The source of antigen in an adult tapeworm

Hopkins C. A. and Barr I. F. 1982. The source of antigen in an adult tapeworm. International Journal for Parasitology12: 327–333. Although a primary infection of Hymenolepis diminuta is not rejected for 9–15 days by a mouse, it has been shown that a primary infection terminated chemically after only 3 days induces as good protection against challenge. This demonstrated that a scolex and 1–2 mm of neck tissue (all that is formed by day 3 post infection) are an adequate source of ‘protective’ antigen. Irradiated (350 Gy) cysticercoids which survive but show little growth immunize as effectively as normal cysticercoids which indicates actively growing neck tissue is not essential and hence the scolex alone is a sufficient source of ‘protective’ antigens. In the rat irradiated cysticercoids were found to establish, double their length over 3–6 days and then slowly shrink, but 14% of the worms were still present 49 days p.i. Although a primary infection of normal worms in a rat markedly depresses growth of a secondary infection administered 7 days after the chemical expulsion of the primary, irradiated scoleces induced no measurable protection. These results are discussed in relation to the source of antigen and the fundamental difference in the protective response of mice (an abnormal host) and rats (a normal host) to the tapeworm H. diminuta in the small intestine.     

Secondary infections of Hymenolepis diminuta in mice: effects of varying worm burdens in primary and secondary infections.

In one (1 c) and six (6 c) cysticercoid primary infections of Hymenolepis diminuta in NIH (inbred) and CFLP (outbred) male mice 6 +/- 1 weeks old greater than 85% of the worms established but were rejected (destrobilated or expelled) subsequently. Rejection occurs more quickly in 6 c infections than in 1 c infections. Considerable worm growth occurs in 1 c and 6 c primary infections but worms from 6 c infections weighed less than worms from 1 c infections on all days studied. Expulsion of H. diminuta does not occur more rapidly in secondary infections than in primary infections; loss of 6 c secondary worms occurs at the same rate as 6 c primary worms but 1 c secondary worms survive longer than 1 c primary worms. Although worms are not lost more quickly in secondary than in primary infections, they are affected at an early age by the immune response which stunts their growth. Increasing the intensity of primary and secondary infections increases the severity of stunting of secondary worms. The results are discussed and it is suggested that immune responses to Hymenolepis spp. in rodents are common but that thresholds of worm numbers exist below which appreciable worm loss does not occur. Stunting due to crowding, which generally is attributed to inter-worm competition, may be in part immunologically mediated. For future immunological studies attempting to induce secondary responses to H. diminuta in mice, worm growth, not survival, is the criterion to evaluate.     

Kinetics of primary and secondary infections with Strongyloides ratti in mice

Dawkins H. J. S. and Grove D. I. 1981 Kinetics of primary and secondary infections with Strongyloides ratti in mice. International journal for Parasitology11: 89–96. The kinetics of infection with S. ratti were quantitated in normal and previously exposed C57B1 /6 mice. In primary infections, larvae penetrated the skin rapidly and were seen in peak numbers 12 h after infection. By 24 h after infection, larval numbers had declined appreciably and there was a slow decrease in numbers thereafter. Larvae were first observed in the lungs at 24 h and maximal recovery occurred at 48 h. It is thought that larval migration through the lungs is rapid. Worms were first seen in the intestines two days after infection. Maximum numbers were seen on the fifth day and worm expulsion was complete by day 10. Two moults took place in the small intestine during days 3 and 4 after infection. Rhabditiform larvae were first noted on the fourth day after infection. Mice exposed to S. ratti four weeks previously had significantly less larvae in the skin 4 and 12 h after infection but by 24 h there was no difference when compared with mice with primary infections. Peak recovery of larvae from the lungs occurred 24 h after infection; significantly less larvae were recovered on days 2 and 3 when compared with normal mice. There was a marked reduction in the adult worm burden in the gut; the number of worms recovered was less than one fifth of that seen in primary infections. Those worms which did mature were less fecund and were expelled from the intestines within 7 days of infection. It is suggested that in previously exposed animals, the migration of larvae from the skin is hastened, many of these larvae are destroyed in the lungs and that expulsion of worms which do mature in the intestines is accelerated.     

Complement-mediated lysis in vitro of newly excysted tapeworms: Hymenolepis diminuta, Hymenolepis microstoma, Hymenolepis nana and Hymenolepis citelli

Bøgh H., Christensen J.P.B. and Andreassen J. 1986. Complement-mediated lysis in vitro of newly excysted tapeworms: Hymenolepis diminuta, Hymenolepis microstoma, Hymenolepis nana and Hymenolepis citelii. International Journal for Parasitology16: 157–161. Newly excysted worms of Hymenolepis diminuta were lysed in 50% normal serum from all 13 animal species tested, including man. Since H. diminuta was neither lysed in complement inactivated serum—by heat or adding EDTA, LPS or CVF—nor in C5-deficient mouse serum, it is concluded that the lysis was associated with the complement cascade. It is shown that H. diminuta can activate the complement system via both the classical and alternative pathway. Furthermore, it is indicated that the lysis is independent of serum antibodies. Hymenolepis nana and H. citelli were also lysed in all normal sera tested, eight and six respectively, while newly excysted worms of H. microstoma were lysed in normal sera from 10 mammals and birds, but not in sera from its hosts, the mouse, rat and golden hamster. This indicates that the complement system of these three species differs from that of the other species tested in such a way that H. microstoma is able to avoid lysis in these sera.     

Influence of primary infection on the population dynamics of Nematospiroides dubius after challenge infections in mice

Dobson C., Sitepu P. and Brindley P. J. 1985. Influence of primary infection on the population dynamics of Nematospiroides dubius after challenge infections in mice. International Journal for Parasitology15: 353–359. Similar proportions of the inoculum of Nematospiroides dubius larvae reached sexual maturity by 14 days after administration of 50–400 larvae but more adult worms had been expelled by day 63 after infection from those mice infected with 50 vs 400 larvae. There was a significant correlation between time and worm expulsion for all inoculum size groups except for mice given 400 larvae.In mice reinfected with 100 larvae, after termination of primary infections derived from 10 through 400 larvae, more worms from the challenging dose were recovered from mice given greater compared with those given smaller numbers of larvae at primary infection. The N. dubius population size after challenge infection was correlated positively both with number of larvae administered as the primary infection and with the resultant population size during that infection. The serum anti-N. dubius antibody titres after reinfection were higher in mice given 400 compared with those given fewer larvae at primary infection, and the fecundity and female to male sex ratio of the N. dubius populations decreased in proportion to these antibody titres.Protective immunity against challenge N. dubius infection, in mice which had been drenched free of adult worms established from 400 larvae for 5 down to 1 weeks before reinfection, increased from 45% (1 week) to 80% (5 weeks). There was a negative correlation between the population size of N. dubius during challenge infection and the duration between anthelmintic treatment and challenge infection.     

Immunological damage to Hymenolepis diminuta following a challenge infection in C57 mice

Immunological damage to Hymenolepis diminuta following a challenge infection in C57 mice. International journal for Parasitology17: 795–803. Ultra-structural observations were made on the scpleces of Hymenolepis diminuta from 10-worm 2° infections in C57 mice to determine whether the immune stress causing reduced establishment, stunting of growth and early rejection was accompanied by significant damage to the worm fine structure. In almost all of the worms recovered there was extensive damage to tissues throughout the scolex, even in those examined 24 h post-secondary-infection (p-2°-i). Many of the muscle, tegumental and parenchyma cells were completely disrupted and dispersed, leaving only isolated strands of cytoplasm and cell debris. A number of excretory ducts were breached, and large and apparently empty spaces were evident throughout the scolex tissues. There was an increase in lipid accumulation in the tegumental syncytium, underlying cytons and in the suckers. Extensive vacuolation also occurred in the sucker tegument. Although some scoleces showed certain regions to be apparently undamaged, close examination revealed a fine structure consistent with enhanced metabolic activity. The structural abnormalities observed are discussed in relation to host immunity.     

Immunity to tapeworms: acquired resistance to Hymenolepis citelli in the mouse

The dynamics of secondary infections with Hymenolepis citelli in mice are described. A primary infection of one and six cysticercoids for 21 days sensitized CFLP male mice against homologous challenge infections. Acquired resistance was manifested mainly as stunting/destrobilation of secondary worms. The severity of stunting depended on the intensity of the primary infection. Secondary worms were not expelled more rapidly than primary worms but the protective response retards growth early in challenge infections. Sensitization of mice for seven days with six or 24 cysticercoids did not confer a measurable protective response, whereas priming by the same regime for 21 days induced a significant protective response. Acquired resistance to challenge waned with time in the absence of the primary worms. The growth and survival of a six-cysticercoid primary infection was enhanced by the administration of the immunosuppressant drug cortisone acetate. Worms from cortisone-treated mice were heavier than those from untreated controls. Acquired resistance to homologous challenge was also partially ablated in cortisone-treated mice. It is suggested that rejection of primary infections and stunting/destrobilation of secondary worms may be immunologically mediated.     

Loss of Hymenolepis diminuta from the rat

One, 5, 15 and 30 worm infections of Hymenolepis diminuta were established in juvenile or adult male (Hooded Rowett or Sprague-Dawley) rats. Worm numbers and weight, and egg output were determined from day 15 to day 85 post infection. Gradual worm loss occurred only from 15 and 30 worm infections. In 5, 15 and 30 worm infections worm weight decreased from day 19 to day 50 but no weight loss occurred in single worm infections. The size range of individual worms from a multiple infection of a single rat increased markedly following infection. Adult rats showed a greater worm loss and harboured smaller worms than juvenile rats. The data will fit either a competitive or an immunological model.     

Growth and development of Hymenolepis nana in mice maintained at different environmental temperatures

Growth and development of Hymenolepis nana in mice maintained at different environmental temperatures. International Journal for Parasitology16: 13–17. On days 3 and 4 post infection (p.i.) the number of Hymenolepis nana cysticercoids in the villi of male mice kept at 5°C did not differ from those in controls (21°C), but fewer larvae were observed in hosts at 35°C. However, on day 10 and 14 p.i. in cysticercoid and egg-induced infections respectively, the incidence of infection was higher and significantly more worms per host were found in mice at 5°C than in those kept at 21 or 35°C. Also, worms from mice maintained at 5°C were significantly heavier and became patent 1 day earlier than those from 21°C, which, in turn, were significantly heavier than those grown in hosts at 35°C.     

Hymenolepis diminuta: Worm loss and worm weight loss in long-term infections of the rat

Infections of one and two Hymenolepis diminuta established in newly weaned rats continued to grow for the duration of the experiment (238 days), whereas infections of 5 worms per rat became asymptotic around Day 55 postinfection and remained at or below this level thereafter as shown by biomass and mean weight per worm measurements. Infections of 50 worms established in newly weaned rats became asymptotic around Day 28 postinfection and thereafter worms were lost from the rats. Initially the biomass fell with the loss of worms, but by Day 56 a new lower biomass persisted for the remainder of the infection period. This level was maintained, despite diminishing numbers of worms, due to the growth of surviving individuals to a weight exceeding the original weight at maturity by a factor of more than 2. Experiments using rats that were mature at the time of infection demonstrated that the same response occurred, but approximately 3 weeks earlier.     

Enzymes of adenosine metabolism in Hymenolepis diminuta (Cestoda)

Gaitanaki C. and Beis I. 1985. Enzymes of adenosine metabolism in Hymenolepis diminuta (Cestoda). International Journal for Parasitology15: 651–654. The activities of 5-nucleotidase (E.C. 3.1.3.5), adenosine deaminase (E.C. 3.5.4.4), adenosine kinase (E.C. 2.7.1.20), AMP deaminase (E.C. 3.5.4.6) and adenylate kinase (E.C. 2.7.4.3) were demonstrated in homogenates of Hymenolepis diminuta. The K_m values for adenosine and AMP of the above enzymes were determined. The importance of these enzymes in the maintenance of adenosine concentration on a steady state in H. diminuta is discussed     

Histopathological appearances in primary and secondary infections with Strongyloides ratti in mice

Dawkins H. J. S., Muir G. M. & Grove D. I. 1981. Histopathological appearances in primary and secondary infections with Strongyloides ratti in mice. International Journal for Parasitology11: 97–103. The histological appearances of the skin, lungs and small intestines of mice with primary and secondary infections with S. ratti are described. When the skins of mice with a primary infection were examined, larvae were seen scattered throughout the dermis. An inflammatory reaction of neutrophils and eosinophils was first noted around larvae 12 h after infection. By 48 h, mononuclear cells were prominent. The intensity of the inflammatory reaction gradually increased to a maximum on the fifth day and the larvae were destroyed. Very few larvae were seen in the lungs; those observed were located in the alveolar spaces and were not surrounded by an inflammatory infiltrate. Worms in the small intestines were found mostly in the crypts of Leiberkuhn, and were probably located within the epithelial layer; there was no significant villous atrophy or cellular infiltration. Marked differences were found in the tissues of mice with secondary infections. In the skin, oedema and neutrophils and eosinophils were seen around worms as early as 2 h after infection. By 24 h after infection, there was a mixed inflammatory infiltrate and worms were undergoing disintegration. Larvae in the lungs were surrounded by polymorphonuclear and mononuclear cells 48 h and 72 h after infection and the engulfed larvae were undergoing lysis. Only a few worms were seen in the intestines of mice with a secondary infection; the histological appearances were similar to that found in animals with primary infections. It is suggested that the rapid development of an oedematous reaction in the skins of immune mice may facilitate the entry of larvae into the bloodstream and that inflammatory cells destroy many larvae in the lungs of immune mice.     

Immunological aspects in the rejection process of Hymenolepis muris-sylvaticae from CFLP and NMRI mice

When mice were treated with 1.25 mg cortisone acetate thrice weekly, recovery of Hymenolepis muris-sylvaticae was significantly higher than in untreated controls, both in oral infections with six cysticercoids and surgical transplantations of one 7-day or 8-day-old worm. Cortisone treatment also resulted in the worms being located more anteriorly in the small intestine. Evidence of an immunological response against the tapeworm in the intestine is given by: an accelerated rejection of a secondary oral cysticercoid infection and a significant difference of the dry weights of the worms recovered on day 10 in CFLP mice; an accelerated rejection of a secondary surgical infection on days 4 and 6 in CFLP mice and on days 3 and 4 in NMRI mice; an accelerated rejection of a secondary surgical infection given 3 and 6 months after the primary immunizing infection in SWISS-albino mice.     

Hymenolepis murissylvatici: humoral response in intestinal lavages of the mouse

Hymenolepis murissylvatici elicits a humoral response in serum and in the intestine of the mouse from which it is immunologically rejected. In serum, significant differences were recorded 3 days after reinfection, while in intestinal lavages it takes place from day 9 after reinfection. In serum the response is largely the result of IgG and IgM antibodies whereas in the intestine, IgA is the most abundant antibody. Although specific IgE could not be demonstrated in serum, it was present in intestinal lavages, although rather late (i.e. day 14 after reinfection). Treatment of young worms in vitro both with immune serum or intestinal lavages had no apparent effect on their viability. Immune serum produced a complement independent precipitation on the surface of the worms in vitro. This reaction did not affect viability or infectivity of the parasite, as demonstrated by the successful implantation of treated worms in recipient mice. The above-mentioned results, together with the knowledge that the Hymenolepis model has no tissue stages and causes no tissue damage, make it probable that further study of this model will reveal some specific intestinal immunological reactions.     

Immunologic studies on Heligmosomoides polygyrus infection in the mouse: the dynamics of single and multiple infections and the effect of DDT upon acquired resistance

Neilson J.T. McL., Forrester D.J. and Thompson N.P. 1973. Immunologic studies on Heligmosomoides polygyrus infection in the mouse: The dynamics of single and multiple infections and the effect of DDT upon acquired resistance. International Journal for Parasitology3: 371–378. Swiss Webster mice were given infections of 100,200, 300 and 400 Heligmosomoides polygyrus (= Nematospiroides dubius) larvae respectively at intervals of 4 weeks. Where appropriate, the preceding infection was terminated with anthelmintic 7 days prior to the subsequent infection. Animals were killed at regular inteivals following each infection and the worm burdens compared with those found in control mice given a primary infection of similar size. The expulsion of worms in mice given three previous infections occurred after day 3 and before day 7 postinfection indicating that those larvae moulting from the fourth to fifth stages may be most susceptible to the host's resistance mechanisms. The administration of p,p'-DDT to hyperinfected mice did not interfere with the immunologic expulsion of worms.     

Pathophysiology of cestode infections: Effect of Hymenolepis diminuta on oxygen tensions,pH and gastrointestinal function

Studies on the normal and parasitized rat intestine were used to investigate the effect of the tapeworm, Hymenolepis diminuta, on in vivo intestinal lumenal oxygen tensions, acid-base balance and mucosal absorption and accumulation of fluid and glucose.The lumenal bulk aqueous phase is considerable, well mixed and aerobic with an oxygen tension of 40–50 mm Hg. Neither the unstirred layers adjacent to the brush border membrane nor the area adjacent to the mucosa (“paramucosal lumen”) are significant barriers to the diffusion of oxygen from the blood to the intestinal lumen. In the uninfected distal ileum and colon anoxic conditions may occur in the central lumen, but, in the parasitized intestine fluid absorption is reduced and anoxic conditions do not occur. Increased H⁺ ion concentration in the parasitized intestine plays a role in increasing the availability of oxygen to intestinal helminths. Concomitant with the lower pH, the pCO₂ in the lumen of the parasitized intestine was twice as high as that found in normal animals. The total CO₂ in the parasitized intestine steadily decreased over a 3-h perfusion period, while in the normal intestine the total CO₂ content increased after an initial fall during the first 30 min of perfusion. When the worms were removed, the ability of the intestine to restore normal acid-base balance was restored. Glucose and fluid absorption in both the infected and uninfected intestine were reduced by an increase in H⁺ ion concentration; both parameters were lower in the parasitized intestine than in the normal animals. Low pH increased fluid and glucose transport by H. diminuta.While the dry weights of both the parasitized and uninfected total small intestine and of the intestinal mucosa were the same, the wet weights were considerably different, indicating defective fluid balance in the infected intestine. Accumulation of glucose by the parasitized mucosa was greater than in control animals and decreased with an increase in H⁺ ion concentration. The glucose transport system in the parasitized gut was therefore affected at two levels, one at the brush border, where transport into the mucosa was decreased by lowering the pH, and secondly at the level of the basal and lateral membranes, where transport out of the mucosal tissue into the circulatory system was also reduced.The above results are discussed in terms of current widely accepted but erroneous concepts relating to the intestinal ‘microcosm’.     

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.     

Interactions between Trichinella spiralis and Hymenolepis nana in the intestine of the mouse

Ferretti G., Gabriele F., Palmas C. and Wakelin D. 1984. Interactions between Trichinella spiralis and Hymenolepis nana in the intestine of the mouse. International Journal for Parasitology14: 29–33. The rejection of the intestinal phase of Trichinella spiralis in outbred CD₁ mice is associated with an inflammatory response. The effects of this inflammation were studied in mice concurrently infected with an unrelated parasite, Hymenolepis nana, which stimulates a slight inflammation but is also immunologically rejected by this strain of mice. Moreover though Cd(In)1 mice seem to be ‘slow responders’, in concurrent infections with T. spiralis and H. nana there was a marked effect upon the cesode survival. At the highest level of T. spiralis infection, H. nana failed to establish at all. On the other hand, if 300 T. spiralis were administered 10 weeks earlier, H. nana become established in all mice and the distribution of parasites suggests that immunodepression is involved. An accelerated loss of the nematode, when H. nana was present, was also demonstrated. There was no evidence of any reciprocal or specific cross-immunity between the two parasites.     

Strongyloides ratti: reversibility of immune damage to adult worms

Transplantation experiments were conducted to assess the reversibility or irreversibility of the damage sustained by Strongyloides ratti during infections in the rat host. Worms of different ages from primary and secondary infections were recovered from their original hosts and transplanted surgically into naive rats. The size and fecundity of normal (Days 6–11 postinfection) worms were maintained after transfer. Damaged worms from primary infection (Days 22–26) showed complete recovery of size and fecundity within 10 days of transfer; damaged worms from a secondary infection (Days 6–7) also showed functional recovery but to a lesser extent. The ultrastructural changes observed mainly in the intestine of damaged worms from primary infections, prior to their transfer, were, however, only partially ameliorated following transplantation into new naive hosts; there was no complete return to structural normality. On the other hand, second infection worms did show almost complete ultrastructural recovery. The course of a transplanted infection established with either damaged or normal worms was similar to infections established percutaneously. Increase in the size of transplanted infections from 100 to 250 worms per recipient did not alter the dynamics of the host/parasite relationship. There was no evidence of adaptation in S. ratti and damaged worms, when transplanted into naive rats, were as successful as normal worms in protecting the host against a subcutaneous larval infection. The implications of this work on the present understanding of the phenomenon of autoinfection in experimental rodent strongyloidiasis are discussed.     

The intestinal cestode Hymenolepis diminuta as a lead sink for its rat host in the industrial areas of Riyadh,Saudi Arabia

The present study sought to assess the potential of the cestode Hymenolepis diminuta as a bioindicator for lead accumulation in two industrial areas of the city of Riyadh, Saudi Arabia. Rats (Meriones libycus) were collected from two sites (industrial area II and Salbukh) in Riyadh. In the industrial area II, the mean levels of lead concentrations were found to be 1.96, 1.92, 1.4 and 30.72 μg/g in the rats’ liver, kidney and intestine, and in H. diminuta, respectively. In Salbukh, meanwhile, the lead concentrations were 1.63, 1.52, 1.20 and 21.31 μg/g in the rats’ liver, kidney, and intestine, and in H. diminuta, respectively. In addition, in industrial area II, compared with the liver, kidney and intestine of their host, the bioconcentration factors of lead were found to be, respectively, 15.6, 16 and 21.9 times higher in H. diminuta, and were 7.5, 8, and 10.2 times higher in the same organs compared to H. diminuta in Salbukh. The present study, therefore, proved that H. diminuta could be used as a bioindicator for heavy metal contamination in the industrial areas of the city of Riyadh.