Antigenic variation during the developmental cycle of Trypanosoma brucei

During the complex life cycle of Trypanosoma brucei, changes in the exposed surface antigens occur in both the mammalian host and the insect vector (Glossina spp.). These antigenic changes are associated with alterations of the variant surface glycoprotein (VSG) composition or with the loss of the VSG. In the bloodstream of the mammalian host, trypanosomes successfully evade destruction by the host's immune response by continuously expressing alternative VSGs, at low frequency, which are not destroyed by host antibodies. When ingested by the tsetse fly, the bloodstream trypanosomes rapidly lose their surface coat and surface membrane antigens are exposed which are normally covered in the bloodstream. In the salivary glands of the tsetse fly, the trypanosomes differentiate to the metacyclic stage, which reacquires a surface coat. The antigenic composition of the metacyclics is heterogeneous. The same metacyclic types are expressed regardless of the bloodstream antigenic type ingested by the tsetse fly. In the mammal the metacyclics differentiate to long-slender bloodstream forms but continue to express the metacyclic VSG for at least three days. The next VSGs expressed in the mammalian host appear to be influenced by the antigenic type ingested by the tsetse. The ingested antigenic type is often expressed in the first parasitemia following expression of the metacyclic antigenic types.     

A revised arithmetic model of long slender to short stumpy transformation in the African trypanosomes

An arithmetic model that closely approximates an African trypanosome infection in immunosuppressed mice is presented. The final model was based on an examination of the following parameters: the rate of long slender to short stumpy transition, the maximum percentage of long slender to short stumpy stages that can be induced, the survival time or half life of the short stumpy stage in vivo, and the rate (%) of long slender to short stumpy stage transition following the peak in transformation. The model is based on the assumption that the long slender to short stumpy transition is parasite population dependent and that in mice the long slender to short stumpy transition only begins when the trypanosome population reaches a density of 1 x 10(7) trypanosomes/ml. The model predicts that the parasitemia during the first several days of an infection is controlled solely by the kinetics of the transition of the dividing long slender stage to the nondividing short stumpy stage. It was not necessary to include in the model the host's immune response in order to simulate the early growth kinetics of pleomorphic trypanosomes in infected mice.     

Morphological changes in trypanosoma brucei rhodesiense following inhibition of polyamine biosynthesis in vivo

The effect of α-difluoromethylornithine (DFMO) treatment on the morphology of African trypanosomes was investigated. For this purpose inbred mice were immunosuppressed and infected with a clone of the protozoan blood parasite Trypanosoma brucei rhodesiense. The mice were then treated with DFMO, an irreversible inhibitor of ornithine decarboxylase, which inhibits polyamine synthesis. DFMO treatment in the absence of host immunity resulted in arrest of cytokinesis of the trypanosomes and many binucleated cells could be seen in blood smears. If mice were infected with a highly virulent trypanosome clone (ETat 1.10), which does not normally transform from long slender (LS) to short stumpy (SS) forms, DFMO treatment caused SS transformation to occur on days 3–4. This morphological SS transformation was substantiated by the presence of diaphorase activity and nuclear and mitochondrial changes. The results suggest a possible involvement of polyamines in the transformation from LS to SS forms.     

Ablastin: Control of Trypanosoma musculi infections in mice

Trypanosoma musculi infections in CBA mice consist of a phase of increasing parasitemia during which dividing forms of the parasite are present in the blood, followed by a period when only nondividing trypomastigotes are seen. A second crisis terminates the blood infection and leaves the host immune, but small numbers of trypanosomes, including multiplicative forms, persist in the kidneys for many months. Studies were made involving infections in T-lymphocyte deprived mice, the effects of passive transfer of serum and cells, measurement of DNA synthesis by the parasite, serological responses, and in vitro effects of serum on the trypanosomes. These indicated that the initial check on the increase in blood parasitemia is due in part to two humoral factors. One of these has a trypanocidal effect (this is thought to be an IgM antibody) while the other, which may be an IgG antibody, is the ablastin that inhibits further reproduction by the parasite. Both trypanocidal and ablastic effects were demonstrable in the serum of immune mice yet the parasite was still able to survive and multiply in the kidneys.     

Development of metacyclic forms of Trypanosoma brucei sspp. in cultures containing explants of Phormia regina Meigen

When procyclic trypanosomes of Trypanosoma brucei brucei and Trypanosoma brucei rhodesiense were cultivated in Nunclon 25 cm2 flasks at 27 C in a liquid medium containing various tissue explants of Phormia regina Meigen, some of them developed into forms infective for mice. The infective stages were present at various periods of up to 29 days when the cultures were terminated. Larger numbers of explants of head-salivary glands than the other tissues used were required to produce infections. Infectivity titrations on trypanosome suspensions of T. b. brucei TRUM 252 and T. b. rhodesiense TRUM 497 indicated that only a small proportion of the populations was infective. Mice were rarely infected with trypanosomes grown in medium without explants. Only 1 mouse of the 11 inoculated developed a parasitemia from a control culture of T. b. rhodesiense TRUM 545. A few trypanosomes resembling epimastigotes and metacyclic forms were seen in stained samples of infective inocula.     

The role of B-cells and IgM antibodies in parasitemia, anemia, and VSG switching in Trypanosoma brucei-infected mice

African trypanosomes are extracellular parasitic protozoa, predominantly transmitted by the bite of the haematophagic tsetse fly. The main mechanism considered to mediate parasitemia control in a mammalian host is the continuous interaction between antibodies and the parasite surface, covered by variant-specific surface glycoproteins. Early experimental studies have shown that B-cell responses can be strongly protective but are limited by their VSG-specificity. We have used B-cell (microMT) and IgM-deficient (IgM(-/-)) mice to investigate the role of B-cells and IgM antibodies in parasitemia control and the in vivo induction of trypanosomiasis-associated anemia. These infection studies revealed that that the initial setting of peak levels of parasitemia in Trypanosoma brucei-infected microMT and IgM(-/-) mice occurred independent of the presence of B-cells. However, B-cells helped to periodically reduce circulating parasites levels and were required for long term survival, while IgM antibodies played only a limited role in this process. Infection-associated anemia, hypothesized to be mediated by B-cell responses, was induced during infection in microMT mice as well as in IgM(-/-) mice, and as such occurred independently from the infection-induced host antibody response. Antigenic variation, the main immune evasion mechanism of African trypanosomes, occurred independently from host antibody responses against the parasite's ever-changing antigenic glycoprotein coat. Collectively, these results demonstrated that in murine experimental T. brucei trypanosomiasis, B-cells were crucial for periodic peak parasitemia clearance, whereas parasite-induced IgM antibodies played only a limited role in the outcome of the infection.     

Trypanosoma rhodesiense blood forms express all antigen specificities relevant to protection against metacyclic (insect form) challenge

Monoclonal antibodies were used to demonstrate the expression of four distinct metacyclic (infective insect form) trypanosome antigens on blood forms of T. rhodesiense. Metacyclic antigens were consistently expressed on the blood forms on days 4 and 5 of the first parasitemia after metacyclic infection of C57BL/6 mice. In different mice examined, the percent of blood forms expressing metacyclic antigens ranged from 46 to 85%. Immunization with irradiated day-5 blood form trypanosomes was protective against metacyclic challenge, indicating that all antigen specificities relevant to protective immunization against metacyclic challenge are expressed on blood form trypanosomes. Blood forms, in contrast to metacyclic forms, can be isolated in quantities sufficient for purification of antigens and genetic cloning.     

Trypanosoma brucei: Antigenic analysis of bloodstream,vector, and culture stages by the quantitative fluorescent antibody methods

Quantitative direct fluorescent antibody methods were used in antigenic analysis of developmental stages of Trypanosoma brucei brucei strains, most of them having the same variant antigen B, which were derived from a cyclically transmissible stabilate. Antigen-B trypanosomes were used for initiation of cultures in modified Tobie's (Tm) medium and in Glossina morsitans morsitans organ cultures, and for the infective feed of G. m. morsitans. Antisera against antigen-B bloodstream forms and against Tm-grown culture forms were developed in rabbits by inoculations of disrupted organisms mixed (1:1) with complete Freund's adjuvant. The globulin fractions of the antisera were conjugated with fluorescein isothiocyanate, and processed on Sephadex G-25 and DEAE-cellulose columns. The DEAE fractions with 2.0 and 4.7 or 4.8 molar fluorescein:protein ratios were pooled and concentrated twofold.Examination of 109 flies at 30 or 31 days after the infective feed revealed about 18.3% midgut, about 10.1% proventricular, and about 3.7% salivary-gland infections. A salivary gland suspension from one of the infected flies gave rise to a parasitemia in a mouse, and trypanosomes from the first parasitemia were transferred by two 3-day syringe passages into another mouse. Smears were prepared of trypanosomes (antigens B-164, B-167) from the first parasitemias from these two mice, of intact B-antigen trypanosomes, of culture forms (CT) from Tm medium, and of procyclics (CG) from Glossina cultures as well as of midgut (GM), proventricular (GP), and salivary-gland (GS) forms from tsetse flies. All these forms were fixed by one or more of the three following methods: complete fixation (CoFix) by the formalin-NH₄OH-Tween 80 procedure; fixation before affixation to slides (F+); fixation after affixation to slides (F?). The best results with regard to fluorescence intensity and specificity were obtained by using the CoFix technique.Statistical analyses of the fluorescence means of the antigens subjected to direct and inhibition staining gave the following results: (1) CT, CG, GM, and GP forms were antigenically the same. (2) GM and GP trypanosomes from different flies were antigenically indistinguishable. (3) The surface antigen of the variant-B bloodstream trypanosomes was different from these antigens of culture, midgut, and proventricular forms. It differed also from those of metacyclics from two flies and of B-164 and B-167 bloodstream forms. (4) No antigenic differences were found, in preparations fixed by the F? method, between B-164 and B-167 bloodstream trypanosomes and the metacyclics from two flies, one of which served as the source of the salivary-gland trypomastigotes (GS-98) that gave rise to these two bloodstream form antigens. (5) Closer antigenic relationships were noted between B forms and B-164 and B-167 trypanosomes than between B and CT organisms in smears fixed by the F+ technique, but no such differences were discernible in preparations fixed by the F? procedure.     

Trypanosoma vivax: adaptation of two East African stocks to laboratory rodents

Two Trypanosoma vivax stocks from East Africa have been adapted to rats and mice. Adaptation was induced by rapid passage at two- to four-day intervals in sublethally irradiated rats. After 200 such passages, the two stocks gave rise to parasitemias of 10(9)-10(10) trypanosomes/ml in peripheral blood, and the infection was fatal in 90% of the rats. By passaging the rat-adapted T. vivax into normal mice at two- to three-day intervals for over 200 passages, the two stocks also became pathogenic to mice. One of the stocks was also capable of maintenance in non-irradiated rats. The two stocks displayed a marked degree of pleomorphism in irradiated and non-irradiated rats and mice. In the early rising parasitemia, the organisms were predominantly short, with a well formed undulating membrane, a pointed posterior end, and a large terminal kinetoplast. As parasitemia approached its peak, the organisms transformed into long, slender forms with an inconspicuous undulating membrane, an elongated posterior end, and a sub-terminal kinetoplast. The short forms associated with the early, rising parasitemia were more infective for mice than the long forms encountered at peak parasitemia. Although the two rodent-adapted stocks retained their pathogenicity for goats, neither the original stocks nor their corresponding rodent-adapted stocks could be cyclically transmitted by tsetse flies. The availability of these stocks will greatly facilitate investigations on East African T. vivax which would otherwise be difficult to carry out in experimental rodents.     

Trypanosoma rhodesiense: variant specificity of immunity induced by irradiated parasites.

Rats immunized with irradiated Trypanosoma rhodesiense resisted infection with the homologous strain. When similarly immunized rats were challenged with parasites obtained from rhesus monkeys infected with the same strain, resistance depended on when parasites were obtained from the donor monkeys. Immunized rats challenged with trypanosomes obtained from a monkey during the first peak of parasitemia were solidly immune; immunized rats challenged with trypanosomes obtained from monkeys after their initial peak of parasitemia all succumbed to the challenging infection. These observations indicate that parasites of a variant antigenic specificity arose during the course of the monkey infections. Neutralization tests performed on the various isolates from rats and monkeys using antiserum obtained from immunized rats confirmed that the immunity produced by irradiated trypanosomes was variant specific.     

Changes in the adenylate energy charge of Nippostrongylus brasiliensis and Nematodirus battus during the development of immunity to these nematodes in their host

Infection of rats with 2000 infective juveniles of Nippostrongylus brasiliensis and of lambs with 60 000 infective juveniles of Nematodirus battus results in a well-marked immunity to these nematodes in their respective host. There is a fall in the adenylate energy charge value of these nematodes during the course of these infections, reaching values of 0.37 in males and 0.27 in females of N. brasiliensis, and 0.31 in males and 0.23 in females of N. battus towards the end of the infections. In hosts given relatively small numbers of infective juveniles, the values for the nematodes removed from the hosts late in the infection remain at a relatively high level. These results indicate that the immune response of the host may affect the energy status of these nematodes, and this could help to explain their subsequent expulsion from the immune host.     

Trypanosoma vivax: Adaptation of Two East African Stocks to Laboratory Rodents1

Two Trypanosoma vivax stocks from East Africa have been adapted to rats and mice. Adaptation was induced by rapid passage at two- to four-day intervals in sublethally irradiated rats. After 200 such passages, the two stocks gave rise to parasitemias of 10⁹–10¹⁰ trypanosomes/ml in peripheral blood, and the infection was fatal in 90% of the rats. By passaging the rat-adapted T. vivax into normal mice at two- to three-day intervals for over 200 passages, the two stocks also became pathogenic to mice. One of the stocks was also capable of maintenance in non-irradiated rats. The two stocks displayed a marked degree of pleomorphism in irradiated and non-irradiated rats and mice. In the early rising parasitemia, the organisms were predominantly short, with a well formed undulating membrane, a pointed posterior end, and a large terminal kinetoplast. As parasitemia approached its peak, the organisms transformed into long, slender forms with an inconspicuous undulating membrane, an elongated posterior end, and a sub-terminal kinetoplast. The short forms associated with the early, rising parasitemia were more infective for mice than the long forms encountered at peak parasitemia. Although the two rodent-adapted stocks retained their pathogenicity for goats, neither the original stocks nor their corresponding rodent-adapted stocks could be cyclically transmitted by tsetse flies. The availability of these stocks will greatly facilitate investigations on East African T. vivax which would otherwise be difficult to carry out in experimental rodents.     

Activation of endocytosis as an adaptation to the mammalian host by trypanosomes

Immune evasion in African trypanosomes is principally mediated by antigenic variation, but rapid internalization of surface-bound immune factors may contribute to survival. Endocytosis is upregulated approximately 10-fold in bloodstream compared to procyclic forms, and surface coat remodeling accompanies transition between these life stages. Here we examined expression of endocytosis markers in tsetse fly stages in vivo and monitored modulation during transition from bloodstream to procyclic forms in vitro. Among bloodstream stages nonproliferative stumpy forms have endocytic activity similar to that seen with rapidly dividing slender forms, while differentiation of stumpy forms to procyclic forms is accompanied by rapid down-regulation of Rab11 and clathrin, suggesting that modulation of endocytic and recycling systems accompanies this differentiation event. Significantly, rapid down-regulation of endocytic markers occurs upon entering the insect midgut and expression of Rab11 and clathrin remains low throughout subsequent development, which suggests that high endocytic activity is not required for remodeling the parasite surface or for survival within the fly. However, salivary gland metacyclic forms dramatically increase expression of clathrin and Rab11, indicating that emergence of mammalian infective forms is coupled to reacquisition of a high-activity endocytic-recycling system. These data suggest that high-level endocytosis in Trypanosoma brucei is an adaptation required for viability in the mammalian host.     

Infectivity of Trypanosoma rhodesiense Cultivated at 28°C with Various Tsetse Fly Tissues1

ABSTRACT. Metacyclic trypanosomes developed in populations of procyclic forms of four stocks of Trypanosoma brucei rhodesiense cultivated at 28°C in a liquid medium containing explants of tsetse fly head-salivary glands, alimentary tract, abdominal body wall, or thoracic muscle. The cultures became infective for mice 7–16 days after they were prepared, and infective trypanosomes were present for prolonged periods. In the culture series of stock TRUM 545, infectivity persisted for 138 days when the cultures were terminated. Only one explant of thoracic muscle tissue was required for the production of metacyclic stages in stock TRUM 497 cultures. Infectivity titrations on trypanosome suspensions from cultures of stocks TRUM 497, TRUM 545, and TRUM 567 revealed that only a small proportion of the culture population was infective. Using stock TRUM 530, mice were infected consistently from inoculations of trypanosomes grown in the presence of explants; infectivity of the trypanosomes ceased when the explants were removed from the flasks, but reappeared when they were returned to the cultures. Parasites grown in medium “conditioned” by explants produced sporadic infections in mice. The control cultures of trypanosomes grown in medium alone were generally not infective, but two of the stocks produced occasional parasitemias. Stained samples of infective inocula contained a few epimastigote-like and metacyclic-like trypanosomes.     

Infectivity of Trypanosoma rhodesiense cultivated at 28 degrees C with various tsetse fly tissues

Metacyclic trypanosomes developed in populations of procyclic forms of four stocks of Trypanosoma brucei rhodesiense cultivated at 28 degrees C in a liquid medium containing explants of tsetse fly head-salivary glands, alimentary tract, abdominal body wall, or thoracic muscle. The cultures became infective for mice 7-16 days after they were prepared, and infective trypanosomes were present for prolonged periods. In the culture series of stock TRUM 545, infectivity persisted for 138 days when the cultures were terminated. Only one explant of thoracic muscle tissue was required for the production of metacyclic stages in stock TRUm 497 cultures. Infectivity titrations on trypanosome suspensions from cultures of stocks TRUM 497, TRUM 454, and TRUm 567 revealed that only a small proportion of the culture population was infective. Using stock TRUM 530, mice were infected consistently from inoculations of trypanosomes grown in the presence of explants; infectivity of the trypanosomes eased when the explants were removed from the flasks, but reappeared when they were returned to the cultures. Parasites grown in medium "conditioned" by explants produced sporadic infections in mice. The control cultures of trypanosomes grown in medium alone were generally not infective, but two of the stocks produced occasional parasitemias. Stained samples of infective inocula contained a few epimastigote-like and metacyclic-like trypanosomes.     

A culture and biochemical assay system for Trypanosoma lewisi

Trypanosoma lewisi was cultivated as forms which appeared to be physiologically similar to those found in vivo. The medium consisted of 1.0 g peptone, 1.0 g glucose, 10 ml rat serum, 10,000 units penicillin G, 10,000 μg streptomycin and 90 ml Hank's Balanced Salt Solution. It was supplemented with 8.0 × 10⁸ rat erythrocytes per milliliter. In the complete medium trypanosomes multiplied for 48–72 hr. Cultured forms were lethal to newborn rats and infective to adults.Adsorbed early immune serum inhibited the growth of the trypanosomes in vitro and the percentage of reproductives declined from 66 to 45%. The cultured trypanosomes were also susceptible to both trypanocidal antibodies.     

The within-host dynamics of African trypanosome infections

African trypanosomes are single-celled protozoan parasites that are capable of long-term survival while living extracellularly in the bloodstream and tissues of mammalian hosts. Prolonged infections are possible because trypanosomes undergo antigenic variation—the expression of a large repertoire of antigenically distinct surface coats, which allows the parasite population to evade antibody-mediated elimination. The mechanisms by which antigen genes become activated influence their order of expression, most likely by influencing the frequency of productive antigen switching, which in turn is likely to contribute to infection chronicity. Superimposed upon antigen switching as a contributor to trypanosome infection dynamics is the density-dependent production of cell-cycle arrested parasite transmission stages, which limit the infection while ensuring parasite spread to new hosts via the bite of blood-feeding tsetse flies. Neither antigen switching nor developmental progression to transmission stages is driven by the host. However, the host can contribute to the infection dynamic through the selection of distinct antigen types, the influence of genetic susceptibility or trypanotolerance and the potential influence of host-dependent effects on parasite virulence, development of transmission stages and pathogenicity. In a zoonotic infection cycle where trypanosomes circulate within a range of host animal populations, and in some cases humans, there is considerable scope for a complex interplay between parasite immune evasion, transmission potential and host factors to govern the profile and outcome of infection.     

Modulation of innate immunity by African trypanosomes

The experimental studies of Brucei group trypanosomes presented here demonstrate that the balance of host and parasite factors, especially IFN-γ GPI-sVSG respectively, and the timing of cellular exposure to them, dictate the predominant MP and DC activation profiles present at any given time during infection and within specific tissues. The timing of changes in innate immune cell functions following infection consistently support the conclusion that the key events controlling host resistance occur within a short time following initial exposure to the parasite GPI substituents. Once the changes in MP and DC activities are initiated, there appears little that the host can do to reverse these changes and alter the final outcome of these regulatory events. Instead, despite the availability of multiple innate and adaptive immune mechanisms that can control parasites, there is an inability to control trypanosome numbers sufficiently to prevent the emergence and establishment of virulent trypanosomes that eventually kill the host. Overall it appears that trypanosomes have carefully orchestrated the host innate and adaptive immune response so that parasite survival and transmission, and alterations of host immunity, are to its ultimate benefit.     

Trypanosoma lewisi: Avidity and adsorbability of ablastin,the rat antibody inhibiting parasite reproduction

The relation of naturally acquired host IgG in the surface coat of bloodstream forms of Trypanosoma lewisi to ablastin was studied to determine whether, contrary to a long-held conclusion, the antibody is avid and adsorbable. It was found by immunofluorescence and agglutination tests with monospecific antisera to rat IgG that bloodstream forms collected from immunosuppressed hosts, in contrast to those from immunocompetent hosts, have little or no detectable surface IgO. Specificity of adsorption was also demonstrated in other immunofluorescence experiments in which bloodstream forms from immunosuppressed hosts adsorbed IgG from immune serum with ablastic activity only (previously adsorbed with trypanosomes from immunocompetent hosts to remove the trypanocidal antibodies), but did not adsorb IgG from normal rat serum. To determine whether this specific adsorption of IgG by the parasite could be correlated with a reduction in ablastic activity, immune sera were adsorbed with bloodstream forms from immunosuppressed hosts at packed cell/serum ratios of either 1.2 or 2.0, and the adsorbed sera were then tested for ablastic activity in vitro. With both cell/serum ratios, ablastic activity was reduced by 50%. In comparison, similar adsorptions of immune sera with trypanosomes from immunocompetent hosts resulted in reductions of ablastic activity of only about 9 and 27% with the low and high cell/serum ratios, respectively. It is concluded that the failure to effect significant adsorption of ablastin in earlier studies resulted from the use of ablastinsensitized trypanosomes from immunocompetent hosts.     

African trypanosomiasis: naturally occurring regulatory T cells favor trypanotolerance by limiting pathology associated with sustained type 1 inflammation

Tolerance to African trypanosomes requires the production of IFN-gamma in the early stage of infection that triggers the development of classically activated macrophages controlling parasite growth. However, once the first peak of parasitemia has been controlled, down-regulation of the type 1 immune response has been described. In this study, we have evaluated whether regulatory T cells (Tregs) contribute to the limitation of the immune response occurring during Trypanosoma congolense infection and hereby influence the outcome of the disease in trypanotolerant C57BL/6 host. Our data show that Foxp3+ Tregs originating from the naturally occurring Treg pool expanded in the spleen and the liver of infected mice. These cells produced IL-10 and limited the production of IFN-gamma by CD4+ and CD8+ effector T cells. Tregs also down-regulated classical activation of macrophages resulting in reduced TNF-alpha production. The Treg-mediated suppression of the type 1 inflammatory immune response did not hamper parasite clearance, but was beneficial for the host survival by limiting the tissue damages, including liver injury. Collectively, these data suggest a cardinal role for naturally occurring Tregs in the development of a trypanotolerant phenotype during African trypanosomiasis.