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.     

Acquired resistance in snails. Induction of resistance to Schistosoma mansoni in Biomphalaria glabrata

Acquired resistance to Schistosoma mansoni PR-I strain has been induced in Biomphalaria glabrata 442132 strain by infecting the snails with irradiated homologous miracidia. Present and previous results support the hypothesis that acquired resistance to trematodes in snails is an enhancement of the host's natural resistance to the parasite.     

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.     

Inducement of miracidia-immobilizing substance in the hemolymph of Biomphalaria glabrata

Lie K. J., Jeong K. H. and Heyneman D. 1980. Inducement of miracidia-immobilizing substance in the hemolymph of Biomphalaria glabrata. Intemational Journal for Parasitology10: 183–188. More than 85% of echinostome-infected albino B. glabrata laboratory strain snails develop miracidia-immobilizing substance(s) (MIS) in the hemolymph, while less than 5% of control uninfected snails show this ability. Snails infected with Echinostoma lindoense show a strong miracidial immobilizing test (MIT) when homologous miracidia are exposed to the hemolymph and a moderate response when E. liei and Paryphostomum segregatum miracidia are used. Infection with E. paraensei results in a high level of hemolymph MIS with E. lindoense miracidia, a moderate one with P. segregatum miracidia, and a weak one when hemolymph is tested against E. liei as well as the homologous E. paraensei miracidia. Infection with E. liei induces a strong MIT with E. lindoense miracidia whereas only a moderate one was observed when using homologous or P. segregatum miracidia. Infection with P. segregatum gives a moderate MIT reaction to miracidia of the homologous species, as well as to E. lindoense and E. liei, and only a weak response to E. paraensei miracidia. Infection with S. mansoni fails to induce hemolymph that shows MIS to any of the parasites tested. Production of hemolymph MIS is temporary. It begins one day postexposure, reaches its maximum 10–14 days postexposure, and declines to the preinfection level several weeks later. Infection of snails with irradiated parasites also results in a temporary production of hemolymph MIS.Uninfected snails show a tissue-extract MIS, which is especially strong when digestive gland extracts are used. However, these snails give little or no evidence of a hemolymph MIS.     

Pathophysiologic alterations in Biomphalaria glabrata infected with Angiostrongylus costaricensis

Hemolymph glucose, alkaline phosphatase, lactic dehydrogenase, and creatine phosphokinase in Biomphalaria glabrata infected with Angiostrongylus costaricensis were significantly higher on day 27 postinfection (PI) than in uninfected snails. Hemolymph total calcium from infected snails was less on days 6, 12, and 27 PI than that from controls. Total hemolymph protein was similar for controls and infected animals during the entire study. Throughout the study the mean number of amoebocytes/mm³ hemolymph from infected snails was significantly less than that for controls. Mean total wet weights of digestive gland and foot muscle from infected and uninfected snails was similar throughout the study. Mean μg glycogen/mg wet weight of digestive gland from infected snails was significantly greater on days 24, 27, and 28 PI than that from controls. Mean μg glycogen/mg wet weight of foot muscle from infected snails was significantly reduced between days 12 and 28 PI from that of uninfected snails. It is suggested that hemolymph glucose and digestive gland glycogen in infected snails are augmented by glycogen breakdown in the foot muscle of parasitized animals. Elevations in hemolymph enzymes are due to tissue destruction by larvae emerging from the foot muscle of infected snails. Parasite-induced derangements in shell metabolism underlie observed changes in hemolymph calcium in infected snails.     

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.     

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.     

Leucocytosis in Biomphalaria glabrata sensitized and resensitized to Echinostoma lindoense

Leucocytosis was shown to occur in the pulmonate gastropod Biomphalaria glabrata exposed to the trematode Echinostoma lindoense. In these sensitized snails, the leukocyte count in the hemolymph was elevated 3 to 5 days postexposure to miracidia, and prior to complete encapsulation of sporocysts. This increase continued 1 to 5 days after destruction of sensitizing, irradiated E. lindoense sporocysts. Counts returned to normal levels after this period. A significant and more rapid increase in numbers of circulating leukocytes occurred 1 to 6 hr after reexposure of snails to a sensitizing dose of nonirradiated E. lindoense sporocysts. The leukocyte counts usually returned to normal levels after this period, except in snails in which some resensitizing sporocysts remained alive.     

Total protein and carbohydrate content and protease and disaccharidase activities in the hemolymph of Lymnaea stagnalis naturally infected with digenean larvae

Lymnaea stagnalis is an intermediate host of many Digenea. The infestation affects host metabolism. The aim of the work was to investigate hemolymph biochemical indicators of L. stagnalis infected with four species of trematodes: Diplostomum pseudospathaceum, Paryphostomum radiatum, Plagiorchis elegans or Opisthioglyphe ranae. The protein profiles and proteinase activity in the hemolymph of sexually mature individuals of Lymnaea stagnalis maintained at 19°C were tested. As the carbohydrates are main substrates for energetic metabolism of the great pond snail their content and disaccharidase activity were also studied. Hemolymph samples were collected during weeks 3 and 4 of rearing. No significant differences in the total protein content between uninfected individuals and snails infected with the first three trematode species were detected. In the snails infected with O. ranae the quantity of total proteins was near twice higher than in those uninfected. A higher share of 70 kDa proteins in infected than in uninfected snails as well as reduction of the low molecular weight fractions of proteins for snails infected with D. pseudospathaceum and P. radiatum were detected. During week 3, carbohydrate content in the infected snails did not differ from that in the controls while during week 4 it was significantly lower in snails infected with P. elegans or O. ranae. The content of the major soluble carbohydrate in the hemolymph - saccharose — changed in a similar way. No activity of trypsin or pepsin in the hemolymph sample was detected while the activity of chymotrypsin was lower in infected snails vs. controls. On the other hand, saccharase and maltase activities were higher in infected than in uninfected snails. The biochemical hemolymph indicators in naturally infected host-snails show some differences depending on the parasite species but they are not sufficiently species-specific to offer the basis for establishing the model unique for a particular parasitosis. Our results from the field did not always coincide with those from the laboratory.     

SELECTION AND STRAIN SPECIFICITY OF COMPATIBILITY BETWEEN SNAIL INTERMEDIATE HOSTS AND THEIR PARASITIC SCHISTOSOMES

Many theoretical models of host-parasite coevolution assume that variation in host resistance to parasite infection is, at least partially, genetically determined and specific to the strain of infecting parasite. However, very few experimental studies have been conducted to test this assumption in animal-parasite systems. Biomphalaria glabrata snails serve as the intermediate hosts of Schistosoma mansoni. Although some snails are resistant to infection, there is no evidence of fixation of resistance in field populations. Two possible explanations for this are high fitness costs associated with resistance and a dynamic coevolution between parasite and host, perhaps involving matching alleles or gene-for-gene interactions. Two strains of B. glabrata were artificially selected for either resistance or susceptibility to each of two strains of S. mansoni parasite for three generations. Third-generation snails were then were exposed to either the parasite strain to which they had been selected or to a different parasite strain. In both host strains, resistance and susceptibility (compatibility) were found to be heritable. Moreover, compatibility to one parasite strain was not associated with compatibility to another strain, implying no genetic trade-off. Our results are discussed in terms of potential mechanisms of resistance in this host-parasite system and their implications to general coevolutionary theory.     

Resistance of Clostridium perfringens Type A Spores to γ-Radiation

The radiation resistance of the spores of a classical strain and of an atypical, heat-resistant strain of Clostridium perfringens was determined. Spores were produced in Ellner's and in a Trypticase broth medium. Approximately 10⁶ viable spores per milliliter were suspended in 0.06 m phosphate buffer and irradiated with γ rays from cobalt-60; the survivors were counted in Tryptone-yeast extract-agar by the Prickett-tube technique. Radiation D values for spores of the atypical strain in phosphate buffer and in cooked-meat broth were 0.23 and 0.30 Mrad, respectively, and the D value of the classical strain was 0.25 Mrad in phosphate buffer. Spores of the classical and atypical strains of C. perfringens type A are characterized by differences in heat resistance; yet, all strains tested demonstrated similar radiation resistance. Also, the spores were more resistant to ionizing radiation in cooked-meat broth than in phosphate buffer.     

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 ($\text{S}\text{C}\text{= 0.81}$).     

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.     

Clearance of schistosome parasites by resistant genotypes at a single genomic region in Biomphalaria glabrata snails involves cellular components of the hemolymph

Schistosomiasis is one of the most detrimental neglected tropical diseases. Controlling the spread of this parasitic illness requires effective sanitation, access to chemotherapeutic drugs, and control over populations of the freshwater snails, such as Biomphalaria glabrata, that are essential intermediate hosts for schistosomes. Effectively controlling this disease, while minimising ecological implications of such control, will require an extensive understanding of the immunological interactions between schistosomes and their molluscan intermediate hosts. Here we histologically characterise the clearance of schistosome larvae by snails that exhibit allelic variation at a single genomic region, the Guadeloupe resistance complex. We show that snails with a resistant Guadeloupe resistance complex genotype clear schistosomes within the first 24–48?h, and that this resistance can be transferred to susceptible snails via whole hemolymph but not cell-free plasma. These findings imply that Guadeloupe resistance complex-coded proteins help to coordinate hemocyte-mediated immune responses to schistosome infections in Guadeloupean snails.     

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.     

Alterations in the osmoregulation of the pulmonate gastropod Biomphalaria glabrata due to copper

Specimens of Biomphalaria glabrata were exposed to 0.06 ppm of copper in the form of CuSO₄, and the resulting changes in the wet and dry weights of the soft tissues and in the osmolality of the hemolymph were measured. The wet weights of snails exposed to copper increased as a function of time, while those of the controls decreased. The dry weights of both the experimental and control snails decreased equally. Finally, the ratio of wet weight to dry weight of the experimental snails was significantly higher than that of the controls after 24 and 48 hr of exposure to copper. In addition, the osmolality of the hemolymph of snails exposed to copper was significantly lower than that of the controls after 12, 24, and 36 hr of exposure. These data have led to the conclusion that exposure of B. glabrata to copper results in an osmotic influx of water into its tissues and thereby causes death.     

Inactivation of the Radiation-Resistant Spoilage Bacterium Micrococcus radiodurans: II. Radiation Inactivation Rates as Influenced by Menstruum Temperature, Preirradiation Heat Treatment, and Certain Reducing Agents1, 2, 3

The R₁ strain of Micrococcus radiodurans, previously determined to be more resistant than three other strains exposed to gamma radiation, was studied further to determine the influence of certain environmental factors on resistance to radiation inactivation. The frozen state offered insignificant protection to the organisms irradiated in raw puréed beef. Resistance was reduced by higher menstruum temperatures (40 and 50 C) during irradiation. Preirradiation heat treatment was found to lower resistance to subsequent irradiation. When the cells were irradiated in buffer at pH 5, 7, or 9, no differences in resistance were noted. Cell suspensions in buffer were protected to some extent by cysteine but not by thioglycolate. Ascorbate enhanced radiation inactivation.     

Comparative mortality studies on Biomphalaria glabrata (mollusca: Pulmonata) exposed to copper internally and externally

Various concentrations of copper in the form of CuSO₄ were injected into the hemocoel of Biomphalaria glabrata, and mortality of this snail was subsequently monitored. The concentrations of copper in the hemolymph of injected snails were calculated, and specimens were incubated in these concentrations. Greater mortality was observed when snails were incubated in concentrations of copper than when they were injected with a sufficient amount of copper to attain these same concentrations in the hemolymph. Injection of copper into the hemocoel of B. glabrata resulted in the formation of a noncellular hemolymph precipitate, most likely denatured proteins, at the injection site, which was most noticeable with higher concentrations of copper. It has been concluded that external concentrations of copper are more cidal to B. glabrata than are internal, i.e., injected, concentrations. These data support the hypothesis that the cidal action of copper on B. glabrata is due to an attack on the mollusc's surface epithelia.