Trypanosoma cruzi: antigenic composition of axonemes and flagellar membranes of epimastigotes cultured in vitro

ExperimentalLeishmania (L.) amazonensisLeishmaniasis: Characterization and Immunogenicity of Subcellular Fractions

A technique developed in Trypanosoma cruzi biochemical studies was successfully used to fractionate Leishmania (Leishmania) amazonensis promastigotes. Ultrastructural analyses revealed a membrane fraction (MF) associated to subpellicular microtubules, a ribosomal-rich microsomal fraction (MicF), and a flagellar fraction (FF) free of associated membrane. All fractions proved to be immunogenic through delayed type hypersensitivity reaction assays. Therefore, a protocol was designed to test whether these fractions could elicit a protective response in mice infected by L. (L), amazonensis. The protocol consisted of a BCG injection (as cellular immunity inducer), followed by cyclophosphamide (once its cytotoxic effect is over, this immunosuppressor can increase the number of circulating leukocytes), then an injection with one of the fractions followed by a challenge. When compared to infected control animals, mice injected with any of the fractions presented a smaller footpad swelling, especially those injected with MicF or FF. Macroscopically, immunized mice under modulation by BCG presented no swelling. Histopathological studies performed on day 120 revealed fewer amastigotes and more intense inflammation in lesions of MicF and FF injected mice. Animals injected with MF presented an intermediate pattern. Parasite quantification corroborated these results. The results show that all fractions are potent immunostimulators, but MicF and FF have the strongest protective ability.

Cell fractionation of parasitic protozoa: a review

Cell fractionation, a methodological strategy for obtaining purified organelle preparations, has been applied successfully to parasitic protozoa by a number of investigators. Here we present and discuss the work of several groups that have obtained highly purified subcellular fractions from trypanosomatids, Apicomplexa and trichomonads, and whose work have added substantially to our knowledge of the cell biology of these parasites.

Purification of the paraflagellar rod of the trypanosomatid Herpetomonas megaseliae and identification of some of its minor components

The paraflagellar rod (PFR) is a component of the flagellar cytoskeleton of trypanosomatid protozoa, representing a filamentous structure that runs alongside the common 9 + 2 microtubular axoneme. The high degree of ultrastructural complexity and organization of the PFR suggests that it might be formed by numerous biochemical components. However, biochemical analysis of the PFR has revealed, to date, a modest degree of complexity in what concerns both major and minor PFR proteins. In this paper the preparation of purified PFR fractions by a combination of conventional cell-fractionation procedures, non-ionic detergent treatment and limited proteolysis is described. Comparative SDS-PAGE analysis of the different purification steps indicates that the purified PFR fractions possess high amounts of the well-known major PFR proteins (77 and 83 kDa). Also, bands of 147, 139, 129 and 122 kDa are clearly enriched in such fractions and may correspond to minor PFR components. A slight enrichment in a specific fraction of a doublet of bands of 181/188 kDa suggest the participation of these proteins in the composition of the bridges between the PFR and the axoneme.

The cytostome of Trypanosoma cruzi epimastigotes is associated with the flagellar complex

Okuda, K., Esteva, M., Segura, E. L., and Bijovsky, A. T. 1999. The cytostome of Trypanosoma cruzi epimastigotes is associated with the flagellar complex. Experimental Parasitology 92, 223-231. Proliferative forms of Trypanosoma cruzi, amastigotes and epimastigotes, have a cytostome, a specialized structure formed by an invagination of the flagellar pocket's membrane surrounded by microtubules and frequently followed by a row of vesicles. All this assemblage penetrates deeply into the cytoplasm overpassing the nucleus. This structure, together with the flagellar pocket, appears to play an important role in the nutrition of the parasite. We demonstrated that the monoclonal antibody 2C4, made-up against isolated flagellar complex of T. cruzi epimastigotes, recognizes a protein doublet of 76 and 87 kDa in total epimastigotes homogenate. The 76-kDa polypeptide is enriched in the detergent-soluble fraction whereas the 87-kDa polypeptide is highly represented in the insoluble fractions and the purified flagella. Immuno-fluorescence assays show the antigen as a small spot at the flagellar pocket region. Immunogold labeling of ultrathin sections of epimastigote forms reveals gold particles at the opening of flagellar pocket, concentrated in the cytostome region. Immunocytochemistry of epimastigote whole-mount cytoskeletons reveals the labeling on an array of three to four microtubules that appears attached to flagellum, running in the direction of the nucleus. Ultrastructural observations have shown that the posterior region of isolated flagella, corresponding to the level of the flagellar pocket, possesses a microtubular structure compatible with that from the cytostome. The relationship between the cytostome, an endocytic organelle, and the flagellum is here described for the first time.

Organization and expression of the gene encoding an immunodominant repetitive antigen associated to the cytoskeleton of Trypanosoma cruzi

We have studied the genomic organization and expression of the gene encoding a high molecular mass (300 kDa) repetitive antigen associated with the cytoskeleton of Trypanosoma cruzi. Protease digestion of the native protein, restriction analysis of genomic DNA and sequencing of genomic and cDNA clones indicated that most of the protein is built up by tandemly arranged, nearly identical repeats of 68 amino acids. The gene size was estimated to be approx. 9.4 kb based on the sizes of the transcript and the native protein. The nucleotide sequence conservation among the repeats indicates that selective sequence homogenization, presumably through gene conversion, maintained the amino-acid sequence conservation. Two duplicated allelic forms of this gene were mapped in fragments of about 20 kb. In some strains an additional allele was located in a fragment of 9.4 kb. Our results suggest that this repetitive antigen is a structural protein which could be involved in the attachment of the flagellum to the cell body.

Chagas' disease and blood transfusion: a New World problem?

American trypanosomiasis (Chagas' disease) can be transmitted by blood transfusion. For almost 40 years, this transmission has been limited to Latin America, but recently, three cases have been reported in the USA and Canada. With increasing emigration to North America and Europe, Chagas' disease may be introduced to the Northern hemisphere by transfusion of blood from carriers. This review will focus on the discovery, biology and antigenic profile of Trypanosoma cruzi (the aetiological agent of Chagas' disease), including the invertebrate vectors, animal reservoirs and transmission to humans, with special reference to blood transfusion. Finally, diagnostic tests and prophylactic measures for the prevention of Chagas' disease will be discussed.

Comparison of genes encoding Trypanosoma cruzi antigens

Trypanosoma cruzi, the causative agent of Chagas disease, simultaneously expresses several different surface antigens. This contrasts sharply with blood-stream forms o f the African trypanosomes, which display only one variant surface glycoprotein at a time. Over the past few years, the genes coding for a number of T. cruzi proteins recognized by sera from patients have been cloned and at least partially sequenced. However, some of those discovered in more than one laboratory have been given different names. Here, Carlos Frasch, Juan Cazzulo, Lena Aslund and UIf Pettersson try to systematize the literature available on these antigens, including what is known about their localization and function.

Expression in Escherichia coli of a dominant immunogen of Trypanosoma cruzi recognized by human chagasic sera

A genomic clone expressing a Trypanosoma cruzi antigen in Escherichia coli was identified using human chagasic sera. Chagasic antibodies affinity purified on extracts of this clone recognized a high-molecular-weight protein expressed in all developmental stages of the parasite life cycle, as well as in various T. cruzi strains. The antigen is associated with the cytoskeleton of the parasite and localizes along the attachment region between the flagellum and the cell body. Antibodies to the recombinant antigen were detected in the sera of 115 chagasic patients from different endemic regions, but not in sera of patients with leishmaniasis, T. rangeli infection, or other parasitic diseases. Our data suggest that the presence of antibodies to this antigen may be specifically associated with Chagas' disease.

Structure and expression of two Trypanosoma cruzi genes encoding antigenic proteins bearing repetitive epitopes

Trypanosoma cruzi genes were cloned in lambda gt11 and screened with an anti-trypomastigote antiserum. Two out of twelve clones were selected in view of their reactivity with human chagasic sera. One clone encodes a flagellar antigen (FRA) of more than 300 kDa, whereas the other corresponds to a roughly 225-kDa cytoplasmic antigen (CRA). The flagellar antigen is present in both epimastigotes and trypomastigotes, but the cytoplasmic antigen is not found in trypomastigotes. The CRA clone is entirely composed of at least 23 copies of a 42-bp repeat and the FRA gene contains at least 14 copies of a 204-bp motif. The FRA gene hybridizes to a RNA of about 10 kb, while the CRA gene detects a transcript of 5.2 kb.

A monoclonal antibody to alpha tubulin recognizes host cell and Trypanosoma cruzi tubulins

A mouse monoclonal anti-alpha-tubulin antibody was used to investigate the disposition of the cytoskeletal microtubules of three tissue culture cell lines--J774 macrophages, BSC-1, and Vero cells--infected with the Brazil strain of Trypanosoma cruzi. Indirect immunofluorescence light microscopy was used to demonstrate the antigenic response in host cells and parasites, simultaneously. In all morphotypes of T. cruzi, the monoclonal antibody reacted with all subpopulations of microtubules, inclusively, the subpellicular, flagellar, cytopharyngeal, and mitotic. The host cell cytoskeletal microtubule framework was revealed and the redistribution and destruction of the microtubular lattice in response to parasite infection over a 120 h period recorded. Our results show that after the initial inoculation of tissue cultures with trypomastigotes, the parasites penetrate the cells and locate in the perinuclear region of the cell where they multiply. The number and distribution of host cell microtubules were altered during the infection. The normal radial distribution of microtubules extending from the center of the cell to the periphery was destroyed. The remaining microtubules were observed at the periphery encircling, but well removed from the proliferating parasites. The complete transformation of the parasites was monitored throughout the infection with the end result being the liberation of parasites and the near complete destruction of the microtubular framework of the host cell. A residual population of dividing spheromastigotes was observed in cells liberating trypomastigotes. Colloidal gold labeling of thin sections as seen in the electron microscope affirmed the specificity of our monoclonal antibody to all subpopulations of microtubules in T. cruzi.

[Evaluation of Trypanosoma cruzi antigens for the indirect hemagglutination reaction. I. Different antigenic extracts]

Alguns procedimentos descritos na literatura (ultrasom, água destilada, NaOH, TRITON x 100 e congelamento-descongelamenao) foram avaliados determinando o melhor extrato antigênico para a reação de hemaglutinação indireta (RHI) no diagnóstico sorológico da doença de Chagas. Para isso, foram ensaiados 30 soros de indivíduos chagásicos e 30 soros de indivíduos não chagásicos. A reação de imuno-fluorescência indireta foi considerada como reação de referência no cálculo dos indices de co-positividade (i.c.p.) e co-negatividade (i.cn.). O valor do i.c.p, para a RHI com antígeno obtido por NaOH foi mais elevado do que para os outros antígenos. Os cinco antígenos apresentaram valores máximos para o i.cn., indicando boa especificdade. Os títulos apresentados pelos soros chagásicos com antígeno obtido por NaOH foram, significativamente, superiores aos demais antígenos. A avaliação de cinco partidas de antígeno extraídas por NaOH em épocas diversas indicam boa sensibilidade, especificidade e reprodutibilidade de resultados, traduzidas pelos valores elevados para os i.c.p. e i.cn., além de títulos próximos entre si.

Localization of the Trypanosoma cruzi-specific Mr 25,000 antigen by immune electron microscopy using monoclonal antibodies

Two monoclonal antibodies reacted with the Trypanosoma cruzi-specific antigen of an apparent Mr 25,000 from all developmental forms (Tachibana et al. 1986). This T. cruzi-specific antigen was found at the plasma membrane by immunoperoxidase electron microscopy using the monoclonal antibodies TCF48 and TCF87. The TCF48 and TCF87-treated cells showed stain deposits at the plasma membrane clearly distinguishable from those in cells treated with a monoclonal antibody against a surface antigen. This suggests that the epitope(s) of the Mr 25,000 antigen is located on the inner surface or in the matrix of the plasma membrane. TCF48 and TCF87 also reacted with an antigen on the microtubules of the axoneme, but not with the subpellicular microtubules. These results suggest that the T. cruzi-specific Mr 25,000 antigen is common to both the plasma membrane and axoneme but it is not located at the subpellicular microtubules. Its identity and that of the surface antigen, Gp25 (Scharfstein et al. 1983) as well as its role in the pathogenicity of the parasite are discussed.

Tubulin biosynthesis in the developmental cycle of a parasitic protozoan, Leishmania mexicana: changes during differentiation of motile and nonmotile stages

Cytodifferentiation in the transition cycle of the parasitic protozoan Leishmania mexicana amazonensis was studied in vitro. The flagellated motile promastigotes transform into the nonmotile amastigotes in 7 days at 35 degrees C intracellularly in the murine macrophage line J774G8. In medium 199 plus fetal bovine serum, the reverse transformation occurs extracellularly at 27 degrees C in 2 days. Slab gel electrophoresis of leishmanias labeled with [35S]methionine during transformation revealed changes in protein banding patterns. The intensity of two protein species with apparent molecular weights of approximately equal to 55,000 increased in the amastigote-to-promastigote differentiation and decreased during the reverse transformation. These two protein species comigrated approximately with alpha- and beta-tubulin of Chlamydomonas flagella in two-dimensional gel electrophoresis. The lower band was further identified as beta-tubulin by immunoprecipitation using rabbit antiserum specific to the beta-tubulin of Chlamydomonas axonemes. The biosynthetic change of tubulin was found to correlate with the morphological change of microtubules is leishmanial flagella and cytoskeleton during transformation.