Acid phosphatase in granulocytic capsules formed in strains of Biomphalaria glabrata totally and partially resistant to Schistosoma mansoni

Cheng T. C. and Garrabrant T. A. 1977. Acid phosphatase in granulocytic capsules formed in strains of Biomphalaria glabrata totally and partially resistant to Schistosoma mansoni. International Journal for Parasitology7: 467–472. Acid phosphatase (EC 3.1.3.2, orthophosphoric monoester phosphohydrolase) has been demonstrated cytochemically in isolated granulocytes from the hemolymph of three strains of Biomphalaria glabrata. This enzyme was not detected in hyalinocytes. By employing acid phosphatase as a marker, it was determined that the cells comprising the capsule surrounding Schislosoma mansoni mother sporocysts in a totally and partially resistant strain of B. glabrata are granulocytes.The process of encapsulation of S. mansoni mother sporocysts in resistant B. glabrata was traced for 72 h post-penetration by miracidia and has been ascertained to involve two stages: (1) enlargement of the granuloma around intact sporocysts, followed by (2) disintegration of the parasite and a decrease in the size of the granuloma. There is an increase in the level of acid phosphatase activity within granulocytes comprising the granuloma during the second stage.Host cellular responses to S. mansoni mother sporocysts does not occur in susceptible snails.     

Schistosoma haematobium in Bulinus guernei: Electron microscopy of hemocyte-sporocyst interactions

Electron microscopy has revealed that in Bulinus guernei (Gambian strain) snails infected with Schistosoma haematobium (Egyptian strain) daughter sporocysts and cercariae, two kinds of hemocytes called granulocytes and hyalinocytes are found associated with the sporocysts. Granulocytes are small, numerous, plumbophilic, and amoeboid. They contain lysosome-like granules. Hyalinocytes are large, sparse, less plumbophilic than granulocytes, and have intracellular microfilaments (about 9 nm wide), and few or no pseudopods. They are devoid of lysosome-like granules. Granulocytes and hyalinocytes infiltrate near sporocysts, but only granulocytes interact with sporocyst microvilli by contact. Granulocytes induce a restricted multilamellated encapsulation reaction. Extracellular microfilaments (about 12.5 nm wide), with a regular transverse structure pattern of about 50-nm periodicity, frequently are found along the outer surface of granulocytes located adjacent to sporocysts. Intracellular filamentous structures and a prominent glycocalyx also are features of the seemingly more active granulocytes contiguous with sporocysts. Cell adhesions may occur between surfaces of (1) granulocytes and sporocysts, (2) interdigitating pseudopodial processes of capsular granulocytes, and (3) granulocytes and hyalinocytes.     

An ultrastructural study on ventricular encapsulation reactions in Biomphalaria glabrata exposed to irradiated echinostome parasites

Jeong K. H., Lie K. J. and Heyneman D. 1984. An ultrastructural study on ventricular encapsulation reactions in Biomphalaria glabrata exposed to irradiated echinostome parasites. International Journal for Parasitology14: 127–133. Encapsulation reactions around sporocysts of Echinostoma lindoense and E. paraensei have been studied in the ventricle of Biomphalaria glabrata using ultrastructural procedures. Amebocytes and ameboblasts migrate from the amebocyte-producing organ to the ventricle and there surround irradiated echinostome larvae. Specialized junction sites were found that linked amebocytes in the three phases of capsule formation, migratory, flattening and phagocytic. Active engulfing of portions of the tegument by amebocytes was followed by phagocytosis of parasite internal cells and formation in amebocytes of residual bodies of indigestible material. Regression of encapsulation reactions in the ventricle was frequently associated with formation of sear tissue. Comparisons made between types of encapsulation reactions observed around echinostomes and schistosomes in B. glabrata reveal differences in speed of response, number of cells involved and size of amebocyte pseudopodia.     

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.     

Histopathological effects of larval digenea on the digestive epithelia of the marine prosbranch Cerithidea californica: Fine structural changes in the intestine

Light and electron microscopy were employed to study the effects of infection by sporocysts of Renicola buchanani on the posterior intestine of the marine snail Cerithidea californica. Columnar intestinal epithelium in close contact with renicolid sporocysts usually are compressed by growing larval stages resulting in the reduction of epithelial height, the disruption of cell-cell junctions, and the formation of convolutions in the supporting basal lamina. Intestinal cells of infected snails are further characterized by a reduction of rough endoplasmic reticulum, microtubules and microfilaments, and the formation of cytoplasmic vacuoles and electron-dense lysosome-like inclusions. Mitochondria of degenerating intestinal and smooth muscle cells show signs of cristolysis. In addition, the cytoplasm of smooth muscle cells often display a fine grainy appearance due to the breakdown of actin and paramyosin filaments.     

Schistosoma mansoni: Cloning by microsurgical transplantation of sporocysts

Development of a method of infecting of the molluscan host by microsurgical transplantation of the parasite's sporocysts enables the researcher to maintain the host cycle of Schistosoma mansoni exclusively by asexual means and without the participation of a vertebrate host. After transplantation, larval morphogenesis becomes altered to form an additional generation of sporocysts. These invade the digestive gland of the recipient mollusc progressively, producing normally infective cercariae. The maintenance of the life cycle of S. mansoni in the laboratory for 1 year, solely in the mollusc, has been obtained through six successive transplantations. Thus, a true cloning of S. mansoni has been achieved, the original transplant material being derived from a monomiracidial infection. From the practical viewpoint, this transplantation technique is of definite utility in the maintenance of the cycle, the vertebrate stage having been eliminated. From the theoretical viewpoint, unexpected analogies become apparent with the two types of larval demography found in Digenea (Digenea with sporocyst and Digenea with rediae).     

Encapsulation of Aspidogaster conchicola (Trematoda: Aspidogastrea) by unionid mussels

Of 334 mussel specimens representing 13 species, 143 individuals of seven species were found infected with Aspidogaster conchicola; encapsulation of worms was seen in six molluscan species. Encapsulated worms were most abundant anterior to the pericardium and were surrounded by inner fibroblastic and outer fibrocytic/fibrous walls, with occasional adjoining compressed host connective tissues. The inner wall contained acid mucins and phospholipids, while the outer wall contained reticulum fibers, neutral mucins, and phospholipids. Capsule structure was compared to the molluscan encapsulation classification system of T. C. Cheng and E. Rifkin (1970, Amer. Fish. Soc. Spec. Pub., No. 5, pp. 443–496) and to G. B. Pauley and C. D. Becker's (1968, J. Parasitol., 54, 917–920) account of A. conchicola encapsulation. Capsule contents included living or moribund adult worms, viable eggs or empty egg shells produced by disintegrated worms, juveniles hatched from eggs deposited by encapsulated adults, and host cells of which “brown cells” were most abundant. Because of the high frequency of encapsulated moribund worms observed in this study (more than 60%), we infer that this host reaction probably contributed to the parasite's death. Worm eggs individually encapsulated by hemocytes in hemal spaces also were observed. Life cycle implications of juvenile A. conchicola within digestive gland diverticula are discussed.     

Encapsulation reactions in vitro by haemocytes of Heliothis virescens

A simple in vitro system for studying capsule formation by Heliothis virescens haemocytes was devised. The system produced capsules morphologically and ultrastructurally similar to those formed in vivo. Encapsulation proceeded normally when melanization was inhibited and when divalent cations were absent. Capsule development took place in two physiologically distinct phases. Aggregation of haemocytes around a foreign object (phase 1) was a passive process. Consolidation of haemocytes into a smooth, adherent capsule (phase 2) required metabolic energy. Phase 1 was inhibited irreversibly by propranolol and caffeine. Inhibition of phase 1 by mild trypsinization could be reversed by haemolymph lysate. Preliminary evidence indicates that encapsulation promoting factors in the lysate originate in haemocytes.     

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.     

Infectivity of a microsporidium of mosquitoes (Nosema algerae) to larval stages of Schistosoma mansoni in Biomphalaria glabrata

Lai P. F. and Canning E. U. 1980. Infectivity of a microsporidium of mosquitoes (Nosema algerae) to larval stages of Schistosoma mansoni in Biomphalaria glabrata. International Journal for Parasitology10: 293–301. Nosema algerae derived from a closed colony of Anopheles stephensi was fed to Biomphalaria glabrata infected with Schistosoma mansoni. Mother and daughter sporocysts became hyperinfected but the snail tissues remained free of the microsporidia except for rare small aggregates of spores. These lay close to the sites occupied by mother or daughter sporocysts and were probably liberated from them. Irrespective of dose, fewer snails contained infected sporocysts when spores were given at 7 days post-miracidial infection than when given at 14 days. These periods corresponded respectively to stages when mother sporocysts only or daughter sporocysts as well were present in the snails. Infection of the sporocysts began in the tegumental cells, spread to the brood chamber and ultimately to the cercariae themselves. Heavily infected sporocysts contained fewer developing embryos. Doses of 10⁶ and 10⁷ spores/snail caused significant depression of cercaria output when given at 14 days but not at 7 days.     

Neoaplectana carpocapsae: Encapsulation in Aedes aegypti and changes in host hemocytes and hemolymph proteins

Following encapsulation of a nematode parasite Neoaplectana carpocapsae by larval Aedes aegypti, there were significant decreases in both the total hemocyte count and in the number of DOPA-oxidase positive hemocytes within the anal papillae. Ligation experiments indicate these hemocytes are not necessary for successful capsule formation. The possibility of these changes resulting from a pathological condition created by the parasite are discussed.Disc electrophoresis revealed several changes in the protein migration pattern of A. aegypti hemolymph following encapsulation of N. carpocapsae. Gels stained with amido schwartz showed a shift in certain bands, a reduction in intensity of another, and the presence of an additional protein fraction. These changes appear to be specific for parasitism and/or encapsulation. Incubation of gels in DOPA solution revealed an increased intensity of one protein fraction which is not specific for encapsulation but may be the result of a wound response. It appears that some protein is released by the host or by the parasite in response to parasitism. While the function of this protein is unknown, it may play a role in the defense reactions of the host.     

The effects of parasitic water mite larvae (Arrenurus spp.) on zygopteran imagoes (Odonata)

Arrenurus larvae, ectoparasitic on zygopteran imagoes, attach to the host's cuticle and tear it to obtain the host's tissue fluids. Within the host's epidermis, each larval mite produces a feeding device, the stylostome, a narrow gelatinous resilient blind sac. Heavy mite infestation brings about several wounds in close proximity, accompanied by loss of more or less extensive areas of the epidermis. Despite wound repair by congregating hemocytes, local lack of epidermis seems to enfeeble the host, presumably owing to desiccation. Heavily mite-loaded zygopterans have lost the typical agility and are easily caught. A mite-induced mortality seems to exist in zygopteran populations; the infestation contributes to reduced longevity. The study of formation and decline of the arrenurid stylostome in zygopterans renders it possible to trace cellular defence reactions under natural conditions. Most stylostomes seem to thwart the ability of the host to recognize them as foreign bodies. The host's defence appears as a two-step reaction: (1) initial hemolymph clotting and deposition of melanin associated with aggregating hemocytes at the penetration site, (2) occasional subsequent melanization and cellular encapsulation of the stylostome.     

Hemocyte reactions and early cellular changes during melanotic tumor formation in Drosophila melanogaster

In Drosophila melanogaster tu bw larvae melanotic tumors form as a result of a cell-mediated immune response involving the encapsulation and melanization by hemocytes of portions of the caudal adipose tissue. The tissue-specific encapsulation response is not due to the disintegration of the basement membrane surrounding the adipose tissue as is reported to be the case in other melanotic mutants. Prior to encapsulation large numbers of hemocytes appear in the circulation and begin to differentiate into flattened cells termed lamellocytes. This transformation occurs at a time when changes are noted within the adipose cells. The localized accumulation of blood cells near intact basement membrane suggests that abnormally developing adipose cells acquire altered molecular surfaces or release substances to which the hemocytes respond. The initial reaction of the hemocytes with the adipose tissue is cell lysis, and this is rapidly followed by the aggregation of numerous additional blood cells which eventually cohere to one another to form a multilayered capsule. What little evidence there is of disintegration of the basement membrane occurs only after hemocytes have lysed at the surface, and other blood cells begin to invade the adipose tissue. Melanization occurs first in the intercellular spaces along the plasma membranes of the lysed cells, and progresses from the innermost layers toward the periphery of the encapsulating cells. Since the changes observed in the hemocytes and adipose cells are precocious, occurring to a lesser degree later in normal development, the initial effect of the genetic mutation in tu bw larvae may be an endocrine dysfunction which causes an asynchronous and abnormal development of the caudal adipose tissue and/or the hematopoietic organs.     

Phyllocarida and the origin of the Malacostraca

Tentative homologies with Decapoda are proposed for grooves on the carapace of Echinocaris and Montecaris. Together with F.R. Schram's hoploid trend, reinforced by the discovery of a raptorial limb in Sairocaris, this may strengthen a phyllocarid origin for Eumalacostraca. Both these trends, however, may be parallelisms, and phylogenetic analysis is required. Pleopods are here proved to have been present in additional Archaeostraca, which improves their ancestral condition. E. Dahl's view of the phyllocarids as an evolutionary dead end is falsified from fossils, and the phyllocarids are supported as a stem group of the Malacostraca.     

The hormonal control of salivary gland secretion in Drosophila melanogaster: Studies in vitro

The larval salivary gland of Drosophila melanogaster synthesises a complex secretion, known as ‘glue’. which is secreted at puparium formation and then cements the puparium to its substrate. This secretion is made during the third larval instar and is stored in the gland cells as large granules. A few hours before puparium formation it is secreted into the gland's lumen by exocytosis. This process is induced by ecdysone and can be studied in vitro. Secretion is initiated about 3.5 hr after exposure of glands to ecdysone and is complete by 8 hr. The effects of varying the ecdysone concentration, of inhibitors of RNA or protein synthesis, and of withdrawing the hormone at various times after initial exposure on the process of secretion have been studied. We conclude that some event(s) occurring during the first 3 hr exposure to ecdysone is necessary to initiate secretion of the glue into the gland lumen. The possible relationship between this event(s) and the ecdysone induced changes in gene activity (puffs) which occur in the salivary glands at the same time is discussed.     

In vitro cultivation of Schistosoma japonicum-parasites and cells

Schistosomiasis is a serious parasitic zoonosis caused by blood-dwelling flukes of the genus Schistosoma. Understanding functions of genes and proteins of this parasite is important for uncovering this pathogen's complex biology, which will provide valuable information to design new strategies for schistosomiasis control. Effective applications of molecular tools reported to investigate schistosome gene function, such as inhibitor studies and transgenesis, rely on the developments of in vitro cultivation system of this parasite and cells. Besides the in vitro culture studies dealing with Schistosoma mansoni, there are also numerous excellent studies about the in vitro cultivation of Schistosoma japonicum, which were performed by Chinese researchers and published in Chinese journals. Nearly every stage of the life-cycle of S. japonicum, including miracidia, mother sporocysts, cercariae, schistosomula, and egg-laying adult worms, was employed for developing in vitro cultivation methods, being accompanied by the introduction of several media and supplements that helped to improve culture conditions. It was not only possible to generate mother sporocysts from miracidia in vitro, but also to obtain adult worms from cercariae through in vitro cultivation. The main obstacles to complete the life cycle of S. japonicum in the lab are the transition from mother sporocysts to cercariae, and the production of fertilized and completely developed eggs by adult worms generated in vitro. With regard to cells from S. japonicum, besides established isolation protocols and morphological observations, media optimizations were conducted by using different chemical reagents, biological supplements and physical treatment. Among these, mutagens like N-methyl-N-nitro-N-nitrosoguanidine and the addition of extracellular matrix were found to be able to induce mitogenic activities. Although enzyme activities or the level of silver-stained nucleolar region associated protein in cultured cells indicated still suboptimal conditions, the achievements made point to the possibility of reaching the aim of establishing cell lines for S. japonicum. Both the improvements of the in vitro culture of larval and adult worms of S. japonicum as well as the access of cells of this parasite provide excellent advances for research on this important parasite in the future.     

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

Schistosomatium douthitti: Exposure of Lymnaea catascopium to irradiated miracidia

Irradiation of Schistosomatium douthitti miracidia (4000, 5000, or 6000 rad) did not substantially alter their behavior or ability to penetrate their snail host. Treatment with 4000 rad was not sufficient to prevent all miracidia from establishing patent infections in Lymnaea catascopium, although significantly fewer snails exposed to these miracidia shed cercariae than did controls exposed to normal miracidia. Irradiation of miracidia with either 5000 or 6000 rad totally prevented cercarial production. Although destruction of irradiated mother sporocysts by encapsulating amebocytes was occasionally observed, most expanded without concomitant multiplication of germinal cells and embryo production and then collapsed. They generally persisted in this state throughout the period of observation (32 days). Snails sensitized by exposure to irradiated miracidia and challenged 2 or 10 days later with normal miracidia were as likely to develop patent infections as were snails exposed only to normal miracidia. Double sensitization of snails with irradiated miracidia also failed to confer protection upon challenge with normal miracidia. Most challenge sporocysts developed normally, often in close proximity to collapsed irradiated sporocysts.     

Trypanosoma cruzi: Antibody-induced mobility of surface antigens

Antibody induces mobility of surface antigens of live blood forms of Trypanosoma cruzi when these cells are incubated with human or animal antisera. Parasites of one strain (Y) showed aggregation of surface antigens to form an anterior or more frequently a posterior cap. The proportion of cap forming trypomastigotes increased with time and was dependent on temperature and amount of antiserum. Cap formation was inhibited by sodium azide or iodoacetamide. Crosslinking of surface antigens by antibodies causing agglutination of trypomastigotes decreased antigenic mobility and capping. Capping was not affected by treatment of the parasites with colchicine or cytochalasin B. Antigen mobility was not related to the presence of antibodies against parasite and host tissue cross-reacting antigens. Aggregation of surface membrane antigens was also observed in parasites which survive after immune lysis. Results of light and electron microscopic studies suggested that at least part of the aggregated antigens was eliminated from the trypomastigote's surface. Cap formation was strain and stage dependent. It was not observed when Y-strain epimastigotes were used and it occurred less frequently in CL than in Y-strain trypomastigotes.     

Schistosoma mansoni: Agglutination of sporocysts,and formation of gels on miracidia transforming in plasma of Biomphalaria glabrata

The resistance or susceptibility of Biomphalaria glabrata strains to strains of Schistosoma mansoni, the human blood fluke, are evidenced by the responses of snail hemocytes to sporocysts of the schistosome, both in vivo and in vitro. It is now reported that living sporocysts of the PR1 strain of S. mansoni agglutinate in the plasma of all tested strains of B. glabrata, in contrast to fixed sporocysts which agglutinate only in plasma from resistant snail strains. The agglutinating activity in resistant plasmas is not divalent cation dependent, and was not inhibited by the 26 carbohydrates and four amino acids tested. In addition, the observation that gelatinous deposits develop on transforming miracidia-sporocysts in B. glabrata plasmas is also reported. Both the agglutination and gel-formation phenomena may facilitate recognition of, and attacks on, sporocysts, thereby contributing to susceptibility and resistance in this host-parasite system.