A comparative proteomic study of the undeveloped and developed Schistosoma mansoni egg and its contents: The miracidium, hatch fluid and secretions

The schistosome egg is the key agent responsible both for transmission of the parasite from human to molluscan host, and is the primary cause of pathogenesis in schistosomiasis. Characterisation of its proteome is a crucial step in understanding the egg’s interactions with the mammalian host. We devised a scheme to isolate undeveloped eggs from mature schistosome eggs by Percoll gradient and then fractionate the mature egg into miracidial, hatch fluid and secreted protein preparations. The soluble proteins contained within the five preparations were separated by two-dimensional electrophoresis and their spot patterns compared by image analysis. Large numbers of representative spots were then excised and subjected to tandem mass spectrometry to obtain identities. In this way, the principal components of each sub-proteome were established. Chaperones were the most abundant category, with heat shock protein 70 (HSP70) dominant in the undeveloped egg and Schistosoma mansoni protein 40 (Smp-40) in the miracidium. Cytoskeletal proteins were expressed at similar levels in the undeveloped egg and miracidium, with tubulins the most abundant. The proteins of energy metabolism reflected the change from anaerobic to aerobic metabolism as the miracidium developed. None of the above categories was abundant in the hatch fluid but this peri-miracidial compartment was highly enriched for defence proteins such as thioredoxin. Hatch fluid also contained several host proteins and schistosome proteins of unknown function, highlighting its distinct nature and potentially its role. The egg secretions could not be compared with the other preparations due to their unique composition featuring the previously characterised IL-4-inducing principal of S. mansoni eggs (IPSE), Omega-1, egg secreted protein 15 (ESP15), a micro-exon gene 2 (MEG-2) protein and two members of the recently described MEG-3 family. This last preparation contains the subset of egg proteins that probably enables eggs to escape from host tissues and may also initiate granuloma formation, emphasising the need to establish fully the roles of its components in schistosome biology.     

Ribeiroia marini: pathogenesis and larval trematode antagonism in the snail, Biomphalaria glabrata

Larval trematode antagonism between Ribeiroia marini and Schistosoma mansoni was studied in the snail Biomphalaria glabrata. A laboratory-raised Puerto Rican strain of B. glabrata was exposed to single and double infections with given numbers of: (1) embryonated eggs of R. marini from laboratory rats, and (2) miracidia of S. mansoni from mice. Snails were maintained in outside environmental tanks in San Juan, Puerto Rico and larval trematode interactions were examined in a series of five experiments. Snails of all sizes were highly susceptible to single infections with R. marini. Rediae and cercariae caused extensive damage to the digestive gland and ovotestis resulting in premature death of snails. Heavily infected snails were castrated and stopped laying eggs. Snails infected first with S. mansoni were only partly susceptible to superinfection with R. marini given on Day 23. In a reverse experiment, snails infected first with R. marini were only partly susceptible to a second infection with S. mansoni given on Day 23. In simultaneous exposures, snails developed double infections (22%) with R. marini dominant and S. mansoni sporocyst and cercaria production reduced. While R. marini is not a strong direct antagonist against established S. mansoni infections, it has several attributes as a possible biological control agent: hardy eggs easily produced in rats; high infectivity to snails of all ages; and ability to castrate and prematurely kill B. glabrata. The R. marini-rat system described here provides a convenient laboratory and field model for the study of intrasnail trematode antagonism and biological control.     

An ultrastructural study of the egg wall surrounding the miracidium of the digenean Brandesia turgida ( ) (Plagiorchiida: Pleurogenidae), with the description of a unique cocoon-like envelope

The intrauterine eggs of the pleurogenid trematode Brandesia turgida ( Brandes, 1888), exhibiting advanced stages of miracidial differentiation and fully formed, ciliated miracidia, were examined by means of transmission electron microscopy (TEM). Each embryonated egg is composed of a mature miracidium surrounded by a four-layered egg wall: (1) an outer, anucleate layer external to the eggshell, which forms a thick cocoon; (2) the operculate egg-shell; (3) a small remnant of the compact, granular cytoplasm of the outer embryonic envelope (sensu stricto); and (4) a relatively distinct cellular remnant of the inner embryonic envelope. Layers enveloping the egg apparently play an important role in the protection, metabolism and storage of nutritive reserves for the developing miracidium. The outer, anucleate layer, or cocoon, situated externally to the eggshell and composed of a transparent, electron-lucent substance with numerous dense, osmiophilic islands attached to its peripheral membrane, has never previously been seen in TEM studies of the eggs of parasitic platyhelminths. The origin, formation, functional ultrastructure and chemical composition of this peculiar layer remain enigmatic, although its function appears to be protective. The thick, electron-dense eggshell resembles that of other trematodes, exhibiting a characteristic fissure zone around the operculum. The very small, indistinct remnants of the outer embryonic envelope appear in the form of a very thin, compact, granular cytoplasm closely attached to the inner surface of the eggshell. Conversely, the inner embryonic envelope is frequently apparent at one or both poles of the developed egg as a syncytial envelope formed by the fusion of mesomeres. This envelope, even in eggs containing a fully formed miracidium, still has the features of a metabolically active layer with an energy storage capability. Lysosome-like structures observed in some eggs may be involved in the autolysis of the embryonic envelopes.     

Effect of amphotericin B on the infection success of Schistosoma mansoni in Biomphalaria glabrata

In the present study, we examined the effect of amphotericin B on larval stages (miracidia and primary sporocyst) of the helminth Schistosoma mansoni, the causative agent of human schistosomiasis. Amphotericin B (AmB) is a polyene macrolide that disturbs the function of the cell membrane; it is widely used as prophylactic antimycotic agent in in vitro culture. We show for the first time that S. mansoni miracidia infectivity is considerably reduced after AmB treatment. Moreover we demonstrate that AmB does not affect the development, growth, viability, and behavior of miracidia and primary sporocysts. Our data indicate that AmB effects on S. mansoni sporocyst prevalence are linked to the oxidative properties of AmB. These may alter the capacity of sporocysts to respond to the oxidative stress generated by the snail immune defence system.     

An ultrastructural study of the egg wall surrounding the miracidium of the digenean Brandesia turgida () (Plagiorchiida: Pleurogenidae), with the description of a unique cocoon-like envelope

The intrauterine eggs of the pleurogenid trematode Brandesia turgida (Brandes, 1888), exhibiting advanced stages of miracidial differentiation and fully formed, ciliated miracidia, were examined by means of transmission electron microscopy (TEM). Each embryonated egg is composed of a mature miracidium surrounded by a four-layered egg wall: (1) an outer, anucleate layer external to the eggshell, which forms a thick cocoon; (2) the operculate egg-shell; (3) a small remnant of the compact, granular cytoplasm of the outer embryonic envelope (sensu stricto); and (4) a relatively distinct cellular remnant of the inner embryonic envelope. Layers enveloping the egg apparently play an important role in the protection, metabolism and storage of nutritive reserves for the developing miracidium. The outer, anucleate layer, or cocoon, situated externally to the eggshell and composed of a transparent, electron-lucent substance with numerous dense, osmiophilic islands attached to its peripheral membrane, has never previously been seen in TEM studies of the eggs of parasitic platyhelminths. The origin, formation, functional ultrastructure and chemical composition of this peculiar layer remain enigmatic, although its function appears to be protective. The thick, electron-dense eggshell resembles that of other trematodes, exhibiting a characteristic fissure zone around the operculum. The very small, indistinct remnants of the outer embryonic envelope appear in the form of a very thin, compact, granular cytoplasm closely attached to the inner surface of the eggshell. Conversely, the inner embryonic envelope is frequently apparent at one or both poles of the developed egg as a syncytial envelope formed by the fusion of mesomeres. This envelope, even in eggs containing a fully formed miracidium, still has the features of a metabolically active layer with an energy storage capability. Lysosome-like structures observed in some eggs may be involved in the autolysis of the embryonic envelopes.     

Ribeiroia marini: Irradiated miracidia and induction of acquired resistance in Biomphalaria glabrata

Biomphalaria glabrata snails sensitized by exposure to X-irradiated miracidia of the trematode, Ribeiroia marini, acquired resistance to challenge with nonirradiated R. marini miracidia. Resistance was acquired within 1 day of sensitization; was strongest at 1 week, when infection rates of sensitized snails were 15% of the controls (i.e., $\text{S}\text{C}\text{= 0.15}$); and persisted for at least 3 weeks. By 30 days the difference between the infection rates of sensitized and control snails was no longer statistically significant. As in previous studies with echinostomes, acquired resistance to R. marini was characterized histologically by the destruction of irradiated sporocysts by host amoebocytes. Following destruction of all irradiated sporocysts, snails became resistant and encapsulated and destroyed nonirradiated challenge sporocysts within 1 day postchallenge. Associated with sporocyst destruction was an enlargement of the amoebocyte-producing organ, which showed intense mitotic activity. A proportion of the nonirradiated challenge sporocysts were also destroyed in most nonsensitized control snails, which consequently had a temporarily enlarged amoebocyte-producing organ. In contrast to acquired resistance reported to echinotomes, which is quite specific, acquired resistance to R. marini was associated with nonsusceptibility to both Echinostoma paraensei ($\text{S}\text{C}\text{= 0.19}$) and Schistosoma mansoni ($\text{S}\text{C}\text{= 0.81}$).     

Echinostoma revolutum: Labeling of miracidia with radioselenium in vivo and assay for host finding

Radioactivity was incorporated into Echinostoma revolutum worms and eggs when ⁷⁵Semethionine was administered intraperitoneally to mice infected with the fluke parasites. The levels of incorporation of radioactivity increased in proportion to the amounts of radioselenium used. During the period 3–10 days p.i. the maximum egg-bound radioactivity was, in general, achieved 3 days after the administration of the radioisotope, but substantial radiolabeling was obtained at all isotope levels until Day 10. The radioactivity of the miracidium constituted 29–34% of that of the egg. The radiolabeling procedure did not interfere with the biological characteristics (behavioral activity, infectivity) of the radiolabeled miracidia. Thus, the use of such labeled miracidia for host-finding studies seems acceptable. A radioisotope tracer system for assaying E. revolutum miracidial host finding was described. This system employs exposure of the first intermediate host snail, Biomphalaria alexandrina, to radiolabeled miracidia. A linear proportionality was found to exist between the number of penetrating miracidia and the amount of snail-bound radioactivity. Thus, snail-bound radioactivity retained after exposure to radiolabeled miracidia can be used to measure miracidial host-finding capacity under various experimental conditions.