Schistosoma mansoni: topochemical features of cercariae, schistosomula, and adults

The teguments of developing and mature cercariae, recently transformed, and 1-wk-old schistosomula and adult worms were examined for the ultrastructural location of macromolecular carbohydrates and polyelectrolytes. The surface of mature cercariae within sporocysts and cercariae released from the snail is covered by a filamentous coat which reacts with cytochemical reagents for the demonstration of vicinal glycols, but neither the coat nor the surface of the tegument plasmalemma binds cationic colloidal iron at low pH.Upon penetrating mammalian skin, the cercaria sheds its surface coat; the tegument surface of newly transformed schistosomula, older schistosomula and adult worms stains en bloc with acidic colloidal iron, as does the tegument plasmalemma of mature cercariae if the overlying filamentous coat is first removed by physicochemical means. The cercarial coat thus serves to mask anionic groups at the surface of the tegument plasmalemma which become functionally exposed after penetration of the mammalian host. The distribution of colloidal iron binding sites coincides with those for the carbohydrate-complexing phytohemmagglutnin, concanavalin A, which suggests that these membrane-fixed anions are acid mucopolysaccharides, glycoproteins or glycolipids. Carbohydrate-containing material was also localized within membrane-bound vesicles of the tegument matrix and perikarya of developing cercariae and postcercarial schistosomes, suggesting that surface mucosubstances contributing to the tegument glycocalyx of these worms are elaborated, at least in part, by the tegument itself.     

The cercarial glycocalyx of Schistosoma mansoni

Cercariae, the freshwater stage of Schistosoma mansoni infectious to man, are covered by a single unit membrane and an immunogenic glycocalyx. When cercariae penetrate the host skin, they transform to schistosomula by shedding tails, secreting mucous and enzymes, and forming microvilli over their surface. Here the loss of the glycocalyx from cercariae transforming in vitro was studied morphologically and biochemically. By scanning electron microscopy, the glycocalyx was a dense mesh composed of 15-30 nm fibrils that obscured spines on the cercarial surface. The glycocalyx was absent on organisms fixed without osmium and was partially lost when parasites aggregated in their own secretions before fixation. By transmission electron microscopy, a 1-2 microns thick mesh of 8-15-nm fibrils was seen on parasites incubated with anti-schistosomal antibodies or fixed in aldehydes containing tannic acid or ruthenium red. Cercariae transformed to schistosomula when tails were removed mechanically and parasites were incubated in saline. Within 5 min of transformation, organisms synchronously formed microvilli which elongated to 3-5 microns by 20 min and then were shed. However, considerable fibrillar material remained adherent to the double unit membrane surface of schistosomula. For biochemical labeling, parasites were treated with eserine sulfate, which blocked cercarial swimming, secretion, infectivity, and transformation to schistosomula. Material labeled by periodate oxidation and NaB3H4 was on the surface as shown by autoradiography and had an apparent molecular weight of greater than 10(6) by chromatography. Periodate-NaB3H4 glycocalyx had an isoelectric point of 5.0 +/- 0.4 and was precipitable with anti-schistosomal antibodies. More than 60% of the radiolabeled glycocalyx was released into the medium by transforming parasites in 3 h and was recovered as high molecular weight material. Parasites labeled with periodate and fluorescein-thiosemicarbazide and then transformed had a corona of fluorescence containing microvilli, much of which was shed onto the slide. Material on cercariae labeled by lodogen-catalyzed iodination was also of high molecular weight and was antigenic. In conclusion, the cercarial glycocalyx appears to be composed of acidic high molecular weight fibrils which are antigenic and incompletely cleared during transformation.     

Schistosoma mansoni: increasing saline concentration signals cercariae to transform to schistosomula

Cercariae of S. mansoni shed the surface glycocalyx, form a double lipid bilayer on their surface, and transform to schistosomula when tails are removed and parasites are transferred from pond water to 300 mOsm phosphate-buffered saline. To determine whether the absolute concentration of saline or the relative change in saline concentration was the signal for surface transformation, cercariae were isolated from the snail hepatopancreas, sheared to remove the tails, and incubated in defined media for 3 hr at 37 degrees C. Surface transformation was assayed using the binding of the fluorescein-conjugated lectin concanavalin A to the schistosomular double unit membrane but not to the cercarial glycocalyx. An increase in salinity either from 18 mOsm (artificial pond water) to 120 mOsm (the snail osmolarity) or from 120 to 300 mOsm (the mammalian osmolarity) triggered transformation to schistosomula. Organisms constantly exposed to 120 mOsm or shifted from 120 mOsm to pond water did not transform their surfaces. The signal for transformation appeared to be increasing salinity rather than increasing osmolarity because cercarial bodies did not become schistosomula in 300 mOsm mannitol. Surface transformation was inhibited when cercariae were incubated with the acetylcholinesterase inhibitor eserine sulfate during a 10 min time when the osmolarity was raised. We conclude that increasing salinity rather than the absolute saline concentration is the signal for surface transformation and that eserine sulfate may inhibit the receipt of this signal.     

The cercarial tail in Proterometra macrostoma (Digenea: Azygiidae): permeability and fine structure of the tegument

Permeability of the cercarial tail in Proterometra macrostoma was examined in vitro with 1 mM 3H-glucose, which tails absorb by diffusion alone. Naturally emerged cercariae (bodies withdrawn into tails) were permeable, but they rapidly (3 min) equilibrated with glucose in the bathing medium and maintained steady state for 4 hr. Metabolism of absorbed glucose was not detectable until after 90 min, and radioactivity in bodies dissected from tails after 4 hr was negligible. On the basis of cercarial water content (90% of total weight) and absorbed isotope at steady state, the calculated volume of the equilibrating compartment was 4% of an intact cercaria. This value correlated well with that of the tegument (3-5%), which was 1-2 microm thick as seen by transmission electron microscopy. A continuous, electron-dense basal membrane/lamina separated the tegument from subtegument. We conclude that the glycocalyx and external plasma membrane are freely permeable, whereas the basal membrane is the barrier that effectively isolated the subtegument from exogenous glucose. The basal membrane also may be the primary structure that protects the subtegument and cercarial body from effects of osmotic stress.     

Schistosoma mansoni and Biomphalaria glabrata have some common epitopes. I. Common epitopes are present on the surface of early stages of S. mansoni.

1. The presence of snail and glycocalyx antigens in the Schistosoma mansoni cercarial surface and their permanence throughout development in vitro and in vivo was investigated. 2. Rabbit antisera raised against two fractions of glycocalyx released from cercariae and Biomphalaria glabrata soft tissues or haemolymph were obtained. 3. All four antisera bound to cercariae and schistosomula kept in vitro or in vivo for up to 24 hr. 4. No binding to schistosomula kept in vivo for 5 days or longer was observed. 5. Schistosomula cultured in vitro for up to 12 days bound the antisera throughout the period of culture.     

Intermediate host antigens associated with the cercariae of Schistosoma haematobium.

Bulinus (Physopsis) africanus antigens were shown to be associated with the cercarial glycocalyx of Schistosoma haematobium using immunofluorescence and the Cercarienhüllen Reaktion. It is proposed that this snail antigen may sensitise the definitive host and that resistance to further invasion by cercariae could be induced in this manner.     

Evidence that a protective membrane epitope is involved in early but not late phase immunity in Schistosoma mansoni

An anti-egg monoclonal antibody E.1, which is partially protective in passive transfer experiments, is shown in this study to recognize a membrane epitope on cercariae, schistosomula, and the ciliary plates of miracidia. E.1 did not bind to the surface membranes of lung or adult worms, or recognize secreted egg antigen in infected liver tissue. The E.1 epitope was present in the glycocalyx of cercariae, as well as on the syncytial membrane as determined by electron microscopy. Immunoprecipitation of iodinated surfaces of cercariae and schistosomula demonstrated E.1 binding to a high m.w. moiety in cercariae, which corresponds to the glycocalyx because it was not immunoprecipitated from schistosomula. In addition, a band at 38,000 daltons was immunoprecipitated from both cercariae and schistosomula. When compared with in vitro cultured parasites, schistosomula that were obtained from mice 1 to 24 hr after tail vein injection showed significant loss of E.1 binding. Consistent with the rapid loss of antigen in vivo, E.1 antibody was unable to passively transfer protection to naive mice when administered 5 days after cercarial challenge.     

Ultrastructure, carbohydrate, and amino acid analysis of two preparations of the cercarial glycocalyx of Schistosoma mansoni

This study determined the amino acid and carbohydrate composition of 2 cercarial glycocalyx preparations obtained after phenol-water extraction and subsequent gel chromatography. Labeled cercariae were subjected to 85% phenol, thereby dissociating the glycocalyx into the aqueous phase, which was dialyzed and chromatographed on Sepharose CL-2B or -4B in either 4 M guanidine hydrochloride (GuHCl) or 0.1% sodium dodecyl sulfate (SDS). The label eluted primarily in the void volume and was antigenic as tested with rabbit polyclonal antibodies by immunoblotting. Approximately 6 micrograms of protein and 28 micrograms of carbohydrate were obtained from 10(5) cercariae in the antigenic void volume fraction after SDS chromatography. Threonine, serine, and glutamic acid comprised 44% of the amino acid residues of the protein. The predominant sugar was fucose. Galactosamine, glucosamine, galactose, and mannose were also detected. After GuHCl chromatography, free amino acids, predominantly glycine and serine, comprised 17% of the total protein. The carbohydrate composition was similar to that of SDS-chromatographed extracts. Phenol-water extracts eluting in the void volume of Sepharose CL-2B were compared by negative staining and scanning electron microscopy with material obtained from medium in which cercariae shed glycocalyx during transformation to schistosomula. Both the isolated material and the transformation medium contained particles 20-50 nm in diameter, with subunits of 15-20 nm. These studies show that the cercarial glycocalyx is particulate, contains mainly carbohydrate and some protein, and is solubilized by phenol-water extraction.     

Morpho-functional specialization of the branching sporocyst of Prosorhynchoides borealis Bartoli, Gibson & Bray, 2006 (Digenea, Bucephalidae)

Sporocysts of Prosorhynchoides borealis were obtained from the marine bivalves Abra prismatica and studied using transmission electron microscopy. The sporocyst body consists of a mass of branching and intertwining hollow tubules that ramify through the host's digestive gland and gonads. This study investigated the ultrastructure of the sporocyst branches which comprise alternate distended areas (brood chambers) with a relatively thin body wall, narrower portions with a thicker body wall (constricted areas) and terminal regions. Pronounced differences between these areas were revealed in the structure of their tegument and body cavity lining, as well as in the cellular composition of the subtegumental layers. Body wall composition in distended areas was consistent with the specialization for cercarial nurture in the brood chambers. The structure of the constrictions suggested a dual role of nutrient absorption and physical separation of adjacent brood chambers. Two types of terminal region were identified, one specialized for the investigation and penetration of host tissues and the other, in which the germinal cells are formed, for cercarial production. The overall structure of the sporocyst branches helps explain why this linear modular system, i.e. brood chambers and constrictions continuously growing into the host tissue, enables the sporocyst's long-term existence and can continuously produce cercariae in numbers comparable with those produced by rediae and/or daughter sporocyst infrapopulations in other digeneans. The origin of the nuclei in the outer tegumental layer of some branching bucephalid sporocysts is also discussed.     

Effects of alterations in the heartbeat rate and locomotor activity of Schistosoma mansoni-infected Biomphalaria glabrata on cercarial emergence

During a 27-hr period of food deprivation, Biomphalaria glabrata infected with Schistosoma mansoni had lower heartbeat rates and locomotor activities than did controls that were feeding ad lib. However, there was no difference between the cercarial emergence from control and experimental snails either before, during, or after the period of food deprivation. No correlation was found between the locomotor activity of the snail and the number of cercariae emerging from the snail in continuous light. Our results indicated that the emergence of S. mansoni cercariae from B. glabrata was not affected by the heartbeat rate or locomotor activity of the snail. The factors controlling the rhythm of S. mansoni cercarial emergence from B. glabrata may be independent of the snail.     

Schistosoma mansoni: ultrastructural demonstration of a miracidial glycocalyx that cross-reacts with antibodies raised against the cercarial glycocalyx

Cercariae are covered by a glycocalyx that is highly antigenic. Here, we have examined the surface of miracidia for a similar structure. The miracidia are covered by epithelial plates and syncytial ridges. By transmission electron microscopy, the plates and ridges were covered by a 0.5-micron-thick glycocalyx composed of a mesh of 9- to 10-nm fibrils that were stained by ruthenium red delivered in the aldehydes or ferrocyanide-reduced osmium tetroxide. Rabbit antibodies prepared against phenol extracted and chromatographed cercarial glycocalyx were detected by immunoelectron microscopy with secondary antibodies conjugated to horseradish peroxidase. Reaction product bound to both the miracidial and cercarial glycocalyx. In addition, the outer leaflets of the cercarial tegumental membrane and membranes of the miracidial surface structures, including plates, ridges, terebratorium, and sensory papillae, had reaction product. Controls incubated with nonspecific rabbit serum had no reaction product. By indirect immunofluorescence, antibodies against the cercarial glycocalyx stained both plates and ridges. As the miracidia transformed to sporocysts, the glycocalyx remained associated with the plates as they were sloughed. These studies demonstrate that miracidia possess a glycocalyx similar in structure and antigenicity to the cercarial glycocalyx.     

Ultrastructure of the daughter sporocyst and developing cercaria of Schistosoma japonicum in experimentally infected snails, Oncomelania hupensis hupensis

Ultrastructure of daughter sporocysts and cercariae of Schistosoma japonicum were studied 2 and 4 months after infection of Oncomelania hupensis hupensis. The body walls of daughter sporocysts are similar at all infectious stages. They consist of an external syncytial tegument on a basement membrane, and an internal cellular subtegument surrounding a body cavity containing developing cercariae. The cercariae embryos develop 2 months after infection from germinal balls in the brood chamber of the daughter sporocyst. They are at first enveloped by a primitive epithelium rising from the daughter sporocyst. Four months after infection, the cercariae were almost fully developed and the primitive epithelium had degenerated. The body wall of the cercaria consists of a thin tegument covered by a surface coat of fibrous material and connected to the subtegumental cells by cytoplasmic processes. The matrix of the tegument contains numerous dense bodies, vacuoles, and spines. Two types of sensory structures - uniciliated and multiciliated - are found at the anterior tip of the cercaria. There are five pairs of penetration gland cells of two distinct types differentiated by the morphology of secretory granules. Flame cells are found in both daughter sporocysts and in cercariae. The cilia of the flame cells are characterized by the typical 9 and 2 cilium pattern.     

Schistosoma mansoni: a comparative study of artificially transformed schistosomula and schistosomula recovered after cercarial penetration of isolated skin.

A comparison was made of the ultrastructure, development and antigenic nature of the surfaces and of the viability of three types of Schistosoma mansoni: schistosomula formed after cercariae had penetrated isolated skin (SS) schistosomula produced after mechanical separation of cercarial tails from bodies (MS), and schistosomula transformed from cercariae after incubation in fresh rat serum (RS). Within 2h of transformation, the surface membranes of all three types of schistosomula had changed from trilaminate to heptalaminate structures and SS and MS had lost their cercarial glycocalyx. Initially a dense amorphous material was demonstrated on the surfaces of RS, which was thought to be the result of an interaction between a factor in rat serum and the glycocalyx; this material was greatly reduced within 2 h of transformation. The pre-acetabular glands of SS were emptied while those of MS and RS retained their contents. Immunofluorescent studies showed that all schistosomula bound serum from mice immune to S. mansoni, but the binding was stronger with MS and RS. The mixed agglutination reaction demonstrated the presence of human A and B blood group-like antigenic determinants on approximately 30% of 3h old SS; these determinants were not detected on MS or RS. In vitro, the development of MS and RS was similar to SS; the first schistosomula reached the "gut-closed" stage by day 10; 50-70% of SS reached this stage by day 12, in contrast to only 25-50% of MS and RS. Between 28 and 45% of all schistosomula developed to maturity when injected intravenously into mice. It was concluded that the two types of artificially prepared schistosomula fulfil the main criteria of transformation from cercaria to schistosomulum. Further, it is suggested that MS are the most appropriate source of material for immunochemical and physiological studies.     

<Emphasis Type="Italic">Trichobilharzia regenti</Emphasis>: Antigenic structures of intravertebrate stages

Like several other bird schistosomes, neurotropic schistosome of Trichobilharzia regenti can invade also mammals, including humans. Repeated infections cause cercarial dermatitis, a skin inflammatory reaction leading to parasite elimination in non-specific mammalian hosts. However, in experimentally primo-infected mice, the worms escape from the skin and migrate to the central nervous system. In order to evade host immune reactions, schistosomes undergo cercaria/schistosomulum transformation accompanied with changes of surface antigens. The present study is focused on localization of the main antigens of T. regenti; cercariae, schistosomula developed under different conditions and adults were compared. Antigens were localized by immunofluorescence and ultrastructural immunocytochemistry using sera of mice repeatedly infected with T. regenti. Detected antibody targets were located in glycocalyx and penetration glands of cercariae and in tegument of cercariae, schistosomula and adults. Shedding of cercarial glycocalyx significantly reduced surface reactivity; further decrease was reported during ongoing development of schistosomula. Spherical bodies, probably transported from subtegumental cell bodies to worm surface, were identified as the most reactive tegumental structures. Based on similar results for schistosomula developed in specific, non-specific hosts and in vitro, it seems that the ability of T. regenti to decrease the surface immunoreactivity during ontogenesis is independent on the host type.     

Fasciola hepatica: ultrastructure and histochemistry of the glycocalyx of the tegument.

The morphology and histochemistry of the glycocalyx of the tegument was investigated by electron microscopy. The results showed that both the morphology and histochemistry of the glycocalyx varied depending on the environment immediately prior to fixation and also on postfixation treatments. Conventional electron microscope fixation appeared to preserve only about half the total thickness of the glycocalyx, and only histochemical tests applied en bloc gave a true morphological and histochemical picture. The glycocalyx, therefore, consists of two parts, an inner continuous layer which is tightly bound to the apical plasma membrane and is always preserved, and an outer fibrillar layer, which is not always preserved by conventional fixation. Both layers are anionic and carbohydrate-rich and therefore contain glycoproteins and sialic acids. The surface of Fasciola hepatica, therefore, has morphological and chemical features very like those proposed for the “greater membrane” by Lehninger.     

Oxygen uptake and lactate production by Schistosoma mansoni cercaria, cercarial body and tail, and schistosomule.

1. Oxygen consumption by Schistosoma mansoni cercarial bodies varies, with the batch of organisms, the incubation media and the temperature (27-37 degrees C), from 27.4 +/- 3.4 to 55.0 +/- 4.8 microliters O2/mg larval protein per hr. It is proportional to the concentration of organisms incubated, up to 25,000/ml, as calculated from whole protein. 2. Oxygen uptake by cercariae is inhibited by 5.6 mM glucose in the incubation media, a concentration that stimulates the respiration of cercarial bodies. 3. No significant differences in the oxygen uptake were presented by cercarial bodies with and without glycocalyx or glandular secretions, or devoid of all of them. 4. Inhibitors of the Krebs cycle and the respiratory chain, and uncoupling agents influence the oxygen uptake by cercariae, cercarial bodies and schistosomules to the same extent. 5. The permeability change presented by transformed larvae had no influence on the excretion of lactate by cercarial bodies, which is about 0.3 mumoles/mg protein per hr and remains constant for 5 hr; under nitrogen, this amount increased 70%. Cercariae in anaerobiosis, however, excreted as much as 15 times more lactate than under air. 6. Lactic dehydrogenases of cercariae, cercarial bodies and tails, and schistosomules are of the muscle type and do not change during the transformation.     

Larval development of Fasciola hepatica in experimental infections: variations with populations of Lymnaea truncatula

A retrospective study was undertaken on 70 French populations of Lymnaea truncatula experimentally infected with Fasciola hepatica to determine whether or not susceptibility of snails to infection influenced redial and cercarial production. Results were compared with those obtained from two control populations, known for prevalences higher than 60% when experimentally infected with F. hepatica. In the 70 other populations examined, the prevalences ranged from 2 to 75%. In 55 of these populations, where the prevalence was more than 20%, a high proportion (50.1-56.8%) of snails died after cercarial shedding, whereas in the other groups (non-shedding snails with the most differentiated larvae being free cercariae, rediae containing cercariae, immature rediae, or sporocysts, respectively), snail death was significantly less. In 11 populations, where the prevalence values were 5-19%, only 14% of snails died after cercarial shedding, whereas snails with free cercariae, rediae with cercariae, or immature rediae showed significant increases in snail mortality. In the remaining four snail populations, with prevalences of less than 5%, the most differentiated larval forms were only immature rediae and/or sporocysts. Overall, the number of rediae containing cercariae significantly decreased with decreasing prevalence values. The low prevalence of experimental infection in several populations of snails might be explained by the occurrence of natural infections with miracidia originating from a mammalian host other than cattle, and/or by genetic variability in the susceptibility of snails to infection.     

The life cycle of Cloacitrema michiganensis McIntosh, 1938 (Trematoda: Philophthalmidae)

Experimental infections of Cloacitrema michiganensis were established in chicks by inoculation per cloaca with excysted metacercariae. Ovigerous adults were present 20 days later with eggs containing ocellate miracidia after 21 days. The eggs hatch in utero; the miracidium contains a fully developed redia. Rediae of 2 size groups were present in the digestive gland of the brackish-water snail, Cerithidea californica. Megalurous cercariae are released and encyst on submerged objects. The stages of C. michiganensis resembled those of Parorchis acanthus, a philophthalmid also infecting C. californica, except for differences in the epidermal plate count of their miracidia and in their cercarial stage which was larger in P. acanthus and had a spinuous tegument with a collar of spines.     

An ultrastructural study of alimentary tract development in the cercariae of Prosorhynchoides borealis (Digenea,Bucephalidae)

Podvyaznaya I. 2011. An ultrastructural study of alimentary tract development in the cercariae of Prosorhynchoides borealis (Digenea, Bucephalidae). —Acta Zoologica (Stockholm) 92 : 170–178. The development of digestive system in Prosorhynchoides borealis cercariae was studied using transmission electron microscopy. The foregut and caecum primordia arise in early cercarial embryos as two adjoining cellular cords. The primordial pharynx appears as a cluster of myoblasts in the mid‐part of the foregut primordium whose proximal end abuts onto the ventral embryonic tegument. Later, a lumen develops within the gut primordia and their component cells form the embryonic cellular epithelium with an essentially similar structure in the foregut and caecal regions. Subsequently, the foregut epithelial cells merge to form a syncytium. This process proceeds asynchronously and the most proximal foregut area remains cellular for the longest time. The syncytial lining of the foregut establishes syncytial connections with secretory cytons differentiating in the surrounding parenchyma. These cytons produce secretory granules, which are transported through cytoplasmic connections to the foregut syncytium. Before cercariae reach maturity, their foregut epithelium becomes anucleate and continuous with the external tegument. By the end of cercarial development, numerous short lamellae appear on the luminal surface of the caecal epithelium. The caecal cells become involved in secretory activity as indicated by the presence of Golgi‐derived secretory bodies in their cytoplasm.     

Fasciola hepatica and Schistosoma mansoni: immunofluorescent antigen localization and cross-reactivity

In an attempt to identify the tissue sources of biochemically purified antigenic fractions of Fasciola hepatica and Schistosoma mansoni, antisera were tested against plastic-embedded sections of worms of various ages by an indirect fluorescent-antibody-labeling technique. Antibodies prepared against antigens purified by chromatography of F. hepatica whole worm extract through concanavalin A-Sepharose 4B labeled the parenchyma and tegument of adult F. hepatica strongly while antibodies developed against antigens purified by antibody-affinity chromatography against antibodies of S. mansoni labeled only the parenchyma. Antigens common to these two groups clearly originated from F. hepatica parenchyma. Certain of these common antigens are known to provide significant protection in mice to challenge with S. mansoni cercariae, and in the present study antisera against F. hepatica extracts cross-labeled S. mansoni adult male parenchyma. Reciprocal cross-reactions between antisera against S. mansoni and the parenchyma of adult F. hepatica were also noted. FhFIIb, an extract of F. hepatica which Tailliez described as not cross-reacting with S. mansoni, was found to contain no F. hepatica parenchymal antigens. Antigenic fractions of F. hepatica and S. mansoni collected from the surface of worms after incubation in nonionic detergent were unexpectedly found to contain much parenchymal antigen, suggesting leakage of internal components into the supernatant during preparation. Antisera to F. hepatica developed during a natural infection in rabbits labeled tegumental components and gut strongly but did not react with parenchymal tissue. Antisera against extracts of adult schistosomes labeled the parenchyma of male worms and the glycocalyx of the cercarial tegument, indicating the presence of common antigens in the adult and the cercarial stage. Reciprocal reactions between anticercarial sera and adult sections provided further evidence of shared antigenicity. Antisera against S. mansoni egg antigens strongly labeled sections of eggs in liver tissue and cross-reacted with cercarial glycocalyx, indicating the existence of common antigens between these two stages. The antisera also cross-reacted with what appeared to be non-membrane-bound protein in the tegument of F. hepatica. The soluble egg antigen extract shared antigenicity with the parenchyma of both S. mansoni and F. hepatica but circumoval precipitin had no cross-reactivity with this tissue. Thus S. mansoni eggs contain nondiffusable components sharing antigenic specificity with adult parenchymal tissue.(ABSTRACT TRUNCATED AT 400 WORDS)