T-dependent suppression of the primary antibody response to sheep erythrocytes in mice infected with Trichinella spiralis

Infection with Syphacia obvelata (pinworm) induces protective Th2 immune responses and influences ovalbumin-induced allergic reactions

Infections with pinworms are common in rodent animal facilities. In this study, we show the consequence of an outbreak in a transgenic barrier facility of infection by Syphacia obvelata, a murine pinworm gastrointestinal nematode. Immune responses were defined in experimental infection studies with BALB/c mice. Infection with S. obvelata induced a transient Th2-type immune response with elevated interleukin 4 (IL-4), IL-5, and IL-13 cytokine production and parasite-specific immunoglobulin G1 (IgG1). In contrast, BALB/c mice deficient in IL-13, IL-4/13, or the IL-4 receptor alpha chain showed chronic disease, with a >100-fold higher parasite burden, increased gamma interferon production, parasite-specific IgG2b, and a default Th2 response. Interestingly, infected IL-4-/- BALB/c mice showed only slightly elevated parasite burdens compared to the control mice, suggesting that IL-13 plays the dominant role in the control of S. obvelata. The influence that pinworm infection has on the allergic response to a dietary antigen was found to be important. Helminth-infected mice immunized against ovalbumin (Ova) elicited more severe anaphylactic shock with reduced Ova-specific IL-4 and IL-5 than did noninfected controls, demonstrating that S. obvelata infection is able to influence nonrelated laboratory experiments. The latter outcome highlights the importance of maintaining mice for use as experimental models under pinworm-free conditions.

Immunosuppression of in vivo and in vitro lymphocyte responses in swine induced by Trichinella spiralis or excretory-secretory antigens of the parasite

The in vivo and in vitro effects of Trichinella spiralis excretory-secretory (ES) antigens on porcine peripheral blood lymphocyte (PBL) responses induced with mitogens (phytohemagglutinin, PHA; concanavalin A, Con A; pokeweed mitogen, PWM) or unrelated antigen (Protein A) were studied to determine whether ES antigens depress lymphocyte responses in experimental swine trichinosis, and/or if this response was manifested after lymphocytes from infected pigs had been pretreated with ES antigens. Additionally, the range of inhibition of lymphocyte responses was tested in parasite-free pigs using different doses of ES antigens and compared with the responsiveness of control cultures from the same animals. The responses of lymphocytes from pigs inoculated with 4 x 10(3) muscle larvae (ML) were strongly depressed (P < 0.05) at post-inoculation days (PID) 7 (after stimulation with PHA), 14, 35 (Con A or PWM), and 49 (PWM). At PID 56 and 63 the lymphocytes from T. spiralis-infected pigs responded better (P < 0.05) to all three mitogens than those from non-infected controls. After 7 weeks post-inoculation, PBL which were pretreated with 10 or 250 micrograms ml-1 of ES antigens showed significantly weaker (P < 0.05, P < 0.001) responses to PWM or PHA, respectively, than those from non-infected animals. The responsiveness of lymphocytes from both groups of pigs to Protein A was not affected by the pretreatment with ES antigens in vitro. The responses of lymphocytes from the parasite-free pigs induced by PHA, PWM or Protein A were strongly depressed (P < 0.01) after in vitro pretreatment regardless of the dose of ES antigens (5, 10, 15, or 20 micrograms ml-1) applied.

Host resistance to Trichinella spiralis infection in rats and mice: species-dependent effects of cyclophosphamide exposure

Host resistance to Trichinella spiralis infection was compared in male rats (F344) and female mice (C57BL/6J) following various cyclophosphamide (CY) treatment schedules. Doses of CY given to mice were adjusted by body surface area to be comparable to rat doses. Adult parasite elimination was not affected by oral administration of 1.5, 3 or 6 mg CY/kg per day to rats or 1.05, 2.1 or 4.2 mg CY/kg per day to mice for 10 days. In rats, resistance was suppressed by a single oral dose of 80 mg/kg given the day prior to infection, but was not affected at 20 or 40 mg/kg. A single oral dose of 14, 28 or 56 mg CY/kg did not affect parasite expulsion in mice. Rats were also given four daily intraperitoneal (i.p.) injections of 20, 40 or 80 mg CY/kg per day and mice received 14, 28 or 56 mg CY/kg per day. Infected rats did not survive at the two higher dose levels and parasite expulsion was suppressed at 20 mg/kg per day; parasite expulsion was suppressed in mice by four i.p. injections of 56 mg CY/kg per day, but not by lower doses. In rats, doses of CY which suppressed adult parasite expulsion also severely suppressed the proliferative response of mesenteric lymph node cells (MLNC) to an extract of T. spiralis (TsE). However, significant suppression of TsE-driven blastogenesis occurred at a dose of CY which did not affect parasite expulsion, indicating that the proliferative response in rats was more sensitive to suppression than actual parasite elimination. In contrast, the proliferative response to the T cell mitogen concanavalin A was elevated in the MLNC of CY-exposed rats. This was determined to be related to the interval between CY dosing and the day of assay rather than to an effect of infection with T. spiralis. Mouse MLNC proliferative responses to TsE were not suppressed by CY treatment, even at levels of CY which suppressed adult parasite expulsion. Mice differed from rats in that CY exposure did not affect the proliferative response to concanavalin A in infected animals. The species-dependent differences observed in these studies may have been secondary to the greater sensitivity of rats to CY. Nonetheless, these results highlight the potential for species-specific responses to chemical exposure and underscore the need for additional comparative studies of host resistance in rats and mice.

[Effects of immunoactivity on Ascaris suum infection in mice]

The immune response to sheep red blood cell (sRBC) was monitored in the mice infected with Ascaris suum or Trichinella spiralis. The effects of the infection with T. spiralis or the injection with cyclophosphamide(CY) as an immunosuppression agent prior to challenge infection with the embryonated eggs of A. suum were monitored in mice by means of the level of infection with A. suum and cellular and humoral immune response to sRBC. Following the oral administration of 1,000 eggs of A. suum to mice, delayed-type hypersensitivity (DTH) and rosette-forming rate were gradually decreased and reached to the lowest levels at the 5th week and 6th week postinfection, respectively, and then returned to normal at the 10th week. The hemagglutinin(HA) and hemolysin(HE) titers were gradually elevated and reached to peak at the 3rd week postinfection, and then returned to normal level. The appearance ratios of the eosinophils and mast cells were in peak at the 4th week and the 2nd week postinfection, respectively. Meanwhile the harvest ratio of A. suum larvae from the liver and lungs was 21.97% at the 1st week postinfection. Following the oral administration of 300 T. spiralis infective larvae, DTH and rosette-forming rate were gradually decreased with the lapse of time and reached the lowest values in the 30th and 21st day of postinfection, and then slightly increased and transiently decreased in the 70th and 80th day of postinfection, respectively. HA and HE titers were the lowest in the 21st and 90th day, whereas the ratios of eosinophils and mast cells were the highest on the 40th and 14th day postinfection, respectively. Following the intraperitoneal injection of CY, the body weight, the spleen weight, DTH, rosette-forming ratio, HA and HE titers, the number of WBC and the ratio of the mast cell were predominantly decreased in the 5th day, and then returned to the same value of the 1st day postinjection. The ratio of eosinophils was gradually decreased following to advance of days. At the 1st, 5th and 10th days after intraperitoneal injection of CY of 400 mg/kg, a dose with 1,000 eggs of A. suum was administered orally to mice, and harvest rate of the larvae at the 7th day postadministration was 7.07% in the 1st day, 14.94% in the 5th day, 10.1% in the 10th day, 8.02% in control group. The effect of prior infection with infective larvae of T. spiralis upon immunological sequelae of a challenge infection of mice with embryonated eggs of A. suum in 30 or 70 days interval was checked.(ABSTRACT TRUNCATED AT 400 WORDS)

Specific immunosuppression by Trichinella: fine specificity and effect on lymphocyte function in vivo

Muscle-phase Trichinella larvae depress the immune response of mice to the phosphorylcholine (PC)-bearing Trichinella antigen FCp without affecting responses to other PC-bearing or non-PC antigens. The depressive activity is independent of antigen dose and Trichinella species and, in adoptive cell transfer experiments with lethally irradiated recipient mice, depended on the state of the recipient (infected recipients had a depressed response even a month after their encysted larvae had been killed and regardless of whether the donor had been exposed to FCp) but not on the state of the transferred cells. We conclude that lymphocytes are not permanently altered by the depressive action, that the agent responsible persists in the host at least a month after the death of the encysted Trichinella larvae, and that the alteration does not eliminate lymphocyte immunological memory.

Modulation of the anti-phosphorylcholine immune response during Trichinella spiralis infections in mice

The nematode Trichinella spiralis is able to modulate the antibody response, as measured by the plaque-forming cell (PFC) technique, to three thymus-dependent (TD) antigens: (1) a heterologous antigen unrelated to the parasite (sheep red blood cells (SRBC]; (2) an antigenic fraction, rich in phosphorylcholine (PC), obtained from T. spiralis (FCp1) and (3) a heterologous antigen unrelated to the parasite, but sharing the PC epitope with the FCp1 fraction (PC-KLH). During the life-cycle of the parasite in BCF1 mice, two opposing immunomodulating activities occur: (1) an immuno-potentiating activity in mice infected during the intestinal and larval migratory stages, for all three antigens, and (2) a carrier-specific immunosuppressive response in mice infected and immunized with the FCp1 fraction during the muscle phase of the life-cycle. The anti-PC PFC response of these mice is dependent on the infection dose and decreases from day 35 post-infection (p.i.) until at least day 85 p.i. The factor responsible for the stimulating effect observed during this stage is the presence of migratory larvae in the host. All the foregoing seems to indicate that T. spiralis can use specific suppression mechanisms to aid in its own survival.

Suppression of antibody responses by Toxoplasma infection in mice

The immunosuppression elicited by Toxoplasma infection was proved to be due to suppressor macrophages. The induction of the suppressor macrophages are regulated by both H-2-linked and -nonlinked genes. The suppressor macrophages affect the proliferating step of lymphocytes, inhibiting them to reduce helper T cells, plasma cells and memory T- and B cells. The suppressive effect is via close contact of suppressor macrophages with lymphocytes, and not mediated by prostaglandins or H2O2. The more suppressive strain of mouse had heavier parasite burden than non-suppressive mouse strain. The patterns of induction of suppressor cells by various parasitic infections were compared and discussed.

The antiphosphorylcholine plaque-forming cell responses induced by the nematode Trichinella in BWF1 mice

We have tested the ability of the nematode Trichinella to infect young and old (NZB x NZW) F1 (BWF1) mice. We report the capacity of these mice to respond to the parasite antigens containing the epitope phosphorylcholine. The values obtained in adult worm intestinal retention rates and in the number of encysted larvae on the 35th day postinfection showed that the old BWF1 mice are more susceptible than young BWF1 and control (BALB/c x CBA/j)F1 (BCF1) mice to Trichinella infection. However, unlike the BCF1 mice, young BWF1 mice were unable to produce a good anti-phosphorylcholine plaque-forming cell response after the killing of Trichinella larvae by the anthelminthic mebendazole. Old BWF1 mice presented a discrete response which is discussed. Finally, our results seem to indicate that the lack of anti-phosphorylcholine response in young BWF1 mice after mebendazole treatment may be related to the high susceptibility of these mice to the suppressive properties of encysted Trichinella larvae against their own antigens.

Immunomodulation by nematodes: a review

There is current evidence that infections with Trichinella spiralis, Ascaris suum, Nippostrongylus brasiliensis, Nematospiroides dubius (syn. Heligmosomoides polygyrus) and diverse filariae affect the immune responsiveness of their hosts. T. spiralis, or its extracts, can depress or enhance the heterologous humoral or cell-mediated immunities, and affect macrophage activity or the response to other invaders. These effects are induced by products of the migratory and early muscle larvae and appear to obey more than one single-mechanism. A suum acute infections or extracts depress responses involving T cell activity, but stimulate polygonal expansion of B-cells. Nippostrongylus brasiliensis causes polyclonal stimulation of IgE-producing cells, enhances immune responses during the first week of infection and inhibits them later on. Nematospiroides dubius depresses homologous and heterologous immunity and facilitates the permanence of other intestinal nematodes. Filarial worms appear to depress the homologous cell-mediated immunity and the heterologous humoral response by induction of suppressor cells and humoral factors. These phenomena are probably the result of evolutionary pressures on the parasites that facilitate their survival. In the host, they are likely to aggravate the homologous infection, facilitate intercurrent conditions and interfere with immunoprophylaxis procedures.

Acquired resistance to Hypoderma lineatum: comparative immune response of resistant and susceptible cattle

The humoral and cellular immune responses of previously infested and noninfested cattle were compared after a single experimental exposure to 1st-instar Hypoderma lineatum. No correlation was found between the development of humoral antibodies as measured by passive hemagglutination assay and resistance in cattle. However, the most resistant cattle had higher macrophage migration-inhibition activity before and 1 month after infestation than did low- or non-resistant animals, and resistant animals also had greater sensitivity to antigens from larvae as they penetrated the skin. These results suggest that acquired resistance to hypodermatosis involves a cellular component of the immune mechanism.

The reversal of the immunodepression phenomenon in trichinellosis and its effect on the life cycle of the parasite

Immunodepression phenomena in infections with protozoan and metazoan parasites have raised a great deal of interest because of the apparent lack of immunological control in a primary infection. Therefore, this phenomenon has been proposed as a working hypothesis to explain the successful association. However, the role that immunodepression can play in parasitic infections as a mechanism to assure an equilibrium between the host and its parasite has never been evaluated. The immunodepression to SRBC in Trichinella-infected mice was removed by treating mice with low doses of cyclophosphamide (CY). The elimination of immunodepression resulted in a significantly lower number of encysted muscle larvae. In the absence of immunodepression, a higher number of circulating eosinophils was counted. The results of these experiments are discussed firstly with regard to the mechanisms which could explain immunodepression in trichinellosis and secondly, the role that immunodepression plays in the relationship between the host and the parasite during a primary infection.

Possible role of macrophage-like suppressor cells in the anti-tumour activity of BCG

The i.v. injection of high doses (3 mg) of BCG into C3H mice bearing a transplantable 3-methylcholanthrene-induced fibrosarcoma caused the regression of a significant proportion. This effect was most evident when the BCG was injected on the day of the graft, or 7 days later. The injection of this agent either 14 days before the graft, or in low doses (0.1 or 0.5 mg), or directly into the tumour (i.t.) only prolonged the survival of the animals. Spleen cells from systemic high-dose BCG-treated mice were found to exert a strong nonspecific cytostatic effect in vitro that was not an artefact of the test conditions, and was not expressed by cells from low-dose animals. The cytostatic effect was shown to be caused by cells with the characteristics of macrophages, i.e. they were strongly adherent, unaffected by treatment with anti-Thy 1.2 + C', radioresistant but heat-sensitive, and were detected in BCG-treated "B" mice. The spleens of high-dose BCG-treated mice also contained suppressor cells that were capable of inhibiting the in vitro reactivity of normal T cells to PHA. Like the cytostatic effect, this suppressor activity was not detected in low-dose mice, and the cells responsible had the properties of macrophages; the effect was lost after the removal of adherent cells by sequential exposure to plastic and colloidal iron, but was conserved after treatment with anti-Thy 1.2 + C'. T-cell-deprived animals, such as "B" or nude mice, also developed suppressor-cell activity when treated with systemic high-dose BCG. Close parallels became evident between the in vivo anti-tumour activity of BCG, the in vitro cytostatic effect, and the suppressor-cell activity. We here discuss the possible role of suppressor cells in the mechanism of action of this agent.

Suppressive action of cytoplasmic and metabolite extracts of Candida albicans on the immune response in guinea pigs

This study investigated the possibility that Candida albicans components exert a suppressive effect on the immune response of guinea pigs (GP), similar to that of live C. albicans organisms as was previously shown. Hartley GP were inoculated with C. albicans crude cytoplasmic or metabolite (culture filtrate) extracts (containing most of the organism's cell contents or its metabolite and degradation products, respectively). Their immunological responses towards sheep red blood cells (SRBC) were compared with those of GP inoculated with SRBC alone or with SRBC together with live C. albicans organisms. The immunological responses were measured by: 1) rosette formation (RF) of SRBC with peritoneal macrophages, 2) haemolytic plaque formation (PFC) with lymph node-cells, 3) haemagglutination and 4) haemolysis tests. According to the RF tests, inoculation of GP with either cytoplasmic or metabolite extracts resulted in decreased RF as compared to GP inoculated with SRBC only; the decrease was correlated with the protein concentration of the extracts. Inoculation with metabolite extract led to a more diminished RF than with cytoplasmic extract, but less than with live C. albicans organisms. Inoculation of cytoplasmic extracts did not affect the haemagglutinin and haemolysin titers, while that of metabolite extracts resulted in a slight decrease of these titers. The assays for PFC were not conclusive enough to point to a suppressive effect of C. albicans extracts. In summary, it appears that both the cytoplasmic and metabolite extracts of C. albicans exert a partial suppressive effect on the immune response in GP, as judged primarily on the basis of the RF results.

[Dynamics of splenic lymphocytes and immunosuppression in Toxoplasma infected mice (author's transl)]

Mice infected with high-virulent strains of T. gondii sustained a marked decrease of splenic lymphocytes within 7-10 days after infection, just prior to death. When infected with a low-virulent strain, the numbers of splenic lymphocytes and of T-lymphocytes fluctuated, but gradually increased over a period of 30 days. To evaluate their immunologic potential, the mice infected with a low-virulent strain of Toxoplasma were immunized with sheep erythrocytes on different days after infection, and antibody levels were measured by direct hemagglutination. Antibody response was minimal when sheep cells had been injected 10 days after infection with Toxoplasma; subsequently immunologic reactivity improved, but even after 30 days anti-sheep agglutinin titers were still below pre-infection levels.