Trypanosoma lewisi: accumulation of antigen-specific host IgG as a component of the surface coat during the course of infection in the rat.

Naturally acquired host IgG, adsorbed to the surface of Trypanosoma lewisi during the course of infection in the rat, was labeled with fluorescein-conjugated rabbit IgG, or Fab fragments of this IgG, directed against rat IgG. The intensity of fluorescent labeling increases with time, concomitant with the increase in anti-T. lewisi activity of host plasma. Trypanosomes harvested from immunosuppressed hosts lack detectable surface IgG. Trypanosomes having little or no detectable surface IgG (harvested from immunosuppressed hosts or early in the infection from immunocompetent hosts) can adsorb IgG from serum with ablastic activity only (obtained from other infected rats between the first and second crises and adsorbed to remove trypanocidal antibodies), but not from normal serum. Therefore, the absence of detectable surface IgG on such cells is not caused by the parasites' inability to adsorb host IgG, but rather results from the immune state of the host. Hence surface IgG on T. lewisi is specific antibody. Host albumin is nonspecifically adsorbed, in contrast to IgG. Trypanosomes from immuno-suppressed and immunocompetent rats were positive and visually indistinguishable from each other when labeled with anti-rat albumin, and were equally agglutinable with anti-rat albumin serum.     

Flow cytometric analysis of immunoglobulin and complement component C3 on the surface of Trypanosoma lewisi

We have reinvestigated whether surface immunoglobulin (sIg) on Trypanosoma lewisi is antibody directed toward parasite antigen by using flow cytometry to analyze parasites stained with fluoresceinated F(ab')2 fragments of antibodies to rat IgG and IgM. We have confirmed that IgG antibody to the parasites is present both in the serum of rats and on the surface of parasites between the fourth and twentieth days of infection, that the amount of sIg per cell increases as the infection progresses, and that considerably more IgG is present on parasites harvested from intact rats than on those from rats that had been immunosuppressed by whole body gamma-irradiation. In addition sIgM was detected on trypanosomes from intact, but not on parasites from irradiated rats. We have also made two observations suggesting that not all sIg is specific antibody made in response to T. lewisi. First, a low but significant amount of sIgG was detected on parasites throughout infection in irradiated rats; no sIgM was detected on these parasite. Second, when parasites harvested from immunosuppressed rats were incubated in normal rat serum, the amount of both sIgG and sIgM detected by flow immunofluorescence increased. Parasites harvested from intact animals bound IgM but not IgG from normal rat serum. These results suggest either that natural antibody to the trypanosomes is present in the serum of uninfected rats or that some rat immunoglobulins bind to structures on the trypanosome surface in ways that do not depend on usual antigen-antibody interactions. Finally, flow immunofluorescence was also used to detect complement component C3 on the surface of both intact and trypsinized bloodstream forms harvested from intact or immunosuppressed rats. The amount of sC3 per cell did not increase until late in the infection and consequently did not correlate with the increase of sIgG. Therefore, T. lewisi avoids destruction by the immune system although immune effector molecules, IgG, IgM, and C3, are on its surface.     

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.     

Elicitation of the reproduction-inhibiting antibody ablastin by serum exoantigens of Trypanosoma lewisi

Serum exoantigens of Trypanosoma lewisi were collected 5 days after infection from immunocompetent (untreated) rats and rats immunosuppressed by treatment with either hydrocortisone acetate or dexamethasone. Normal rats were then immunized with pooled, whole exoantigen-containing serum from 1 of these 3 sources plus alum as an adjuvant, and the immune sera produced were tested individually. All contained agglutinating (trypanocidal) antibodies to both antigenic variants of T. lewisi, but only about two-thirds showed precipitating activity with exoantigens in gels. More importantly, however, when these antisera were thoroughly adsorbed with living trypanosomes (from immunocompetent hosts) to remove agglutinating antibody only and then tested for ablastic activity in vitro, all showed significant (P less than 0.01) reproduction-inhibiting activity, comparable to that shown by ablastic serum collected from rats that experienced a natural infection. Antisera from control rats similarly immunized with normal rat serum were negative in all antibody tests. The exoantigens of T. lewisi are, therefore, a complex mixture of immunogens that are related to the known immune responses to the parasite and can elicit the formation of ablastic antibody with the same biological properties as that produced during a natural infection.     

Flow Cytometric Analysis of Immunoglobulin and Complement Component C3 on the Surface of Trypanosoma lewisi1

ABSTRACT. We have reinvestigated whether surface immunoglobulin (sIg) on Trypanosoma lewisi is antibody directed toward parasite antigen by using flow cytometry to analyze parasites stained with fluoresceinated F(ab′)₂ fragments of antibodies to rat IgG and IgM. We have confirmed that IgG antibody to the parasites is present both in the serum of rats and on the surface of parasites between the fourth and twentieth days of infection, that the amount of sIg per cell increases as the infection progresses, and that considerably more IgG is present on parasites harvested from intact rats than on those from rats that had been immunosuppressed by whole body γ-irradiation. In addition sIgM was detected on trypanosomes from intact, but not on parasites from irradiated rats. We have also made two observations suggesting that not all sIg is specific antibody made in response to T. lewisi. First, a low but significant amount of sIgG was detected on parasites throughout infection in irradiated rats; no sIgM was detected on these parasites. Second, when parasites harvested from immunosuppressed rats were incubated in normal rat serum, the amount of both sIgG and sIgM detected by flow immunofluorescence increased. Parasites harvested from intact animals bound IgM but not IgG from normal rat serum. These results suggest either that natural antibody to the trypanosomes is present in the serum of uninfected rats or that some rat immunoglobulins bind to structures on the trypanosome surface in ways that do not depend on usual antigen-antibody interactions. Finally, flow immunofluorescence was also used to detect complement component C3 on the surface of both intact and trypsinized bloodstream forms harvested from intact or immunosuppressed rats. The amount of sC3 per cell did not increase until late in the infection and consequently did not correlate with the increase of sIgG. Therefore, T. lewisi avoids destruction by the immune system although immune effector molecules, IgG, IgM, and C3, are on its surface.     

Surface immunoglobulins, a possible mechanism for the persistence of Trypanosoma lewisi in the circulation of rats.

The results presented below show that the dividing and adult forms of T. lewisi share common antigens and indicate that the persistence of adult forms in the circulation of rats immune to reinfection is not due to a change in surface antigens as has been postulated. Using a rabbit anti-rat immunoglobulin serum, the presence of rat immunoglobulins on the surface of adult trypanosomes could be demonstrated. These immunoglobulins were not complement-fixing or opsonic. It is suggested that these immunoglobulins are responsible for the persistence of the adult forms in the circulation of the rat.     

Trypanosoma lewisi: antibody classes which mediate precipitation, agglutination, and the inhibition of reproduction

Sera from Trypanosoma lewisi-infected and uninfected rats were applied to Protein A-Sepharose CL-4B columns. The absorbed fractions of antisera which contained only IgG molecules were reacted in microimmunodiffusion analyses with the exoantigens of T. lewisi in plasma collected from irradiated infected rats, and formed one precipitin line. These sera were also applied to T. lewisi extract immunoabsorbent columns and bound proteins were eluted and analyzed by immunodiffusion against antisera specific for rat immunoglobulins. IgG₁, IgG_2a, IgG_2b, IgG_2c, and IgM were absorbed by the immuno-absorbent columns. Absorption of the rat antisera with anti-rat IgG or anti-rat IgM removed one of the two precipitin lines against extracts prepared from parasites collected from irradiated infected animals. The absorbed IgG fractions and nonabsorbed fractions of antisera which were collected after Protein A-Sepharose CL-4B column chromatography agglutinated trypanosomes. After treatment of antisera with 2-mercaptoethanol, the agglutinin titers were lower than those of the control antisera suggesting both IgG and IgM are involved in the agglutination. The ablastic activity of the fractions eluted from Protein A-Sepharose CL-4B Chromatographic columns was assayed in cultures of bloodstream forms ofT. lewisi. Ablastic activity of proteins of antisera absorbed by the columns was demonstrated indicating they belonged to the IgG class of antibodies.     

Trypanosoma lewisi: production of exoantigens during infection in the rat

Exoantigens are produced by Trypanosoma lewisi during infections in the rat. They were detected in rat serum and plasma by gel-diffusion techniques with hyperimmune rat sera and with rabbit antiserum to washed, living trypanosomes. Their parasite origin is indicated by their presence in trypanosome homogenates, which also contain bound antigens, the continued reactivity of rabbit antisera after absorption with normal rat serum, and the reactions of identity obtained with rat and rabbit antisera. Moreover, by immunoelectrophoresis, the exontigens are revealed as new components in infected rat serum with a mobility slightly anodal to the origin. The results also show that the exoantigens are continuously released in vivo and that the trypanosomes avidly bind non-antibody rat serum proteins to their surface. Unlike the complete qualitative changes in exoantigens that accompany antigenic variation of pathogenic species of trypanosomes, at least one exoantigen remains unchanged when antigenic variation occurs with T. lewisi although additional exoantigens may appear and disappear. The relation of the exoantigens to the known ablastic and trypanocidal antibodies is difficult to determine since these antibodies and the exoantigens occur simultaneously in the blood during and after the infection. Although it cannot yet be ruled out that the exoantigens elicit the formation of these antibodies, a review of all the available evidence suggests that the exoantigens of T. lewisi may not be immunogenic during a natural course of infection. Possibly they are hemolysins with a nutritive function.     

Anti-Trypanosoma brucei activity in Cape buffalo serum during the cryptic phase of parasitemia is mediated by antibodies

Cape buffalo are reservoir hosts of African trypanosomes. They rapidly suppress population growth of the highly antigenically variable extracellular haemoprotozoa and subsequently maintain a cryptic infection. Here we use in vitro cultures of trypanosomes cloned from Cape buffalo blood during cryptic infection, as well as related and unrelated trypanosomes, to identify anti-trypanosome components present in cryptic-phase infection serum. Trypanosome clone-specific complement-dependent trypanolytic IgM and IgG arose after appearance of target trypanosomes during cryptic infection. Serum collected late in the cryptic phase of infection contained complement-independent growth-inhibitory IgG which varied in activity among target trypanosomes. Removal of protein A/G-binding IgG from the serum restored its capacity to support trypanosome growth in vitro. Recovered growth-inhibitory IgG reacted with the variable surface glycoprotein (VSG) of parasites most affected by it, and reacted with trypanosome common antigens, notably the endosome-restricted tomato lectin-binding glycoproteins (TL-antigens). The inclusion of purified TL-antigens in culture medium did not affect the trypanosome growth-inhibitory activity of immune Cape buffalo serum. In addition, hyperimmune rabbit IgG against TL-antigens showed little or no binding to intact trypanosomes and did not affect trypanosome growth in vitro although it did react strongly with TL-antigens and trypanosome endosomes. We conclude that antibodies, particularly clone-specific (putatively VSG-specific) antibodies are responsible for the anti-trypanosome activity of cryptic phase infection serum consistent with a dominant role in parasite control in Cape buffalo.     

The relation of agglutinins to antigenic variation of Trypanosoma lewisi.

During the course of infection in the rat, Trypanosoma lewisi produces 2 antigenic variants: the 1st represents the initial, reproducing population of cells; and the 2nd the nonreproducing, ablastin-inhibited adult population. The specificities of the agglutinins elicited by the variants were studied by adsorption and agglutination methods and the newer immunoelectroadsorption technic. It was found that the reproducing variant has a surface antigen that reacts with the agglutinin specific for the adult variant, but this antigen does not become immunogenic until transformation to the adult variant occurs. It was also found, with fractions of immune sera obtained by gel filtration, that the agglutinin specific for the reproducing variant is IgG and that specific for the adult variant, IgM. The antigenic variants of pathogenic and nonpathogenic trypanosomes are compared, and the roles of trypanocidal and ablastic antibodies in the induction of antigenic variation are discussed.     

Cell surface saccharides of Trypanosoma lewisi. I. Polycation-induced cell agglutination and fine-structure cytochemistry.

Trypanosoma lewisi bloodstream and culture forms were agglutinated differentially with low concentrations of the cationic compounds: ruthenium red, ruthenium violet, Alcian blue chloride, 1-hexadecylpyridinium chloride, lanthanum chloride, and cationized ferritin. The bloodstream form trypanosomes gave the highest agglutination levels with each of the compounds tested. Ruthenium red was the most effective inducer of cell agglutination among the several cations used. Trypsin-treated bloodstream forms were agglutinated less in the presence of ruthenium red than untreated controls. Ruthenium red-induced cell agglutination also was lowered with chondroitin sulphate and dextran sulphate, but not with alpha-D-glucose, alpha-D-mannose or with several methyl glycosides. Treatment of the bloodstream trypanosomes with alpha-amylase, dextranase, or neuraminidase had little effect on agglutination levels obtained with ruthenium red. Fine-structure cytochemical staining with ruthenium red, ruthenium violet, and Alcian blue-lanthanum nitrate was used to ascertain the presence and distribution of presumptive carbohydrates in the trypanosome cell surface. The extracellular surface coat of the bloodstream forms stained densely with each of the polycationic dyes. Trypsin treatment removed the surface coat from bloodstream trypanosomes; however, the surface membranes of the organisms were stained densely with the several dyes. Similar surface-membrane staining was obtained with the cationic compounds and the culture forms, which lack a cell surface coat. Cationized ferrin was used at the fine-structure level to visualize the negative surface charge present in the cell surface coat and external membrane of the several trypanosome stages. Results obrained from the agglutination and cytochemistry experiments indicate that complex polysaccharides are present in the surface membranes and cell surface coat of T. lewisi bloodstream forms. Similar conclusions also pertain to the surface membranes of the T. lewisi culture from trypanosomes. The carbohydrates probably represent glycopeptide and glycoprotein structural components of the surface membrane of this organism.     

Trypanosoma lewisi: stage-specific surface antigens and exoantigens recognized by monoclonal antibodies

The stage-specific expression of surface antigens by Trypanosoma lewisi was investigated using monoclonal antibodies directed against this parasite. Hybridomas secreting monoclonal antibodies were produced by the fusion of SP2/0-Ag 14 mouse plasmacytomas with spleen cells from rats infected previously with the Taliaferro strain of T. lewisi. Additivity enzyme-linked immunosorbent assays and indirect immunofluorescent antibody tests indicated the determinant recognized by monoclonal antibody TL40.3 (IgM) was different from those recognized by monoclonal antibodies TL40.1 (IgA), TL40.2 (IgM), and TL40.6 (IgG2 alpha). Monoclonal antibody TL40.3 agglutinated trypanosomes collected 3 days after parasite inoculation while monoclonal antibodies TL40.1, TL40.2, and TL40.6 agglutinated trypanosomes collected 6 days after inoculation. Since agglutinin titers against trypanosomes from irradiated (700 rad from a 60Co source) and nonirradiated rats were similar, expression of the antigens recognized by the monoclonal antibodies appeared to be independent of the immunological state of the host and the morphology of the parasite. The reproduction of T. lewisi in in vitro trypanostatic assays was inhibited only when the monoclonal antibodies were present in concentrations greater than or equal to those needed to agglutinate the trypanosomes. Monoclonal antibodies TL40.1 and TL40.3, but not TL40.2 and TL40.6, agglutinated erythrocytes collected later in the infection from irradiated, infected rats. None of the monoclonal antibodies agglutinated erythrocytes from nonirradiated, infected rats, from irradiated, noninfected rats or from nonirradiated, noninfected rats. This suggests that immunocompetent rats may make blocking antibodies against the exoantigens recognized by monoclonal antibodies TL40.1 and TL40.3.     

Polyamine oxidase-mediated trypanosome killing: the role of hydrogen peroxide and aldehydes

Trypanosoma lewisi and T. musculi were lysed when incubated with bovine serum in the presence of either spermine or spermidine. Similar results were obtained when a fraction from bovine serum containing polyamine oxidase (PAO) activity or a commercially available purified beef plasma PAO were used in lieu of bovine serum. Trypanosomes treated with cytotoxic concentrations of PAO-spermine failed to establish infection in rats. These results are similar to those from our previous studies with African trypanosomes. We now extend the properties of PAO by showing that human retroplacental serum (RPS) containing PAO activity was also capable of mediating trypanosome killing. This is of significance because the macrophage PAO resembles the human RPS PAO. In addition, our preliminary studies, in which an attempt was made to characterize the factors responsible for cytotoxicity, suggested that a number of products of the PAO-polyamine reaction display trypanocidal properties. These included hydrogen peroxide (H2O2), the aldehyde acrolein, and possibly aminoaldehydes. No evidence was obtained that the oxygen intermediates, superoxide and hydroxyl radicals, play a role in the PAO-mediated trypanosome killing. Ammonia, an additional product of PAO-polyamine reaction, was not trypanocidal. Furthermore, the data suggested that less than 30 min exposure to the reaction mixture (and possibly to aminoaldehydes) was adequate to cause irreversible damage to trypanosomes.     

Suppressor and protector factors derived from Trypanosoma lewisi.

Trypanosoma lewisi is a specific protozoan blood parasite of rats. Normal rats infected 2 h after treatment with plasma from day 8 irradiated (8.5 Gy) infected rats had significantly higher parasitaemia; in contrast, animals infected 7 days post-plasma treatment were significantly protected. Trypanolytic and ablastic antibodies could be demonstrated in the serum of normal rats treated with the plasma; the trypanolytic antibodies were stage-specific. Suppression of normal rat splenocyte responses to Con A and lipopolysaccharide (LPS) stimulation were also observed in the presence of different protein concentrations of whole lysate from epimastigote forms. The suppression by mitogen Con A was ablated by the addition of exogenous IL 2, or by washing cells incubated with the lysate prior to mitogen stimulation. These results indicate that immunoregulatory factors are present in the plasma of rats infected with T. lewisi, and the effect of these factors can be demonstrated in vitro with whole parasite lysate. The restoration of normal splenocyte responses to Con A by addition of exogenous IL 2 or by washing cells suggests that the suppressor factor(s) act(s) on the T cells by inhibiting their proliferation and IL 2 production, and the continued presence of these products is essential in the maintenance of suppression.     

Simplified elimination of rabbit anti-rat acute phase protein IgG that shows cross reactivity with albumin

Antibody preparations against rat acute phase proteins were tested for cross reactivity with other serum proteins, including rat albumin. Rabbit anti-rat a alpha1-acid glycoprotein and ceruloplasmin IgG purified on protein A-Sepharose did not show any cross reactivity with rat albumin, hemoglobin or transferrin. Rabbit anti-rat haptoglobin and -macroglobulin IgG purified on protein A-Sepharose showed a 39% and 30% cross reactivity with rat albumin and a 20% and 19% cross reactivity with rat hemoglobin. Because these proteins in whole serum were not adsorbed on Cibacron Blue F3-GA Sepharose, the albumin would be adsorbed on Cibacron Blue F3-GA Sepharose by the use of whole rat serum. Rabbit anti-rat haptoglobin and alpha2-macroglobulin IgG showing cross reactivity with albumin was simply eliminated.     

Trypanosoma lewisi: effects of immunosuppression on the serological reactivities of exoantigens and cellular antigens of bloodstream parasites.

Groups of rats were immunosuppressed with antithymocyte serum (ATS) and infected with Trypanosoma lewisi. Immunodiffusion studies were performed which demonstrated that trypanosome exoantigens, present in the plasma of these animals, were precipitated by antibodies in the sera of rats undergoing a typical primary T. lewisi infection; extracts of trypanosomes which had been collected from ATS-treated rats contained antigens which also were precipitated by antibodies in these sera. These precipitating antibodies could not be detected using either the plasma of untreated infected rats or extracts of trypanosomes which had been collected from untreated rats. With the exoantigens, precipitating antibodies were detected in serum samples collected from rats 14 to 250 days after infection. With the extract, precipitating antibodies were found as early as 5 days after infection and could be detected as late as 90 days after infection. Antigens of trypanosome extracts partially blocked the precipitin reactions between antisera and exoantigens, suggesting the presence of common antigens in the two preparations. Intact trypanosomes were serologically more reactive when collected from immunosuppressed rats. Trypanosomes collected from ATS-treated rats were agglutinated by antisera at titers fourfold higher than trypanosomes collected from untreated hosts. Absorption with exoantigens from immunosuppressed infected rats blocked trypanosome agglutination, indicating that these antigens are of cell surface origin. The experiments suggest that a likely result of immunosuppressing the host is a trypanosome antigen preparation that is a more reactive serodiagnostic reagent.     

Role of phospholipids in the cytotoxic action of high density lipoprotein on trypanosomes.

Host range among the African trypanosomes, protozoa that cause fatal diseases both in humans and livestock, may be, in part, regulated by toxic properties associated with host high density lipoproteins (HDL). High density lipoproteins from hosts resistant (baboon, human) or susceptible (rabbit, rat) to Trypanosoma brucei infection were isolated and their trypanocidal activity was determined in in vitro cell lysis assays. Rabbit and rat HDL were not cytotoxic while baboon and human HDL rapidly lysed trypanosomes within 2 h at 37 degrees C. Analysis of the phospholipid composition of HDL preparations from these species suggested a correlation between trypanocidal activity and low phosphatidylinositol content. Phospholipase digestion of HDL resulted in a loss of trypanocidal activity, indicating the importance of native phospholipids in maintaining this biological activity of HDL. Cell lysis and loss of trypanosome infectivity induced by baboon HDL could be inhibited either by addition of rabbit or rat HDL to the incubation medium or by addition of purified phospholipids, phosphatidylinositol being the most effective inhibitor. Although the mechanism by which HDL lyses trypanosomes remains to be elucidated, these results suggest an important role for phospholipids in determining the specificity of this cytotoxic property of HDL.     

Coated Vesicles from the Protozoan Parasite Trypanosoma brucei: Purification and Characterization

ABSTRACT. A procedure was developed to purify a coated vesicle fraction from the protozoan parasite Trypanosoma brucei. Electron microscopy revealed a difference between T. brucei coated vesicles and clathrin-coated vesicles from other eukaryotes: trypanosome vesicles were larger (100 to ISO nm in diameter) and contained an inner coat of electron-dense material in addition to the external coat. Evidence suggests that the internal coat is the parasite's variant surface glycoprotein (VSG) coat. The SDS-PAGE analysis shows the major protein of T. brucei coated vesicles has a molecular mass of 61 kD, similar to VSG; this protein was recognized in an immunoblot by anti-VSG serum. Trypanosome coated vesicles also contain a protein which comigrates with the major protein (clathrin) of coated vesicles purified from rat brains. However, this protein is a minor component and it is not serologically cross-reactive with mammalian clathrin. Immunoblot analysis demonstrated that the parasite vesicles contained host IgG, IgM, and serum albumin.     

Coated vesicles from the protozoan parasite Trypanosoma brucei: purification and characterization

A procedure was developed to purify a coated vesicle fraction from the protozoan parasite Trypanosoma brucei. Electron microscopy revealed a difference between T. brucei coated vesicles and clathrin-coated vesicles from other eukaryotes: trypanosome vesicles were larger (100 to 150 nm in diameter) and contained an inner coat of electron-dense material in addition to the external coat. Evidence suggests that the internal coat is the parasite's variant surface glycoprotein (VSG) coat. The SDS-PAGE analysis shows the major protein of T. brucei coated vesicles has a molecular mass of 61 kD, similar to VSG; this protein was recognized in an immunoblot by anti-VSG serum. Trypanosome coated vesicles also contain a protein which comigrates with the major protein (clathrin) of coated vesicles purified from rat brains. However, this protein is a minor component and it is not serologically cross-reactive with mammalian clathrin. Immunoblot analysis demonstrated that the parasite vesicles contained host IgG, IgM, and serum albumin.     

Trypanosoma brucei brucei: antigenic stability of its LDL receptor and immunological cross-reactivity with the LDL receptor of the mammalian host.

The rapid growth of Trypanosoma brucei brucei in the blood and tissue fluids of vertebrates requires the receptor-mediated endocytosis of LDL from the host (Coppens et al. 1987; Gillett and Owen 1987) and is slowed by a monospecific rabbit antiserum against the purified LDL receptor of the parasite. We have used this antiserum in combination with several well-characterized antigenic variants (originating from stock 427: MITat 1.1a, 1.3a, 1.4a, 1.5a, 1.5d, 1.8b) to examine whether the LDL receptor of T. b. brucei is a stable surface antigen, common to all parasite variants despite antigenic variation of the major surface glycoprotein, and whether it is immunologically distinct from the LDL receptor of the host. At low concentrations, binding at 4 degrees C of rat LDL to several variants of T. b. brucei and to isolated rat hepatocytes was inhibited to a similar extent by the antiserum. In double immunodiffusion, a single precipitation line was observed, showing continuity between the extracts of all variants as well as between that of trypanosomes and of mammalian tissues. In Western blots of trypanosome extracts, the LDL receptor was strongly labeled as a single band of Mr 145,000, whereas with a rat liver extract, a single band of similar electrophoretic mobility was weakly labeled at a high concentration of the antiserum. In conclusion, the LDL receptor occurred in all variants of T. b. brucei, was a stable surface antigen despite variation of the major surface glycoprotein, and displayed biochemical and immunological similarities with the LDL receptor of the rat host.