Plasmodium yoelii: Adverse outcome of non-lethal P. yoelii malaria during co-infection with Schistosoma mansoni in BALB/c mouse model

Plasmodium yoelii and Schistosoma mansoni co-infections were studied in female BALB/c mice aged 4-6 weeks to determine the effect of time and stage of concomitant infections on malaria disease outcome. Patent S. mansoni infection in BALB/c mice increased malaria peak parasitemia and caused death from an otherwise non-lethal, self-resolving P. yoelii malaria infection. Exacerbation of malaria parasitemia occurred during both pre-patent and patent S. mansoni infection resulting in a delay of 4-8 days in malaria parasite resolution in co-infected mice. Praziquantel administered to mice with patent schistosome infection protected from fatal outcome during co-infection. However, this treatment did not completely clear the worm infestation, nor did it reduce the peak malaria parasitemia reached, which was nonetheless resolved completely. Hepatosplenomegaly was more marked in schistosome and malaria co-infected mice compared to either infection separately. The results suggest a complex relationship between schistosome co-infection and malaria disease outcome in which the timing of malaria infection in relation to schistosome acquisition is critical to disease outcome and pathology.     

Plasmodium chabaudi: relationship between the occurrence of recrudescent parasitaemias in mice and the effective levels of acquired immunity

In NIH inbred mice infected with the $\text{A}\text{S}$ strain of Plasmodium chabaudi the erythrocytic infection shows an acute primary parasitaemia which becomes subpatent after about 2 weeks. A period (7–10 days) of subpatency follows before a short-lasting patent recrudescence appears. The appearance of the recrudescent parasitaemia was examined in relation to (1) the level of antiplasmodial antibody detected by the indirect fluorescent antibody (IFA) test, (2) the antiparasite activity of the serum measured by the passive protection test, and (3) the ability of the mice to control and eliminate a large intravenous challenge infection. In the period between the primary parasitaemia becoming subpatent and the onset of the recrudescence there was a slight drop in the IFA levels, and a steep decline in passive protective levels and in the ability of the mice to control a large intravenous challenge infection. It is suggested that a decline in the effector arm in the immune response contributes to emergence of the recrudescent parasitaemias.     

Plasmodium berghei: Isolation and maintenance of an irradiation attenuated strain in the nude mouse

An attenuated strain of malaria causing limited parasitemia in mice was derived from a highly virulent strain of Plasmodium berghei (NK65) which produced 100% lethality in mice. A pool of mouse blood infected with the original highly virulent P. berghei was exposed to 40 Krad irradiation and parasites were inoculated into nude mice as well as into thymus competent normal littermates. Thymus competent mice showed no parasitemia, while one out of the five nude mice inoculated with the irradiated parasites developed a slow and progressive parasitemia. These parasites induced a self-limiting parasitemia in thymus competent mice, even when a large inoculum was administered. Maintenance of the low virulence strain required passage through nude mice. After 50 passages at two weekly intervals, reversion to virulence did not occur. A single vaccination with the attenuated strain induced immunity in mice against a challenge inoculation with the original virulent strain. Specific IgG persisted at high titer for more than 9 weeks in mice receiving a single inoculation of the attenuated strain.     

Schistosoma mansoni: Role in vivo of complement in primary infection of mice

The role of complement in the control of the primary Schistosoma mansoni infection in mice was investigated in vivo. The number of recovered adult schistosomes 6–7 weeks postinfection was used as a parasitological criterion of immunity. No significant difference in the worm burden was observed between C5-sufficient and C5-deficient mice. In contrast, when cobra venom factor (CVF) was injected into normal or C5-deficient mice 24 hr before challenge, a significant increase of the worm burden was noticed in comparison to the untreated mice. These results indicated that, although C5 and probably the late complement components are not essential for the control of the primary infection, the alternative pathway and some of its components are involved. In fact, the injection of C3 2 hr before infection of CVF-treated mice completely restored the immunity. A role for C3, in association with effector cells, in the nonspecific immunity occurring in the first hours after a primary S. mansoni infection is suggested.     

T cell function during fatal and self-limiting malarial infections of mice.

Delayed-type hypersensitivity (DTH) to sheep erythrocytes (SRBC) was found to be depressed during fatal Plasmodium berghei and self-limiting P. yoelii infections of mice. By testing mice presensitized to SRBC before P. berghei infection, and by transfer of cells sensitized in uninfected mice into P. yoelii-infected recipients, the immunological lesion was found to be at the level of DTH expression, rather than at the level of T cell sensitization. That acute inflammatory responsiveness is impaired during malarial infection was confirmed by testing this response to local injection of LPS in P. yoelii-infected mice. The results suggested that depressed DTH responsiveness in malarious mice is not a valid indication of impaired T cell function.     

Plasmodium chabaudi: Humoral and cell-mediated responses of immunized mice

Antigen preparations of Plasmodium chabaudi parasites enriched in merozoites and schizonts, obtained from in vitro culture, and combined with saponin protected C57BL/6J mice from P. chabaudi infection as judged by reduced primary parasitemias and recrudescences. Sera passively transferred from immunized and untreated mice after a challenge infection were more protective in recipients than serum from normal mice. Mice treated with antilymphocyte serum during immunization did not develop as strong an immunity to infection as did controls treated with normal serum. Immunized mice had depressed delayed-type hypersensitivity reactions to malarial antigen but increased serum titers of malarial antibody (measured by imniunofluorescence) after challenge with P. chabaudi when compared to immunized mice which remained unchallenged. The protective activity of sera from various groups of mice did not necessarily correlate with the serum antibody titers.     

Trypanosoma cruzi: Role of different antibody classes in protection against infection in the mouse

Immune serum obtained from mice with a chronic infection of Trypanosoma cruzi was fractionated on Sephadex G-200 or on protein ASepharose 4B. Mice were infected with a standard infective dose of T. cruzi 24 hr after injection with either IgM, IgG, IgG1, or IgG2 + IgG3 fractions. Mice were also pretreated with immune serum depleted by affinity chromatography of either IgG2a, IgG2b, or both subclasses before infection with T. cruzi. Control mice were pretreated with normal mouse serum or immune serum depleted of IgG. The parasitemia and survival of the animals were determined and used as parameters of protection. The results of these experiments demonstrated that the protective antibodies were mostly IgG2 and seem to be preferentially located in IgG2b subclass. IgM and IgG1 fractions were very little, if any, protection.     

Transfer of immunity to Babesia microti of human origin using T lymphocytes in mice

Lymph node and spleen cells from mice infected with Babesia microti of human origin developed the ability to transfer adoptive immunity to naive mice within 25 days after infection. This protective activity was greater in cells obtained at 32 days than in cells obtained at 25 days postinfection and remained stable up to 52 days postinfection. Recipients of lymph node cells and spleen cells displayed similar peak parasitemias although 2 days after peak parasitemia, immune spleen cell recipients had significantly lower parasitemias than immune lymph node cell recipients. Strong protective activity was demonstrated when cells were transferred 1 day postinfection, while equal numbers of cells, transferred 3 days postinfection did not confer significant protection over nonimmune cells. There was also a suggestion that the number of immune spleen cells necessary for significant protection was directly related to the number of parasites inoculated. The subpopulation of lymphocytes responsible for the transfer of adoptive immunity to B. microti of human origin was then studied in BALB/c mice depleted of T lymphocytes by thymectomy and lethal irradiation. One day after infection with B. microti, T-cell-depleted mice were given complement-treated immune spleen cells, anti-θ serum-treated immune spleen cells, nonimmune spleen cells, or no cells. Similar experiments were performed comparing the effects of anti-immunoglobulin serum-treated and unfractionated immune spleen cells on B. microti parasitemia. Treatment with anti-θ serum abrogated the protective activity of immune spleen cells while anti-immunoglobulin serum treatment had no effect. These results suggest that immunologic memory of B. microti in BALB/c mice is modulated by T rather than B lymphocytes.     

Plasmodium chabaudi: Adoptive transfer of immunity with different spleen cell populations and development of protective activity in the serum of lethally irradiated recipient mice

Groups of lethally X-irradiated NIH mice were injected with either glass wool-filtered (g.w.) immune spleen cells or nylon wool enriched immune T cells from syngeneic mice immune to Plasmodium chabaudi, or g.w. normal spleen cells. After cell recipients were infected with P. chabaudi the three groups reached similar mean peak parasitaemias on Day 11. In passive transfer tests serum obtained from mice sacrificed at this time gave little protection compared to normal serum. On Day 14 g.w. immune spleen cell recipients had subpatent infections and enriched immune T-cell recipients had a lower mean parasitaemia than g.w. normal spleen cell recipients. Serum obtained on Day 14 from g.w. immune spleen cell recipients gave better protection after passive transfer than sera from enriched immune T-cell or g.w. normal spleen cell recipients. Day 14 serum from enriched immune T-cell recipients, but not from g.w. normal spleen cell recipients, produced some initial protection after passive transfer. These results suggest that the transferred immune spleen cells contributed to the observed humoral immunity in lethally irradiated recipient mice.     

Babesia hylomysci and Babesia microti: Dexamethasone treatment of infected mice

The effect of dexamethason on Babesia hylomysci and B. microti was investigated in LACA mice. The drug enhanced both infections by depressing the immune mechanisms of the host when treatment was initiated before parasite inoculation, but had no effects on established and subpatent infections. The degree of parasitemia in the treated mice seemed to depend on the tropism of either parasite toward mature erythrocytes or reticulocytes. B. hylomysci, which favors mature erythrocytes, produced fulminating infections in treated mice. B. microti, which prefers reticulocytes, produced similar parasitemia patterns in treated and untreated mice, but only the treated mice succumbed to the infection. The drug, which suppressed cellular proliferation in the spleens of infected animals, together with its direct lympholytic effects, drastically changed the architecture of the organ.     

Evaluation of immunization with tachyzoite excreted-secreted proteins in a novel susceptible mouse model (A/Sn) for Toxoplasma gondii

Toxoplasma gondii is an important food-borne parasite transmitted primarily from animals to humans through meat consumption, mainly pork and lamb, as well as through oocysts shed by cats. Infection in humans can cause severe neonatal malformations, ocular complications or encephalitis. Toxoplasmosis infection during pregnancy, especially in sheep, often results in abortion, representing considerable economic loss. The aim of this study was to investigate whether Toxoplasma gondii pooled excreted-secreted antigens (ESA), recovered from infected culture supernatants with tachyzoites used as immunogen, can protect experimental mice against T. gondii infection. For immunization experiments, we evaluated A/Sn inbred mice, a novel susceptible mouse model for T. gondii and a virulent strain (RH) for challenge experiments. The antigen selection was based on those produced by tachyzoites since they are responsible for disseminating the infection as well as stimulating the humoral and cellular immune responses. ESA were recovered from VERO cell-culture supernatants infected with virulent RH strain tachyzoites harvested after 48 h. Groups of 5 female mice were intraperitoneally (i.p.) immunized with 4 doses at 2 week intervals with 20 μg of ESA adsorbed to 0.5 mg of alum. The control group received only the adjuvant in PBS on the same dates. Pooled serum collected from chronically infected mice was used as positive control. Blood samples were collected from tail veins 14 days after each immunization. Antibody was detected using ELISA, indirect immunofluorescence and immunoblotting. Anti-ESA antibodies were also evaluated by agglutination, complement-mediated lysis and antibody-mediated cellular toxicity. Fifteen days after the last immunization, both groups were challenged (i.p.) with 1 × 10³ RH strain tachyzoites. The parasitemia was evaluated by PCR, and survival was followed daily. The results showed an increase of antibody levels after each immunization. Anti-ESA antibodies also reacted with a crude tachyzoite antigen and bonded on the parasite surface, with particularly high intensity at the apical region. Anti-ESA antibodies were also able to agglutinate and kill tachyzoites in vitro through interactions with complement and cellular pathways. Even though the tachyzoite challenge was lethal to the mice, PCR results suggested that immunized mice had lower parasitemia as well as longer survival (72 h) than mice from the control group.     

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.     

Molecular Analysis of Non-Specific Protection against Murine Malaria Induced by BCG Vaccination

Although the effectiveness of BCG vaccination in preventing adult pulmonary tuberculosis (TB) has been highly variable, epidemiologic studies have suggested that BCG provides other general health benefits to vaccinees including reducing the impact of asthma, leprosy, and possibly malaria. To further evaluate whether BCG immunization protects against malarial parasitemia and to define molecular correlates of this non-specific immunity, mice were vaccinated with BCG and then challenged 2 months later with asexual blood stage Plasmodium yoelii 17XNL (PyNL) parasites. Following challenge with PyNL, significant decreases in parasitemia were observed in BCG vaccinated mice relative to naïve controls. To identify immune molecules that may be associated with the BCG-induced protection, gene expression was evaluated by RT-PCR in i) naïve controls, ii) BCG-vaccinated mice, iii) PyNL infected mice and iv) BCG vaccinated/PyNL infected mice at 0, 1, 5, and 9 days after the P. yoelii infection. The expression results showed that i) BCG immunization induces the expression of at least 18 genes including the anti-microbial molecules lactoferrin, eosinophil peroxidase, eosinophil major basic protein and the cathelicidin-related antimicrobial peptide (CRAMP); ii) an active PyNL infection suppresses the expression of important immune response molecules; and iii) the extent of PyNL-induced suppression of specific genes is reduced in BCG-vaccinated/PyNL infected mice. To validate the gene expression data, we demonstrated that pre-treatment of malaria parasites with lactoferrin or the cathelicidin LL-37 peptide decreases the level of PyNL parasitemias in mice. Overall, our study suggests that BCG vaccination induces the expression of non-specific immune molecules including antimicrobial peptides which may provide an overall benefit to vaccinees by limiting infections of unrelated pathogens such as Plasmodium parasites.     

Evolution of infection in mice inoculated by the oral route with different developmental forms of Trypanosoma cruzi I and II

Oral infection has become the most important transmission mechanism of Chagas disease in Brazil. For this study, the development of Trypanosoma cruzi infection in mice, induced by the oral and intraperitoneal (IP) routes, was compared. Four groups of Swiss mice were used to evaluate the influence of parasite genetics, number of parasites, inoculation volume and developmental stages on the development of the orally induced infection: 1 – blood trypomastigotes (BT) via oral; 2 – BT via IP; 3 – culture metacyclic trypomastigotes (MT) via oral; and 4 – culture MT via IP. Animals inoculated orally showed levels of parasitemia, as well as infectivity and mortality rates, lower than animals inoculated via IP, regardless of DTU (discrete typing unit) and inoculum. Animals infected with TcII showed higher levels of these parameters than did animals infected with TcI. The larger volume of inoculum showed a greater capacity to cause an infection when administered via the oral route. BT infection was more virulent than culture MT infection for both routes (oral and IP). However, mice inoculated orally with BT showed lower levels than via IP, while mice inoculated orally with culture MT showed similar levels of infection to those inoculated via IP. Mice inoculated with culture MT showed more histopathological changes than those inoculated with BT, regardless of the inoculation route. These results indicate that this alternative experimental model is useful for evaluating infection by T. cruzi isolates with subpatent parasitemia and low virulence, such as those belonging to the TcI and TcIV DTUs, which are prevalent in outbreaks of orally transmitted Chagas disease.     

Plasmodium berghei: vaccination of mice against malaria with heat inactivated parasitized blood

Heat inactivated Plasmodium berghei-infected blood acted as a vaccine against P. berghei infection in mice. The heat inactivated blood was noninfective. Intact or splenectomized vaccine-treated mice, as well as P. berghei susceptible mice inoculated with whole blood or homogenized spleens from vaccine-treated animals, did not become infected. A/J, DDS and Carworth CF₁ mice were all protected against P. berghei challenge after vaccination. A/J and DDS mice developed good immunity after a single vaccination injection. Similar levels of immunity were obtained in CF₁ mice after at least two vaccine injections. Immunized mice responded to P. berghei challenge with mild anemias and low level parasitemias. Resolution of infection occurred between the first and third weeks after challenge. Nonvaccinated mice developed progressive anemia and parasitemia during the same time period. The immunity appears to be caused by P. berghei antigens; it could not be induced by homologous or heterologous noninfected red blood cells, P. gallinaceum-infected blood or Freund's Complete Adjuvant.     

Fas has a role in cerebral malaria, but not in proliferation or exclusion of the murine parasite in mice

We examined the susceptibility of murine Fas-deficient mutants to malaria infection in order to investigate the role of Fas in an experimental murine model of cerebral malaria (CM). We infected mice of B6 and CBA wild-type and mutant backgrounds with Plasmodium berghei ANKA. The incidence of CM in the mutant mice (B6-lpr, CBA-lpr^cg) was decreased by about 50% compared with wild-type control strains at 2 weeks after infection. We did not observe significant differences of parasitemia during a murine malaria infection with nonlethal Plasmodium yoelii 17XNL between wild-type and lymphoproliferative (lpr) mutant mice of C3H and MRL genetic backgrounds, although B6-lpr mice exhibited significantly higher parasitemia than did B6 mice 12 to 18 days after infection. These results suggest Fas has a possible role in CM but may not play a major role in the proliferation or exclusion of a murine malaria parasite in a nonlethal infection.     

Leishmania mexicana and Leishmania tropica: Cross immunity in C57BL/6 mice

Leishmania mexicana and Leishmania tropica infection were comparatively studied in C57BL/6 mice. Infection with 10⁴ amastigotes of L. mexicana was followed by the appearance of a single lesion which ulcerated in 8 weeks and healed in 24 weeks. Mice infected with 10⁴ amastigotes of L. tropica developed less severe lesions which healed in 18 weeks. In both cases healing was accompanied by a delayed hypersensitivity response and an in vitro lymphocyte reactivity to leishmanial antigens. Mice recovered from a primary infection with L. mexicana or L. tropica were resistant to both homologous and heterologous challenge. In vitro and in vivo immunological tests indicated that L. mexicana and L. tropica share antigenic determinants which are involved in cell-mediated immune responses to these parasites.     

Malaria infections do not compromise vaccine-induced immunity against tuberculosis in mice

Background

Given the considerable geographic overlap in the endemic regions for malaria and tuberculosis, it is probable that co-infections with Mycobacterium tuberculosis and Plasmodium species are prevalent. Thus, it is quite likely that both malaria and TB vaccines may be used in the same populations in endemic areas. While novel vaccines are currently being developed and tested individually against each of these pathogens, the efficacy of these vaccines has not been evaluated in co-infection models. To further assess the effectiveness of these new immunization strategies, we investigated whether co-infection with malaria would impact the anti-tuberculosis protection induced by four different types of TB vaccines in a mouse model of pulmonary tuberculosis.

Principal Findings

Here we show that the anti-tuberculosis protective immunity induced by four different tuberculosis vaccines was not impacted by a concurrent infection with Plasmodium yoelii NL, a nonlethal form of murine malaria. After an aerogenic challenge with virulent M. tuberculosis, the lung bacterial burdens of vaccinated animals were not statistically different in malaria infected and malaria naïve mice. Multi-parameter flow cytometric analysis showed that the frequency and the median fluorescence intensities (MFI) for specific multifunctional T (MFT) cells expressing IFN-γ, TNF-α, and/or IL-2 were suppressed by the presence of malaria parasites at 2 weeks following the malaria infection but was not affected after parasite clearance at 7 and 10 weeks post-challenge with P. yoelii NL.

Conclusions

Our data indicate that the effectiveness of novel TB vaccines in protecting against tuberculosis was unaffected by a primary malaria co-infection in a mouse model of pulmonary tuberculosis. While the activities of specific MFT cell subsets were reduced at elevated levels of malaria parasitemia, the T cell suppression was short-lived. Our findings have important relevance in developing strategies for the deployment of new TB vaccines in malaria endemic areas.     

Schistosoma mansoni: reduction in clinical manifestations and in worm burdens conferred by serum and transfer factor from immune or normal rhesus monkeys.

Although delayed hypersensitivity to Schistosoma mansoni was conferred on rhesus monkeys (Macaca mulatta) by means of dialyzable transfer factor prepared from peripheral leukocytes or lymph node cells of infected immune donors, when such animals were challenged with 1000 cercariae of S. mansoni they developed worm burdens similar to those of nontreated controls. However, recipients of transfer factor that, in addition, received hyperimmune serum showed minimal clinical symptoms and significantly reduced worm burdens after subsequent infection with S. mansoni irrespective of whether the donors used for the transfer factor were immune or uninfected. A significant but lower degree of protection was conferred by combinations of either S. mansoni transfer factor or normal transfer factor and normal serum. Neither transfer factor nor hyperimmune serum alone conferred protection to recipients. Susceptibility to infection was assessed by observing the signs of the disease, determining the worm burdens by perfusion 10 weeks after exposure, and by observing the appearance of the intestine at autopsy. The animals which received transfer factor and immune serum were protected against clinical disease. Good correlation between worm burdens and severity of disease was observed.