Antagonistic effects of Schistosoma mansoni on superimposed Hymenolepis diminuta and H. microstoma infections in mice

Patent, but not prepatent, Schistosoma mansoni infections in mice enhanced the expulsion of a superimposed infection with Hymenolepis diminuta. An antagonistic effect was also directed against a superimposed H. microstoma infection in mice harbouring patent S. mansoni infections.     

The effect of the expulsion phase of Trichinella spiralis on Hymenolepis diminuta infection in rats.

The effect of the intestinal changes brought about by the expulsion of Trichinella spiralis in rats was studied in relation to the growth and survival of a concurrent infection with Hymenolepis diminuta, a cestode not normally rejected by the rat in low-level infections. Growth of H. diminuta was stunted in rats given T. spiralis just before, or after, infection with H. diminuta, the stunting being more pronounced when the cestode was given closer to the period of inflammation. There was no loss of the cestode from dual-infected rats and no evidence for destrobilation was found. Lower T. spiralis burdens had a correspondingly weaker effect on growth of H. diminuta, and stunting was abolished by administration of the anti-inflammatory drug cortisone acetate. It is concluded that the stunting of H. diminuta is probably due to the non-specific inflammatory component of the rat's response to T. spiralis infection.     

Delayed expulsion of Hymenolepis diminuta in Trypanosoma brucei infected mice

An experiment was conducted to study the effect of Trypanosoma brucei on the expulsion of Hymenolepis diminuta in the mouse. The study showed that T. brucei given 8 days before infection with H. diminuta resulted in a significant delay in the expulsion of the H. diminuta worm burden. This finding is suggested to be due to the immunosuppressive effect of the trypanosome.     

Adsorption of bile salts by the cestodes, Hymenolepis diminuta and H. microstoma.

The accumulation of purified sodium taurocholate (NaTC) and sodium glycocholate (NaGC) by Hymenolepis diminuta and Hymenolepis microstoma (Cestoda: Cyclophyllidea) was determined using radioactive bile salts. H. diminuta reached equilibrium levels of approximately 120 nmoles NaTC/g dry wt and 300 nmoles NaGC/g dry wt. Presentation of the bile salts in mixed micelles with 0.35 mM oleic acid did not alter these values. With H. microstoma, the maxima were 195 nmoles NaTC/g dry wt and 614 nmoles NaCG/g dry wt. These values were similarly unaffected by the addition of 0.35 mM oleic acid to the micelles. Equilibrium values of this magnitude, in media containing as much as 25 or 30 mM bile salt, and the maintenance of this level during incubations of 15 to 60 min eliminated the possibility that the accumulation was by diffusion or by any form of mediated transport into the worm. The accumulation on NaTC by H. diminuta was [Na+] independent, and insensitive to ouabain, DNP, and high [K+]. These observations, the maintenance of different levels of NaTC and NaGC, and the failure of the 2 bile salts to compete indicated that there was no active excretion mechanism operating in a fashion similar to the active transport of bile salts in the vertebrate small intestine. It was concluded that the accumulation of NaTC by H. diminuta was actually adsorption to the tegument. Comparable, although more limited, experiments extended this conclusion to the accumulation of NaGC by H. diminuta and of NaTC and NaGC by H. microstoma. It is suggested that bile salt monomers, rather than intact micelles, adsorb to specific loci on the tegument.     

Effect of the expulsion phase of Trichinella spiralis on Hymenolepis diminuta infection in mice

The rapid elimination of the intestinal phase of Trichinella spiralis in NIH mice is associated with progressive inflammation of the intestinal tract. The non-specific effects of this inflammation were studied in mice concurrently infected with an unrelated parasite, Hymenolepis diminuta, which does not stimulate a visible inflammatory response but is also immunologically rejected by this strain of mice. It was demonstrated that the rejection phase of T. spiralis infection had a marked effect upon the growth and survival of H. diminuta. The cestode either failed to establish or to grow; if the worms were already strobilate when inflammation developed then destrobilation occurred. There was no cross-immunity between the parasites, nor was the interaction a direct consequence of inter-specific competition.     

Mucosal mast cell response to Hymenolepis diminuta infection in different rat strains.

Five-week-old DA male rats infected with 10 Hymenolepis diminuta cysticercoids showed significant mastocytosis 6 weeks post-infection and low persistence of worms. In F344/N rats, however, no mastocytosis and no worm loss occurred during a 6 week infection. Mucosal mast cells appear to be associated with the expulsion of H. diminuta from DA rats.     

Hymenolepis citelli, H. diminuta and H. microstoma: immunoglobulin-containing cells in the lamina propria of the mouse gut during primary and secondary infections

The indirect immunofluorescent technique was used to determine the occurrence of IgA, IgM and IgG1 immunoglobulin-containing cells in local intestinal mucosal immune responses to Hymenolepis citelli, H. diminuta and H. microstoma infections in mice. In the intestinal lamina propria of H. citelli and H. diminuta infected mice there was no increase in the mean numbers of immunoglobulin-containing cells when compared with uninfected control mice, but there was in H. microstoma infected mice. The numbers of IgG1- positive cells in both infected and uninfected mice were very small relative to IgA and IgM immunocytes. The distribution of immunocytes in the lamina propria of infected and uninfected mice was essentially similar and the localization of isotypes in duodenal sections showed no immunoglobulins in the villous epithelial cells. There was also no marked difference between primary and secondary infections indicating that immunoglobulin-containing cells play no major role in functional immunity against hymenolepid infections in the mouse. The presence of IgA and IgM was also demonstrated on the tegument of the tapeworms, although the distribution was patchy and more abundant on H. microstoma than on H. diminuta or H. citelli. The time of appearance of both isotypes was latest on H. citelli.     

Possible immunological damage to the tegument of Hymenolepis diminuta in mice and rats.

Opaque or darkened areas (DA) of variable size and position occur on Hymenolepis diminuta in mice and rats. In mice DA normally first appear in the neck region of the worm but subsequently they appear elsewhere and increase in number until destrobilation or worm expulsion. The posterior of destrobilated worms is often darkened. In the more immunogenic infections with six cysticercoids there are more DA per worm than in infections with one cysticercoid. DA are areas of the tegument with a homogeneous increase in electron density; abnormal mitochondria; reduced granular endoplasmic reticulum, Golgi complexes and discoidal secretory bodies; and accumulation of lipid droplets. DA disappear from worms maintained for up to 4 h in Hanks' balanced salt solution and can be induced by mechanical damage to the worms. As the numbers of DA increase with the duration and intensity of infection and have similarities with types of cell injury, they are probably sites of worm pathology induced by host immunity.     

Hymenolepis muris-sylvaticae and H. microstoma: immunological cross-reaction in mice

A primary infection with Hymenolepis microstoma strongly protects against cross-infection with H. muris-sylvaticae and also against secondary infection with H. microstoma in NMRI mice, resulting in an accelerated loss of worms and a weight reduction of the remaining worms. A primary infection with H. muris-sylvaticae causes an accelerated rejection of secondary infection with H. muris-sylvaticae but it has no effect on cross-infection with H. microstoma, neither with regard to worm recovery nor with regard to worm biomass. Determinations by enzyme-linked immunosorbent assay of antibody concentrations in the mouse sera revealed that: (1) the antibody response evoked by H. microstoma infection is much greater than by H. muris-sylvaticae infection; (2) a cross-infection with H. muris-sylvaticae boosts the antibody response evoked by H. microstoma infection; (3) H. microstoma antigen can be used to measure antibody concentration against both H. microstoma and H. muris-sylvaticae; and (4) although H. muris-sylvaticae is rejected faster in a cross-infection (i.e., after a primary H. microstoma infection) than in a secondary infection (i.e., after a primary H. muris-sylvaticae infection), antibodies evoked by the primary H. microstoma infection show little cross-reaction with H. muris-sylvaticae antigen. This suggests that it is doubtful whether serum antibodies are the direct effectors in worm rejection.     

Characterization of the immuno-regulatory response to the tapeworm Hymenolepis diminuta in the non-permissive mouse host

Hymenolepis diminuta is spontaneously expelled from mice; concomitant with worm expulsion was protection against colitis induced by dinitrobenzene sulphonic acid (DNBS). Here we examined the immune response mobilized by Balb/c and C57Bl/6 male mice in response to H. diminuta and assessed the requirement for CD4+ cells (predominantly T cells) in worm expulsion and the anti-colitic effect. Wild-type (CD4+) or CD4 knock-out (CD4-/-) mice received five H. diminuta cysticercoids and segments of jejunum and mesenteric lymph nodes (MLNs), or spleen, were excised 5, 8 and 1l days later for mRNA analysis and cytokine production, respectively. In separate experiments uninfected and infected mice received DNBS by intra-rectal infusion and indices of inflammation were assessed 3 days later (i.e. 11 days p.i.). Infection of Balb/c mice resulted in a time-dependent increase in intestinal mRNA for Foxp3, a marker of natural regulatory T cells, and markers of alternatively activated macrophages (arginase-1, FIZZ1), while concanavalin-A activation of MLN cells revealed a significant increase in T helper 2 (TH2) type cytokines: IL-4, -5, -9, -10, -13. MLN cells showed a reduced ability to induce Foxp3 expression upon stimulation. CD4-/- mice did not display this response to infection, but surprisingly did expel H. diminuta. Moreover, DNBS-induced colitis in CD4-/- mice (wasting, tissue damage, elevated myeloperoxidase) was not reduced by H. diminuta infection, whereas time-matched infected CD4+ C57Bl/6 mice had significantly less DNBS-induced inflammation. In conclusion: (i) in addition to stereotypical TH2 events, H. diminuta-infected Balb/c mice develop a local immuno-regulatory response; and (ii) CD4+ cells are not essential for H. diminuta expulsion from mice but are critical in mediating the anti-colitic effect that accompanies infection in this model.     

Immunity to adult cestodes: basic knowledge and vaccination problems. A review.

Immunity in mammals to intestinal cestodes has been reviewed using the normal final host infected with the tapeworms Hymenolepis diminuta in rats and H. microstoma and H. nana in mice as a model. Primary infections up to a certain level continue to live as long the host, while most worms in infections with larger doses are destrobilated and expelled. It has been argued that concomitant immunity against a superimposed infection exists in rats and mice infected with H. diminuta and H. microstoma, respectively, and suggested that it also takes place in humans infected with Taenia spp. Immunity to secondary infections after expulsion of a primary infection occurs, but immunological memory is rather short-lived, although depression of worm growth occurs for at least two third of the rat's life. Serum antibodies have been shown to produce a direct precipitate on the surface of cestodes in vitro, but a direct effect of antibodies in vivo or the relationship with e.g. host effector cells, like mast cells and eosinophils, is unknown. It has been shown that peritoneal exudate cells from rats are able to kill H. diminuta in vitro. Very little is known about the mechanisms of tapeworms to counteract host immunological responses, but the tegumental glycoconjugates and discoidal secretory bodies are possible candidates. Passive transfer of immunity by mesenteric lymph node cells has only been successful using cells from H. nana egg-infected mice and has shown that only short-lived proliferating cells are responsible for transferring immunity. Vaccination procedures and problems are discussed with special reference to E. granulosus in dogs.     

Hymenolepis diminuta: ultrastructural abnormalities in worms from C57 mice

Ultrastructural studies, including stereological analyses of micrographs, have been made of five-worm primary infections of Hymenolepis diminuta from C57 mice to determine whether the immune destrobilation/rejection process was accompanied by significant changes in the fine structure of the scolex tegument. Destrobilation/rejection of worms occurred from Days 9-12 after infection. For the first 5 days after infection, the scolex tegument showed no detectable differences in ultrastructure compared with that of "control" worms from either Wistar rats or immunosuppressed C57 mice. By Day 6, large lipid deposits were observed in the tegument and associated musculature of worms from untreated C57 mice. Further, worms recovered from Days 6-8 after infection also showed increased activity of the Golgi apparatus, GER, and mitochondria of the tegument, resulting in increased numbers of discoidal secretory bodies. Concomitant with destrobilation/rejection from Day 9 was a drop in the number of secretory bodies, an increase in autophagic activity throughout the tegument, and a blistering of the tegument surface plasma membrane. The possible functional significance of the results is discussed in relation to host immunity.     

Specific cross-immunity between Hymenolepis nana and H. diminuta: immunization with heterologous and homologous light infections

The consequences of previous and concurrent infection with two related species of cestodes, Hymenolepis nana and H. diminuta, were studied in CD1 mice. A H. diminuta infection strongly affected the establishment and the survival of a secondary H. nana egg or cyst infection administered 30 days later. An infection of 20 H. nana eggs strongly protected against a 5-cyst H. diminuta challenge, whereas an infection of 10 H. nana cysts was ineffective; 20 H. nana eggs also protected against a challenge with 5 cysts of H. diminuta administered 5 days later. No effects were observed in either parasite during a concurrent infection established by administration of cysts. An H. nana egg-infection was unable to affect the establishment of a secondary H. nana cyst-infection given 1 month later; however a significant decrease in growth was found. Similar results were found when a primary H. nana egg-infection was followed 5 days later by the homologous cyst-infection. But an infection with 5 H. nana cysts was unable to protect against a homologous challenge of 5 cysts or 200 eggs. The reciprocal cross immunity between the heterologous parasites and the failure of protection of homologous challenges are discussed in relation to light infections.     

Effect of host feeding and available glucose on glycogen synthase and phosphorylase activities in Hymenolepis diminuta and Vampirolepis microstoma

The influences of host feeding and the availability of glucose in vitro on the activities of glycogen synthase and glycogen phosphorylase in Hymenolepis diminuta and in Vampirolepis microstoma were studied. The worms were recovered from hosts that had been fed ad libitum, starved for 24 hr, or starved 24 hr and then refed for 1 hr immediately prior to worm recovery. The ratios of active to inactive glycogen synthase and phosphorylase were correlated with the host feeding regimen prior to recovery. Glycogen synthase in H. diminuta was predominately in the inactive D form in worms from both fed and fasted hosts. One hour after refeeding, up to 80% of the synthase was in the active I form. Phosphorylase in H. diminuta was predominantly in the active a form in worms from fed and fasted hosts, but activity of this enzyme was suppressed in worms from refed hosts. When H. diminuta from fasted hosts was incubated in a balanced salt solution containing 40 mM glucose, glycogen synthase I increased, and phosphorylase a decreased. Glycogen synthase in V. microstoma was predominantly in the inactive D form in worms from both the fed and fasted hosts, but the proportion in the active I form increased to over half the total synthase by 1 hr of host refeeding. The proportion of glycogen phosphorylase a was high in worms from fed hosts and decreased, but not dramatically, in worms from fasted hosts. The results suggested that the worms had access to another source of glucose, probably from the host bile, and we measured a low but significant concentration of carbohydrate in the gall bladder bile of mice.(ABSTRACT TRUNCATED AT 250 WORDS)     

Ileal mucosal mast cell, eosinophil, and goblet cell populations during Hymenolepis diminuta infection of the rat.

The population dynamics in the enteric connective tissues of eosinophils, mucosal mast cells (MMC), and in the mucosal epithelium of goblet cells were examined morphometrically in fixed ileal tissue of outbred Sprague Dawley rats during the first 32 days of infection with the tapeworm Hymenolepis diminuta. MMC and eosinophils were present in the lamina propria and submucosa; however, only eosinophils were also present in the muscularis externa. Eosinophilic infiltrate was first observed in the lamina propria at 15 days postinfection (dpi) and the numbers of eosinophils remained elevated through 32 dpi. Initial mucosal mastocytosis was detected on 6 dpi and MMC numbers continued to rise over the study period without reaching a plateau. Goblet cell hyperplasia occurred only at 32 dpi. In contrast to some intestinal nematode infections where these same 3 cell types are associated with the host's expulsion responses, H. diminuta is not lost by a rapid host response in the outbred Sprague Dawley rat strain used in these experiments. We suggest that either the induction of hyperplasia of these host effector cells in ileum tissue during H. diminuta infection is not capable of triggering parasite rejection mechanisms, or the function of the induced hyperplasia is necessary for some as yet unassociated physiological or tissue architecture change in the host's intestine.     

Hymenolepis nana: immunity against oncosphere challenge in mice previously given viable or non-viable oncospheres of H. nana, H. diminuta, H. microstoma and Taenia taeniaeformis

When mice, previously given oral inoculation with viable oncospheres of the heterologous cestode species (Hymenolepis diminuta, H. microstoma, Taenia taeniaeformis) and the homologous one (H. nana), were challenged with oncospheres of H. nana 4 days after the primary inoculation, they showed strong and complete resistance to H. nana challenge, respectively. However, the resistance was not evoked in mice given either infective eggs of Toxocara canis or non-viable oncospheres of all cestode species examined. Congenitally athymic nude mice given viable oncospheres did not show any resistance to H. nana either. Eosinophil infiltration around cysticercoids of H. nana in the intestinal villi appeared to be more prominent in mice previously given viable oncospheres of H. diminuta than in mice given non-viable oncospheres or PBS only. Some of the eosinophils in the villus harboring cysticercoid(s) of H. nana invaded the epithelia in the former, whereas all eosinophils remained in the lamina propria in the latter. There was almost no eosinophil infiltration in nude mice. Microscopic observations revealed that oncospheres of H. diminuta, which require beetles as the intermediate host like H. microstoma, could invade the mouse intestinal tissue. Therefore, it is strongly suggested that the strong cross resistance to H. nana in mice, induced by oncospheres of all heterologous cestode species, is thymus-dependent and due to oncospheral invasion into the intestinal tissue of mice.     

Differential establishment and survival of Hymenolepis diminuta in syngeneic and outbred rat strains.

Experimental Hymenolepis diminuta infection was carried out in inbred strains of rats (F344/N, JAR-2, LOU/M, TM, DA and DA-bg/bg) and outbred Wistar rats. All strains became infected with this cestode, but clear strain-dependent variation in the susceptibility to H. diminuta infection was observed. Marked differences in worm persistence and worm weight were found at 6 weeks post-infection in TM and DA rats. These strains would be useful to clarify the interactions between H. diminuta and its rat host.     

Biochemical, physiological and morphological variation in unarmed hymenolepids (Eucestoda: Cyclophyllidae)

The genus Hymenolepis contains a number of unarmed species. These frequently possess similar morphologies and are difficult to discriminate using the traditional method of comparative morphology. A parasite of the long-tailed field mouse, Apodemus sylvaticus in northeast Ireland, resembles the widespread H. diminuta which is usually a parasite of the rat. Analysis of general and specific proteins of the adults in A. sylvaticus , laboratory mice and rats suggests that the parasite found in the former host and H. diminuta are genetically distinct, though more closely allied than either is to H. nana, H. citelli and H. microstoma . Experimental analysis of the growth and expulsion of the Irish material and H. diminuta from SPF C57 laboratory mice, rats and wild caught A. sylvaticus suggests that there are behavioural and physiological differences in these taxa. Both are expelled from C57 mice though the hymenolepid from Irish A. sylvaticus persists for 3 days more than those of H. diminuta . The former prospers better in rats than H. diminuta in A. sylvaticus . Detailed comparison of the gross morphology of cysticercoid and adult H. diminuta and the Irish hymenolepid reveals differences in size rather than qualitative attributes. The occurrence of H. diminuta in A. sylvaticus is discussed. It is concluded that the hymenolepid recovered from Irish A. sylvaticus differs sufficiently from H. diminuta to warrant species status and that it has adapted to the alimentary canal of A. sylvaticus . This cestode material is described under the name of H. hibernia sp. nov.     

Hymenolepis diminuta and H. nana: cross immunity against the lumen phase in BALB/c mice

When BALB/c mice initially given cysticercoids of Hymenolepis diminuta orally (Day 0) were challenged with eggs or cysticercoids of H. nana, almost all the mice became completely resistant to H. nana challenges from Day 30 onward, and no luminal adults of H. nana were established. There was a tendency for the number of tissue cysticercoids recovered 4 days after egg challenge in immunized mice to be much less than that in control mice (P less than 0.001, Student's t test). However, when these cysticercoids recovered from immune group mice were inoculated into uninfected mice, they matured in the lumen. Thus, the cross immunity to H. nana challenge evoked by an initial prepatent infection with H. diminuta appeared to be directed not against the tissue phase but against the lumen phase of H. nana. When BALB/c mice initially given eggs of H. nana were challenged with H. diminuta, they became resistant to H. diminuta from Day 15 onward. When the mice given eggs of H. nana were treated with a cestocide, praziquantel, at the beginning of the expected luminal development of H. nana and experienced a tissue phase only before challenge with H. diminuta, they showed no resistance to H. diminuta. Thus, the cross immunity to H. diminuta challenge evoked by an initial patent infection with H. nana appeared to be due to the immunogens of the lumen phase of H. nana but not those of the tissue phase. The cross immunity may be, therefore, essentially evoked by the lumen phase of these two phylogenetically closely related species and not by or against the tissue phase of H. nana.(ABSTRACT TRUNCATED AT 250 WORDS)