Hymenolepis nana: Maturation in an immunosuppressed unnatural rat host

When eggs of the dwarf tapeworm Hymenolepis nana, cycled exclusively and directly through mice for more than 10 years, were inoculated into previously uninfected inbred Fischer (F344) strain rats, they failed to mature in the rat intestinal lumen. Eggs of H. nana inoculated into the rat developed normally into cysticercoids (cysts) in the intestinal tissue, but thereafter failed to mature in the lumen except when the host was treated with cortisone acetate from the day of cyst maturation. The Fischer rat initially given eggs of H. nana became completely immune to egg challenge within 2 days of egg inoculation; no cysts derived from challenge eggs were found in the immunized rat. Immunosuppression, assessed by the success of cyst recovery in the tissue 4 days after egg challenge, had no promotive effect on the recovery of adult worms derived from eggs initially inoculated. Rats initially given eggs and immunosuppressed by cyclophosphamide or antithymocyte serum did not harbor any adult worms. Cortisone acetate treatment which was sufficient for eggs inoculated to mature (a total of 75 or even 200 mg, from Day 5 of egg inoculation) had no effects of immunosuppression, whereas cortisone acetate treatment which was sufficient for immunosuppression (a total of 150 mg from Day -2, two days prior to the initial egg inoculation) induced some adult formation as well. In addition, when mouse-derived cysts were inoculated into the rat instead of eggs, they also failed completely to mature even when the rat was treated with cyclophosphamide or antithimocyte serum. However, when the rat was treated with cortisone acetate from the day of cyst inoculation, the cysts developed into adult worms. Therefore, these results indicate that the Fischer rat clearly differs in its susceptibility to the tissue phase of egg inoculation and to the lumen phase of cyst inoculation of H. nana, and strongly suggest that the failure of maturation of H. nana in the unnatural host Fischer rat is not attributed to innate and/ or acquired immunity of the rat but to other nonimmunological mechanisms.     

Cortisone-sensitive, innate resistance to Hymenolepis nana infection in congenitally athymic nude rats

The innate resistance of the unnatural rat host to the mouse tapeworm Hymenolepis nana is cortisone sensitive but thymus independent. When congenitally athymic nude rats were orally given eggs, cysticercoids, or adult worms of H. nana, no lumenal adults were established except when they were treated with cortisone acetate during the expected lumenal development. The effect of cortisone to promote adult maturation in the rats was compared in nude and normal rats given eggs of H. nana. The fecundity of the worms (assessed by the fresh worm biomass and the number of infective eggs produced) was much higher in cortisone-treated nude rats than in cortisone-treated normal rats. When the nude rats reconstituted with thymocytes were given eggs and treated with cortisone, the fecundity of H. nana dropped to the same level as in cortisone-treated normal rats. It is strongly suggested that the unnatural rat host has thymus-independent cortisone sensitive resistance to an initial infection (which is the main component of the innate resistance and blocks the lumenal establishment of this parasite) and thymus-dependent resistance (which suppresses the established worms' fecundity and may be ascribed to acquired resistance to the ongoing infection).     

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)     

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.     

Failure to infect laboratory rodent hosts with human isolates of Rodentolepis (= Hymenolepis) nana

Confusion exists over the species status and host-specificity of the tapeworm Rodentolepis (= Hymenolepis) nana. It has been described as one species, R. nana, found in both humans and rodents. Others have identified a subspecies; R. nana var. fraterna, describing it as morphologically identical to the human form but only found in rodents. The species present in Australian communities has never been identified with certainty. Fifty one human isolates of Rodentolepis (= Hymenolepis) nana were orally inoculated into Swiss Q, BALB/c, A/J, CBA/ CAH and nude (hypothymic) BALB/c mice, Fischer 344 and Wistar rats and specific pathogen free (SPF) hamsters. Twenty four human isolates of R. nana were cross-tested in flour beetles, Tribolium confusum. No adult worms were obtained from mice, rats or hamsters, even when immunosuppressed with cortisone acetate. Only one of the 24 samples developed to the cysticercoid stage in T. confusum; however, when inoculated into laboratory mice the cysticercoids failed to develop into adult worms. The large sample size used in this study, and the range of techniques employed for extraction and preparation of eggs provide a comprehensive test of the hypothesis that the human strain of R. nana is essentially non-infective to rodents.     

Stage-specific immunogens of Hymenolepis nana in mice

Treatment with praziquantel at the beginning of the lumen phase of Hymenolepis nana in mice showed conclusively that: (i) the mouse given eggs of H. nana produces two separate immune responses against reinfection, one directed exclusively against the tissue phase of egg challenge (early response), the other against the lumen phase of cysticercoid challenge (late response); (ii) a tissue phase of egg inoculation is not necessary for initiating the late response but is necessary to provoke the early response; and (iii) H. nana expresses several stage-specific immunogens through its development in the mouse host.     

Lumen phase specific cross immunity between Hymenolepis microstoma and H. nana in mice

, and 1988. Lumen phase specific cross immunity between Hymenolepis microstoma and H. nana in mice. International Journal for Parasitology 18: 1019–1027. When mice inoculated with five cysticercoids of Hymenolepis microstoma were challenged with H. nana, they showed strong resistance to challenges with both eggs and cysticercoids of H. nana from day 20. The immunity became complete from day 30 onward: no tissue cysticercoids or lumenal adults of H. nana were established in these mice. However, when mice were challenged with H. nana 10 or 20 days after 10-day old immature H. microstoma were removed by an anthelmintic, the immunity evoked was directed exclusively against the lumenal phase of the cysticercoid challenge but not the tissue cysticercoids of the egg challenge. When mice experienced the prepatent infection with H. microstoma twice, the immunity evoked was also against the lumenal phase of the egg challenge: the oncospheres developed into tissue cysticercoids but thereafter completely failed to develop into lumenal adult tapeworms. Infection with a single cysticercoid of H. microstoma was shown to be sufficient to evoke immunity against H. nana cysticercoid infections in two strains of mice. Sera from mice which experienced a patent infection with H. microstoma revealed that IgG, IgA, IgM isotypes reacted against oncospheres and cysticercoids of both species, while sera from mice which experienced two prepatent infections reacted with cysticercoids only. Sera from H. microstoma infected mice resistant to H. nana caused precipitations on 4-day-old H. nana in vitro. A correlation exists between the presence of stage specific antibodies and resistance to the different stages.     

Hymenolepis microstoma: direct life cycle in immunodeficient mice

The mouse bile duct tapeworm Hymenolepis microstoma requires beetles as the obligatory intermediate host. However, when congenitally athymic NMRI-nu mice were infected with the mature tapeworm and allowed to eat their own faeces with tapeworm eggs, the oncospheres penetrated the intestinal tissue and developed to cysticercoids. After excysting, growth to adult worms occurs in the lumen of the small intestine and bile duct. Furthermore, the same happened when NMRI-nu mice, non-obese diabetic severe combined immunodeficiency (NOD/Shi-scid) mice and NOD/Shi-scid, IL-2 Rgamma(null) (NOG) mice were orally inoculated with shell-free eggs of this parasite. Differences between the cysticercoids of H. microstoma and H. nana developed in the mouse intestinal tissues were: (i) the time course for the development of fully matured cysticercoids of H. microstoma in mice was about 11 days but only 4 days for H. nana; and (ii) cysticercoids of H. microstoma developed in mice had a tail while those of H. nana had none.     

Complete resistance to challenges with Hymenolepis nana cysticercoids derived from mouse, rat and beetle in mice

and 1986. Complete resistance to challenges with Hymenolepis nana cysticercoids derived from mouse, rat and beetle in mice. International Journal for Parasitology 16: 623–628. When BALB/c and dd strains of mice were given eggs of Hymenolepis nana, they all became completely resistant not only to challenge with mouse-derived cysticercoids but also to challenges with rat-derived and beetle-derived cysticercoids. Serum IgG antibodies at 47–60 days post egg inoculation reacted strongly with these three different host-derived cysticercoids when examined by IFA test, but IgA and IgM isotypes reacted very weakly. Antibodies of infected mouse sera (IgG, IgM and IgA were examined) reacted not only with the protoscolex (scolex of the excysted juvenile) but also with the outer cyst wall. By contrast, uninfected mouse sera and immune sera prepared seven days post cysticercoid inoculation did not react at all. Antigens of both cyst wall and protoscolex appeared to be of parasite origin and not of host origin, and appeared similar in parasites from the different host species.     

Hymenolepis nana: passive transfer of mouse immunity by T-cell subset of phenotype Lyt-1

Mesenteric lymph node cells obtained from donor mice (BALB/c strain) actively immunized by oral inoculation with Hymenolepis nana eggs were syngeneically transferred by intravenous injection into athymic nude mice previously uninfected. The adoptively immunized recipients were then challenged with 1000 H. nana eggs 2 days after cell transfer. The degree of immunity transferred was assessed by examining cysticercoids developed in the intestinal villi of the recipients on Day 4 of challenge infection. The criterion for success in cell transfer of immunity was the complete rejection of cysticercoids as was generally expected in mice infected previously. The transfer of 1.5 X 10(8) immune mesenteric lymph node cells obtained from donors immunized 4 days before cell collection resulted invariably in the complete rejection of cysticercoids, though not less than this cell dosage. The immunity was passively transferable to recipients by T cells, especially by T-cell subset of phenotype Lyt-1 but not those of phenotype Lyt-2.3 and Lyt-1.2.3. However, 1.5 X 10(8) immune mesenteric lymph node cells obtained from donors immunized 21 days before cell transfer and 1.5 X 10(8) immune spleen cells obtained from donors immunized 4 days before cell transfer had little or no effect on the rejection of cysticercoids.     

Hymenolepis nana: adoptive transfer of protective immunity and delayed type hypersensitivity response with mesenteric lymph node cells in mice

A marked degree of footpad swelling was observed in BALB/c mice infected with Hymenolepis nana eggs, when soluble egg antigen was injected into their footpads 4 to 21 days after the egg infection, indicating delayed type hypersensitivity responses in infected mice. Adoptive transfer with mesenteric lymph node cells from donor mice (BALB/c strain; +/+) infected with eggs 4 days before cell collection could confer this hypersensitivity to recipient nude mice (BALB/c strain; nu/nu). These mesenteric lymph node cells were then divided into two fractions, blast-enriched and blast-depleted cells, by density gradient centrifugation with Percoll. The recipients intravenously injected with the blast-depleted cell fraction showed a marked increase in footpad thickness, whereas the intravenous transfer of the blast-enriched cell fraction resulted in an insignificant increase in footpad thickness. The transfer of the blast-enriched cell fraction, but not of the blast-depleted cell fraction, conferred a strong adoptive immunity on syngeneic recipient nude mice, when the immunity transferred was assessed by examining cysticercoids developed in the intestinal villi on Day 4 of challenge infection. The lack of delayed type hypersensitivity response in mice that received the blast-enriched cell population was not due to a lack of the capacity of the cells to induce the response, because the cells were capable of inducing a significant increase in thickness of footpads of normal mice when these cells were locally injected into the footpad together with soluble egg antigen.(ABSTRACT TRUNCATED AT 250 WORDS)     

Hymenolepis nana: intestinal tissue phase in actively immunized mice.

We investigated the fate of the intestinal cestode Hymenolepis nana in immunized mice. Immunity was induced by infection with the parasite eggs. These immunized animals and unimmunized controls were then challenged with 50,000 H. nana eggs. The mice were killed 4 to 90 hr after challenge, and H. nana in the intestinal tissue were counted. At 4 hr after challenge the unimmunized and immunized animals had approximately equal numbers of oncospheres. By 12 hr there were fewer parasites in the immunized than in the unimmunized animals. At 90 hr, no H. nana were seen in the immunized mice, whereas in the unimmunized animals the median number of cysticercoids was more than 1,000. It appears, therefore, that in mice well immunized to H. nana by infection, challenge oncospheres can burrow into the intestinal tissue before they are killed. The reduced number of oncospheres in the immunized mice 12 hr after challenge, and the accumulation of eosinophils near individual oncospheres still present, indicate that an immune response to the parasite was taking place. Absence of a lymphocyte infiltration near any of the oncospheres suggests that the mechanism of immunity was not lymphocyte mediated; thus, the histopathology of the reaction is consistent with that of humoral immunity.     

Some influences of population density on Hymenolepis diminuta in rats.

When measured 56 days postinfection the length, wet weight and dry weight of Hymenolepis diminuta were all found to decrease with increasing number of cysticercoids given up to 20. The mean position of the worms in 10, 12 and 20 worm infections is significantly posterior to that of 1, 2 and 5 worm infections and the worms are attached over a wider area of the intestine. Egg production by the worms was followed up to day 56 postinfection; the number of eggs produced per worm and even per rat decreased with increasing population density. Thus the best way to get most eggs and to maintain the parasite in the laboratory is to have rats infected with only one tapeworm. Rats given 1-20 cysticercoids showed a mean recovery of 100-65%, while rats given 40-200 cysticercoids showed a mean recovery ranging from 13 to 2%. In addition to 'normal' worms, defined as worms greater than 10 mm, small, most probably destrobilated, worms were found. In the 50 and 100 cysticercoid infections, worm recoveries were, respectively, 8% 'normal', 16% small, and 2% 'normal', 5% small. From the significantly lower recovery from heavy infections it is concluded that a deleterious factor is operating during the 8 weeks after the infection.     

Hymenolepis nana: Protective immunity against mouse-derived cysticercoids induced by initial inoculation with eggs

Mice were almost completely resistant to a mouse-derived cysticercoid (cyst) challenge after 6 to 10 months following an initial immunizing inoculation with eggs of Hymenolepis nana. Previously uninfected control mice of the same age became infected with the cyst-derived tapeworms. There was no age resistance to H. nana in mice. Immunity against the cyst challenge was acquired by initial egg inoculation and blocked by injecting cortisone acetate just prior to the challenge. However, the number of worms recovered from mice given cortisone was significantly less than that from nonimmunized controls. Unexpected evidence was obtained that a few of the egg-derived tapeworms can survive for 6 or more months in some of the immunized mice, which are resistant to both egg and cyst challenges. The relative immunogenicity of oncospheres and cysts is discussed. It is strongly suggested that the cysts are different from the oncospheres in their immunogenicity, and, because of this, H. nana can complete its life cycle in the same immunized host. It is also suggested that the host possesses at least two separate immune responses: One is an early response directed exclusively against the oncosphere and/or the early postoncospheral stage (s) acquired within 2 days of egg inoculation, and the other is a late response against the cyst acquired after a time lag of unknown duration.     

Immunity to Hymenolepis diminuta: unresponsiveness of the athymic nude mouse to infection.

Male and female congenitally athymic nude (nu/nu) mice infected with a single cysticercoid of Hymenolepis diminuta at 6 weeks of age retain the infection for at least 33 days. In the males of their phenotypically normal litter-mates, however, a single cysticercoid infection establishes and grows but is expelled between days 11 and 17. The unresponsiveness of the nude mouse to single H. diminuta infection is evidence that the immune rejection from normal mice is thymus-dependent.     

Reinfection and recidive in Hymenolepis nana infections (author's transl)]

The excretion of Hymenolepis nana eggs begins in CF-1 mice between the 11th and 12th day irrespective of the wormload. In Swiss mice, however, the onset of egg excretion can be retarded up to the 15th day if the number of parasites is high. The re-appearance of eggs after treatment occurs between the 6th and 9th day using an exact diagnostic method. If the number of parasites is low, than re-appearance of eggs occurs later than if it is high. An infection with eggs protects mice for several months against a re-infection with eggs but not against one with cysticercoids. If cysticercoids are used to establish the primary infection no immune reaction against a re-infection develops. If eggs reappear in the faeces after treatment then the following conclusion can be drawn: Eggs reappear within a week after treatment then it must be a relapse. Eggs reappear during the second week then it can be either a relapse or a re-infection. Eggs reappear at three weeks or later then it can only be due to a re-infection.     

Hymenolepis nana: Immunogenicity of a lumen phase of the direct cycle and failure of autoinfection in BALBc mice

When $\text{BALB}\text{c}$ mice were given $\text{BALB}\text{c}$ mouse-derived cysticercoids (cysts) of Hymenolepis nana, only $\text{1}\text{43}$ mice became autoinfected, whereas most ($\text{31}\text{38}$) of dd mice given the same infection became massively autoinfected with mature worms. When $\text{BALB}\text{c}$ mice initially given cysts were challenged with eggs on Day 7, just before the patency of the primary infection, there was normal development into cysts, but almost none of them developed into adult worms. Thus, the failure of autoinfection of H. nana in $\text{BALB}\text{c}$ mice was not a result of failure of eggs to differentiate into cysts in the intestinal tissue, but a result of failure of these cysts to develop into adult worms in the lumen. The reasons why autoinfection does occur in dd and other strains of mice and not in the $\text{BALB}\text{c}$ strain are discussed in terms of the difference in onset of the late response in these strains of mice, ie., the response that is acquired after egg inoculation, and is directed against the lumen phase of cyst challenges. It is strongly suggested that (1) the lumen phase which follows cyst inoculation is highly immunogenic, but clearly differs from tissue phase which follows egg inoculation, (2) the autoinfection which occurs in some strains of mice is therefore not a result of no or poor immunogenicity of the lumen phase but is due to a delay of onset of the late response with the result that a secondary generation may mature, and (3) in other strains of mice, including $\text{BALB}\text{c}$, which acquire the late response within 15 days of initial egg inoculation, autoinfection normally does not occur after cyst infections.     

Mannose and the ‘Crowding effect’ of Hymenolepis in rats

Hymenolepis diminuta from rats infected with 10 cysticercoids and fed on a diet containing 3% (w/w) mannose for 4 weeks were found to be, on average, much heavier in terms of dry weight (46 mg) than those from rats fed on diets containing an equivalent concentration of either galactose, glucose or fructose (18 mg). Subsequently, the numbers, egg production and dry weights of worms were determined from rats which had been infected with doses varying from 0 to 160 cysticercoids per rat and fed on diets containing either 0, 1, 4, or 8% mannose (w/w). Density-dependent decreases in both worm dry weight and egg production were detected at 5 weeks post-infection, but both the number of worms recovered and their prepatent period appeared to be independent of cysticercoid dose. Differences in the distribution pattern of individual worm dry weights were observed between rats harbouring low (1–15) and high (16–135) worm burdens. Worms recovered from rats infected with 10 cysticercoids and fed on a diet containing 4% mannose (w/w) for 3 weeks were found to be, on average, more than twice as heavy (37 mg) as those from rats fed on diets containing 1, 2, or 8% mannose (w/w) for equivalent periods of time (16 mg). The results indicate that the ‘crowding effect’ cannot be explained simply in terms of inter-worm competition for carbohydrate.     

Effects of homozygosity of the nude (rnu) gene in an inbred strain of rats: studies of lymphoid and non--lymphoid organs in different age groups of nude rats of LEW background at a stage in the gene transfer

Several age groups of nude homozygous rnu/rnu and heterozygous rnu/+ rats of the same genetic background at an early stage of back-crossing (LEW/Mol) were compared as to body and organ weights, histological appearance and cell density of lymphoid organs, haematological values and differential counts of bone marrow and peripheral blood. No thymic tissue was found in the nude animals. 7-week-old nudes were smaller than control animals and had relatively larger non-lymphoid organs and cell-depleted peripheral lymphoid organs. Other age groups showed little difference. Peripheral blood of nude rats showed no signs of lymphopaenia in contrast with the findings in nude mice. The number of thoracic duct lymphocytes was, however, significantly smaller in all age groups of the nude rats, and the bone marrow tended to contain fewer lymphocytes.     

Host age and the growth and fecundity of Hymenolepis diminuta in the rat

Five, 20, and 80 cysticercoid infections of Hymenolepis diminuta were established in 1-, 2- and 5-month-old male Wistar rats. Worm numbers, dry weights and egg outputs were determined on day 28 post infection. Worm recovery was found to be independent of cysticercoid dose in 1-month-old rats, but density-dependent in older rats. Density dependence affected both worm dry weight and egg production in all 3 age classes of host studied. However, at the highest dose both dry weight and egg production were significantly decreased in 2- and 5-month-old rats compared with 1-month-old rats. The results cannot be explained solely in terms of competition for a resource, and suggest that immunological mechanisms may have an important role in the "crowding effect".