Positive phototropism is accelerated in Biomphalaria glabrata snails by infection with Schistosoma mansoni

Parasite-induced behavioral changes in their hosts favor to complete the lifecycle of parasites. Schistosome infection is also known to cause physiological changes in infected freshwater snail intermediate hosts. Here, we report, a novel phenomenon in which Schistosoma mansoni, a highly debilitating worm affecting millions of people worldwide, alters the phototropic behavior of Biomphalaria glabrata, the vector snail. S. mansoni-infection enhanced positive phototropism of vector snails and infected snails spent significantly more time in light. Possibly, these behavioral changes help the parasite to be released efficiently from the infected intermediate hosts, and to infect mammalian hosts.     

Studies on resistance in snails: Interference by nonirradiated echinostome larvae with natural resistance to Schistosoma mansoni in Biomphalaria glabrata

Most of the genetically selected juvenile Biomphalaria glabrata snails, normally strongly resistant to Schistosoma mansoni, lost their juvenile resistance to this parasite when other trematodes were concurrently present in the snail. Three echinostome species all were able to reduce this genetically controlled juvenile resistance: Echinostoma lindoense, E. paraensei, and e. liei. Subsequently, adult resistance to S. mansoni, clearly present in control snails of the same age and strain that were not doubly infected, failed to develop in most of the snails that also harbored echinostomes. Other snails, selected for resistance as adults to S. mansoni, also usually became susceptible to this parasite following infection with E. paraensei. The capacity of E. paraensei to interfere with the snails' resistance to S. mansoni was greater than that of E. lindoense. Destruction by predation of primary sporocysts of S. mansoni by echinostome rediae prevented completion of development of the S. mansoni infections. In a number of snails all primary S. mansoni sporocysts were consumed before secondary sporocysts could be formed. In most experimental snails, however, some of the schistosomes survived, often as a small number of degenerated secondary S. mansoni sporocysts. The capability of flukes to interfere with the natural defense of snails may be an important phenomenon whereby trematode species survive in their snail hosts.     

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.     

Schistosoma mansoni: Cytotoxicity of hemocytes from susceptible snail hosts for sporocysts in plasma from resistant Biomphalaria glabrata

Sporocysts of Schistosoma mansoni (PR1 strain) survive and grow in Biomphalaria glabrata PR albino strain snails, whereas they are encapsulated and die in B. glabrata 10R2 strain snails. These processes also occur in an in vitro system in which the only living cells are those of sporocysts and snail hemolymph. Hemocytes of the susceptible snail are normally not effective in damaging sporocysts. However, when the encounter occurred in the presence of cell-free plasma from resistant snails, previously impotent hemocytes severely damaged sporocysts in 24 hr. The cytotoxic capacity of resistant strain hemocytes was not altered by plasma from susceptible snails. Furthermore, it was retained even when plasma was replaced by culture medium free of snail components. The nature of the plasma factor(s) which facilitated damage by otherwise impotent hemocytes is discussed, and evidence is evaluated for the hypothesis that snail resistance is dependent upon the specificity of cytophilic factors present both in the plasma and on the hemocyte plasma membranes.     

Distribution and variation of hemagglutinating activity in the hemolymph of Biomphalaria glabrata

A sensitive hemagglutination assay utilizing glutaraldehyde-fixed trypsinized calf erythrocytes (GTC) is described to test for agglutinin levels in hemolymph and albumen gland extracts from nine populations of Biomphalaria glabrata, and from B. straminea and B. obstructa. High levels of GTC-reactive hemagglutinin were found in all snail populations. There was no correlation between hemagglutinin titer and innate resistance of B. glabrata strains to Schistosoma mansoni. However, an increase in hemagglutinin titer occurs in B. glabrata M-RLc snails infected with Echinostoma lindoense and in snails sensitized and reexposed to this parasite.     

N-Glycosylation patterns of hemolymph glycoproteins from Biomphalaria glabrata strains expressing different susceptibility to Schistosoma mansoni infection

Comparative analyses of the N-glycosylation pattern of hemolymph glycoproteins from Biomphalaria glabrata strains Puerto Rico (BgPR) and Salvador (BgBS-90), differing in their susceptibility towards Schistosoma mansoni infection, were performed by Western blotting, enzyme-linked immunosorbent assays, two-dimensional high-performance liquid chromatography and mass spectrometry. Obtained data demonstrated an enhanced expression of serologically cross-reacting, fucosylated carbohydrate epitopes by the highly susceptible BgPR-strain in comparison to the resistant BgBS-90-strain. In particular, glycoproteins of BgPR snails exhibited larger amounts of glycans with (β1-2)-linked xylose or terminal Fuc(α1-3)GalNAc(β1-4)[±Fuc(α1-3)]GlcNAc(β1-)-units which are known to mediate cross-reactivity with schistosomal glycoconjugates. This finding could be corroborated by immunohistochemical studies showing again an enhanced expression of such carbohydrate epitopes in BgPR tissue. Hence, our results provide evidence for a correlation of B. glabrata susceptibility towards S. mansoni infection and the expression of carbohydrate determinants shared by the parasite and its intermediate host.     

Larval excretory-secretory products from the parasite <Emphasis Type="Italic">Schistosoma mansoni</Emphasis> modulate HSP70 protein expression in defence cells of its snail host, <Emphasis Type="Italic">Biomphalaria glabrata</Emphasis>

Synthesis of heat shock proteins (HSPs) following cellular stress is a response shared by many organisms. Amongst the HSP family, the ∼70 kDa HSPs are the most evolutionarily conserved with intracellular chaperone and extracellular immunoregulatory functions. This study focused on the effects of larval excretory-secretory products (ESPs) from the parasite Schistosoma mansoni on HSP70 protein expression levels in haemocytes (defence cells) from its snail intermediate host Biomphalaria glabrata. S. mansoni larval stage ESPs are known to interfere with haemocyte physiology and behaviour. Haemocytes from two different B. glabrata strains, one which is susceptible to S. mansoni infection and one which is resistant, both showed reduced HSP70 protein levels following 1 h challenge with S. mansoni ESPs when compared to unchallenged controls; however, the reduction observed in the resistant strain was less marked. The decline in intracellular HSP70 protein persisted for at least 5 h in resistant snail haemocytes only. Furthermore, in schistosome-susceptible snails infected by S. mansoni for 35 days, haemocytes possessed approximately 70% less HSP70. The proteasome inhibitor, MG132, partially restored HSP70 protein levels in ESP-challenged haemocytes, demonstrating that the decrease in HSP70 was in part due to intracellular degradation. The extracellular signal-regulated kinase (ERK) signalling pathway appears to regulate HSP70 protein expression in these cells, as the mitogen-activated protein-ERK kinase 1/2 (MEK1/2) inhibitor, U0126, significantly reduced HSP70 protein levels. Disruption of intracellular HSP70 protein expression in B. glabrata haemocytes by S. mansoni ESPs may be a strategy employed by the parasite to manipulate the immune response of the intermediate snail host.     

Schistosoma mansoni: Lysozyme activity in Biomphalaria glabrata during infection with two strains

Levels of lysozyme activity were determined in the hemolymph, digestive gland, and headfoot extracts of M-line stock of snails, Biomphalaria glabrata, during infection with the PR-1 and Lc-1 strains of the trematode, Schistosoma mansoni. At 3 hr postexposure there was a 10-fold increase in the levels of enzyme activity in the hemolymph of snails infected with the Lc-1 strain to which the snail is resistant. This increase was considerably higher when compared to the threefold increase in the PR-1-infected snails. The infection also induced a gradual depletion of lysozyme activity in the headfoot muscles of the two groups of infected snails. There were no changes in the levels of enzyme activity in the digestive gland extracts of the control and the two groups of infected snails. Similar changes in the levels of enzyme activity in the hemolymph and headfoot extracts of infected snails suggest a nonspecific response to a parasite infection and do not indicate that lysozyme is primarily responsible for the destruction of schistosome parasite in a resistant snail host.     

Effects of UVB on interactions between Schistosoma mansoni and Biomphalaria glabrata

Ultraviolet B (UVB, 280-315 nm) radiation is detrimental to both of larvae of the digenetic trematode Schistosoma mansoni and its snail intermediate host, Biomphalaria glabrata. We explored effects of UVB on three aspects of the interaction between host and parasite: survival of infected snails, innate susceptibility and resistance of snails to infection, and acquired resistance induced by irradiated miracidia. Snails infected for 1 week showed significantly lower survival than uninfected snails following irradiation with a range of UVB intensities. In contrast to known immunomodulatory effects in vertebrates, an effect of UVB on susceptibility or resistance of snails to infection could not be conclusively demonstrated. Finally, exposure of susceptible snails to UVB-irradiated miracidia failed to induce resistance to a subsequent challenge with nonirradiated miracidia, a result similar to that reported previously with ionizing radiation.     

Schistosome sporocyst-killing Amoebae isolated from Biomphalaria glabrata.

Explants and swabs from the pericardium and mantle of three strains of Biomphalaria glabrata, two of them resistant to infection with Schistosoma mansoni, have yielded small amoebae, 3–5μm in diameter, in culture. These amoebae have been grown axenically through > 50 passages to date. The amoebae form cysts in dense cultures. When mixed with S. mansoni mother sporocysts in vitro, the amoebae adhere to and kill the trematodes within several hours. For 1–2 days thereafter, the amoebae proliferate rapidly at a generation time of about 5 hr, then return to normal growth. Sonically disrupted sporocysts also induce proliferation. Live sporocysts do not attract the amoebae or emit soluble substances which influence amoebal growth. Amoebae also adhered to and killed S. mansoni daughter sporocysts and cells derived from B. glabrata embryos; however, they did not harm S. mansoni cercariae or rediae of other trematode species. The proportion of mantle explants yielding amoebae was significantly higher (P<0.05) in one of the resistant snail strains than in the susceptible strain; however, whether amoebae contribute to snail resistance is unknown. Exposure of snails to S. mansoni miracidia did not influence the proportion of snails yielding amoebae.     

Field studies on the bionomics of the free-living stages of St. Lucian Schistosoma mansoni.

Densities of Schistosoma mansoni miracidia and cercariae in natural habitats in three St. Lucian valleys were monitored over a 3-year period by exposure of sentinel snails, Biomphalaria glabrata, and a cercariometric technique, supplemented by sampling of field snails. Separate measures for control of S. mansoni transmission were under evaluation in two of the valleys. Sentinel snails became infected sporadically and their infection rates per valley ranged from 0·12% to 4·99%. S. mansoni miracidial inoculation rates ranged from 1 to over 4 per infected sentinel snail. Combined rainfall of more than 3 in on the day before any day of sentinel snail exposure interfered with miracidium-snail interaction. Densities of S. mansoni cercariae ranged from 0·05 to 21 per litre of water sampled. The number of cercariae detected in a habitat by cercariometry was directly proportional to the number of infected field snails. Sentinel snail infection rates exhibited a downward and an upward trend, respectively, in the controlled and uncontrolled areas, although the changes were not significant statistically.     

Hemocytes from neonates of Biomphalaria glabrata are functionally less mature than those from adult snails

Gastropod molluscs, which serve as obligatory intermediate hosts for digenetic trematodes, possess an internal defense system (IDS) consisting of phagocytic hemocytes and plasma factors. This IDS is responsible for resistance to infection with larval trematodes, which are encapsulated and killed by hemocytes in incompatible snails. Like other physiological systems, the IDS probably undergoes maturation during early stages of life, and the relatively undeveloped state of the IDS in young snails has been hypothesized to be a factor in their increased susceptibility to infection with larval trematodes. In this study, hemocytes were examined in the BS-90 laboratory strain of Biomphalaria glabrata that is resistant to infection with Schistosoma mansoni as adults but susceptible to infection as neonates. Compared with hemocytes from adults, hemocytes from neonates had a smaller perimeter and lower intrinsic directional motility on glass microscope slides. Additionally, in vitro assays showed a lower association with fucoidan-linked polystyrene beads and less ability to produce superoxide anion in hemocytes from neonates compared to hemocytes from adults. These results support the hypothesis that the gastropod IDS undergoes maturation during growth. However, whether the observed differences between hemocytes of neonatal and adult BS-90 snails play a role in the susceptibility of the former and resistance of the latter to infection with S. mansoni is not known.     

Resistance to schistosome infection in Biomphalaria glabrata induced by gamma radiation

Two strains of Biomphalaria glabrata were studied with respect to the effects of ionizing radiation on their susceptibility to Schistosoma mansoni infection. Gamma radiation at levels of 3.5 and 5 krad did not induce susceptibility in the resistant S-3 strain, but was found to initiate resistance in the susceptible PR-1 strain. In an attempt to understand the induced resistance in irradiated snails, histopathologic examinations and analyses of snail hemolymph were performed. Results indicated that miracidia invading irradiated snails were quickly surrounded and encapsulated by amoebocytes. Similarly, alterations in the hemolymph of irradiated snails suggested that radiation induced aging. It is suggested that radiation-altered snails may be of value in studying the defense mechanisms of these organisms.     

Schistosoma mansoni in Susceptible and Resistant Snail Strains Biomphalaria tenagophila: In Vivo Tissue Response and In Vitro Hemocyte Interactions

Schistosomiasis is a parasitic disease that is highly prevalent, especially in developing countries. Biomphalaria tenagophila is an important invertebrate host of Schistosoma mansoni in Brazil, with some strains (e.g. Cabo Frio) being highly susceptible to the parasite, whereas others (e.g. Taim) are completely resistant to infection. Therefore, B. tenagophila is an important research model for studying immune defense mechanisms against S. mansoni. The internal defense system (IDS) of the snail comprises hemocytes and hemolymph factors acting together to recognize self from non-self molecular patterns to eliminate the threat of infection. We performed experiments to understand the cellular defenses related to the resistance and/or susceptibility of B. tenagophila to S. mansoni. During the early stages of infection, fibrous host cells of both snail strains were arranged as a thin layer surrounding the sporocysts. However, at later stages of infection, the cellular reactions in resistant snails were increasingly more intense, with thicker layers surrounding the parasites, in contrast to susceptible strains. All parasites were damaged or destroyed inside resistant snails after 10 h of infection. By contrast, parasites inside susceptible snails appeared to be morphologically healthy. We also performed experiments using isolated hemocytes from the two strains interacting with sporocysts. Hemocyte attachment started as early as 1 h after initial infection in both strains, but the killing of sporocysts was exclusive to hemocytes from the resistant strain and was time course dependent. The resistant strain was able to kill all sporocysts. In conclusion, our study revealed important aspects of the initial process of infection related to immune defense responses of strains of B. tenagophila that were resistant to S. mansoni compared with strains that were susceptible. Such information is relevant for the survival or death of the parasites and so is important in the development of control measures against this parasite.