Schistosomula of Schistosoma mansoni clear concanavalin A from their surface by sloughing

Functions of the tegument of schistosomes: clues from the proteome and lipidome

The tegumental outer-surface of schistosomes is a unique double membrane structure that is of crucial importance for modulation of the host response and parasite survival. Although several tegumental proteins had been identified by classical biochemical approaches, knowledge on the entire molecular composition of the tegument was limited. The Schistosoma mansoni genome project, together with recently developed proteomic and lipidomic techniques, allowed studies on detailed characterisation of the proteins and lipids of the tegumental membranes. These studies identified tegumental proteins and lipids that confirm the function of the tegument in nutrient uptake and immune evasion. However, these studies also demonstrated that compared to the complete worm, the tegument is enriched in lipids that are absent in the host. The tegument is also enriched in proteins that share no sequence similarity to any sequence present in databases of species other than schistosomes. These results suggest that the unique tegumental structures comprise multiple unique components that are likely to fulfil yet unknown functions. The tegumental proteome and lipidome, therefore, imply that many unknown molecular mechanisms are employed by schistosomes to survive within their host.

Surfactant protein D binding to terminal alpha1-3-linked fucose residues and to Schistosoma mansoni

Pulmonary surfactant protein (SP)-D is an important component of the innate immune system of the lung, which is thought to function by binding to specific carbohydrates on the surface of viruses and unicellular pathogens. SP-D has been shown to have a relatively high affinity for the monosaccharides mannose, glucose, and fucose. However, there is limited information on SP-D binding to complex carbohydrate structures, and binding of SP-D to fucose in the context of an oligosaccharide has not yet been investigated. In this study, we used surface plasmon resonance spectroscopy to examine the potential of SP-D to bind to various synthetic fucosylated oligosaccharides, and identified Fucalpha1-3GalNAc and Fucalpha1-3GlcNAc elements as strong ligands. These types of fucosylated glycoconjugates are presented at the surface of Schistosoma mansoni, a parasitic worm that, during development, transiently resides in the lung. In line with the findings by surface plasmon resonance, we found that SP-D can bind to larval stages of S. mansoni, demonstrating for the first time that SP-D interacts with multicellular lung pathogens.

The ultrastructural architecture of the adult Schistosoma japonicum tegument

The tegument of the adult blood fluke Schistosoma japonicum is in direct contact with the host blood and immune systems. A comprehensive understanding of the ultrastructure of the tegument is crucial to the understanding of how the parasite maintains itself within the mammalian host. Important functions such as nutritional uptake and immune evasion are suspected functions of the tegument and this review discusses these aspects and presents some insights into some of these crucial functions. Transmission electron microscopy has allowed the identification of ultrastructural features of the adult S. japonicum, some of which differ from the reported features of other schistosome species. Morphological differences within the tegument of the adult S. japonicum are noted between sexes, among different regions of the worms and between aspects along the length of the parasite. Differences included variations in the ultrastructure, size and number of tegumental bodies and mitochondria within the matrix, and differences in the relative area of the apical surface of the tegument. Functions of the various components of the tegument matrix and specialised functions of different regions of the male and female parasites are discussed based on ultrastructural findings and previously reported biochemical and molecular data.

The interaction of human LDL with the tegument of adult Schistosoma mansoni

The occurrence of a receptor for human LDL was investigated in the tegument of adult Schistosoma mansoni employing several approaches. Binding of LDL to SDS-PAGE fractionated tegument proteins was measured directly on nitro-cellulose membranes and visualised by an anti-human LDL antibody. Proteins with an Mr of 60, 35 and 14 kDa were evidenced. Affinity chromatography of 125I-labelled tegument proteins on a LDL-Sepharose column, revealed the same pattern of proteins observed in the immunoblot experiments. Finally, the binding of human LDL to the intact tegument was measured by microcalorimetry. Binding was shown to be an exothermic reaction, releasing approximately 2500 kcal/mol, it was saturable, and reproducibly displayed a biphasic curve suggesting that binding of LDL to S. mansoni might occur through a two step process, initiated by a nonspecific hydrophobic interaction followed by a specific high affinity ligand-receptor reaction. Pre-treatment of the tegument with trypsin reduced the binding of LDL to the tegument. Furthermore, albumin, which is an abundant lipid carrier protein in the serum and thus a potential ligand, failed to release any measurable heat when incubated with the tegument.

Immunolocalization of a Schistosoma mansoni facilitated diffusion glucose transporter to the basal, but not the apical, membranes of the surface syncytium

Adult parasites of Schistosoma mansoni reside within vertebrate mesenteric veins where they consume immense quantities of host glucose after transporting the sugar through their surface syncytium or tegument. Previously we obtained cDNA clones encoding two functional facilitated diffusion glucose transporter proteins expressed by S. mansoni adult worms (Skelly et al. 1994). Antibodies specific for one transporter (SGTP1) have been generated against an extrafacial and an internal domain of the protein and used to localize the protein by light and electron microscopy. By light microscopy both antibodies stain a linear structure approximately 1-5 microns from the surface of the tegument of adult male and female schistosomes. Electron microscopic examination of frozen thin sections show binding of the antibodies to membranes in the base of the tegument and not to the membranes covering the outer surface or their invaginations. Analysis of the gold distribution suggests that the extrafacial domain is disposed toward the interstitial space beneath the tegument and the internal domain faces the syncytial plasm. The localization suggests that SGTP1 may function to transport free glucose from within the tegument and into the interstitial fluids that bathe the internal organs of these parasites.

Schistosoma mansoni: stage-dependent formation and repair of membrane pores induced by a cytotoxin from Pseudomonas aeruginosa

Various stages of Schistosoma mansoni were treated with a cytotoxin from Pseudomonas aeruginosa and their response to the damaging effect was studied in detail. Marker release and membrane potential measurements showed that the cytotoxin formed stable pores in all developmental stages. However, in juvenile 27-day-old worms, which are refractory to the killing effect of the cytotoxin, the pores had a smaller functional diameter as compared to other stages including 31-day-old worms. Furthermore, these resistant 27-day-old worms, but not susceptible older juvenile worms were able to repair the membrane lesions as shown by restoration of the resting membrane potential. In contrast, older juvenile and adult parasites were unable to cope with the breakdown of the resting potential induced by the cytotoxin. The results demonstrate the existence in 27-day-old schistosomes of effective repair mechanisms dealing with damage to the surface membrane.

Specific binding of human low-density lipoprotein to the surface of schistosomula of Schistosoma mansoni and ingestion by the parasite

Low-density lipoproteins (LDL) may be important in human schistosomiasis because LDL bound to the surface of the parasite inhibits the binding of anti-schistosomal antibodies. Low-density lipoproteins also may serve as a source of lipids for the parasite membrane synthesis. Here LDL fluorescently labeled with carbocyanine dye (DiI-LDL) was used to measure the specificity of binding of LDL to the surface of schistosomula of Schistosoma mansoni and to examine the distribution of the LDL particles over time. DiI-LDL binding was saturable and specific, with strong inhibition by unlabeled LDL and apoB but not by apoA1, bovine serum albumin, or IgG, and only weak inhibition by high-density lipoproteins. Half of the bound DiI-LDL was displaced by unlabeled LDL. DiI-LDL remained bound on the surface of schistosomula for up to 36 hours in culture. However parasites also ingested both DiI-LDL and a second fluorescent LDL, Bodipy-LDL. Over time, both fluorophores appeared throughout the worm tissues, suggesting the LDL particles were breaking down and that the fluorophores and lipids originally contained within the LDL particle were partitioning throughout the worm. Thus human LDL appears to bind to the surface of schistosomula specifically. Ingested LDL appears to be broken down and may serve as a source of host lipids for the parasite.

Tegumental surface modulation in Schistosoma mansoni primary sporocysts in response to ligand binding

The clearance of host molecules from the surface of a parasite constitutes a potential immune evasive strategy. The possibility that certain ligands, when bound to the tegument of Schistosoma mansoni primary sporocysts, could induce such a modulating effect was investigated. Live, in vitro cultured primary sporocysts were first treated with either snail host Biomphalaria glabrata plasma, an anti-sporocyst monoclonal antibody (MoAb III-1), or concanavalin A (con A). The capacity of these primary ligands to produce a modulating effect alone, or when subsequently crosslinked by secondary or tertiary ligands, was measured using quantitative fluorescence microscopy. Snail plasma alone, or plasma crosslinked at the sporocyst surface with a mouse anti-plasma MoAb had little or no modulating effect. However, a tertiary level of ligand crosslinking with an anti-mouse IgG antibody produced an average 1.8-fold decrease in surface fluorescence within 1 h post-labelling. The anti-sporocyst MoAb III-1 also required secondary antibody reactivity to induce an average 1.5-fold decrease in MoAb III-1 recognized epitopes. Sporocysts labelled with con A crosslinked by secondary and tertiary ligands showed inconsistent modulation, with a 1.5-fold decrease in fluorescence in one out of three replicates. Overall, however, analysis of combined data revealed no significant effect of tertiary ligand level crosslinkage on modulation of con A-tegumental receptor complexes. In contrast, con A binding alone to tegumental determinants induced a small, but significant, reduction in surface con A complexes. Modulation of ligand-receptor complexes on the sporocyst tegumental membrane appears to be an energy-requiring event, since clearance of surface complexes was inhibited in the presence of sodium azide and/or sodium iodoacetate, or when larvae were incubated at 4 degrees C. It is concluded that alterations in sporocyst tegumental surface components may be triggered by specific (but as yet undefined) signals. Sporocysts are capable of exhibiting different responses depending on the nature of the binding signal and reactive tegumental receptor, and the degree of ligand crosslinkage.

Parasitic protozoa and helminths: biological and immunological challenges

Parasitic protozoans and helminths pose considerable medical as well as scientific challenges. Investigations of the complex and very different life cycles of these organisms, their adaptation to the obligate parasitic mode of life, and their ability to face the hostile host environment have resulted in many exciting discoveries. Invasion of host erythrocytes by plasmodial sporozoites and intact skin by schistosomal cercariae are outlined as examples of the elaborate mechanisms of parasitism. Isolation and characterization of single protective antigens or subunit vaccines from these two organisms are examined as models for vaccine development. Finally, developments in exploring gene regulation in protozoans and free and parasitic nematodes are briefly outlined.

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.

Schistosoma mansoni: synthesis and release of phospholipids, lysophospholipids, and neutral lipids by schistosomula

Lipids in the two surface membranes of Schistosoma mansoni may play an important role in the parasite's defense against host immunity. In particular, lysophosphatidylcholine lyses erythrocytes attached to the parasite and alters the lateral mobilities of their membrane proteins and lipids (Golan et al. 1986). Here, we have studied the incorporation of radiolabeled precursors into the major lipid classes of schistosomula as well as into lipids released by schistosomula into the medium. Radiolabeled polar head groups (choline and ethanolamine) and fatty acid precursors (palmitate and oleate) were linearly incorporated into parasite phospholipids. Fatty acids were differentially incorporated into the various phospholipid classes, principally into phosphatidylcholine and, to a lesser extent, into phosphatidylethanolamine, lysophosphatidylcholine, and phosphatidylserine. The major neutral lipid class labeled, triglycerides, had a decrease in specific activity with time after pulse labeling and the specific activity of the phospholipids increased with time. Thus, triglycerides may provide acyl chains for phospholipid synthesis. Choline was incorporated into phosphatidylcholine and lysophosphatidylcholine, and ethanolamine into phosphatidylethanolamine and lysophosphatidylethanolamine. No evidence was found for phospholipid methylation or demethylation in schistosomula. Labeled lipids were linearly and selectively released into the medium. Triglycerides were released at the highest rate with measurable quantities of phosphatidylcholine, lysophosphatidylcholine, and phosphatidylethanolamine also observed. Monopalmitoylphosphatidylcholine was the only lysophosphatidylcholine present in the medium as demonstrated by reverse-phase chromatography of released choline-labeled lysophosphatidylcholine. These studies demonstrate that schistosomula synthesize phospholipids and neutral lipids and release some of them into the culture medium. In particular, they release a single molecular species of a potent biologically active molecule, monopalmitoylphosphatidylcholine, that may play a role in the parasite's evasion of the immune response.

The binding of human low-density lipoproteins to the surface of schistosomula of Schistosoma mansoni is inhibited by polyanions and reduces the binding of anti-schistosomal antibodies

Host molecules such as serum lipoproteins, blood group glycolipids, and histocompatibility antigens may bind to schistosomes and thereby prevent immune recognition of the parasite. This study examines the kinetics of lipoprotein binding, the ability of polyanions to inhibit lipoprotein binding, the binding of anti-schistosomal antibodies to worms that have previously bound low-density lipoprotein (LDL), and the distribution of lipoproteins bound to the parasites. Lipoproteins in human serum (HS) and purified LDL, very low-density lipoprotein (VLDL), and apolipoprotein B (apo B) in defined media were demonstrated on the surface of schistosomula of Schistosoma mansoni by fluorescence and immunoelectron microscopy using a polyclonal goat anti-human apolipoprotein B antibody (anti-apo B). By fluorophotometric microscopy, lipoprotein binding began within 15 minutes and was largely completed within 3 hours of exposure. Lipoprotein binding saturated at 10% HS or 20 micrograms protein/300 microliters of purified LDL. Suramin inhibited LDL binding by 59% in a dose-dependent fashion. In the absence of LDL in the medium, 2 mM suramin dissociated 41% of bound LDL from the worm surface within 15 minutes and 10 mg/ml heparin dissociated 36%. The binding of human anti-schistosomal antibodies to schistosomula was inhibited by bound LDL. By fluorescence microscopy, serum or purified lipoproteins were distributed over the entire surface of the parasite with focal areas of high intensity. Ultrastructurally, reaction product was seen on the outer leaflet of the outer tegumental membrane and in aggregates and surrounding vesicular structures varying in diameter from 13 to 83 nm. These studies demonstrate that lipoproteins bind to the surface of schistosomula. The binding of lipoproteins is partially inhibited by polyanions, reduces the binding of human anti-schistosomal antibodies, and may help the parasite escape the immune response.

Inhibition of surface membrane maturation in schistosomula of Schistosoma mansoni

The surface membrane of the multicellular parasite Schistosoma mansoni is radically reorganized during the transformation of cercariae into schistosomula. The current study investigates factors involved in maturation of the surface from a trilaminate to a multilaminate membrane. When maturation was induced in the presence of puromycin (900 microM), the acquisition of a multilaminate surface and stainability with fluorescein-conjugated Con A were similar to that of control parasites. Similarly, although organisms treated with monensin (0.1 microM) for 3 hr showed large vacuoles in the perinuclear cytoplasm of the subtegumental cells, the surface membrane became multilaminate. In contrast, microtubule-active drugs interfered with maturation: the surface remained largely trilaminate and the percentage of organisms binding Con A to their surface was significantly reduced. Furthermore, large accumulations of multilaminate bodies were found in the subtegumental cells of colchicine-treated parasites, whereas few were seen in the controls. Colchicine-treated schistosomula failed to mature to adult worms upon injection into mice and, like cercariae, they were water tolerant. We therefore conclude that the components that constitute the schistosomula surface preexist in cercariae and suggest that they are stored in multilaminate bodies before being transported to the surface with the help of microtubules. The acquisition of the multilaminate membrane may be essential for survival of the parasites in vivo and in vitro.

Schistosoma mansoni: sterol and phospholipid composition of cercariae, schistosomula, and adults

The sterol and phospholipid composition of cercariae, schistosomula, and adult Schistosoma mansoni was analyzed by gas-liquid chromatography and high-performance liquid chromatography (HPLC). Cercariae and schistosomula contained cholesterol, desmosterol, campesterol, stigmasterol, and beta-sitosterol while adults contained only cholesterol. In all stages cholesterol comprised greater than 50% of the total sterols, and in cercariae and schistosomula desmosterol comprised 38 and 21% of the total sterols, respectively. The other three sterols, campesterol, stigmasterol, and beta-sitosterol, made up approximately 10% of the total. The same five sterols found in cercariae and schistosomula were present in the hepatopancreas of uninfected snails but with a much higher desmosterol concentration in the parasite, 38%, than in the snail, 2%. As in cercariae and schistosomula the three minor sterols comprised approximately 10%. Thus, the sterol composition of cercariae and schistosomula was similar but not identical to that of the snail host. Phosphatidylcholine was the major phospholipid of all three stages (50%) as determined by two HPLC procedures. The remaining phospholipids consisted of phosphatidylethanolamine, phosphatidylserine, and phosphatidylinositol. In addition, in adults there were small quantities of sphingomyelin and lysophosphatidylcholine. The percentage of each phospholipid was similar among stages with the exception of a slight increase in phosphatidylserine in adults compared to cercariae and schistosomula. These results show that a characteristic lipid composition is found in cercariae, schistosomula, and adults.

Human monocyte-derived macrophages are lysed by schistosomula of Schistosoma mansoni and fail to kill the parasite after activation with interferon gamma

In this study was examined the interaction between schistosomula of Schistosoma mansoni and human monocyte-derived macrophages activated with interferon gamma (IFN-gamma). Peripheral blood monocytes were matured for 6 days and activated by further culture with IFN-gamma (600 U/ml). These IFN-gamma-treated monocyte-derived macrophages are cytotoxic for the tumor cell line K562, which is not killed by nonactivated monocyte-derived macrophages. Activated monocyte-derived macrophages were incubated with schistosomula at ratios of 10(3):1 and 10(4):1 in the presence of serum pooled from patients with schistosomiasis. This antiserum promoted an increased adherence of cells to the parasite. However, the activated monocyte-derived macrophages failed to kill the schistosomula under all conditions tested. On the contrary, the monocyte-derived macrophages were killed by schistosomula in a time-dependent and antibody-dependent manner, which was most evident at a lower effector/target ratio, 200:1. Electron microscopy showed that monocyte-derived macrophages were lysed on the surface of schistosomula. Further, both monocyte-derived macrophages and contaminating blood platelets fused with the parasite surface membrane, so that the cell plasma membrane and the outer tegumental membrane formed a hybrid membrane. The results indicate that matured human monocyte-derived macrophages activated by IFN-gamma are unable to kill schistosomula. Instead, the effector cells fuse with the parasites and are lysed by them.

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

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

Schistosoma mansoni: human serum and release of proteins from schistosomula

Radioiodinated surface proteins of schistosomula of Schistosoma mansoni, including those involved in low density lipoprotein binding, are released into a defined culture medium at 37 C at slower rates than proteins from schistosomula incubated in a serum-containing medium. When schistosomula were incubated at 4 C, a higher degree of reassociation of the same proteins into the parasites was detected. Purified human low density lipoproteins and a fraction containing very low density lipoprotein plus chylomicrons were also able to promote the release of iodinated proteins from the parasites. These observations suggest that serum may play a role in accelerating the turnover of membrane components in schistosomula.

Identification and characterization of a polysaccharide-containing antigen from Schistosoma mansoni eggs which cross-reacts with the surface of schistosomula

Antisera were produced by immunizing rabbits with either a trichloroacetic acid-soluble fraction, or a high molecular weight (Mr) fraction of Schistosoma mansoni SEA (a saline-soluble fraction of homogenized egg). Both of these sera reacted monospecifically in immunoelectrophoresis against unfractionated SEA, recognizing a cathodally migrating antigen. This antigen had been identified previously as being responded to by S. mansoni-infected mouse sera, and has been designated K3 (Kappa 3). The rabbit antisera were used to partially characterize antigen K3 as having Mr in the range greater than 750-70 K, and being resistant to boiling, resistant to the action of proteases, but sensitive to periodate. It partially binds to Concanavalin A. In addition to SEA, the antigen was present in homogenized cercariae and schistosomula, but not adult worms, and it was also present in detergent extracts of intact cercariae and schistosomula. Using an antibody-dependent cell adherence assay, anti-K3 serum was found to react with the surface of live cercariae and with the surface of schistosomula recovered from the skin of mice infected up to 48 h previously. Anti-K3 serum also reacted with the surface of S. bovis, S. haematobium and to a lesser extent S. japonicum schistosomula.

Actin and intermediate-sized filaments of the spines and cytoskeleton of Schistosoma mansoni

The organization of spines and filaments in whole worms and cytoskeletal fractions of adult Schistosoma mansoni was investigated. The ultrastructure of the spine revealed a closely packed filamentous organization of 3.5- to 5.6-nm elements and electron-lucent areas. Spines were surrounded at the base by electron-dense bodies and membrane invaginations, and covered at the tip by the syncytial surface membrane. Filaments, 7.5-11.1 nm in diameter, were closely associated with the base of the spines, between muscles, near mitochondria or nuclei, and in spaces of the subtegument. Cytoskeletal fractions prepared by homogenizing adults in Tris-HCl buffer, containing 0.6 M KCl and 1.0% Triton X-100, represented 19%-25% and 32%-38% of wet weight of males and females, respectively. The fractions contained nuclei, spines, 8 to 11 nm filaments, myofibrils, and granules. Vitellaria and egg shells were abundant in fractions from females. Six polypeptides with estimated molecular weights of 130, 96, 84, 78, 74 and 43 kdaltons were identified by sodium dodecyl sulfate-polyacrylamide gel electrophoresis as the major components of the cytoskeleton. Monoclonal antibody to chicken actin (MAA) was localized predominantly in surface spines and tubercles of adult schistosomes by the indirect immunofluorescence test, while immune serum from infected mice reacted less specifically with the tegument. A 43-kdalton polypeptide with electrophoretic mobility identical to that of vertebrate actin, identified in cytoskeletal and tegumental fractions of adult worms, reacted positively with MAA on immunoblotting.(ABSTRACT TRUNCATED AT 250 WORDS)

Schistosoma mansoni: phospholipid methylation and the escape of schistosomula from in vitro cytotoxic reaction

The ability of Schistosoma mansoni schistosomula to evade in vitro cytotoxic activity of antibodies plus complement is shown to be increased by incubation with Concanavalin A (Con A) or with non-immune inactivated human serum. This effect was not observed if S-adenosyl-homocysteine (SAH) a methyltransferase inhibitor was added to the incubation medium. Methyl group incorporation occurs in schistosomulum phospholipids if parasites are incubated in Earle's balanced salt solution. This incorporation is increased by Con A addition and this increase is inhibited by SAH. Supernatants of schistosomula incubated in culture media containing Con A were able to promote phospholipid methylation, showing that methyltransferases were liberated into the culture media. The possible roles played by these phenomena in host-parasite interactions are discussed.

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.

Schistosomula of Schistosoma mansoni use lysophosphatidylcholine to lyse adherent human red blood cells and immobilize red cell membrane components

Human red blood cells (RBCs) adhere to and are lysed by schistosomula of Schistosoma mansoni. We have investigated the mechanism of RBC lysis by comparing the dynamic properties of transmembrane protein and lipid probes in adherent ghost membranes with those in control RBCs and in RBCs treated with various membrane perturbants. Fluorescence photobleaching recovery was used to measure the lateral mobility of two integral membrane proteins, glycophorin and band 3, and two lipid analogues, fluorescein phosphatidylethanolamine (Fl-PE) and carbocyanine dyes, in RBCs and ghosts adherent to schistosomula. Adherent ghosts manifested 95-100% immobilization of both membrane proteins and 45-55% immobilization of both lipid probes. In separate experiments, diamide-induced cross-linking of RBC cytoskeletal proteins slowed transmembrane protein diffusion by 30-40%, without affecting either transmembrane protein fractional mobility or lipid probe lateral mobility. Wheat germ agglutinin- and polylysine-induced cross-linking of glycophorin at the extracellular surface caused 80-95% immobilization of the transmembrane proteins, without affecting the fractional mobility of the lipid probe. Egg lysophosphatidylcholine (lysoPC) induced both lysis of RBCs and a concentration-dependent decrease in the lateral mobility of glycophorin, band 3, and Fl-PE in ghost membranes. At a concentration of 8.4 micrograms/ml, lysoPC caused a pattern of protein and lipid immobilization in RBC ghosts identical to that in ghosts adherent to schistosomula. Schistosomula incubated with labeled palmitate released lysoPC into the culture medium at a rate of 1.5 fmol/h per 10(3) organisms. These data suggest that lysoPC is transferred from schistosomula to adherent RBCs, causing their lysis.

The lateral diffusion of lipid probes in the surface membrane of Schistosoma mansoni

The technique of fluorescence recovery after photobleaching was used to measure the lateral diffusion of fluorescent lipid analogues in the surface membrane of Schistosoma mansoni. Our data reveal that although some lipids could diffuse freely others exhibited restricted lateral diffusion. Quenching of lipid fluorescence by a non-permeant quencher, trypan blue, showed that there was an asymmetric distribution of lipids across the double bilayer of mature parasites. Those lipids that diffused freely were found to reside mainly in the external monolayer of the outer membrane whereas lipids with restricted lateral diffusion were located mainly in one or more of the monolayers beneath the external monolayer. Formation of surface membrane blebs allowed us to measure the lateral diffusion of lipids in the membrane without the influence of underlying cytoskeletal structures. The restricted diffusion found on the normal surface membrane of mature parasites was found to be released in membrane blebs. Quenching of fluorescent lipids on blebs indicated that all probes were present almost entirely in the external monolayer. Juvenile worms exhibited lower lateral diffusion coefficients than mature parasites: in addition, the lipids partitioned into the external monolayer. The results are discussed in terms of membrane organization, cytoskeletal contacts, and biological significance.

Schistosoma mansoni: killing of transformed schistosomula by the alternative pathway of human complement

The interaction of mechanically transformed schistosomula of Schistosoma mansoni with the alternative pathway of human complement was studied in vitro. To detect early changes in transformation, the schistosomula were prepared at a low temperature and used immediately. As shown previously, freshly transformed schistosomula were highly susceptible to killing by normal human serum and by C4-depleted normal human serum. This serum activity was concentration dependent and was markedly reduced on a twofold serum dilution. Upon incubation at 37 C in defined synthetic medium, schistosomula rapidly became refractory to killing by the alternative pathway of complement. After 1 hr of incubation at 37 C, the percentage of schistosomula which were resistant to killing increased from 16 to 85. This conversion was accompanied by a fivefold decrease in deposition of C3b on schistosomula which had been exposed to 37 C for 1 hr and then further incubated with C4-depleted normal human serum. The following events occurred concomitantly during incubation of freshly transformed schistosomula at 37 C with a half-life of 30-60 min: (1) Decrease in activation and consumption of the alternative pathway of complement by schistosomula; (2) appearance of a strong complement consuming activity in the supernatant of incubating schistosomula; and (3) shedding of protein- and carbohydrate-containing substances from the surface of schistosomula into the supernatant. Isolated external membranes of freshly transformed schistosomula consumed the alternative pathway of complement to a greater extent than membranes of schistosomula preincubated in medium at 37 C. The results demonstrate that transformed schistosomula acquire resistance to complement killing via the alternative pathway by shedding complement-activating substances.(ABSTRACT TRUNCATED AT 250 WORDS)

Ultrastructure of the attack of eosinophils stimulated by blood mononuclear cell products on schistosomula of Schistosoma mansoni

Purified human eosinophils were treated with peripheral blood mononuclear cell supernatants containing eosinophil cytotoxic enhancing activity (ECEA). Schistosomula of Schistosoma mansoni which had been coated either with antibody (Ab) from the sera of infected patients or with the lectin concanavalin A (Con A) were incubated with ECEA-treated and untreated cells for 2 minutes to 12 hours and examined ultrastructurally. Killing was assayed at 18 hours. ECEA caused an increase in the killing of Ab-coated worms, but Con-A-coated worms were not killed by either ECEA-treated or untreated cells. Eosinophils began to degranulate on Ab-coated worms within 2 minutes and continued to degranulate, so that by 12 hours about half of the parasites had greater than 50% of their surface covered by discharge material. The ECEA-treated cells degranulated more than the untreated cells. There was much less discharge material on Con-A-coated worms than on Ab-coated worms. Eosinophils adhered to discharge material on the surface of both Ab- and Con-A-coated parasites. At 3 and 12 hours, lysed cells and cell fragments were also seen adhering to discharge material. In the absence of discharge material the cells adhered to residual glycocalyx or to the tegumental outer membrane. These studies suggest that eosinophils kill schistosomula by progressively degranulating onto their surface over many hours and that the increased toxicity caused by ECEA is due to an increase in discharge.

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 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.

Serum-induced expression of a surface protein in schistosomula of Schistosoma mansoni: a possible receptor for lipid uptake

When freshly transformed schistosomula of Schistosoma mansoni are incubated with human serum, a protein doublet (molecular weight approximately 45 kDa) is expressed on the surfaces of the parasites; parasites incubated in defined media fail to express the doublet proteins. A 30 min exposure to serum is sufficient to induce the expression of the doublet, and even when the parasites are separated from the serum by a dialysis membrane, the doublet is still expressed. The doublet proteins are shown to be synthesized by cercariae, but not by schistosomula; they can be extracted using detergents and immunoprecipitated by specific antisera. Following expression of the doublet, purified low density lipoproteins from human serum interact with the schistosomula, become adsorbed onto their surface membranes and are possibly internalized and degraded.

Tegument surface membranes of adult Schistosoma mansoni: development of a method for their isolation

Several approaches to surface membrane stripping have been applied to the adult schistosome. Membrane removal was evaluated by the use of different extrinsic and intrinsic markers of which alkaline phosphatase proved to be the most reliable. After initial studies employing incubation of worms in buffer alone, Triton X-100 or freeze/thaw, the last method was chosen for development. The final method applies a single freeze/thaw step to adult worms in balanced salt solution followed by short bursts of agitation on a vortex mixer to release the tegument. Differential and density gradient steps subsequently yield a final membrane pellet enriched over 130 times in surface alkaline phosphatase. The method has been characterized during its development using electron microscopy and enzyme markers for contaminant worm fractions.

The exposed carbohydrates of schistosomula of Schistosoma mansoni and their modification during maturation in vivo

Lectins labeled with 125I or conjugated with fluorescein were employed to study the carbohydrates on the surface of different stages of schistosomula of Schistosoma mansoni. Newly transformed schistosomula were shown to bind concanavalin A; the 60 000 and 120 000 dalton agglutinins from Ricinus communis; the fucose-binding protein from Lotus tetragonolobus; wheat germ agglutinin and peanut agglutinin. Soybean agglutinin, Ulex europaeus agglutinin and Dolichos biflorus agglutinin, on the other hand, failed to bind to the schistosomulum surface. The binding of peanut and soybean agglutinin was unaffected by pretreatment of the parasites with neuraminidase. Binding of concanavalin A, the 120 000 dalton agglutinin from Ricinus communis, wheat germ agglutinin and peanut agglutinin to the surface of 5-day schistosomula, recovered from the lungs of mice, was also demonstrated. In each case, however, the level of binding was approximately 70% less than that observed with newly transformed schistosomula and the binding of the fucose-binding protein from L. tetragonolobus practically disappeared. In contrast with newly transformed schistosomula, lung stage schistosomula, pretreated with neuraminidase, displayed a significant increase in the binding of peanut and soybean agglutinin. The results indicate that a significant alteration in the surface carbohydrates of S. mansoni occurs during in vivo maturation of the parasite. This change may contribute to the organism's ability to survive in the vertebrate host.

Human neutrophils endocytose multivalent ligands from the surface of schistosomula of Schistosoma mansoni before membrane fusion

Human buffy coat cells adhering to schistosomula of Schistosoma mansoni that were preincubated in fluorochrome-conjugated concanavalin A (Con A), wheat germ agglutinin, lentil lectin, or purified IgG from a hyperimmunized rabbit, were examined by fluorescence and transmission electron microscopy and by freeze-fracture. All four fluorochrome-conjugated multivalent ligands were homogeneously distributed on the parasite surface after preincubation. Within 1-3 h after the addition of cells, large areas of nonfluorescence, 10-20 micrometer in diameter, were seen on the parasite surface. In addition, the fluorochromes were observed in granules within the cells. Electron microscope autoradiography of worms preincubated with 125I-Con A showed silver grains evenly distributed over the tegumental membrane. After the addition of cells, grains were seen over phagolysosomes in the cytoplasm of neutrophils adhering to the parasites. In addition, no grains were present over large areas of the tegumental membrane, which still retained its normal architecture, or over fusions between the neutrophil plasma membrane and the outer tegumental membrane. Rabbit IgG formed an electron-dense layer on the tegumental membrane which was endocytosed by neutrophils. Both neutrophils and eosinophils fused with the parasite in areas containing no electron-dense material on the surface. It is concluded that human neutrophils will endocytose a variety of multivalent ligands from the surface of schistosomula, which probably accounts for the failure of neutrophils to kill the parasite and acts to clear the parasite surface of both antigen and antibody. Presumably, the components of the parasite surface which have originally bound the ligands are also endocytosed since surface components labeled by galactose oxidase and NaB3H4 are taken into cells when examined by light microscope autoradiography. Finally, membrane fusion occurs in areas devoid of multivalent glands, which suggests that these ligands serve to bring the cells and parasites close together, but the actual fusigens probably reside in the lipids in the outer tegumental membrane.

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.