Homologous and heterologous resistance of Echinostoma revolutum and E. liei in ICR mice

To study resistance of echinostomes in the mouse, female ICR mice were challenged homologously or heterologously with Echinostoma revolutum or E. liei metacercariae. Mice challenged homologously had significantly fewer worms which weighed less than those from control mice. In heterologous studies where the primary infection was not eliminated with an anthelmintic, the number of worms in challenged mice was not significantly different than that in controls which received only the primary infection. However, the mean dry weight/worm of the secondary infection was less than that of controls. Mice challenged with E. revolutum 2 days after a 21-day-old E. liei infection was eliminated with Zanil contained significantly fewer E. revolutum, which weighed less than those of controls.     

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.     

Echinostoma revolutum: resistance to secondary and superimposed infections in mice

A complete or almost complete resistance (94-100%) to a superimposed Echinostoma revolutum infection existed in mice harboring 20-, 30-, and 40-day-old infections in the range of 2-4 to 30-35 worms, but no resistance was found at challenge Day 10. A similar high level of resistance (85-100%) also existed in mice for at least 6 weeks after natural expulsion of a primary 6 metacercarial infection and for at least 5 weeks after anthelmintic termination of a 30-day-old 20 metacercarial infection. Thymus-deficient nude mice failed to develop resistance to a superimposed infection, and the resistance in normal mice was inhibited by corticosteroid treatment. These findings are all in favor of a host immune response being responsible for the resistance against both a secondary and a superimposed infection. Nearly all the worms of a superimposed infection were, in resistant mice, expelled prior to 24 hr following infection (rapid expulsion), and the few worms circumventing this early expulsion persisted for at least 8 days. Newly excysted juvenile worms implanted intraduodenally into resistant mice were rejected to the same degree as juvenile worms from an oral metacercarial infection indicating that the newly excysted juvenile worms are the target of the host immune response. However, 7-day-old worms implanted intraduodenally into resistant mice survived indicating that adaptation to the host immune response had occurred. In conclusion, this host-parasite model is an example of concomitant immunity because the immunological mechanism responsible for the expulsion of the superimposed infection had no effect on the number of primary worms present.     

Comparison of rapid expulsion of Trichinella spiralis in mice and rats

Alizadeh H. and Wakelin D. 1982. Comparison of rapid expulsion of Trichinella spiralis in mice and rats. International Journal for Parasitology12: 65–73. Primary infections of Tricliinella spiralis in both NIH mice and Wistar rats resulted in increased levels of mucosal mast cells and goblet cells. In mice the numbers of both cell types rose sharply before worm expulsion (days 8–10), remained at an increased level for a short time and declined quickly, reaching control levels on day 14 for goblet cells and between days 28 and 35 for mast cells. In contrast, in rats, the numbers of goblet cells and mast cells increased during worm expulsion and remained above control levels for a prolonged period. Challenge infections given shortly after expulsion of a primary infection (day 14) were expelled rapidly, worm loss being virtually complete with 24 h. In mice this response to challenge was short-lived and persisted only until day 16 after primary infection. After this time, challenge worms were expelled more slowly after infection. In rats the rapid expulsion response was expressed for at least 7 weeks after primary infection. Mice and rats showed differences in the conditions of infection necessary to prime for rapid expulsion, mice requiring larger and longer duration primary infections, but the expression of the response appeared to be similar in both species. In mice it was shown that rapid expulsion of T. spiralis was a response evoked specifically by prior infection with this species; infections with other intestinal nematodes had no effect. Similarly, the effect upon challenge infection was also specific to T. spiralis. The rapidity with which challenge infections are expelled suggests that either the specific inflammatory changes generated during primary infection result in an environment that is unsuitable for establishment of subsequent infections or that challenge infections provide a stimulus that can provoke an almost instantaneous response in the primed intestine. The relationship of the observed cellular changes to such mechanisms is discussed.     

Humoral and cellular response to infection with Echinostoma revolutum in the golden hamster, Mesocricetus auratus

Laboratory hamsters (Mesocricetus auratus) were infected with Echinostoma revolutum (Trematoda). Immunoelectrophoretic studies of hamster serum showed no demonstrable antibody response to E. revolutum. Histopathologic examination of intestinal tissue of infected hamsters showed erosion of intestinal villi and lymphocytic infiltration as the primary host response. Spleens from infected hamsters were hyperplastic during the first 3 weeks of infection and atrophic from 4 to 8 weeks postinfection. Hamsters were unable to acquire a resistance to E. revolutum infection. Lack of resistance was demonstrated in hamsters where the parasite infection was no longer detected based on the absence of eggs in the faeces; these hamsters were then reinfected. Hamsters treated with the anthelmintic oxyclozanide were also reinfected with E. revolutum.     

Trichinella spiralis: evidence that mice do not express rapid expulsion.

The rapid expulsion of Trichinella spiralis by mice of a variety of inbred and F1 mouse strains was examined. Mice were reinfected once with T. spiralis during and immediately after the natural termination of a primary infection and worm rejection was measured less than or equal to 24 hr after the challenge. The results showed that the challenge (super)infection was consistently rejected by all mouse strains before rejection of the adult worms from the primary infection commenced. Rejection of the challenge infection began at different times after the primary infection with NFS (2 days) less than C3H less than or equal to B10.Q approximately B10.BR (greater than 5 days). In all strains, rejection of the challenge infection preceded adult worm rejection from the primary infection by 5-8 days. At its peak, the loss of challenge worms related directly to the strength of the primary rejection process NFS greater than or equal to 98%, C3H 90-98%, and B10 mice 80-90%. Furthermore, loss of the capacity to reject the challenge followed approximately 7 days after the complete loss of the primary infection in each strain examined. Thus, the sooner worms from the primary infection were lost, the earlier the capacity to promptly reject the challenge infection disappeared. B10.Br mice still partially rejected a superinfection 35 days after the primary infection began, whereas NFS mice lost this capacity around 25 days. However, premature termination of the primary infection in B10.BR mice with methyridine at the same time that NFS mice naturally terminated their infection (15 days) abrogated the capacity of B10.BR mice to reject the superinfection at 24 days. Passive transfer of protective rat IgG monoclonal antibody to mice did not lead to rapid expulsion. Transfer of mouse immune serum to intestinally primed rats did result in rapid expulsion, suggesting that mouse antibody responses were adequate. The expression of superinfection rejection was susceptible to the administration in vivo of GK1.5, anti-mouse L3T4 antibody. The data indicate that the principal determinant of the strength, time of initiation, and longevity of rejection of a challenge infection was the response to the primary infection of that individual mouse strain. The genetic determinants of challenge infection rejection were seen to be identical to those that determined rejection of the primary infection. Since no evidence could be found to support the identity of this response with rapid expulsion, as defined in rats, a new term, "associative expulsion," is proposed.(ABSTRACT TRUNCATED AT 400 WORDS)     

Immunity to primary and challenge infections of Trichinella spiralis in mice: a re-examination of conventional parameters.

In young (6- to 8-week-old) NIH strain inbred mice expulsion of a primary infection of Trichinella spiralis began on day 8 and was virtually complete by day 11-5. In older mice expulsion occurred 1 or 2 days earlier. Experience of a primary infection elicited strong immunity to challenge, whether the challenge was given immediately after worm expulsion (day 14) or delayed (day 42). Challenge infections were expelled rapidly the majority of worms being lost during the first day. Immunity to challenge was elicited by low-level primary infections and was effective against large ventionally accepted parameters of immunity to T. spiralis in mice which, it is considered, are applicable only to mice with a genetically determined low-level of responsiveness to the parasite.     

The effects of single and repeated inoculations of various larval doses on Strongyloides ratti burden and distribution in rats

The changes in worm burden, distribution, length, and fecundity after and during single and repeated inoculations of 10, 50, or 500 larvae of Strongyloides ratti were examined in rats. Worm burden after a single inoculation of a higher larval dose reduced rapidly. Repeated inoculations of lower larval doses at weekly intervals led to a delayed peak and slower reduction of worm burden; the repeated inoculations of 10 larvae did not induce worm expulsion for at least 7 wk. In repeated inoculations at 3-wk intervals, a primary inoculation of 500 larvae induced strong resistance to reinfection at week 3, whereas no resistance was induced until week 6 in rats receiving repeated inoculations of 10 or 50 larvae. Similar dose-dependent reductions in worm length and fecundity were observed in single and repeated inoculations, and the reductions began earlier than worm expulsion. Intestinal migration of worms from the upper small intestine to the large intestine was observed during the course of single and repeated inoculations. Earlier and clearer migration was observed in rats receiving higher doses. These findings indicate that in S. ratti infection, the changes of worm burden, distribution, length, and fecundity are dependent on the inoculated larval dose.     

The effect of Plasmodium berghei and Trypanosoma brucei infections on the immune expulsion of the nematode Trichuris muris from mice

The effects of concurrent P. berghei or T. brucei infections on the immune expulsion of primary and challenge infections of T. muris from CFLP strain mice have been examined. CFLP mice usually expel the nematode 18–21 days after a primary infection and within 4–6 days after a challenge infection. Both acute malaria and trypanosome infections initiated at the same time as the T. muris infection suppressed worm expulsion; when the protozoal infections were started 7 days after the T. muris infection worm expulsion was suppressed in a proportion of the mice. Acute trypanosome and malaria infections delayed the expulsion of a challenge infection from immune mice, but in the case of P. berghei the delay was short-lived.     

Depletion of eosinophils by anti-IL-5 monoclonal antibody treatment of mice infected with Trichinella spiralis does not alter parasite burden or immunologic resistance to reinfection.

Mechanisms of parasite killing by eosinophils are widely studied and are often implicated in mediating resistance to parasitic infection, especially in conjunction with specific antibodies. Evidence for the eosinophil as an anti-parasite killer cell in vivo is limited and may not justify the belief that eosinophils engage and/or kill infective helminths. We reexamined this question in a mouse model of trichinosis in which antisera to eosinophils were previously used to show the requirement for eosinophils in resistance to this nematode. The current studies used mAb to IL-5 to suppress eosinophil levels in CF1 mice infected with Trichinella spiralis. In mice given a primary infection and injected with an isotype control mAb or left untreated, the medullary and peripheral blood eosinophil numbers peaked at 3 wk postinfection (PI) and returned to baseline levels by 4 wk PI. Peripheral blood eosinophil numbers in infected mice injected with anti-IL-5 were maintained at levels below those of uninfected normal mice through 4 wk of infection. Histologically, there was a prominent eosinophil accumulation in infected, untreated, or control-mAb-treated mice associated with nurse cell complexes containing infective juveniles in skeletal muscle at 3 and 4 wk PI. This was largely eliminated in mice treated with anti-IL-5 mAb. However, the number of muscle stage juvenile worms recovered 3 and 4 wk PI after acid pepsin digestion was unaffected by eosinophil depletion. Challenge infections, in which mice were infected at day 0 with 125 muscle stage worms and challenged at day 28 PI with 350 muscle stage worms, developed peak eosinophil numbers in bone marrow and peripheral blood 3 wk after primary infection and 2 wk after challenge infection in mice receiving either no treatment or control mAb. In challenged mice receiving anti-IL-5 mAb, medullary and peripheral blood eosinophil numbers remained at or below those of uninfected animals. Although all groups exhibited significant resistance measured as muscle stage worm burdens 56 days PI, eosinophil depletion did not affect resistance of muscle worm recovery. These results suggest that eosinophils are not essential in the control of T. spiralis in either primary or challenge infections of CF1 mice. This in vivo study illustrates the questionable value of in vitro killing assays to assign effector function to any single inflammatory cell type.     

Single and concurrent infections of the golden hamster, Mesocricetus auratus, with Echinostoma revolutum and E. liei (Trematoda: Digenea)

Single or concurrent infections of the intestinal trematodes Echinostoma revolutum and E. liei were studied in the golden hamster (Mesocricetus auratus). In single infections, some hamsters were fed 25 +/- 5 metacercarial cysts and others 100 +/- 25 cysts of either E. revolutum or E. liei. In concurrent infections, hamsters were fed simultaneously 20 +/- 5 metacercarial cysts of E. revolutum and 20 +/- 5 cysts of E. liei or 100 +/- 25 cysts each of both trematodes. All hamsters exposed singly to E. revolutum or E. liei were infected. In concurrent infections, 9 of 10 hamsters were infected with both species of echinostomes, and the ratio of E. revolutum to E. liei was 3:1. In single infections, 80% of the E. liei and 60% of the E. revolutum were in the posterior third of the small intestine. In concurrent infections, 80% of the E. liei were in the posterior third and 57% of the E. revolutum in the middle third of the small intestine. The histopathological response of E. liei and E. revolutum in single and concurrent infections showed erosion of intestinal villi with lymphocytic infiltration as the primary response. Extraintestinal echinostomiasis occurred in 2 of the infection groups. Differences in hemoglobin and packed cell volume occurred in the different infection groups.     

Postnatal challenge infections of congenitally Schistosoma japonicum-infected piglets

The aim of the present study was to assess the effect of a congenital Schistosoma japonicum infection on the establishment, fecundity, and pathogenicity of a postnatal challenge infection. Five prenatally S. japonicum-infected piglets received a challenge infection (prenatal + challenge group), 5 prenatally infected piglets were followed without challenge (prenatal group), and 10 piglets, born by unexposed sows, served as challenge controls (challenge control group). Challenge infections were given 8 wk after the piglets were born (14 wk after the primary infection of the sows), and the study lasted another 11 wk. Variables included worm burden, tissue egg count, and liver pathology. Worm establishment and tissue egg count were comparable in the prenatal + challenge group and in the challenge control group, both exceeding at a statistically significant level those in the prenatal group. No difference in worm fecundity (eggs/female worms/g tissue) was seen between the 3 groups. Liver pathology (i.e., portal and septal fibrosis) was more severe in the challenge control group compared to the other groups. A congenital S. japonicum infection in piglets thus affected neither establishment nor fecundity of a postnatal challenge infection. In spite of this, the challenge infection gave rise to much less liver pathology than the similarly sized challenge control infection.     

Strongyloides ratti: Acquired resistance in the rat to the preintestinal migrating larvae

Potential sites for expression of acquired resistance to Strongyloides ratti larvae in rats were investigated. In rats immunized by exposure to a single live infection and challenged 30 to 40 days later, 46 to 98% of the challenge larvae failed to reach the small intestine. Multiply immunized rats nearly completely eliminated migrating challenge larvae. This early killing of migrating larvae occurred during the first 48 hr after challenge infection. Resistance to migrating challenge larvae was also induced by repeated injections with heat-killed infective larvae. That the intestine may also serve as an effective site for worm expulsion was confirmed by intestinal transfers of worms from rats with primary infections into resistant rats.     

Trichuris muris: effect of concurrent infections with rodent piroplasms on immune expulsion from mice.

Mice concurrently infected with the rodent piroplasms Babesia hylomysci or B. microti during a primary infection with the nematode Trichuris muris showed marked immunodepression, and the normal immune expulsion of the nematode was delayed. Immunodepression was most severe when the Babesia infections reached peak parasitaemia during the preexpulsion phase of the worm infection. Decline in parasitaemia to subpatent levels was associated with a reappearance of the immune response and expulsion of the worm. Babesia infections had little effect upon the expulsion of challenge infections of T. muris from mice previously immunized against the worm. Acute Babesia infections were found to exert a profound immunodepressive effect upon the agglutinating antibody response of mice to sheep red blood cells.     

Schistosoma mansoni-New Zealand rabbit model: resistance induced by infection followed by active immunization with protective antigens

In previous studies, rabbits immunized with adult worm antigens released from fresh adult schistosomes incubated in saline media showed a significant level of protection against challenge parasites. Focusing on the rabbit-Schistosoma mansoni model, concomitant immunity was investigated. A peculiar form of response to cercarial infection was observed: rabbits subjected to percutaneous infection and similar reinfections at different times after primary infection killed schistosomula from the challenge infection as well as established parasites from the primary infection. In this study the challenge infection stimulus was replaced by active immunization with an adult worm-derived protective antigenic mixture. The results show that immunization of New Zealand rabbits with an adult worm antigenic extract is capable of inducing a response that results in a significant reduction of the mean worm burden of the primary infection earlier than did homologous infection, as compared to worm reduction due to a second infection.     

Trypanosoma musculi and Trichinella spirails: Concomitant infections and selection for resistance genotypes in mice

Trypanosoma musculi infections were given to mice of different strains before, at the same time, and after an infection with 400 Trichinella spiralis. Examined parameters of the host response to T. spiralis were worm rejection, antifecundity responses, development of immunological memory, and muscle larvae burden. After dual infection, each mouse strain showed characteristic effects on resistance to T. spiralis. This was due to a dynamic interaction between the genes controlling rejection of T. spiralis and those influencing T. musculi growth. C3H mice develop high trypanosome parasitemias. This impairs worm expulsion and the development of memory to T. spiralis when Trypanosoma infections take place on the same day or 7 days before. The C57B1/6 mouse develops low parasitemias and T. musculi infections on the same day, or 7 days before T. spiralis, delaying worm rejection only slightly despite the overall weak capacity of B6 mice to expel worms. NFR-strain mice are strong responders to T. spiralis and also develop low parasitemias. Trypanosome infections on the same day, or after T. spiralis, produce a delay in worm rejection; the former is comparable to C3H mice. However, NFR mice alone showed enhanced rejection of worm when T. musculi infections preceded T. spiralis by 7 days. An unusual feature of C3H mice was that T. musculi infections 7 days before T. spiralis increased antifecundity responses at the same time that worm expulsion was inhibited. Trypanosome infections can therefore modulate distinct antihelminth immune responses in different directions simultaneously. The different outcomes of dual infections compared with single infections provides another selective mechanism by which genetic polymorphisms can be established and maintained in the vertebrate host.     

Excystation in vitro of Echinostoma liei and E. revolutum (Trematoda) metacercariae

Metacercariae of Echinostoma liei and E. revolutum were excysted in an alkaline bile-trypsin medium at 41 C in the absence of acid-pepsin pretreatment. After 60 min at a pH of 7.8 or 8.0, excystation of E. liei reached 98%; optimal excystation of E. revolutum occurred at pH 8.2 and was 70% after 60 min. The rate of excystation was very rapid in E. liei, reaching 91% at 30 min, and less rapid in E. revolutum reaching 40% at 30 min. Almost 100% of the E. liei cysts stored for 5.5 mo at 4 C in Locke's 1:1 excysted in the medium, compared to 40% for E. revolutum treated identically.     

Response to re-infection with Brachylaima cribbi in immunocompetent and immunodeficient mice

The course of infection in C57BL/6J mice re-infected with Brachylaima cribbi was assessed by comparing faecal egg excretion of re-infected mice with age- and sex-matched mice receiving a primary infection only. For both male and female mice there was a significant reduction in the mean number of eggs per gram of faeces at the peak of infection 4 weeks after the challenge infection compared with mice receiving a primary infection only. There was no significant difference in the duration of the infection. This experiment was repeated using age-matched male mice but on this occasion all mice were killed and dissected 4 weeks after the challenge infection and mean eggs per gram of faeces, worm burden and fecundity determined. There was no significant difference in the worm burdens of the re-infected mice compared with age-matched animals receiving a primary infection only. However, there were significant differences in the mean faecal eggs per gram and worm fecundity with the challenge infection group having lower egg counts and reduced fecundity. An enzyme-linked immunosorbent assay using whole worm antigens was developed and used to determine mouse anti-B. cribbi serum antibody levels during the course of infection. Anti-B. cribbi serum antibody absorbance ratios increased six- to sevenfold by 4 weeks after a primary infection beyond which a constant level was maintained. The course of challenge infection in non-obese diabetic severe combined immunodeficient mice showed no significant differences in egg excretion, worm burden or fecundity when primary and challenge infections were compared. These results indicate that the immune response invoked by a previous B. cribbi infection in immunocompetent mice affects fecundity but does not affect the establishment or duration of infection.     

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.     

The growth and development of Schistosoma mansoni in mice exposed to sublethal doses of radiation

The maturation of Schistosoma mansoni was studied in mice exposed to various sublethal doses of radiation. Although the treatment of mice with 500 rads of radiation prior to infection did not alter parasite maturation, doses in excess of 500 rads led to a reduction in worm burden. This could not be attributed to a delay in the arrival of parasites in the hepatic portal system. Worms developing in mice treated with 800 rads commenced egg-laying about 1 wk later than worms in intact mice, and the rate of egg deposition appeared to be lower in irradiated hosts. The data demonstrate that exposure of C57BL/6 mice to doses of radiation in excess of 500 rads impairs their ability to carry infections of S. mansoni. The findings do not support the hypothesis that primary worm burdens in the mouse are controlled by a host immune response.