vivo, and provides encouragement for the possible use of nematode surface antigens in protection. An example of regional specialization of the nematode cuticle was given by a monoclonal antibody reactive with only the surface of the male intromittent organ and not the female or remainder of the male. The same stages were labelled in vitro with radioactive methionine, and the secreted proteins were also found to be stage-specific. Some, but not all, were antigenic in infected mice. The total concanavalin A-binding somatic glycoproteins of each stage exhibited considerable individuality, and hence stage specificity, when resolved by two-dimensional gel electrophoresis.(ABSTRACT TRUNCATED AT 250 WORDS)