Partial and complete detachment of neutrophils and eosinophils from schistosomula: evidence for the establishment of continuity between a fused and normal parasite membrane

Neutrophils and eosinophils adhering to the surface of schistosomula of Schistosoma mansoni have been partially or completely detached with hypertonic sucrose or by pipetting. The sucrose-treated neutrophils are attached only in areas where there are pentalaminar fusions between the neutrophil and tegumental membranes, suggesting that these fusions attach the cells to the parasites. Pipetting breaks many of the attached cells. In thin section, the tegumental membrane underlying these cells is seen to be pentalaminar. By freeze-fracture techniques, modified attachment areas are found. The edge zone often appears as a single strand of intramembrane particles (IMPs) on the P2 face and as a groove on the E2 face. The edge zone may also have large discontinuities, in which case it no longer separates membrane faces of unequal IMP density from one another. In addition, the IMPs on the IMP- rich areas become aggregated and surrounded by craters in the membrane. These experiments suggest that the fusions may be the mechanism by which the parasite acquires some host membrane components on its surface. On the other hand, eosinophil plasma membranes are seen adhering to a layer of electron-dense material on the parasite after the cells have been disrupted by pipetting. This suggests that eosinophils adhere to the parasite surface through their discharged granule material and not by membrane fusions.     

Human erythrocytes adhering to schistosomula of Schistosoma mansoni lyse and fail to transfer membrane components to the parasite

We studied the adherence of human erythrocytes to larvae of the intravascular parasite Schistosoma mansoni by transmission microscopy, freeze fracture, and fluorescence techniques. In addition, we used the adherent cells to investigate the problem of host antigen acquisition. Schistosomula were cultured for from 24 to 48 h after transformation in order to clear the remnants of the cercarial glycocalyx. In some cases, the worms were preincubated with wheat germ agglutinin to promote adherence of the erythrocytes. The results were similar with and without the lectin except that more cells attached to the lectin-coated parasites. Erythrocytes adhered within a few hours and, unlike neutrophils, did not fuse with the parasite. A layer of 10-20-nm electron dense material separated the outer leaflets of the tegumental and plasma membranes. In addition, many deformed and lysed cells were seen on the parasite surface. The ability of the worm to acquire erythrocyte membrane constituents was tested with carbocyanine dyes, fluorescein covalently conjugated to glycophorin, monoclonal antibodies against B and H blood group glycolipids, and rabbit alpha-human erythrocyte IgG. In summary, glycophorin, erythrocyte proteins, and glycolipids were not transferred to the parasite membrane within 48 h. Carbocyanine dyes were rapidly transferred to the parasite with or without lectin preincubation. Thus, the dye in the worm membrane came from both adherent and nonadherent cells. These studies suggest that, in the absence of membrane fusion, the parasite may acquire some lipid molecules similar in structure to host membrane glycolipids by simple transfer through the medium but that B and H glycolipids and erythrocyte membrane proteins are not transferred from adhering cells to the worm.     

The adherence of human neutrophils and eosinophils to schistosomula: evidence for membrane fusion between cells and parasites

Human neutrophils and eosinophils adhere to the surface of schistosomula of Schistosoma mansoni that have been preincubated with antischistosomular sera with or without complement. Neutrophils are seen to form small (< 0.5 micrometer), heptalaminar and large (5-8 micrometer), pentalaminar fusions with the normal pentalaminar parasite surface membrane. By freeze-fracture techniques, attachment areas 5-8 micrometer in diameter are seen to form between neutrophils and schistosomula. These areas have three zones--an edge and two centrally located areas, one of which is rich and one of which is poor in intramembrane particles (IMPs). The edge zone is continuous around the attachment areas and is usually composed of a skip-fracture that passes out of the schistosomular outer membrane into the inner membrane. In some cases, the edge zone is made up of a string of IMPs. The IMP-rich central areas have an IMP concentration similar to that of unattached neutrophil membranes, are raised off of the surface of the schistosomulum, and have two normal schistosomular membranes underneath indicating that they are indeed unattached. the IMP-poor central areas are composed of a fused or hybrid membrane that is continuous with the neutrophil plasma membrane but that bears the same spatial relationship to the schistosomular inner membrane that the normal outer membrane does. Similar changes are seen in samples prepared with glycerination. Eosinophils generally do not fuse with the schistosomular outer membrane but, instead, discharge their granular contents onto the surface of the schistosomula and appear to adhere to the parasite through this discharged material. It is suggested that schistosomula have a capability to fuse with mammalian cells and that this fusion proceeds from a fusion of the outer leaflets to a fusion of the bilayers, as appears also to be the case in other systems.     

Loss of covalently labeled glycoproteins and glycolipids from the surface of newly transformed schistosomula of Schistosoma mansoni

Schistosomula of Schistosoma mansoni were labeled by oxidation with galactose oxidase or with periodate followed by reduction with NaB3H4 to study the loss of the surface membrane of these parasites in vitro. Grain counts of light microscope autoradiographs (LMARG) of radiolabeled schistosomula show that both galactose oxidase and periodate specifically label the surface of the organisms. Galactose oxidase labels 11 glycoproteins on the surface of skin and mechanical schistosomula, ranging in apparent molecular weight from 17,000 to greater than 105,000. These glycoproteins are lost from the surface of schistosomula with a halftime of 10-15 h in culture in defined medium. Most of these glycoproteins appear to be shed intact from the surface of the schistosomula rather than endocytosed and degraded, because greater than 50% of each of the lost proteins can be recovered by trichloroacetic acid precipitation of the culture medium and because there is no internalization of the radiolabels into cultured schistosomula examined by LMARG. In addition to glycoproteins, periodate labels at least seven glycolipids on the surface of mechanical schistosomula. After culture for 15 h, more than half of each of these periodate-labeled proteins and lipids are lost from the schistosomula, and their abundance relative to each other remains similar to that of freshly labeled organisms. Since both proteins and lipids are lost from the surface of the schistosomula at the same rate, we believe that we are observing a general loss of the parasite surface membrane.     

Schistosoma mansoni: surface membrane stability in vitro and in vivo

The human complement component C3b is known to bind in vitro to the surfaces of all developmental stages of schistosomes as a consequence of complement activation by the alternative pathway. C3b bound to Schistosoma mansoni parasites has now been used in combination with fluorescent labeled antibodies against C3b to label the surfaces of living schistosomes. Binding of complement components and labeled antibodies to adult schistosomes rendered their surface membrane homogeneously fluorescent. At the ultrastructural level, the label was seen as a dense deposit lying on the tegumental membrane. Surface damage was not observed in labeled adults by electron microscopy. Fluorescent schistosomes were cultured in vitro for periods of up to 2 weeks, during which time the parasites remained fully viable and their surface membrane was still fluorescent. The electron dense deposit persisted, and tegumental damage at the electron microscope level was minimal or absent. Consequently, adult schistosomes would seem able to survive in vitro in the absence of rapid and general turnover of their surface membrane. Loss of fluorescence was observed consistently only at the anterior end of the parasite, including the suckers, a finding which indicates that membrane turnover may occur at different rates on different parts of the body. Fluorescent 3-week-old juveniles and 6-day-old lung stage parasites were cultured under the same conditions with similar results: they remained viable and fluorescent for at least 2 weeks. Results with skin schistosomula were different in the sense that many worms died during culture, and those which survived lost large parts of their fluorescent surface. A few of the surviving and fluorescent schistosomula developed the elongate shape typical of lung stage parasites. Fluorescent viable skin schistosomula were injected intravenously into mice and subsequently recovered from the lungs after varying periods. Fluorescence was lost in a patchy way within a few minutes from some individuals and within several hours from most of the worms. These data permit the following conclusions: C3b is a suitable tracer for membrane renewal in all developmental stages of schistosomes. Very slow membrane renewal in vitro and very rapid renewal in vivo are both compatible with parasite survival.     

Suppressing Glucose Transporter Gene Expression in Schistosomes Impairs Parasite Feeding and Decreases Survival in the Mammalian Host

Adult schistosomes live in the host''s bloodstream where they import nutrients such as glucose across their body surface (the tegument). The parasite tegument is an unusual structure since it is enclosed not by the typical one but by two closely apposed lipid bilayers. Within the tegument two glucose importing proteins have been identified; these are schistosome glucose transporter (SGTP) 1 and 4. SGTP4 is present in the host interactive, apical tegumental membranes, while SGTP1 is found in the tegumental basal membrane (as well as in internal tissues). The SGTPs act by facilitated diffusion. To examine the importance of these proteins for the parasites, RNAi was employed to knock down expression of both SGTP genes in the schistosomula and adult worm life stages. Both qRT-PCR and western blotting analysis confirmed successful gene suppression. It was found that SGTP1 or SGTP4-suppressed parasites exhibit an impaired ability to import glucose compared to control worms. In addition, parasites with both SGTP1 and SGTP4 simultaneously suppressed showed a further reduction in capacity to import glucose compared to parasites with a single suppressed SGTP gene. Despite this debility, all suppressed parasites exhibited no phenotypic distinction compared to controls when cultured in rich medium. Following prolonged incubation in glucose-depleted medium however, significantly fewer SGTP-suppressed parasites survived. Finally, SGTP-suppressed parasites showed decreased viability in vivo following infection of experimental animals. These findings provide direct evidence for the importance of SGTP1 and SGTP4 for schistosomes in importing exogenous glucose and show that these proteins are important for normal parasite development in the mammalian host.     

Detection of surface-bound ligands by freeze-fracture autoradiography

This article describes a new freeze-fracture autoradiographic technique for the detection of radioactive ligands associated with the surface of cells in monolayer or suspension culture. Since freeze-fracture replicas are produced in the conventional way, all membrane features normally seen in freeze-fracture are retained, and autoradiographic grains produced by the labeled ligands are seen superimposed on unaltered exoplasmic membrane fracture faces. To assess the feasibility and resolution of this technique, we compared the surface distribution of alpha 2-macroglobulin and cholera toxin, labeled either with 125I or with colloidal gold, on 3T3-L1 fibroblasts. Both by autoradiography and cytochemical gold labeling, alpha 2-macroglobulin was associated specifically with coated pits, whereas cholera toxin was preferentially found over smaller, apparently non-coated membrane invaginations. Together with data on the surface localization of 125I-transferrin on HL-60 myelomonocytic cells, these results demonstrate the application of this technique for the accurate determination of ligand distribution over large areas of plasma membrane. The simplicity and reproducibility of the method should now allow freeze-fracture autoradiography to become a standard technique for investigating the distribution of both endogenous and exogenous cell surface-associated molecules, as well as the redistribution of such molecules under different experimental conditions.     

Gorgoderina vitelliloba: interaction with frog leucocytes in vivo and in vitro

Ultrastructural observations were made on the response in vivo of adult Rana temporaria to Gorgoderina vitelliloba and the interaction between host cells and the parasite in vitro. In both cases, the cellular attack on the fluke was most intense 21-23 days postinfection. Host leucocytes (believed to be eosinophils) lay flat against the surface of the parasite. Degranulation of their electron-dense, peroxidase-positive granules occurred and vacuoles formed. The outer plasmalemma of the tegument was breached and eosinophils migrated over the basal lamina, stripping the tegument from the surface of the fluke. The cellular response was so vigorous in vitro that the tegument was sometimes completely lost. In vivo, damage was slight, and the majority of the parasites successfully completed their migration to the bladder, where there was no further cellular response, and tegumental repair occurred. The fact that the migration of the fluke from the kidney to the bladder occurred at the same time as the peak of the cellular response may not be coincidental, and it is suggested that the cellular attack may initiate migration from the kidneys.     

Ultrastructure of Amoebophrya sp. and its changes during the course of infection

Amoebophrya is a syndinian parasite that kills harmful bloom forming algae. Previously uncharacterized ultrastructural aspects of infection and development were elucidated. The biflagellate dinospore has two mitochondria, electron-dense bodies, striated strips, trichocysts, and a nucleus with peripherally condensed chromatin. After finding an Akashiwo sanguinea host and adhering to its surface, the parasite penetrates the host surface, apparently using a microfilament based motility and electron-dense bodies within a microtubular basket in the process of parasitophorous vacuole membrane formation. After entering the host nucleus, possibly by a similar mechanism used to enter the host cell, the parasite cytosol expanded substantially prior to mitosis. From 12-36 hours mitochondria were inconspicuous but present. Chromatin condensation was variable. By 36 hours post-infection, parasites had multiple nuclei, a microtubule-supported cytopharynx, and were beginning to form a fully internal mastigocoel. By 48 hours, the characteristic "beehive" appearance was apparent with flagella projecting into a fully developed mastigocoel. The cytoplasm contained trichocysts, elongated mitochondria, and nuclei with peripherally condensed chromatin. Although Amoebophrya lacks an apical complex, its electron-dense bodies show functional similarities to apicomplexan rhoptries. Its lack of permanently condensed chromosomes, but compact dinospore chromatin, supports the idea that dinoflagellate permanently condensed chromosomes may be a remnant of a parasitic ancestor with a compact dispersal stage.     

Ultrastructure of the encapsulation of Plasmodium cynomolgi (B strain) on the midgut of a refractory strain of Anopheles gambiae

Using transmission electron microscopy, we investigated the encapsulation of the simian malaria parasite, Plasmodium cynomolgi, in a refractory strain of the mosquito, Anopheles gambiae. After the ookinete penetrates the mosquito midgut epithelium and lodges between the basal membrane and the basal lamina, an electron-dense, melanin-like substance begins to coalesce around the parasite. Completely encapsulated parasites were found as early as 16 hr after the blood meal. Granules of the melanin-like substance often appeared to condense onto the parasite from the fluid in the extracellular spaces of the basal membrane labyrinth. Melanin granules also appeared to condense from the hemolymph onto the basal lamina underlying the parasite. In addition, groups of tubules, vesicles, and membranous whorls often were found in midgut cells that were located next to or were enclosing parasites. These structures were unusually electron-dense, and may have been associated with melanization. Hemocytes rarely were observed near completed capsules and neither hemocytes nor their remnants were components of the capsules. During later stages of encapsulation, parasites appeared abnormal and often were infiltrated with melanin. Although late-stage capsules were usually located basally, completed capsules enclosed by membranes were occasionally observed near the apical border of the midgut. Other capsules associated with cellular debris, were found in the lumen of the midgut from 1 to 6 days after the blood meal.     

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.     

A comparison of two procedures for labelling the surface of the hydatid disease organism, Echinococcus granulosus, with 125I

Living, intact protoscoleces of the British horse and sheep strains of Echinococcus granulosus were subjected to surface radioiodination procedures using 125I and Iodogen and 125I-Bolton Hunter reagent. Subsequent combined electron microscopy and autoradiography revealed specific surface membrane labelling with the Iodogen procedure, but significant tegumental labelling with the Bolton-Hunter reagent. The two parasite strains yielded different profiles of electrophoretically separated labelled proteins; the Iodogen method, not surprisingly, resulted in a less complex pattern of labelled polypeptides than the Bolton and Hunter reagent.     

Metabolite movement across the schistosome surface

Intravascular schistosome parasites are covered by an unusual double lipid bilayer. Nutrients, such as glucose and amino acids, as well as other metabolites, are known to be transported across this surface via specific transporter proteins. For instance, the glucose transporter protein SGTP4 is found in the host-interactive tegumental membranes. A second glucose transporter, SGTP1, localizes to the tegumental basal membrane (and internal tissues). Following expression in Xenopus oocytes, SGTP1 and SGTP4 both function as facilitated-diffusion sugar transporters. Suppressing the expression of SGTP1 and SGTP4 in juvenile schistosomes using RNA interference (RNAi) impairs the parasite's ability to import glucose and severely decreases worm viability. Amino acids can also be imported into schistosomes across their surface and an amino acid transporter (SPRM1lc) has been localized in the parasite surface membranes (as well as internally). In Xenopus oocytes, SPRM1lc can import the basic amino acids arginine, lysine and histidine as well as leucine, phenylalanine, methionine and glutamine. To function, this protein requires the assistance of a heavy-chain partner (SPRM1hc) which acts as a chaperone. Water is transported across the tegument of schistosomes via the aquaporin protein SmAQP. Suppressing SmAQP gene expression makes the parasites less able to osmoregulate and decreases their viability. In addition, SmAQP-suppressed adult parasites have been shown to be impaired in their ability to excrete lactate. Analysis of tegumental transporter proteins, as described in this report, is designed to generate a comprehensive understanding of the role of such proteins in promoting parasite survival by controlling the movement of metabolites into and out of the worms.     

Taenia taeniaeformis (Cestoda) in the rat: ultrastructure of the host-parasite interface on days 8 to 22 postinfection

The host-parasite interface was examined at the ultrastructural level 8 to 22 days postinfection (DPI) with metacestodes of Taenia taeniaeformis in the rat. Throughout this phase of development the parasite surface was invested with a dense surface coat of complex microtriches. At 8 to 14 DPI the plasma membrane of each microthrix extended beyond the distal end of the electron-dense tip, forming a slender tubular streamer over 10 microns long; by 18 DPI these had shortened and withered. Host cell processes interdigitated with the microtriches without evidence of harm to the parasite surface or the underlying tegument. The cells, on the other hand, became damaged, and their contents were shed into the matrix surrounding the microtriches. Lipid inclusions appeared within the parasites, and in the cytoplasm of surrounding inflammatory cells. By 22 DPI fibroblastic activity had resulted occasionally in the formation of a capsule surrounding a free-floating cysticercus, while in others intense granulocytic infiltration persisted with abutment and intermeshing of host cell and parasite surface processes; however there was still no evidence of any adverse effect on the microtriches, though many granulocytes were clearly pyknotic and degenerating. Evidently, the vigorous cellular response of the host is ineffective in either containing the expansion of the parasite or compromising the integrity of its surface membrane. The changing characteristics of the microtriches may be related to the need for dissolution of both intercellular matrices, and host cells as the vesicular organism rapidly increases in volume.     

Development of a rickettsia isolated from an aborted bovine fetus.

An obligate intracellular rickettsial organism isolated from an aborted bovine fetus was studied in bovine turbinate and mouse macrophage cell cultures with light and electron microscopy. Development of the organism was similar in both cell types. The organism replicated within cytoplasmic vacuoles in a developmental cycle that resembled that of both the ehrlichiae and chlamydiae. The inoculum contained only electron-dense forms, which infected cells within 2 h postinoculation by adhering to cell membranes at thickened areas that appeared to be coated pits and then being endocytosed. A striking feature occurred next as the organisms became surrounded by host cell mitochondria and, by light microscopy, appeared to have halos. During this intimate association with mitochondria, the electron-dense organisms changed into large reticulated forms that began to divide by binary fission. These large forms were often in direct contact with mitochondrial membranes. The organisms continued to divide by binary fission, and host cells contained large cytoplasmic inclusions of reticulated organisms. The reticulated organisms gradually changed into electron-dense forms that were released from degenerated host cells.     

Binding, uptake, and transcytosis of ligands for mannose-specific receptors in rat liver: an electron microscopic study

We have investigated the initial distribution of mannose-specific binding sites in rat liver as well as the uptake and transcytosis pathways of ligands for this receptor in in situ and in vivo experiments. As ligands we used mannan adsorbed onto colloidal gold particles of sizes 5, 17, and 35 nm (Man-Au5, Man-Au17, or Man-Au35). The in situ binding pattern of Man-Au5 in the prefixed liver is identical to the one described earlier for galactose-exposing ligands in the same organ. With the exception of the binding by hepatocytes, where only scarce binding of Man-Au5 was observed, ligands were found adhering in a preclustered pattern all over the cell surface of liver macrophages and binding in aggregates over the coated pits of endothelial cells. In double-labeling experiments different particle sizes were used for glycoproteins with terminal mannosyl or galactosyl residues. This simultaneous localization of the two binding activities revealed that on endothelial cells the two activities are always found to be present in the same coated pit. On liver macrophages the clustered binding occurred at different membrane areas. Uptake and transcytosis of Man-Au5, 17, 35 were studied after their injection into the tail vein. Three and fifteen minutes after injection most of the Man-Au5 and all of Man-Au17 or Man-Au35 was found in sinusoidal liver cells, i.e., macrophages and endothelial cells. One hour after injection, endocytosed ligand is redistributed from large--presumably lysosomal--vacuoles to small noncoated vesicles that are localized predominantly near the space of Dissé. Between 1 and 40 h after injection, ligands of all sizes are transcytosed and found in the hepatocytes. No ligand accumulation is observed in hepatocytes as an indirect indication for secretion into bile. With this investigation we give evidence for transcytotic activity not only of liver endothelium but also of the resident liver macrophages.     

Histopathological and ultrastructural studies of cutaneous reactions elicited in naive and chronically infected mice by invading schistosomula of Schistosoma mansoni

Naive and chronically infected CBA mice were challenged percutaneously with cercariae and biopsied at varying times thereafter to provide skin samples for light and electron microscopy. The epidermis and dermis doubled in thickness in both groups; this change occurred within 3 h in immune mice and by 48 h in controls. Immune skin showed a 5-fold increase in total thickness by 72 h. Primary reaction sites were characterised by neutrophil infiltrates but in immune mice, eosinophils replaced neutrophils by day 2. Granulocytic micro-abscesses formed in the epidermis in both naive and immune skin; they entrapped cast cercarial tails and schistosomula and were eventually sloughed from the skin surface. An early loss of challenge parasites may occur in this way. Not all penetrated schistosomula completed transformation by developing the double outer membrane and these may constitute additional casualties. Schistosomula in immune but not naive skin were invested by a surface coat; this is suggested to represent an antigen/antibody complex. Significant numbers of larvae in immune skins were associated with intact granulocytes or free eosinophil granules and dead, infiltrated parasites occurred in the dermis. Such individuals may account for the additional attrition recorded in immune mice. Mast cells became associated with granulocytes in both groups of animals; they degranulated by simple exocytosis in naive skin but compound exocytosis in immune skin.     

Three major surface antigens of Schistosoma mansoni are linked to the membrane by glycosylphosphatidylinositol

Schistosomula of Schistosoma mansoni were examined for the presence of glycosylphosphatidylinositol (GPI) anchored surface membrane Ag. Parasites were surface iodinated and cultured in the presence or absence of a crude phospholipase C (PLC) preparation or phosphatidylinositol-specific PLC (PIPLC). Culture supernatants were then analyzed: 1) by centrifugation to ascertain which molecules released from the surface were soluble or contained in membrane vesicles; 2) by immunoprecipitation with antibodies specific for the "cross-reacting determinant," an epitope revealed on some GPI-anchored proteins only after cleavage of the diacylglycerol from the protein by PIPLC, and 3) by immunoprecipitation with immune mouse sera to establish co-identity with previously described, immunologically relevant surface Ag. By using these techniques, schistosomula were shown to possess three GPI-anchored surface Ag of m.w. 38,000, 32,000 and 18,000 which are spontaneously released from the surface of schistosomula in association with membrane, but remain insoluble until cleaved by PIPLC. All three molecules were recognized by antibodies from mice vaccinated with irradiated cercariae and/or chronically infected mice. Moreover, the m.w. 38,000 component was recognized by a previously described protective mAb (E.1). A major developmental modification appears to occur in the expression of these molecules because, by the same techniques, no GPI-anchored surface Ag were detectable on 7-day-old lung stage parasites. The finding that these important parasite immunogens are GPI-anchored and released from the surface of the parasite in membrane vesicles may, in part, explain why they elicit strong immune responses capable of damaging the schistosomulum tegument.     

Schistosoma mansoni: protein phosphorylation during transformation of cercariae to schistosomula.

Infectivity of the multicellular pathogen Schistosoma mansoni for the human host is dependent upon the ability of free-living cercariae to transform rapidly into parasitic schistosomula. The biochemical pathways that regulate this transitional period are unknown. The role of protein phosphorylation was investigated by examining the incorporation of [32Pi]phosphate into proteins of S. mansoni. A sevenfold increase in total phosphorylation was found in 3-hr-old schistosomula as compared to cercariae. Analysis of radiolabeled proteins by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography demonstrated that a 14-kDa protein served as a marker for transformation, being phosphorylated in schistosomula but not cercariae. The protein was phosphorylated on a serine residue. Phosphorylation was stimulated by a shift of parasites from water to salt-containing medium at 23 degrees C. Incubation of organisms in water at 37 degrees C did not initiate phosphorylation of this protein. The 14-kDa phosphoprotein was extracted from parasite homogenates with 1 M NaCl but was insoluble in 1% Triton X-100. Protein phosphorylation during the cercarial-schistosomula transformation may represent an important biochemical event that regulates infectivity of the parasite for the human host.