Factors affecting surface changes in intact cercariae and cercarial bodies of Schistosoma mansoni

Biology of the schistosome lung-stage schistosomulum

Past and more recent research has examined the ultrastructure, metabolism, cell biology, genomics and post-genomics of schistosome schistosomula. These areas are considered and discussed in this review with particular emphasis on (1) the early migration phases through the host, (2) interaction of the host immune response with the parasite surface, (3) glucose uptake mechanisms, and (4) defining the transcriptional profiles of lung-stage schistosomula compared with other developmental stages using microarrays. The microarray profiling studies suggest caution is required when considering the use of schistosomes obtained by in vitro means for molecular or biochemical studies.

Induction cues for tegument formation during the transformation of Schistosoma mansoni cercariae

Adult schistosomes are parasitic blood flukes that have a continuous double lipid bilayered membrane surrounding the entire worm. This tegumental membrane is synthesised during invasion of the vertebrate host by free-swimming infectious forms called cercariae. As cercariae invade their final hosts they lose their tails and encounter a changing environment that includes altered temperature, sugar concentration and osmolarity. We have identified a glucose transporter protein designated SGTP4 that is found exclusively in the outer adult tegument and on membranous vesicles within the tegumental cytoplasm. By using immunofluorescence analysis to monitor the appearance and distribution of SGTP4 we can track the process of new tegumental membrane formation and examine the cues that trigger this developmental pathway. Cercariae in water do not transform their tegument while those incubated in rich medium do so rapidly. We have examined which of the many constituents of rich medium are responsible for triggering this transformation. Incubation in a solution of moderate osmolarity (120 mOsM PBS) is sufficient by itself to trigger tegument transformation, albeit at a slower rate relative to incubation in rich medium. Adding either glucose (to 100 mM) to the solution or increasing the temperature of incubation (from 22 degrees C to 37 degrees C) further increased the rate of tegument biogenesis. The introduction of glucose together with an increase in the incubation temperature further accelerated the process, suggesting that these factors act synergistically to promote transformation rates. The critical nature of osmolarity in inducing the process is highlighted by the fact that transformation proceeds as efficiently in 360 mOsM alone as it does in rich medium. While the fatty acids linolenic acid (cis-9, cis-12, cis-15-octadecatrienoic acid at 1 mM) and capric acid (Decanoic acid, at 0.1 mM) have both been proposed to stimulate tegumental transformation, we show that neither promotes the morphogenesis of a normal schistosomulum tegument. The schistosomicide praziquantel (to 1 mM) has no detectable effect on new tegument formation.

Ultrastructural and biochemical detection of biotin and biotinylated polypeptides in Schistosoma mansoni

Biotinylation is proposed for the identification of surface proteins in Schistosoma mansoni using the streptavidin-HRP conjugate for the detection of labeled polypeptides. However, control samples also showed several endogenous biotinylated polypeptides. In an attempt to determine the possibility of nonspecific binding between the streptavidin-HRP conjugate and polypeptides from S. mansoni, the conjugate was blocked with biotinamidecaproate-N-hydroxysuccinimide ester (BcapNHS) before biotin-streptavidin blotting. No bands were detected on the nitrocellulose sheet, demonstrating the specific recognition of biotin by the streptavidin present in the conjugate. Whole cercariae and cercarial bodies and tails showed several endogenous biotinylated polypeptides. The biotin concentration was 13 micrograms/190,000 cercariae. Adult worms presented less endogenous biotinylated polypeptides than cercariae. These results may be due to changes in the environment from aerobic to anaerobic conditions when cercarial bodies (schistosomula) are transformed into adult worms and a decrease in CO2 production may occur. Cercariae, cercarial bodies and adult male worms were examined by transmission electron microscopy employing an avidin-colloidal gold conjugate for the detection of endogenous biotin. Gold particles were distributed mainly on the muscle fibers, but dispersed granules were observed in the tegument, mitochondria and cytosol. The discovery of endogenous biotin in S. mansoni should be investigated in order to clarify the function of this vitamin in the parasite.

Role of human decay-accelerating factor in the evasion of Schistosoma mansoni from the complement-mediated killing in vitro

Decay-accelerating factor (DAF) is a 70-kD membrane glycoprotein that prevents complement (C)-mediated hemolysis by blocking the assembly or accelerating the decay of C3 convertase. Purified DAF is known to incorporate into the membrane of DAF-deficient cells, inhibiting lysis. Since Schistosoma mansoni is a blood-dwelling parasite, we investigated whether DAF can be transferred from human erythrocytes to the worm and protect it against C-mediated killing in vitro. We have found that schistosomula (schla) incubated with normal human erythrocytes (N-HuE), but not with DAF-deficient erythrocytes, become resistant to C damage in vitro. Protected parasites acquire a 70-kD surface protein which can be immunoprecipitated by anti-DAF antibodies. The acquired resistance is abrogated by treatment of N-HuE-incubated parasites with anti-DAF antibody. These results indicate that, in vitro, N-HuE DAF can be transferred to schla, and suggest its participation in preventing their C-mediated killing. This could represent an important strategy of parasites to evade the host's immune response in vivo.

Aerobic to anaerobic transition in the carbohydrate metabolism of Schistosoma mansoni cercariae during transformation in vitro

Schistosoma mansoni cercariae in water were shown to possess a largely aerobic energy metabolism, the Krebs cycle being the main terminal of carbohydrate breakdown. A metabolic transition towards a more anaerobic breakdown of carbohydrate could be achieved by incubation conditions which also stimulated biological transformation. Incubation of cercariae in a simple salt medium containing 5 mM glucose induced such a metabolic transition: beside carbon dioxide large amounts of lactate and pyruvate were excreted. The results indicate that the production of pyruvate was coupled to electron transfer in the respiratory chain. Some aspects of this unusual pyruvate production are discussed. The observed change in the end-product pattern of carbohydrate breakdown is very rapid: most of the switch occurred within 2 h. Our results show that the metabolic transition was triggered by the biological transformation itself, or by the same event that induces the biological transformation. The metabolic and the biological changes proceeded synchronously.

Schistosoma mansoni: analysis of cercarial transformation methods

Four methods of transforming cercariae to schistosomulae in vitro in ELAC buffer (pH 7.2, 37 C, 0-6 hr incubation) were compared in relation to biochemical and ultrastructural characteristics. The transformation methods used were chemical (3 mM linoleate), mechanical (centrifuge/vortex), mechanical/chemical, and heat (incubation at 37 C). Ultrastructural characteristics examined were based on the presence or absence of glycocalyx, heptalaminate membrane, cyton granules, and nuclear condition. Two EM fixation methods were used. Biochemical parameters assayed were loss of water tolerance (uptake of trypan blue dye), eicosanoid biosynthesis (PGE, LTB4, and 5-HETE), protein synthesis (leucine uptake), RNA synthesis (uracil and orotic acid uptake), and DNA synthesis (thymidine uptake). EM characteristics were remarkably similar for all transformation methods except heat incubation, with transformed cercariae evidencing the characteristics of schistosomulae (cyton granule migration, absence of glycocalyx and heptalaminate membrane); however, euchromatic nuclei could not be demonstrated using in vivo or in vitro transformation methods. Despite the ultrastructural similarities between transformation methods, biochemical data demonstrated that the resultant organisms were quite different. The chemical transformation method gave the highest rate of loss of water tolerance and eicosanoid production. RNA and protein synthesis were not correlated to ultrastructural changes and were highest in those organisms undergoing mechanical transformation methods, significantly higher than in those cercariae transformed by the chemical method. DNA synthesis was not demonstrated using any transformation method, although thymidine uptake did occur. Our data indicate substantial biochemical differences exist between morphologically similar organisms. Thus, experiments using any type of artificially transformed schistosomule must be interpreted with caution until additional biochemical and physiological studies on cercarial transformation are undertaken.

Characterization of chemical stimuli for the penetration of Schistosoma mansoni cercariae. II. Conditions and mode of action

The mode of action of chemical substances which trigger the penetration of S. mansoni cercariae into agar substrata is studied. The effectiveness of these substances is largely independent on their polarity and water solubility. Thus, they do not seem to act by a passive membrane permeation process, but they may interact with specific receptor sites, which are characterized. The receptor sites seem to respond to the following chemical characteristics of the stimulating aliphatic hydrocarbon chain: Carboxylic end group, lipophilic end group, chain length, cis-double bond. The penetration stimulating substances cause, even in cercariae in free water, a transformation of the tegument, manifested as a reduction of the Cercarienhüllen-Reaktion and a loss of osmotic protection.

[Suppression of parasitemia in rodent filariasis (Litomosoides carinii) by immunization with BCG and microfilaria. I. Intracutaneous inoculation of BCG]

After intracutaneous inoculation of BCG and challenge by subcutaneous injection of infective larvae of Litomosoides carinii, the parasitaemia of the filarial infection in cotton rats remains significantly lower when BCG and larvae are applied in the region of the same popliteal and ileal lymph nodes. However, when the infective larvae are directed to other regional lymph nodes (Ln cubitales and axillares), the depression of microfilaraemia is missed. The worm load (recovery rate) and the expulsion of microfilariae by the adult worms are not influenced by the BCG inoculation. Obviously BCG stimulates the lymphatic tissue unspecifically, and the infective larvae produce the first antigen contact, which is boostered by the microfilariae at the onset of patency. When the intracutaneous BCG inoculation is combined with specific antigen stimulation by simultaneous injection of blood microfilariae in the region of the same lymph nodes, the microfilaraemia of the challenge infection disappears completely or remains extremely low.

Schistosoma mansoni: evidence for a role of serum factors in protecting artificially transformed schistosomula against antibody-mediated killing in vitro

Artificially transformed schistosomula of Schistosoma mansoni develop a consistent but small protection against the lethal effects of antibody plus complement when cultured for 24 h in a chemically defined medium. In contrast, they become rapidly resistant to antibody plus complement, when cultured in the presence of a complex medium consisting of equal parts of heat-inactivated rabbit serum and Earle's/lactalbumin or in defined medium supplemented with small amounts of heat-inactivated rabbit serum. Sephadex G-200 gel filtration revealed that the protective factor in rabbit serum is a macromolecule with a molecular weight between 7 and 19 S. Parasites cultured at 10 degrees C or in the presence of 200 microgram of puromycin show less serum-induced protection against the lethal effects of antibody plus complement than do controls.

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.

Schistosoma mansoni: the occurrence of microvilli on the surface of the tegument during transformation from cercaria to schistosomulum

Microvilli are developed on the surface of Schistosoma mansoni schistosomula during penetration of the host skin; they form rapidly but are lost approximately 90 min after penetration. Identical microvilli are also formed on schistosomula which have penetrated a mouse skin preparation in vitro, and on schistosomula prepared by mechanical separation of the tail from the body of the cercaria. The microvilli, which are limited by the trilaminate tegumental membrane of the cercaria, eventually degenerate and are cast off from the surface of the tegument. There is little change in the surface area of the schistosomulum at this time, and the formation and loss of microvilli coincides with the replacement of the cercarial tegumental membrane by the new heptalaminate membrane. It is suggested that during the cercaria/schistosomulum transformation, some intramembraneous components of the original cercarial membran e may migrate into the new heptalaminate membrane and thus be retained, while other peripheral components such as the glycocalyx are almost certainly lost.