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

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

The cercarial glycocalyx of Schistosoma mansoni

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

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

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

Schistosoma mansoni: immunogenic glycoproteins of the cercarial glycocalyx

Immunochemical studies at the level of the light and electron microscope showed that a monoclonal antibody, 128C3/3, was directed to an epitope in the glycocalyx of Schistosoma mansoni cercariae. Immunoprecipitation of surface labeled cercarial extracts with this monoclonal antibody demonstrated that the glycocalyx is composed of at least five components, including a very large molecular size polypeptide and polypeptides of 220, 180, 170, and 15 kDa. After transformation of cercariae to schistosomula, these polypeptides were shed from the surface and were therefore no longer accessible to surface labeling. Monoclonal antibody 128C3/3 was also reactive with a 38 kDa polypeptide from schistosomula; this polypeptide was weakly expressed on the surface of cercariae. Analysis of immunoprecipitates of radioiodinated protein extracts of cercariae, newly transformed schistosomula, and 36 hr in vitro cultured schistosomula showed that the 180 and 170 kDa polypeptides continued to be expressed within the organism following transformation, but were not accessible to surface labeling. Lectin binding studies revealed differences in the oligosaccharide composition of the six polypeptides. With the exception of the 15 kDa antigen, all the polypeptides reactive with 128C3/3 were highly immunogenic in infected mice and humans.     

The ability of fractionated sera from animals vaccinated with irradiated cercariae of Schistosoma mansoni to transfer immunity to mice

To study the role of IgG and IgM isotypes found in sera of mice or rabbits immunized with irradiated cercariae in schistosome immunity, the respective sera were fractionated by protein A chromatography. Both the protein A-bound and unbound fractions of vaccinated mouse serum (VMS) showed reactivities in ELISA assay using NP-40 membrane extracts of 3-hr schistosomula as antigens and in indirect immunofluorescence assay (IIF) using live 3-hr schistosomula. Both the protein A-bound and unbound fractions possessed high levels (84% and 76%, respectively) of complement-mediated cytotoxicity against schistosomula in vitro. The IgG- and IgM-containing fractions each conferred passive protection (30% and 20%) against challenge infection, although at a lower level when compared to unfractionated VMS (42%). These data demonstrate that in the mouse model both IgG and IgM can recognize epitopes on the surface of schistosomula, mediate cytotoxicity in vitro, and provide passive protection in vivo. Similarly, the protein A-bound and unbound fractions of vaccinated rabbit serum (VRS) were also shown to be positive in ELISA and IIF. The IgG- and IgM-containing fractions each possessed high levels (95% and 85%, respectively) of complement-dependent cytotoxicity against schistosomula in vitro. In contrast to VMS fractions, the IgG fraction of VRS conferred a similar level (28%) of in vivo protection as unfractionated VRS when injected into mice no later than 6 days after challenge. Moreover, the IgG fraction of VRS was still able to provide passive protection to mice when given as late as 15 days postinfection, but failed to confer protection when injected at 24 or 35 days postinfection.(ABSTRACT TRUNCATED AT 250 WORDS)     

In vitro effects of hypothalamic-pituitary-adrenal axis (HPA) hormones on Schistosoma mansoni.

The effects of in vitro treatment of cercariae, schistosomula, and adult worms of Schistosoma mansoni with 4 hypothalamic-pituitary-adrenal (HPA) axis hormones are described. Dehydroepiandrosterone (DHEA) had the strongest effect on viability. Cercariae were more susceptible to this hormone than schistosomula and adults. Mechanically transformed schistosomula showed 100% mortality (determined microscopically by progressive internal disorganization, development of lucent areas in the cytoplasm, and progressive loss of motility) after 48 hr, whereas physiologically induced schistosomula were more resistant, maintaining viability for up to 5 days of exposure. Males were considerably less sensitive than females to the lethal action of DHEA. When adult worms were paired, DHEA lethality was markedly reduced, with viability beginning to decrease only after 4 days in culture. Cortisol reduced the viability of each of the stages tested about equally. Corticotropin-releasing hormone (CRH) and adrenocorticotropin (ACTH) did not affect the viability of any stage. DHEA and cortisol significantly inhibited in vitro oviposition, whereas CRH and ACTH did not. DHEA and cortisol exerted their effects on schistosome viability and oviposition in a concentration-dependent manner. These results suggest possible new avenues for the control of schistosomiasis.     

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

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

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 japonicum (Chinese): Changes of the tegument surface in cercariae, schistosomula and juvenile parasites during development

, , , and 1988. Schistosoma japonicum (Chinese): changes of the tegument surface in cercariae, schistosomula and juvenile parasites during development. International Journal for Parasitology18: 1093–1104. The surface of cercariae of S. japonicum (Chinese) and changes following their transformation into schistosomula were observed at 0.5,1, 3,6,12,24 and 48 hand 5,7,10 and 15 days by scanning electron microscopy. The cercarial surface shows two distinct regions: on the head and the body it is mildly undulating and covered throughout with numerous spines that are partially embedded in a thick layer of glycocalyx; on the tail it is highly folded into tall and thin circumferential ridges, spines are confined to the dorsal and ventral aspects and are prominent due to a thinner glycocalyx. Between 0.5 and 12 h following skin penetration, the surface of schistosomula is gradually cleared of glycocalyx, while small blebs and slender microvilli project out from the glycocalyx-free area and from spines. Subsequently, these structures are detached from the surface and thus responsible for the shedding of the original cercarial membrane and glycocalyx. Between 24 and 48 h, schistosomula show little change in the body size in comparison to earlier stages, and most of the surface is still covered with spines but devoid of blebs and microvilli. From day 2 onwards schistosomula are lengthened but with little net growth. Spines decrease in the middle region of the body; and the surface is invaginated by small pits and folded into thin ridges, which result in rapid increase of the surface area. Between days 5 and 7 schistosomula elongate further, and the disappearance of the spines in the middle region becomes even more pronounced, while those remaining are confined only to the anterior and posterior extremities. Ridges and pits are more developed, and the former begin to show regular foldings throughout all parts of the body. Between days 7 and 10 schistosomula grow rapidly and the body is quadrupled in size. Between days 10 and 15 sexes can be differentiated. The male has a flat ovoid shape body, whose ridges and pitting on the surface are highly developed almost to the same extent as in adult parasites, while spines remain mostly on the posterior end. Sensory papillae greatly increase in number, especially on the ventral and lateral aspects and around the suckers. The surface of the female is relatively smooth; ridges are developed only on the posterior part, while the remaining surface is flat and extensively pitted. Spines are present throughout but less concentrated in the middle region.     

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

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

Role of eosinophils in the destruction of schistosomula of Schistosoma mansoni in vivo (preliminary report)

Schistosoma mansoni cercariae mechanically transformed into schistosomula were injected, either dead or alive, into the tail vein (2.000 larvae/0,15 ml) of Balb/c mice which were either previously infected with S. mansoni (10 weeks/50 cercariae) or non-infected. Histological examination of the lungs 24, 48, 72 and 96 hours after injection revealed that inflammatory reaction around schistosomula occurred only in the groups injected with dead schistosomula (killed by freezing and thawing). In non-infected animals the reaction was predominantly macrophagic while in those infected many eosinophils appeared around the dead larvae. These results are at variance with those obtained in vitro and suggest that in vivo the participation of eosinophils in the schistosomulum induced reaction in sensitized animals is secondary to the death of the larvae.     

IgM antibodies recognizing carbohydrate epitopes shared between schistosomula and miracidia of Schistosoma mansoni that block in vitro killing

A series of monoclonal antibodies (mAb) was raised in mice against Schistosoma mansoni, which recognized a carbohydrate determinant on a major Mr greater than 200,000 schistosomulum surface antigen. These mAb cross-reacted with the surface of cercariae and miracidia and with schistosomula of S. haematobium and S. bovis. Other mAb were generated that only recognized a Mr 20,000 schistosomulum surface antigen; they did not cross-react with eggs or miracidia and were species specific. The anti-Mr 20,000 mAb of the IgG1 isotype exhibited high levels of complement-dependent cytotoxicity to schistosomula in vitro. IgM mAb that recognized carbohydrate epitopes of the Mr greater than 200,000 surface antigen blocked the lethal activity of the anti-Mr 20,000 mAb. The IgM anti-Mr greater than 200,000 mAb also reduced complement-dependent cytotoxicity of serum from mice vaccinated with irradiated cercariae.     

Protective monoclonal antibodies from mice vaccinated or chronically infected with Schistosoma mansoni that recognize the same antigens

An IgM monoclonal antibody, designated mAb 1.G1, has been generated from spleen cells of mice immunized with irradiated Schistosoma mansoni cercariae. As determined by indirect immunofluorescence, mAb 1.G1 binds to the surface membrane of schistosomula and to the ciliated plates of miracidia. mAb 1.G1 also binds to the protonephridial systems of live adult worms and denuded, acetone-fixed schistosomula. Western blot analysis shows that the target epitope of this mAb is found on Nonidet P-40-solubilized schistosomular antigens ranging in molecular size from 85 to 130 kDa and ciliated plate antigens of miracidia at 92, 95, and 102 kDa. The recognized epitope in an 8 M urea adult worm extract is found on a 97-kDa molecule. In addition, mAb 1.G1 mediates a high level of complement-dependent cytotoxic activity against schistosomula when used in an in vitro assay. In passive immunization experiments, approximately 40% protection was provided mice when mAb 1.G1 was administered either at the time of challenge or when given 8 days postchallenge. However, when administered 15 days postchallenge, mAb 1.G1 failed to mediate passive protection. The ability of mAb 1.G1 to mediate protection in vivo correlates with its recognition of epitopes on the surfaces of live schistosomula up to 8 days but not at 15 days. Western blot analysis showed that the antigens were contained within Nonidet P-40 extracts of schistosomula during the same time period. Furthermore, a second monoclonal antibody (mAb 4.4B) derived from mice chronically infected with S. mansoni exhibits the identical properties as described for mAb 1.G1.     

A major role for carbohydrate epitopes preferentially recognized by chronically infected mice in the determination of Schistosoma mansoni schistosomulum surface antigenicity

A radioimmunoassay that makes use of whole schistosomula and 125I-labeled protein A has been used to characterize and to quantify the binding of antisera to the surface of 3 hr mechanically transformed schistosomula of Schistosoma mansoni. This technique facilitates the determination of epitopes on the schistosomula in addition to those detected by surface labeling and immunoprecipitation. By using this technique, it has been demonstrated that there is a much greater binding to the parasite surface of antibodies from chronically infected mice (CMS) than of antibodies from mice infected with highly irradiated cercariae (VMS), and CMS recognizes epitopes that VMS does not. Treatment of the surface of the schistosomula with trifluoromethanesulphonic acid and sodium metaperiodate has suggested that the discrepancy of the binding between the two sera is due to the recognition of a large number of additional epitopes by CMS, which are carbohydrate in nature. Some of the carbohydrate epitopes are expressed on the previously described surface glycoprotein antigens of Mr 200,000, 38,000, and 17,000.     

Schistosoma mansoni: identification and characterization of schistosomula polypeptides

Schistosomula proteins separated by a two-dimensional (NEPHGE) gel system identify 94 major silver-stained polypeptides. When compared to polypeptides similarly separated from cercariae and adult worms; cercariae share the same polypeptides as schistosomula, adult worms share ca. 60% of the polypeptides. A group of five schistosomula polypeptides 15-31 kDa (apparent pI 8.2-8.9) was not found in adult worm extracts. To identify which polypeptides were immunogens, Western blots of the NEPHGE gels were probed with sera either from humans with chronic schistosomiasis or from mice vaccinated with irradiated cercariae. For characterization studies, polyclonal antibodies were made against the five schistosomula-specific and selected immunogenic polypeptides by immunizing mice with silver-stained spots removed from NEPHGE gels. We show that the polyclonal serum against a polypeptide of 12.5 kDa and an apparent pI of 6.70 mediated complement and eosinophil-dependent killing of schistosomula in an in vitro assay. Epitopes recognized by antibody against the 12.5-kDa polypeptide show a diffuse distribution and are found on flame cells of the excretory system of the schistosomula.     

Schistosoma mansoni: in vitro conversion of cercariae to schistosomula.

Schistosoma mansoni cercariae were incubated for 3-5h at 37 degrees C in various test solutions, and the rate and extent of conversion of the cercariae to schistosomula were determined. Criteria used to identify schistosomula included: (1) loss of cercarial tail, (2) viability of organisms in saline but not in water, (3) pre-acetabular gland evacuation and (4) ability to survive in culture. Incubation of cercariae in rat chamber fluid resulted in organisms which were water sensitive, but retained their tails and pre-acetabular gland contents. Conversion to water sensitivity was not blocked by 0-01 M EDTA.     

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.     

Schistosoma mansoni: complexity of antigenic and nonantigenic surface polypeptides

Two-dimensional gel analysis of the surface polypeptides of the schistosomula stage of Schistosoma mansoni resolved a complex pattern of approximately 20 polypeptides. The majority of these were identified as immunogenic since they were immunoprecipitated with antisera from chronically infected mice and from mice vaccinated with irradiated cercariae. However, several major surface polypeptides were not immunoprecipitated by sera from infected or immune mice and were presumed to be nonantigenic.     

The presence of antibody in mice chronically infected with Schistosoma mansoni which blocks in vitro killing of schistosomula

We have previously reported that IgM monoclonal antibodies (mAb) that recognize surface carbohydrate determinants shared between schistosomula, cercariae, and miracidia block antibody/complement dependent killing of schistosomula in vitro. Binding assays that make use of one of the IgM mAb labeled with 125I demonstrated that serum from chronically infected mice (CMS) contained high levels of competing antibody, whereas serum from mice vaccinated with irradiated cercariae (VMS) contained little antibody of this specificity. Absorption of CMS with cercariae that removed antibodies to schistosomulum surface carbohydrate determinants increased its ability to kill schistosomula in vitro; absorption of VMS with cercariae failed to alter the lethal activity of the serum. Furthermore, fractionation of CMS by protein A Sepharose chromatography demonstrated that the IgG fraction had an increased lethal activity compared with unfractionated serum; this result was not seen with VMS. Finally, the IgM fraction of CMS was shown to block in vitro killing of the IgG fractions of both CMS and VMS. These data suggest that the blocking activities observed with the IgM mAb are contained within the serum of chronically infected mice but not in the serum of mice vaccinated with irradiated cercariae.     

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.