Comparative studies of antigens of erythrocytic and exoerythrocytic merozoites of Plasmodium lophurae: characterization of a surface glycoprotein from exoerythrocytic merozoites

Rabbits were immunized with merozoite-enriched preparations of erythrocytic and exoerythrocytic Plasmodium lophurae. The antisera were used to compare antigens of the two types of merozoites. The indirect immunofluorescent antibody test showed the presence of common antigens. The growth of exoerythrocytic parasites was inhibited by the homologous antiserum and to a lesser extent by the antiserum prepared against erythrocytic forms. Cultures of exoerythrocytic parasites as well as their normal host cells were labeled metabolically with 35S-methionine, tritiated proline and glucosamine. Nonidet P-40 extracts of labeled merozoite-enriched preparations, infected cells, and normal cells were immunoprecipitated with the two types of antisera and the immunoprecipitates were analyzed on polyacrylamide gels. The results showed that erythrocytic and exoerythrocytic merozoites have several common proteins. A major difference was a glycoprotein with an approximate molecular weight of 110,000 daltons. This glycoprotein was associated with the surface of exoerythrocytic merozoites and was not recognized by antibodies prepared against erythrocytic forms.     

Monoclonal antibody characterization of Plasmodium falciparum antigens in immune complexes formed when schizonts rupture in the presence of immune serum

When Plasmodium falciparum parasites are cultured with some immune sera, merozoites are agglutinated by antibodies to form immune clusters of merozoites and prevent their invasion into erythrocytes. Within these immune clusters of merozoites, several antigens that are normally found in the soluble fraction after detergent extraction accumulate in relatively insoluble immune complexes. From mice immunized with these immune complexes, we obtained hybridomas secreting monoclonal antibodies (mAb) that react with various immune clusters of merozoites antigens, including mAb 3D5, which recognizes a 101-kDa antigen (p101) and mAb, 5E3, which recognizes a 113-kDa antigen (p113). Both mAb reacted with antigens at the surface of schizonts, in the vacuolar space, and at the surface of merozoites before their release from schizont-infected cells. Both p101 and p113 were synthesized by mature trophozoites and young schizonts. In pulse-chase experiments, p113 was processed to 100-, 70-, 55-, and 50-kDa products. Both p101 and p113 appeared in the culture medium when schizont rupture occurred in normal culture medium but were found in immune complexes when schizont rupture occurred in the presence of immune serum. Antibodies in immune complexes, when dissociated with acid and used to probe immunoblots, reacted with affinity-purified p101 and p113. Antigens such as these, which are accessible at the parasite surface and react with antibodies present in immune serum that inhibits parasite invasion, are logical candidates to study in the search for a vaccine against the erythrocytic stages of malaria.     

Plasmodium berghei XAT: protective 155/160 kDa antigens are located in parasitophorous vacuoles of schizont-stage parasite

Effective blood-stage malaria vaccine candidates have been mainly developed from the proteins in exposed locations on the parasite such as the surface of free merozoites or infected red blood cells. In the present study, we identified and localized novel protective antigens derived from the blood-stage of Plasmodium berghei XAT after establishment of hybridomas producing protective monoclonal antibodies (mAbs) against the parasites. The protective antigens were expressed in schizonts but not in trophozoites, and located in the parasitophorous vacuoles in the infected erythrocyte cytoplasm. The antigens, with molecular weight of 155/160 kDa, were not identical to any merozoite/schizont antigens that have been reported as target molecules recognized by mAbs developed to rodent malaria parasites. The characterization of new malarial antigenic targets of potentially protective antibody responses following infection would give us new insights for the selection of candidate antigens for malaria vaccine.     

Biochemical and immunological characterization of E. coli expressed 42 kDa fragment of Plasmodium vivax and P. cynomolgi bastianelli merozoite surface protein-1

Plasmodium vivax is one of the most widely distributed human malaria parasites and due to drug-resistant strains, its incidence and prevalence has increased, thus an effective vaccine against the parasites is urgently needed. One of the major constraints in developing P. vivax vaccine is the lack of suitable in vivo models for testing the protective efficacy of the vaccine. P. vivax and P. cynomolgi bastianelli are the two closely related malaria parasites and share a similar clinical course of infection in their respective hosts. The merozoite surface protein-1 (MSP-1) of these parasites has found to be protective in a wide range of host-parasite systems. P. vivax MSP-1 is synthesized as 200 kDa polypeptide and processed just prior to merozoite release from the erythrocytes into smaller fragments. The C- terminal 42 kDa cleavage product of MSP-1 (MSP-1(42)) is present on the surface of merozoites and a major candidate for blood stage malaria vaccine. In the present study, we have biochemically and immunologically characterized the soluble and refolded 42 kDa fragment of MSP-1 of P. vivax (PvMSP-1(42)) and P. cynomolgi B (PcMSP-1(42)). SDS-PAGE analysis showed that both soluble and refolded E. coli expressed P. vivax and P. cynomolgi B MSP-1(42) proteins were homogenous in nature. The soluble and refolded MSP-1(42) antigens of both parasites showed high reactivity with protective monkey sera and conformation-specific monoclonal antibodies against P. cynomolgi B and P. vivax MSP-1(42) antigens. Immunization of BALB/c mice with these antigens resulted in the production of high titres of cross-reactive antibodies primarily against the conformational epitopes of MSP-1(42) protein. The immune sera from rhesus monkeys. immunized with soluble and refolded MSP-1(42) antigens of both parasites also showed high titered cross-reactive antibodies against MSP-1(42) conformational epitopes. These results suggested that the soluble and refolded forms of E. coli expressed P. vivax MSP-1(42) antigens were highly immunogenic and thus a viable candidate for vaccine studies.     

Plasmodium falciparum antigens synthesized by schizonts and stabilized at the merozoite surface by antibodies when schizonts mature in the presence of growth inhibitory immune serum

Some immune sera that inhibit erythrocyte invasion by merozoites also agglutinate the merozoites as they emerge from rupturing schizonts. These immune clusters of merozoites (ICM) possess a surface coat that is cross-linked by antibody and is thicker than the surface coat associated with normal merozoites (NM) obtained from cultures containing preimmune serum. Analysis of metabolically labeled ICM and NM performed by using sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed that washed ICM possessed immune complexes containing antigens representative of schizonts and merozoites. Characteristics of the immune complexes included: a) they were not soluble in pH 8 Triton X-100, b) they were soluble at an acid pH, and c) after pH neutralization they were precipitated by using staphylococcal protein A. Merozoite antigens having Mr of 83, 73, and 45 kDa were associated with immune complexes in ICM. The 83 and 73 kDa antigens were recovered in considerably larger quantities from ICM than from NM. Schizont antigens having Mr of 230, 173 (triplet), 152 (doublet), and 31 kDa were associated with immune complexes in ICM, and a 195 kDa antigen(s) from schizonts and merozoites was also present in the immune complexes. In addition, other antigens of Mr 113, 101, 65, and 51 kDa may have been immune complexed. These 15 antigens accounted for less than 30% of the schizont and merozoite antigens recognized by the immune serum. Immune complexes probably formed between antibodies and a) surface antigens of schizont-infected erythrocytes exposed to antibody before schizont rupture, b) surface antigens of merozoites and schizonts exposed during schizont rupture, and c) soluble antigens normally released during schizont rupture. The antibody components of the immune complexes may have prevented rapid degradation or shedding of some antigens from the merozoite surface. Allowing schizonts to rupture in the presence of inhibitory antibodies (to form ICM) is a useful approach to identifying exposed targets of protective immunity against malaria.     

Plasmodium falciparum antigens synthesized by schizonts and stabilized at the merozoite surface when schizonts mature in the presence of protease inhibitors

Schizonts of Plasmodium falciparum were cultured in medium containing a mixture of 10 micrograms/ml each of leupeptin, chymostatin, pepstatin, and antipain. The protease inhibitors did not inhibit macromolecular synthesis but were associated with decreased reinvasion of red cells and the accumulation of well preserved merozoites clustered around pigment granules (PCM, protease inhibitor clusters of merozoites). The parasite pellet from PCM cultures contained increased amounts of merozoite antigens, particularly at Mr 83, 73, 66, 45, and 17 kDa. The increases of the Mr 83, 73, and 45 kDa surface antigens observed in PCM had been observed also in similar merozoite clusters obtained by culturing schizonts in the presence of inhibitory antibodies. These three antigens are processed products of the abundant Mr 195 kDa schizont surface antigen. Liquid-phase double immunofluorescence of PCM demonstrated a residual red cell membrane through which monoclonal antibodies passed and reacted with the Mr 83, 73, and 45 kDa merozoite surface antigens or their precursors. The processes associated with normal reinvasion apparently involve protease(s), which plays a role(s) in the breakdown of the red cell membrane and the shedding of merozoite surface antigens. Interference with these processes by protease inhibitors is useful in increasing recoveries of merozoite antigens, as well as in elucidating mechanisms of reinvasion.     

Identification and the role of soluble antigens detected in bile from Eimeria stiedai-infected rabbits

Antibodies against Eimeria stiedai sporozoites and merozoites were detected in the sera of rabbits immunized with bile obtained from infected rabbits on the 15th day post-infection. The trails made by gliding sporozoites were also detected by the sera. After penetration into the host cell, an antibody-binding region was observed on the parasitophorous vacuole membranes of the parasites. Rabbits administered a combination of the bile and cholera toxin shed fewer oocysts in the feces after infection than control rabbits. The immunized rabbits developed a high level of IgA antibody against soluble antigens in the bile. By immunoblotting, antigens with molecular masses of 32, 37, and 49 kDa were detected in the bile obtained from infected rabbits on the 15th day postinfection. Absorption treatment with sporozoites reduced or abolished the antibody reactivity to the 32-kDa antigen of merozoites and the bile antigens. However, antibody reactivity to the 37- and 49-kDa antigens still remained. These results indicate that soluble antigens are present in the bile of rabbits in the acute phase of infection, and these may be produced and released by merozoites during the host cell invasion process.     

Screening of murine monoclonal antibodies against living schistosomula of Schistosoma mansoni by radioimmunoassay

A radioimmunoassay was developed to screen supernatants of murine monoclonal antibodies against surface antigens of living schistosomula of Schistosoma mansoni. Of 196 clones screened, 10% bound schistosomula. Of these, 74% bound only schistosomula. The remaining molecules also reacted with soluble adult worm antigens and soluble egg antigens as determined by enzyme-linked immunosorbent assay. Immunoblot analysis demonstrated that monoclonal antibody 204-3E4 reacted with a 68 kDa protein, a glycoprotein that induces substantial resistance against S. mansoni infection. Recognition of an 18 kDa antigen by 204-3F1 antibody was stage-specific with the antigen being expressed in cercariae, 3- and 24-h-old parasites but not 4-day, lung stage or adult worms. Monoclonal antibody 204-4E3 reacted with purified S. mansoni paramyosin. These data indicate that radioimmunoassay using living schistosomula is a rapid alternative method to identify murine hybridomas that secrete antibodies which react with surface antigens of S. mansoni.     

Protective antigens of bloodstage Plasmodium knowlesi parasites

The simian malaria Plasmodium knowlesi provides many favourable features as an experimental model; it can be grown in vivo or in vitro. Parasites of defined variant specificity and stage of development are readily obtained and both the natural host and a highly susceptible host are available for experimental infection and vaccination trials. Proteins synthesized by erythrocytic P. knowlesi parasites are characteristic of the developmental stage, as are the alterations that the parasite induces in the red cell surface. Erythrocytic merozoites are anatomically and biochemically complex, their surface alone is covered by at least eight distinct polypeptides. Immune serum from merozoite-immunized rhesus recognizes many parasite components, especially those synthesized by schizonts. All of the merozoite surface components and some of the schizont-infected red cell surface antigens are recognized by such immune sera. Rhesus monkeys rendered immune by repeated infection may by contrast recognize comparatively few antigens; a positive correlation was established for these 'naturally' immunized monkeys between protection and antibody directed against a 74 000 molecular mass antigen. Immunization with this purified antigen confers partial protection. Other putative protective antigens have been identified by monoclonal antibodies that inhibit merozoite invasion of red cells in vitro. The antigens recognized by inhibitory monoclonal antibodies are synthesized exclusively by schizonts and are processed, at the time of schizont rupture and merozoite release, to smaller molecules that are present on the merozoite surface. The multiplicity of protective antigens is clearly demonstrated by the fact that seven distinct merozoite surface antigens are recognized by three different inhibitory monoclonals. None of the protective antigens identified are variant or strain specific.     

Identification of antigens of Sarcocystis cruzi sporozoites, merozoites, and bradyzoites with monoclonal antibodies

Sporozoites and culture-derived merozoites of Sarcocystis cruzi were used to elicit monoclonal antibodies (MAb's) in mice. Some of these antibodies reacted with the surface of live sporozoites and merozoites as determined by immunofluorescence. An array of similar antigens was identified in Western blots of sporozoites by both anti-merozoite MAb's and an anti-sporozoite MAb. At least 1 antigen in blots of bradyzoites was identified by anti-merozoite MAb's and a cluster of antigens was identified by an anti-sporozoite antibody. These results indicate that several surface epitopes of sporozoites and merozoites are shared with molecules of bradyzoites and that antigen patterns of molecules bearing these epitopes in 3 stages of Sarcocystis may be either distinct or similar.     

Characterization of cross-reactive blood-stage antigens of the Plasmodium cynomolgi complex using anti-Plasmodium vivax monoclonal antibodies

Five out of 18 monoclonal antibodies (moAB's) produced against blood stages of a Brazilian (Belem) strain of Plasmodium vivax were shown to cross-react with all of the 11 strains of the P. cynomolgi complex that were assayed. The 5 moAB's produced 3 different patterns of immunofluorescence, identical for both P. vivax and P. cynomolgi. Three of these moAB's appeared to react with antigens associated with the cytoplasm or membranes of infected erythrocytes. By Western blot analysis, 2 of these 3 moAB's identified an antigen with an apparent molecular weight of 31 kDa in extracts of parasitized erythrocytes of both species; the third of these moAB's reacted with an antigen with an apparent molecular weight of 95 kDa. By immunofluorescence, the 2 other moAB's reacted only with parasites at all developmental stages. The target antigen of these 2 moAB's was not identified. Immunoradiometric assays indicated that the moAB's are directed against 3 or possibly 4 distinct nonrepetitive epitopes. None of the moAB's inhibited merozoite invasion or growth of the parasites in an in vitro culture system of the Berok strain of P. cynomolgi.     

A circumsporozoite-like protein is present in micronemes of mature blood stages of malaria parasites

We demonstrate for the first time the presence of a circumsporozoite (CS)-like protein in invasive blood stages of malaria parasites. Immunogold electron microscopy using antisporozoite monoclonal antibodies localized these antigens in the micronemes of merozoites. Western immunoblot and two-dimensional gel electrophoresis of mature blood stage extracts of Plasmodium falciparum, P. berghei, P. cynomolgi, and P. brasilianum identified polypeptides having the same apparent molecular mass and isoelectric points as the corresponding sporozoite (CS) proteins. The CS-like protein of merozoites is present in relatively minor amounts, compared to the CS protein of sporozoites. Mice with long-term P. berghei blood-induced infections develop antibodies which react with sporozoites.     

Monoclonal Antibodies Identify a Subset of Dense Granules in Cryptosporidium parvum Zoites and Gamonts

ABSTRACT. Two monoclonal antibodies raised against purified oocysts and excysted sporozoites of Cryptosporidium parvum identified antigens located in the anterior half of sporozoites by indirect immunofluorescence microscopic assay. The monoclonal antibodies also reacted with Triton X-100-insoluble antigens of asexual and sexual stage parasites developing in epithelial cells in vitro and identified a 110 kilodalton antigen on immunoblots of sodium dodecyl sulfate-extracted oocysts. Immunoblotting reactivity was abolished by prior treatment of blotted antigen with periodic acid suggesting that the monoclonal antibodies recognize a carbohydrate or carbohydrate-dependent epitope(s). By immunoelectron microscopy, the antibodies reacted with a family of small, electron-dense granules located predominantly in the central region of merozoites and also with a population of cytoplasmic inclusions in macrogamonts. In addition, the monoclonal antibodies prominently labeled the parasitophorous vacuole membrane of all intracellular stages examined suggesting that the corresponding antigen(s) may be exocytosed from the granules to become associated with Triton X-100-insoluble components of the vacuolar membrane or cytoskeleton.     

The Morphology and Behavior of Living Exoerythrocytic Stages of Plasmodium gallinaceum and P. fallax and Their Host Cells

The morphology and behavior of living exoerythrocytic stages of Plasmodium gallinaceum and P. fallax were studied by the use of tissue cultures, phase contrast microscopy, and time-lapse cinephotomicrography. The morphology of exoerythrocytic stages of these two species was essentially that previously observed in fixed, stained material, with the following exceptions: (1) the presence of a filament on one end of the merozoite, (2) the absence of clefts in the cytoplasm of the large schizonts, and (3) the absence of a vacuole-like space around the parasite. The following behavior was observed either directly or in time-lapse sequences: (1) emergence of merozoites from mature schizonts, (2) progressive motility of free merozoites, (3) entry of merozoites, both actively and passively, into host cells, (4) nuclear division in the parasite, (5) the various stages of schizogony, including final production of merozoites, (6) massive infection of host cells, and (7) phagocytosis of merozoites and attempted phagocytosis of mature schizonts by macrophages. Exoerythrocytic stages of P. fallax differed from those of P. gallinaceum in that the merozoites of the former were (1) somewhat more curved in shape and (2) present in fewer numbers in mature schizonts. The use of tissue culture, phase contrast microscopy, and time-lapse cinephotomicrography promises to solve many of the remaining problems concerning exoerythrocytic stages of malarial parasites and their interrelationships with host cells.     

Monoclonal antibody immunocytochemistry: novel method extending usefulness of monoclonal antibodies for antigen visualization

We describe a novel procedure combining the multiple-site reactivity of polyclonal antibodies with the defined single epitope-specificity of monoclonal antibodies. The method is based on previous findings that IgG molecules often only react with tissue-bound antigens with one of their two antigen-combining sites; thus, the remaining site is free to bind subsequently added antigen. In the procedure devised, such (undenatured) antigen is subsequently detected by a specific monoclonal antibody and the reaction is finally revealed by immunogold-silver staining. Antibody subpopulations to contaminating antigens may well be present in the polyclonal antiserum and may well bind first to tissue and then to the corresponding contaminants in the crude antigen preparation applied as second layer. Such contaminants will, however, not react with the monoclonal antibody and will therefore not be immunocytochemically detected. The method has been evaluated with one antigen which cannot be detected by monoclonal antibodies in paraffin sections (glial fibrillar acidic protein) and with another antigen (human chorionic gonadotropin) which can only be detected by the monoclonal antibody when occurring in high concentrations. In both cases the procedure resulted in strong specific staining of the antigens with no background.     

FINE STRUCTURE OF THE ASEXUAL STAGES OF PLASMODIUM ELONGATUM

Plasmodium elongatum, an avian malarial parasite, differs from other such parasites by infecting both the circulating red blood cells and the hematopoietic cells. The exoerythrocytic development of P. elongatum occurs mainly in these red cell precursors. The fine structure of the asexual stages of P. elongatum has been studied in the bone marrow and peripheral blood of canaries and compared with that of the asexual stages of other avian malarial parasites. With minor differences, the merozoites of P. elongatum possess the same organelles as those in the exoerythrocytic merozoites of P. fallax and the erythrocytic stages of P. cathemerium, P. lophurae, P. fallax, and P. gallinaceum. The developmental sequence is also essentially similar to that of other avian malarial parasites, in that upon entry into a new host cell, the dedifferentiation, growth, and redifferentiation phases take place. However, we have found some important differences in the feeding mechanism of P. elongatum. The cytostome is involved in the ingestion of host cell cytoplasm in both exoerythrocytic and erythrocytic stages, in contrast to P. fallax, in which the cytostome is inactive in the exoerythrocytic stages. In P. elongatum, host cell cytoplasm is ingested through the cytostome, and "boluses" are formed and incorporated into a large digestive vacuole. Subsequently, the digestion of the boluses takes place in this digestive vacuole. Thus, in regard to the function of the cytostome, the exoerythrocytic stages of P. elongatum appear to be closely related to the erythrocytic stage which has a feeding mechanism similar to that of the erythrocytic stage of other avian malarial parasites.     

Antibodies define multiple proteins with epitopes exposed on the surface of live Babesia bigemina merozoites

Babesia bigemina is one of several tick-borne hemoparasitic diseases of cattle that are inadequately controlled and cause substantial livestock production losses in tropical and subtropical climates. Recovery from acute babesiosis is associated with development of protective immunity against subsequent challenge with both homologous and heterologous parasites. Viable and infectious merozoites, the intraerythrocytic stage of B. bigemina responsible for clinical disease, were separated from contaminating host cells by density gradient centrifugation. Monoclonal antibodies developed against gradient-separated merozoites were screened for surface reactivity against live merozoites in an immunofluorescent binding assay. Surface-reactive antibodies immunoprecipitated five major biosynthetically radiolabeled merozoite proteins with relative m.w. of 72,000, 58,000, 55,000, 45,000, and 36,000 in SDS-PAGE. Two additional proteins immunoprecipitated with the 45,000 m.w. protein were unreactive with monoclonal antibody in western blots and are apparently part of a membrane complex co-precipitated by this antibody. In contrast, additional proteins of m.w. of 36,000, 35,000, and 33,000, immunoprecipitated with the 58,000 protein, all contain the surface-exposed epitope bound by monoclonal antibody. Immune serum from an animal that had recovered from infection with a Mexico isolate of B. bigemina immunoprecipitated five radiolabeled proteins from the Mexico isolate that co-migrated in SDS-PAGE with major proteins precipitated by surface-reactive monoclonal antibodies. In addition, antibodies against a Kenya isolate of B. bigemina immunoprecipitated the same co-migrating proteins from radio-labeled Mexico isolate, demonstrating epitope conservation between surface proteins of geographically different isolates. The identification of proteins with epitopes exposed on the surface of live merozoites and accessible to antibody provides candidates to be tested as protective immunogens in cattle.     

Induction of specific immune responses against the Plasmodium vivax liver-stage via in vitro activation by dendritic cells

Due to chronic morbidity, the risk of increasing drug resistance and the existence of the hypnozoite stage in Plasmodium vivax malaria, there is a need to find out how hosts develop immunity to compromise the malaria parasites. Here we focused on an in vitro model for immunotherapy and vaccine development. Immunosuppressive mechanisms in malaria include inhibition of T cell response and suppression of dendritic cell function. Using in vitro activation of lymphocytes by malaria antigen-pulsed dendritic cells could overcome the limitation of antigen presentation during acute infections. Here we showed that the sporozoite-pulsed dendritic cell could elicit cytotoxicity against liver stage of P. vivax. Analysis using immunophenotypic markers showed maturation of the dendritic cells and stimulation of cytotoxic T cells. Functional assay of the in vitro-activated cytotoxic T cells showed enhancement of specific killing of the P. vivax exoerythrocytic stages within infected hepatocytes. This model may be useful for vaccine development against human malaria.     

In vitro development of exoerythrocytic forms of Plasmodium gallinaceum sporozoites in avian macrophages

Exoerythrocytic forms of Plasmodium gallinaceum were cultured in vitro using salivary gland sporozoites extracted from experimentally infected Aedes fluviatilis mosquitoes. The host cells were macrophage precursors from chicken bone marrow. At various times after introduction of sporozoites, the cultures were stained by Giemsa or by immunofluorescence assay (IFA) using anti-sporozoite-specific monoclonal antibodies (MAb). The time to complete parasite development in vitro was 50-70 h. By 70 h, ruptured segmenters and free merozoites were visible within the cells. Inoculation of normal chickens with infected cultures induced parasitemia after a pre-patent period of 10-11 days. In vitro young exoerythrocytic forms, late schizonts that include the matured segmenters, and free merozoites shared common antigens with the sporozoites as revealed by IFA using anti-sporozoite-specific MAbs. Our data indicate that macrophages support development of P. gallinaceum sporozoites and that the circumsporozoite proteins are present until the end of the primary exoerythrocytic schizogony.     

Echinostoma caproni in mice: ultrastructural studies on the formation of immune complexes on the surface of an intestinal trematode

The binding of mouse antibodies to the surface antigens of juvenile and 7 and 28 day old Echinostoma caproni was examined by transmission electron microscopy of thin sections of parasites, which were treated with antibodies in a double sandwich technique with ferritin-conjugated antibody. The surface of freshly recovered mature adult parasites was covered with an irregular but often rather intensive mouse antibody containing matrix, which probably represents a layer of mouse antibody/parasite antigen complexes. The complexes were lost after in vitro culturing of the parasites for 24 h, but incubation of the in vitro-maintained antibody-negative adult parasites with immune mouse serum led to reformation of a similar but less intensive cover with immune complexes. Juvenile and young stages of E. caproni, which had never been exposed to host antibodies, obtained a layer of immune complexes on their surface after incubation with immune mouse serum in vitro. In both young and mature parasites, the antibody-antigen complexes were observed to be rather loosely attached to the outer surface of the parasites, where the antigens probably constitute a part of the irregular glycocalyx of the organisms. It may also be that the antigens are present as isolated excretion along the surface of the parasites. Several sections indicated that the parasite surface antigens may be present in the tegument in vesicles which fuse with the outer membrane of the parasite whereby their contents are released to the exterior.