Metacyclogenesis of Trypanosoma cruzi in vitro: a simplified procedure

In vitro differentiation of Trypanosoma cruzi epimastigotes into metacyclic trypomastigotes using a biphasic medium

The pathogen Trypanosoma cruzi differentiates from epimastigotes (E) into infective metacyclic trypomastigotes (MTs) to invade the mammalian cell. This process, called metacyclogenesis, is mimicked in vitro by nutrient starvation or incubation with minimal media. Here, we describe an alternative protocol for metacyclogenesis by incubating E forms in a biphasic medium supplemented with human blood. Although time consuming, this procedure yields fully differentiated MTs without the presence of intermediate forms, even for cultures that have been maintained as E for years.

Genome-Wide Proteomics and Phosphoproteomics Analysis of Trypanosoma cruzi During Differentiation

Trypanosoma cruzi is a pathogenic protozoan that still has an impact on public health, despite the decrease in the number of infection cases along the years. T. cruzi possesses an heteroxenic life cycle in which it differentiates in at least four forms. Among the differentiation processes, metacyclogenesis has been exploited in different views by researchers. An intriguing question that rises is how metacyclogenesis is triggered and controlled by cell signaling and which are the differentially expressed proteins and posttranslational modifications involved in this process. An important cell signaling pathway is the protein phosphorylation, and it is reinforced in T. cruzi in which the gene expression control occurs almost exclusively posttranscriptionally. Additionally, the number of protein kinases in T. cruzi is relatively high compared to other organisms. A way to approach these questions is evaluating the cells through phosphoproteomics and proteomics. In this chapter, we will describe the steps from the cell protein extraction, digestion and fractionation, phosphopeptide enrichment, to LC-MS/MS analysis as well as a brief overview on peptide identification. In addition, a published method for in vitro metacyclogenesis will be detailed.

A dominant negative form of inositol 1,4,5-trisphosphate receptor induces metacyclogenesis and increases mitochondrial density in Trypanosoma cruzi

Inositol 1,4,5-trisphosphate receptor (IP3R) is a key regulator of intracellular Ca(2+) concentration that release Ca(2+) from Ca(2+) stores in response to various external stimuli. IP3R also works as a signal hub which form a platform for interacting with various proteins involved in diverse cell signaling. Previously, we have identified an IP3R homolog in the parasitic protist, Trypanosoma cruzi (TcIP3R). Parasites expressing reduced or increased levels of TcIP3R displayed defects in growth, transformation, and infectivity. In the present study, we established parasitic strains expressing a dominant negative form of TcIP3R, named DN-TcIP3R, to further investigate the physiological role(s) of TcIP3R. We found that the growth of epimastigotes expressing DN-TcIP3R was significantly slower than that of parasites with TcIP3R expression levels that were approximately 65% of wild-type levels. The expression of DN-TcIP3R in epimastigotes induced metacyclogenesis even in the normal growth medium. Furthermore, these epimastigotes showed the presence of dense mitochondria under a transmission electron microscope. Our findings confirm that TcIP3R is crucial for epimastigote growth, as previously reported. They also suggest that a strong inhibition of the IP3R-mediated signaling induces metacyclogenesis and that mitochondrial integrity is closely associated with this signaling.

A Novel Method for Inducing Amastigote-To-Trypomastigote Transformation In Vitro in Trypanosoma cruzi Reveals the Importance of Inositol 1,4,5-Trisphosphate Receptor

Background

Trypanosoma cruzi is a parasitic protist that causes Chagas disease, which is prevalent in Latin America. Because of the unavailability of an effective drug or vaccine, and because about 8 million people are infected with the parasite worldwide, the development of novel drugs demands urgent attention. T. cruzi infects a wide variety of mammalian nucleated cells, with a preference for myocardial cells. Non-dividing trypomastigotes in the bloodstream infect host cells where they are transformed into replication-capable amastigotes. The amastigotes revert to trypomastigotes (trypomastigogenesis) before being shed out of the host cells. Although trypomastigote transformation is an essential process for the parasite, the molecular mechanisms underlying this process have not yet been clarified, mainly because of the lack of an assay system to induce trypomastigogenesis in vitro.

Methodology/Principal Findings

Cultivation of amastigotes in a transformation medium composed of 80% RPMI-1640 and 20% Grace’s Insect Medium mediated their transformation into trypomastigotes. Grace’s Insect Medium alone also induced trypomastigogenesis. Furthermore, trypomastigogenesis was induced more efficiently in the presence of fetal bovine serum. Trypomastigotes derived from in vitro trypomastigogenesis were able to infect mammalian host cells as efficiently as tissue-culture-derived trypomastigotes (TCT) and expressed a marker protein for TCT. Using this assay system, we demonstrated that T. cruzi inositol 1,4,5-trisphosphate receptor (TcIP₃R)—an intracellular Ca²⁺ channel and a key molecule involved in Ca²⁺ signaling in the parasite—is important for the transformation process.

Conclusion/Significance

Our findings provide a new tool to identify the molecular mechanisms of the amastigote-to-trypomastigote transformation, leading to a new strategy for drug development against Chagas disease.

Inositol 1,4,5-trisphosphate receptor regulates replication, differentiation, infectivity and virulence of the parasitic protist Trypanosoma cruzi

In animals, inositol 1,4,5-trisphosphate receptors (IP3 Rs) are ion channels that play a pivotal role in many biological processes by mediating Ca(2+) release from the endoplasmic reticulum. Here, we report the identification and characterization of a novel IP3 R in the parasitic protist, Trypanosoma cruzi, the pathogen responsible for Chagas disease. DT40 cells lacking endogenous IP3 R genes expressing T. cruzi IP3 R (TcIP3 R) exhibited IP3 -mediated Ca(2+) release from the ER, and demonstrated receptor binding to IP3 . TcIP3 R was expressed throughout the parasite life cycle but the expression level was much lower in bloodstream trypomastigotes than in intracellular amastigotes or epimastigotes. Disruption of two of the three TcIP3 R gene loci led to the death of the parasite, suggesting that IP3 R is essential for T. cruzi. Parasites expressing reduced or increased levels of TcIP3 R displayed defects in growth, transformation and infectivity, indicating that TcIP3 R is an important regulator of the parasite's life cycle. Furthermore, mice infected with T. cruzi expressing reduced levels of TcIP3 R exhibited a reduction of disease symptoms, indicating that TcIP3 R is an important virulence factor. Combined with the fact that the primary structure of TcIP3 R has low similarity to that of mammalian IP3 Rs, TcIP3 R is a promising drug target for Chagas disease.

Critical importance of the de novo pyrimidine biosynthesis pathway for Trypanosoma cruzi growth in the mammalian host cell cytoplasm

The intracellular parasitic protist Trypanosoma cruzi is the causative agent of Chagas disease in Latin America. In general, pyrimidine nucleotides are supplied by both de novo biosynthesis and salvage pathways. While epimastigotes-an insect form-possess both activities, amastigotes-an intracellular replicating form of T. cruzi-are unable to mediate the uptake of pyrimidine. However, the requirement of de novo pyrimidine biosynthesis for parasite growth and survival has not yet been elucidated. Carbamoyl-phosphate synthetase II (CPSII) is the first and rate-limiting enzyme of the de novo biosynthetic pathway, and increased CPSII activity is associated with the rapid proliferation of tumor cells. In the present study, we showed that disruption of the T. cruzi cpsII gene significantly reduced parasite growth. In particular, the growth of amastigotes lacking the cpsII gene was severely suppressed. Thus, the de novo pyrimidine pathway is important for proliferation of T. cruzi in the host cell cytoplasm and represents a promising target for chemotherapy against Chagas disease.

Aspects of Trypanosoma cruzi stage differentiation

Trypanosoma cruzi alternates between different morphological and functional types during its life cycle. Since the discovery of this parasite at the beginning of the twentieth century, efforts have been made to determine the basis of its pathogenesis in the course of Chagas disease and its biochemical constituents. There has also been work to develop tools and strategies for prophylaxis of the important disease caused by these parasites which affects millions of people in Latin America. The identification of axenic conditions allowing T. cruzi growth and differentiation has led to the identification and characterization of stage-specific antigens as well as a better characterization of the biological properties and biochemical particularities of each individual developmental stage. The recent availability of genomic data should pave the way to new progress in our knowledge of the biology and pathogenesis of T. cruzi. This review addresses the differentiation and major stage-specific antigens of T. cruzi and attempts to describe the complexity of the parasite and of the disease it causes.

The Trypanosoma cruzi metacyclic-specific protein Met-III associates with the nucleolus and contains independent amino and carboxyl terminal targeting elements

Metacyclogenesis in Trypanosoma cruzi involves the differentiation of replicating non-infective epimastigotes into non-replicating metacyclic trypomastigotes. This pre-adapts parasites for infection of the mammalian host and is characterised by several morphological changes and structural alterations to the nucleus, including nucleolar disaggregation. Experimental investigation of these developmental processes has been hampered by a lack of robust molecular markers. Here, we describe the precise temporal expression of the T. cruzi-specific protein Met-III, in the genome reference strain CL Brener. Expression is restricted to metacyclics in the insect stages of the life-cycle and is rapidly down-regulated following invasion of mammalian cells. Met-III localises to dispersed foci typical of the disassembled nucleolus in metacyclics and to the discrete single nucleolus of cells soon after macrophage invasion. To identify elements that target Met-III, we generated a series of tagged green fluorescent protein fusion proteins and examined their sub-nuclear location in transformed parasites. These experiments demonstrated that amino and carboxyl terminal fragments, characterised by clusters of basic residues, could independently mediate nucleolar sequestration. To investigate the function of Met-III, we used gene deletion. This showed that Met-III is not required for the development of metacyclic trypomastigotes and that null mutants can complete the life-cycle in vitro.

Biological aspects of the Trypanosoma cruzi (Dm28c clone) intermediate form, between epimastigote and trypomastigote, obtained in modified liver infusion tryptose (LIT) medium

We describe some biological characteristics of the Trypanosoma cruzi intermediate form derived from the transformation of epimastigotes to trypomastigotes obtained from cultivation in modified liver infusion tryptose (LIT) medium. The ultrastructural analysis of the intermediate forms in this medium showed the enlargement of the kinetoplast located adjacent to the flagellate nucleus. Some biological characteristics of the intermediate form are similar to trypomastigotes and others to epimastigotes. Despite displaying a similar trypomastigote surface charge, the intermediate forms, like the epimastigotes, are not resistant to complement-mediated lysis. Moreover, the intermediate forms are unable to infect cultured fibroblasts cells but develop limited infections in macrophages.

Biological characterization and genetic diversity of Mexican isolates of Trypanosoma cruzi

The present work reports the in vitro biological characterization of 17 Trypanosoma cruzi isolates from southern and central México, and compares these results to those of four South American strains and one clone from Brazil. The parameters evaluated were growth rates, percentage of parasites undergoing transformation from epimastigotes to trypomastigotes, infectivity to, and in vitro killing of cultured Vero and P388 cells. Isoenzyme patterns of 11 enzymatic systems and 16 loci were also determined for the Mexican isolates. The parasites showed differences in growth, depending if they were cultured in LIT with hemin or in Grace's media. Transformation was obtained only in Grace's medium and differences were observed between the stocks. Stocks Z10 and Z21 showed the highest percentage of transformation within the Mexican isolates (39 and 41%, respectively). A second group showed percentages of transformation between 15 and 28%. In contrast, the South American strains showed higher rates of transformation (36-65%). Infection of cultured cells by isolates Z10 and H5 was evaluated in both Vero and P388 cells. Differences were observed both in the percentage of infected cells as well as in the number of amastigotes per cell. Differences in the ability to cause in vitro killing of P388 cells were also observed among the isolates. Isoenzyme analysis revealed genetic variation between the isolates, each of them with an unique zymodeme. This genetic analysis revealed, in general, a clustering based on the geographical origin of the isolates. Finally, correlation with clinical symptoms is discussed.

Characterization of a Trypanosoma rangeli strain of Colombian origin

A Colombian strain of Trypanosoma rangeli was characterized by analyzing its behaviour in different axenic and cellular culture, its infection rate and the histopathological lesions produced in experimental animals. Although slight inflammatory infiltrations were shown in different histopathological sections, no pseudocysts could be observed. Grace's insect medium is better than liver infusion tryptose or artificial triatomine urine supplemented with proline when studying T. rangeli metacyclogenesis, with a peak of 32% trypomastigotes. High infection rates were found in VERO and J774 cells. Because of its 100% infectivity rates and adequacy of parasitemia levels, C23 strain is a suitable model of T. rangeli biology study.

Gastric invasion by Trypanosoma cruzi and induction of protective mucosal immune responses

Trypanosoma cruzi is an intracellular parasite transmitted from a reduviid insect vector to humans by exposure of mucosal surfaces to infected insect excreta. We have used an oral challenge murine model that mimics vector-borne transmission to study T. cruzi mucosal infection. Although gastric secretions have microbicidal activity against most infectious pathogens, we demonstrate that T. cruzi can invade and replicate in the gastric mucosal epithelium. In addition, gastric mucosal invasion appears to be the unique portal of entry for systemic T. cruzi infection after oral challenge. The mucosal immune responses stimulated by T. cruzi gastric infection are protective against a secondary mucosal parasite challenge. This protective mucosal immunity is associated with increased numbers of lymphocytes that secrete parasite-specific immunoglobulin A. Our results document the first example of systemic microbial invasion through gastric mucosa and suggest the feasibility of a mucosal vaccine designed to prevent infection with this important human pathogen.

Identification of complete precursors for the glycosylphosphatidylinositol protein anchors of Trypanosoma cruzi

The survival of Trypanosoma cruzi, the causative agent of Chagas' disease, depends vitally on proteins and glycoconjugates that mediate the parasite/host interaction. Since most of these molecules are attached to the membrane by glycosylphosphatidylinositol (GPI), alternative means of chemotherapeutic intervention might emerge from GPI biosynthesis studies. The structure of the major 1G7 antigen GPI has been fully characterized by us (Güther, M. L. S., Cardoso de Almeida, M. L., Yoshida, N., and Ferguson, M. A. J.(1992) J. Biol. Chem. 267, 6820-6828; Heise, N., Cardoso de Almeida, M. L., and Ferguson, M. A. J.(1995) Mol. Biochem. Parasitol. 70, 71-84), and based on its properties we now report the complete precursor glycolipids predicted to be transferred to the nascent protein. Migrating closely to Trypanosoma brucei glycolipid A on TLC, such species, named glycolipids A-like 1 and A-like 2, were labeled with tritiated palmitic acid, myo-inositol, glucosamine, and mannose, but surprisingly only the less polar glycolipid A-like 1 incorporated ethanolamine. The predicted products following nitrous acid deamination and digestion with phospholipases A2, C, and D confirmed their GPI nature. Evidence that they may represent the anchor transferred to the 1G7 antigen came from the following analyses: (i) alpha-mannosidase treatments indicated that only one mannose was amenable to removal; (ii) their lipid moiety was identified as sn-1-alkyl-2-acylglycerol due to their sensitivity to phospholipase A2 (PLA2), mild base and by direct high performance TLC analysis of the corresponding benzoylated diradylglycerol components; and (iii) both glycolipids incorporated 3H-fatty acid only in the sn-2- and not in the sn-1-alkyl position as previously found in the GPI of the mature 1G7 antigen. Based on the differential [3H]ethanolamine incorporation pattern and the recent report that an aminoethylphosphonic acid (AEP) replaces ethanolamine phosphate (EtNH2-PO4) in the GPI in epimastigote sialoglycoproteins (Previato, J. O., Jones, C., Xavier, M. T., Wait, R., Travassos, L. R., Parodi, A. J., and Mendonça-Previato, L.(1995) J. Biol. Chem. 270, 7241-7250) it is proposed that glycolipid A-like 2 contains AEP and A-like 1 EtNH2-PO4. In the in vitro cell-free system both glycolipids were synthesized simultaneously and do not seem to bear a precursor/product relationship. Among the various components synthesized in vitro a glycolipid C-like corresponding to a form of glycolipid A-like 1 acylated on the inositol was also characterized. Phenylmethylsulfonyl fluoride, an inhibitor known to block the addition of ethanolamine phosphate in T. brucei but not in mammalian cells, also inhibits the synthesis of glycolipids A-like and C-like in T. cruzi, indicating that the putative trypanosome EtNH2-PO4/AEP transferase(s) might represent a potential target for chemotherapy.

Characterization of the lipid moiety of the glycosylphosphatidylinositol anchor of Trypanosoma cruzi 1G7-antigen

The 90-kDa stage-specific 1G7-antigen has been implicated in the invasion of host cells by the metacyclic forms of Trypanosoma cruzi. The antigen is attached to the plasma membrane via glycosylphosphatidylinositol, the partial structure of which was the first to be determined for a protein of this parasite. In this study, the complete structure of the lipid component of the anchor was determined by electrospray mass spectrometry, gas chromatography mass spectrometry, phospholipase sensitivity and high-performance thin-layer chromatography of the diaradylglycerol components after benzoylation. These analyses showed that the lipid moiety of 1G7-antigen is composed essentially of 1-O-hexadecyl-2-O-hexadecanoyl-phosphatidylinositol and 1-O-hexadecyl-2-O-octadecanoyl-phosphatidylinositol. The high sensitivity of the electrospray mass spectrometric analysis unexpectedly revealed the presence of a small proportion of putative inositol-phosphoceramide structures, and confirmed the absence of inositol-acylated species. An interesting finding was that the biosynthetic incorporation of [3H]palmitate labelled solely the acyl position, and not the 1-O-alkyl chain in the 1G7-antigen anchor.

A cyclic AMP inducible gene expressed during the development of infective stages of Trypanosoma cruzi

By using a subtractive hybridization strategy, we have identified a gene (TC26) that is expressed in metacyclic and tissue culture derived trypomastigotes of Trypanosoma cruzi but not log stage epimastigotes and is induced during the differentiation of metacyclic stages in vitro. In contrast, the TC26 transcript is absent from stationary phase epimastigotes of a strain that fails to undergo metacyclogenesis under the same culture conditions. Transcription of TC26 can be induced in epimastigotes by incubation with cyclic AMP and cyclic AMP analogues but it is inhibited by activators of cAMP dependent phosphodiesterases. Cyclic AMP fails to enhance tubulin gene expression in the same parasites. While present in the genome in multiple copies, the TC26 gene is expressed as a single mRNA species of approximately 5 kb. Computer analysis of the sequence of a 650-bp cDNA clone revealed no significant homologies at either the nucleotide or amino acid levels with other known proteins. Possible roles for the TC26 gene product in metacyclogenesis are discussed.

Trypanosoma cruzi: an in vitro cycle of cell differentiation in axenic culture

The operation of an in vitro cycle of cell differentiation of Trypanosoma cruzi in axenic culture was obtained. When epimastigote forms, grown in LIT medium, were transferred to a modified LIT medium (E. Chiari, 1981, "Diferenciação do Trypanosoma cruzi em cultura." Ph.D. dissertation, Universidade Federal de Minas Gerais, Brazil), metacyclic trypomastigotes were generated. The latter, upon treatment with fresh human serum, and subsequent incubation in LIT medium gave origin to clusters of spheromastigote cells. The spheromastigotes were resistent to lysis mediated by the complement system and possess a morphology shown by optical and electron microscopy to be very similar to spheromastigotes derived from tissues of infected vertebrates. Blood-like trypomastigotes, or epimastigotes, could be obtained from spheromastigotes depending on the incubation conditions: at high serum concentration (55%) at 37 C, blood-like trypomastigotes were generated; by aging or heating (37 C), at low serum concentration (10%), epimastigotes were formed, closing the whole sequence of cell differentiation of T. cruzi. The molecular characterization of the different cell forms by sodium dodecyl sulfate-polyacrylamide gel electrophoresis of metabolic pulse labeled proteins showed that the in vitro differentiated cells were distinct, not only by morphological criteria, but by differential gene expression as well. All the forms described could be obtained in large amounts (6 x 10(7) to 1 x 10(8)/ml), making it possible to perform preparative biochemical, molecular biological, and immunological experiments.

Cyclic AMP and adenylate cyclase activators stimulate Trypanosoma cruzi differentiation

A chemically defined in vitro differentiating condition was used to study the potential role of cyclic AMP (cAMP) and adenylate cyclase activators on the transformation of Trypanosoma cruzi epimastigotes to the infective metacyclic trypomastigotes (metacyclogenesis). It was observed that both addition of cAMP analogs or adenylate cyclase activators to the differentiating medium stimulated the transformation of epimastigotes to metacyclic trypomastigotes. These results were further corroborated by showing that inhibitors of cAMP phosphodiesterase were stimulatory while activators of this enzyme inhibited the metacyclogenesis process. On the other hand, inhibitors of calmodulin inhibited the transformation of epimastigotes to metacyclic trypomastigotes, suggesting that T. cruzi adenylate cyclase might be activated by calmodulin. In addition, the results strongly suggest that guanine nucleotide binding proteins are involved in T. cruzi adenylate cyclase activation. This system may be useful for studying cell differentiation mechanisms in eukaryotes.

Purification of metacyclic trypomastigotes of Trypanosoma cruzi and Trypanosoma dionisii from culture using an epimastigote-specific monoclonal antibody

Monoclonal antibodies which react with culture forms of Trypanosoma dionisii and Trypanosoma cruzi were tested for their agglutination capacity. In these studies developmental stage specificity for the epimastigote form could be observed. This specificity meant it was possible to develop a quick and simple method to isolate cultured metacyclic trypomastigotes of T. dionisii and T. cruzi group 2. After agglutination of the epimastigote form with the monoclonal antibody Dion 4.6 the purity of metacyclic trypomastigote developmental forms derived from culture was 96% to 99%.

Trypanosoma cruzi: differentiation after interaction of epimastigotes and Triatoma infestans intestinal homogenate

Incubation of Trypanosoma cruzi epimastigotes with Triatoma infestans intestinal homogenate leads to differentiation to the metacyclic trypomastigote. Features of this interaction are presented. The morphogenetic mechanism was triggered almost at once; for the minimum interaction period assayed (15 min), the degree of differentiation achieved in Grace medium by Day 6 was 70.0 +/- 9.0%. Longer interaction periods failed to improve differentiation. The morphogenesis became irreversible at 4 hr after interaction. Epimastigotes incubated for 4 hr with T. infestans intestinal homogenate and then washed reached significant differentiation, while those washed before this time failed to do so. Treatment of epimastigotes with albumin improved the experimental conditions thereby hastening morphogenesis, the same percentage of metacyclics occurring in only 4 days. The factors capable of triggering differentiation were adsorbed by T. cruzi epimastigotes, as expected, but also by Leishmania mexicana and, to a lesser degree, by sheep red blood cells. Once the morphogenetic mechanism had been triggered following interaction of epimastigotes with intestinal homogenate for 15 min, metacyclic forms developed when parasites were transferred to Grace but not to other media. Treatment of epimastigotes with trypsin abolished their capacity to differentiate, which was completely reversed following a 5 hr incubation in LIT medium.

Evasion of alternative complement pathway by Trypanosoma cruzi results from inefficient binding of factor B

During its differentiation in the insect vector to a stage infective for the mammalian host, Trypanosoma cruzi becomes resistant to lysis by the alternative pathway of complement. To elucidate the mechanism of complement evasion, we studied control of complement activation on the surface of the noninfective epimastigote and the infective culture-derived metacyclic trypomastigote stages (CMT) of T. cruzi. It was found that the predominant form of complement component C3 on epimastigotes is C3b, whereas the majority of C3 on CMT is in the form of the hemolytically inactive fragment iC3b, which cannot participate in C5 convertase formation or lead to deposition of the lytic C5b-9 complex. Our results also showed that C3 binds by a covalent ester linkage to surface molecules of different molecular weight in the epimastigote stage and CMT. Binding studies with purified complement components indicated that CMT do not support efficient formation of an alternative pathway C3 convertase. C3b on the parasite surface fails to bind the amplification component, factor B, rather than showing enhanced binding of the control component, factor H. These results identify the biochemical basis for evasion of complement-mediated killing in T. cruzi and reveal a mechanism for developmental regulation of complement activation.

In vitro differentiation of Trypanosoma cruzi under chemically defined conditions

Metacyclic trypomastigotes of Trypanosoma cruzi have been obtained in chemically defined axenic culture. The differentiating medium, composed of artificial triatomine urine supplemented with proline, allows high yields of metacyclic trypomastigotes after 72-h incubation of T. cruzi cells at 27 degrees C. Morphological differentiation of the parasites is gradual under these chemically defined conditions and is preceded by the expression of stage-specific polypeptides. The yield of in vitro-induced metacyclic trypomastigotes depends upon the age of the epimastigote culture, the size of the inoculum and the depth of the medium. Metacyclic trypomastigotes differentiated in vitro from the Dm 28c clone of T. cruzi are both resistant to complement lysis and to macrophage digestion. They are able to infect mice with an efficiency similar to that obtained for natural metacyclic trypomastigotes obtained from triatomine excreta.

Relevance of hemin for in vitro differentiation of Trypanosoma cruzi

Simple culture conditions that allow good growth and high yields of trypomastigotes are described. The proportion of metacyclic trypomastigotes increases with the concentration of hemin in the culture medium, reaching a peak of 80% after 10 days with 20 mg hemin/liter.

gp72, the 72 kilodalton glycoprotein, is the membrane acceptor site for C3 on Trypanosoma cruzi epimastigotes

We examined the interaction of complement component C3 with surface molecules on Trypanosoma cruzi. Five- to six-fold more C3 was bound to epimastigotes (Epi) than to metacyclic trypomastigotes (CMT) of strain M88. Epi and CMT were surface iodinated, then incubated in C8-deficient serum, and detergent lysates were applied to anti-C3 antibody that had been coupled to Sepharose. We found that 9.20-10.24% of applied 125I-Epi protein bound to anti-C3-sepharose, compared to 2.64% binding of 125I-CMT protein. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed that C3 was attached to 125I-Epi protein by a covalent bond. Samples eluted from anti-C3-sepharose with hydroxylamine revealed a single, major, 72 kD band, suggesting that C3b attaches almost exclusively to the 72 kD glycoprotein of Epi by a hydroxylamine-susceptible ester bond. An antiserum was prepared from lysates of serum-treated Epi that had been affinity-purified on anti-C3-sepharose. This antiserum immunoprecipitated a single 72 kD component (gp72) from surface-iodinated Epi, and specifically recognized only gp72 from Epi in immunoblots. In contrast to the results with Epi, gp72 on CMT was not found to be an efficient acceptor molecule for C3 deposition. The results are the first to evaluate the acceptor site for C3 deposition on a parasite, and they show that gp72 on Epi, but not gp72 on CMT, serves as the preferential acceptor for C3 during antibody-independent alternative complement pathway activation.

Major surface proteins and antigens on the different in vivo and in vitro forms of Trypanosoma cruzi

The surface proteins of six stages of Trypanosoma cruzi were labeled by Iodogen-catalized surface iodination and analyzed by one and two dimensional polyacrylamide gel electrophoresis. These stages included bloodstream trypomastigotes, culture-form trypomastigotes, amastigotes, staphylomastigotes, epimastigotes, and metacyclic trypomastigotes. Antigens recognized by serum antibodies were detected by Western blotting against serum from mice hyperimmunized against bloodstream trypomastigotes. Bloodstream trypomastigotes, culture-form trypomastigotes and staphylomastigotes contained several surface proteins of molecular weight (Mr) 90 000 and isoelectric points (pI) between 5.0 and 7.5. Western blotting reveals that at least two proteins of 90 000 Mr represent the major antigens seen on bloodstream trypomastigotes, culture-form trypomastigotes, staphylomastigotes and amastigotes. However, a 90 000 Mr protein was not detected by either Western blotting or surface iodination on epimastigotes or metacyclic trypomastigotes. The major surface proteins on these latter two stages were represented by several 72 000 Mr proteins with pI values between 5.2 and 5.8. An interesting result of this survey is that a 90 000 Mr surface antigen was present on staphylomastigotes, a stage which can be grown in cell free medium.

Cytochrome P-450 in culture forms of Trypanosoma cruzi

Trypanosoma cruzi epimastigote and trypomastigote forms contain microsomal peptides in the 40-60,000 mol. wt region, some of which are heme-staining-positive and are induced by phenobarbital, as indicated by SDS-gel electrophoresis and by double-labeling experiments. Epimastigotes show induced peptides of mol. wt 56,000, 52,000, 49,000, 44,000, 42,000 and 40,500 whereas only one peptide (52,500 mol. wt) is increased in trypomastigotes. Fractionation of microsomes derived from epimastigotes by octylamine Sepharose-4B column chromatography reveals the presence of two heme peptides with mol. wt of 55,800 and 56,600. The pooled fraction has a typical cytochrome P-450 CO-difference spectrum and appears to correspond to a high spin form. The demonstration of the existence of this family of hemoproteins in T. cruzi further supports the idea that resistance to chemotherapeutic agents is due to active metabolism. The active metabolism, however, may not be similar in the various developmental forms of this organism since differences exist in the patterns of induction of heme-positive microsomal peptides.

Purification of metacyclic forms of Trypanosoma cruzi by Percoll discontinuous gradient centrifugation

A method for the purification of metacyclic forms of Trypanosoma cruzi has been developed. Metacyclic forms obtained in modified Grace medium were separated from the epimastigote forms by Percoll discontinuous density gradient centrifugation. Four different osmotic pressures were applied: 160 +/- 10, 260 +/- 10, 310 +/- 10 and 510 +/- 10 mosmol/kg H2O. At 160 mosmol/kg H2O, 100% of the metacyclic forms with a 21.3% yield were found in the interphase 1.120/1.125 g/ml, while 92.7% of the metacyclic forms with a 73.7% yield were found in the interphase 1.115/1.120 g/ml. At 310 mosmol/kg H2O, 100% of the metacyclic forms in the interphase 1.135/1.140 g/ml with a 36.8% yield were obtained. Metacyclic forms purified in this way do not show alterations in their capacity to infect cultures of HeLa cells.

Incubation in mice provides a signal for the differentiation of Trypanosoma cruzi epimastigotes to trypomastigotes

The differentiation of Trypanosoma cruzi epimastigotes into trypomastigotes was studied in diffusion chambers subcutaneously implanted in mice. Using epimastigotes of the Tulahuén strain, transformation was first evident at 16 h after implantation and reached its maximum (92% trypomastigotes) by 24 h. Shortly before their differentiation into trypomastigotes, epimastigotes were found to develop resistance to lysis by the alternative pathway of complement. Furthermore, implantation of stationary-phase (as opposed to log-phase) parasites resulted in the accumulation of large numbers of complement-resistant epimastigotes in the chambers. These observations suggest that epimastigotes pass through a complement-resistant transitional stage before differentiating into trypomastigotes and that transformation may require cell division. In a further series of experiments, epimastigotes recovered 7 h after implantation in mice were found to differentiate into trypomastigotes when cultured in vitro for an additional 17 h at 37 degrees C. This observation indicates that the events which trigger the morphologic transformation of epimastigotes into trypomastigotes can be dissociated operationally from the differentiation process itself.