Growth of isolated amastigotes of Trypanosoma cruzi in cell-free medium

Amastigotes of Trypanosoma cruzi were purified from overlays of infected Vero cell cultures by centrifugation over a discontinuous gradient of metrizamide. Pure amastigote preparations were usually recovered from the pellet under the layer of specific gravity 1.086. The isolated amastigotes grew in cell-free ML-15HA medium. Growth rate for the different strains of T. cruzi were in the order Y greater than Tulahuen greater than CL. The generation time of amastigotes in ML-15HA medium was 16.8, 18.0 and 26.4 h for the Y, Tulahuen, and CL strains, respectively, in the presence of 5% CO2, and 16.8, 31.2, and 36.4 h, respectively, in the absence of CO2. Intracellular amastigotes did not differ ultrastructurally from amastigotes from either the density-gradient fractionation or culture in cell-free medium.     

Extracellular killing of Trypanosoma cruzi amastigotes by human eosinophils

Granules released from human eosinophils upon interaction with Trypanosoma cruzi amastigotes in vitro were seen attached to the surface of non-internalized parasites by electron microscopy. Amastigote damage was preceded by the binding of eosinophil granule material to its membrane, and eosinophil granule major basic protein (MBP) bound to the parasite surface was readily detectable. Additional evidence of eosinophil cytotoxicity for extracellular amastigotes was the observation that amastigotes trapped between two eosinophils, without being ingested by either one, were destroyed at the interface. Amastigotes isolated from the spleens of infected mice or grown in culture were similarly sensitive to the lytic effects of purified MBP. These results demonstrate the ability of human eosinophils to lyse T. cruzi amastigotes extracellularly in the absence of antibody and suggest that MBP may be involved in the effect. Thus, eosinophils, known to be capable of destroying phagocytosed amastigotes, could also contribute to the clearance of these parasites through extracellular killing.     

Growth of Isolated Amastigotes of Trypanosoma cruzi in Cell-Free Medium1

Amastigotes of Trypanosoma cruzi were purified from overlays of infected Vero cell cultures by centrifugation over a discontinuous gradient of metrizamide. Pure amastigote preparations were usually recovered from the pellet under the layer of specific gravity 1.086. The isolated amastigotes grew in cell-free ML-15HA medium. Growth rate for the different strains of T. cruzi were in the order Y > Tulahuan > CL. The generation time of amastigotes in ML-15HA medium was 16.8, 18.0, and 26.4 h for the Y, Tulahuen, and CL strains, respectively, in the presence of 5% CO₂) and 16.8, 31.2, and 36.4 h, respectively, in the absence of CO₂. Intracellular amastigotes did not differ ultrastructurally from amastigotes from either the density-gradient fractionation or culture in cell-free medium.     

Sialoglycoproteins and sialoglycolipids contribute to the negative surface charge of epimastigote and trypomastigote forms of Trypanosoma cruzi

Epimastigote and trypomastigote forms of Trypanosoma cruzi have a net negative surface charge, as determined by direct measurement of the mean cellular electrophoretic mobility. Treatment of the parasites with neuraminidase reduces by 17 and 52% the mean electrophoretic mobility of epimastigote and bloodstream trypomastigote forms, respectively. Neuraminidase-treated cells recover their normal electrophoretic mobility if incubated for 2 h in the presence of fresh culture medium. The recovering process of epimastigotes is almost totally blocked by addition of inhibitors of either protein synthesis (puromycin) or N-glycosidically linked glycoprotein synthesis (tunicamycin). The recovering process of trypomastigotes is not totally inhibited by either puromycin or tunicamycin. Treatment of T. cruzi with trypsin reduces by 11 and 40% the mean electrophoretic mobility of epimastigote and bloodstream trypomastigote forms. Trypsin-treated cells recover their normal electrophoretic mobility if incubated for 4 h in fresh culture medium. The recovering process of trypomastigotes is partially inhibited by puromycin. The results obtained indicate that sialoglycoproteins and sialoglycolipids exist on the surface of T. cruzi, the latter being predominant on the surface of trypomastigotes.     

Invasion of MDCK epithelial cells with altered expression of Rho GTPases by Trypanosoma cruzi amastigotes and metacyclic trypomastigotes of strains from the two major phylogenetic lineages

In order to invade mammalian cells, Trypanosoma cruzi infective forms cause distinct rearrangements of membrane and host cell cytoskeletal components. Rho GTPases have been shown to regulate three separate signal transduction pathways, linking plasma membrane receptors to the assembly of distinct actin filament structures. Here, we examined the role of Rho GTPases on the interaction between different T. cruzi infective forms of strains from the two major phylogenetic lineages with nonpolarized MDCK cells transfected with different Rho GTPase constructs. We compared the infectivity of amastigotes isolated from infected cells (intracellular amastigotes) with forms generated from the axenic differentiation of trypomastigotes (extracellular amastigotes), and also with metacyclic trypomastigotes. No detectable effect of GTPase expression was observed on metacyclic trypomastigote invasion and parasites of Y and CL (T. cruzi II) strains invaded to similar degrees all MDCK transfectants, and were more infective than either G or Tulahuen (T. cruzi I) strains. Intracellular amastigotes were complement sensitive and showed very low infectivity towards the different transfectants regardless of the parasite strain. Complement-resistant T. cruzi I extracellular amastigotes, especially of the G strain, were more infective than T. cruzi II parasites, particularly for the Rac1V12 constitutively active GTPase transfectant. The fact that in Rac1N17 dominant-negative cells, the invasion of G strain extracellular amastigotes was specifically inhibited suggested an important role for Rac1 in this process.     

Effect of Gossypol on Trypomastigotes and Amastigotes of Trypanosoma cruzi

Bloodstream Trypanosoma cruzi trypomastigotes isolated from infected mice undergo reduction of motility and structural damages after 5 to 45 min exposure to gossypol at concentrations ranging from 5 to 50 μM. When 1% serum albumin is added to the incubation medium, no alterations of parasites are observed, even with 100 μM gossypol. Intracellular T. cruzi amastigotes in infected Vero cell cultures exposed to 5 μM gossypol for 2 h do not show changes. Incubation with 5 μM gossypol for 48 h produces complete disruption of host cells; however, the amastigotes they contain show only mineor alterations. The observations indicate that, in protein-rich media, gossypol is complexed into associations which have no activity on the different forms of the T. cruzi biological cycle.     

Effect of gossypol on trypomastigotes and amastigotes of Trypanosoma cruzi

Bloodstream Trypanosoma cruzi trypomastigotes isolated from infected mice undergo reduction of motility and structural damages after 5 to 45 min exposure to gossypol at concentrations ranging from 5 to 50 microM. When 1% serum albumin is added to the incubation medium, no alterations of parasites are observed, even with 100 microM gossypol. Intracellular T. cruzi amastigotes in infected Vero cell cultures exposed to 5 microM gossypol for 2 h do not show changes. Incubation with 5 microM gossypol for 48 h produces complete disruption of host cells; however, the amastigotes they contain show only minor alterations. The observations indicate that, in protein-rich media, gossypol is complexed into associations which have no activity on the different forms of the T. cruzi biological cycle.     

Trypanosoma cruzi: adrenergic modulation of cyclic AMP role in proliferation and differentiation of amastigotes in vitro

Trypanosoma cruzi amastigotes, obtained from the supernatant of J774G-8 macrophage cultures infected with Y strain trypomastigotes, proliferated and differentiated into epimastigotes in Warren medium at 28-29 C. The basal level of adenosine 3':5'-monophosphate (cAMP) in recently harvested amastigotes was 0.12 pmole/10(7) cells, which could be increased in a dose-dependent manner to 0.62 pmole/10(7) cells with 1 mM of the adrenergic ligand isoproterenol plus 0.5 mM isobutyl methylxanthine. Isoproterenol inhibited [3H]thymidine incorporation into amastigote DNA, as well as the proliferation of amastigotes and newly transformed epimastigotes. Because dibutyryl cAMP had the same effect as isoproterenol on the cells, the experimental results suggest a role for cAMP, modulated by adrenergic ligands, in the control of proliferation and differentiation of amastigotes.     

The cell surface of Trypanosoma cruzi: a fracture-flip, replica-staining label-fracture survey

Fracture-flip and replica-staining label-fracture were used to study the nanoanatomy and topochemistry of the cell surface of Trypanosoma cruzi. Fracture-flip surface images differentiate the three main developmental stages of T. cruzi. Epimastigotes display a smooth surface, except the cytostome which appears as a clearly demarcated, raised, roughly textured platform. Amastigotes and trypomastigotes are covered by numerous surface particles with diameters ranging from 10 to 20 nm and 15 to 30 nm, respectively. Labeling of concanavalin A receptors showed that the surfaces of amastigotes and trypomastigotes were labeled, with amastigotes displaying the highest density of gold particles. In contrast, epimastigotes were sparsely labeled with exception of the cytostome, where a higher density of labeling coincided with the raised platform seen in fracture-flipped specimens, and with the particle-free area exposed on fracture faces. Labeling of epimastigotes by Ricinus communis I and Wistaria floribunda lectins showed that surface receptors for these lectins were absent from the cytostome.     

Trypanosoma cruzi: a specific surface marker for the amastigote form

Among the known life cycle stages of Trypanosoma cruzi only the amastigote form bound lactoferrin (LF), a glycoprotein produced by neutrophils. This capacity was readily demonstrable by indirect immunofluorescence in amastigotes derived from mice, a mammalian cell culture, or grown in an axenic medium. No LF binding was detectable on trypomastigotes from blood or mammalian cells, insect-derived metacyclics or epimastigotes, or on epimastigotes grown in Warren's medium. Serum levels of LF were increased in mice acutely infected with T. cruzi, and amastigotes from the spleens of these animals were found to have the glycoprotein on their surface. The amastigote LF receptor may have biological significance in parasite-host interaction since mononuclear phagocytes also express a LF receptor, and treatment of these cells with LF has been shown to increase their capacities to take up and kill T. cruzi amastigotes in vitro. The LF receptor is the first marker for T. cruzi amastigotes for which a naturally occurring ligand has been described.     

Distribution of α-Galactosyl-Containing Epitopes on Trypanosoma cruzi Trypomastigote and Amastigote Forms from Infected Vero Cells Detected by Chagasic Antibodies

Reactivity of different Trypanosoma cruzi developmental forms with purified Chagasic anti-α-galactosyl antibodies (anti-Gal) was studied using epimastigotes from axenic cultures, trypomastigotes and amastigotes from infected Vero cell cultures, and an immunogold labeling method as observed by electron microscopy. Epimastigotes were poorly labeled, whereas extracellular trypomastigotes and amastigotes bound heterogeneously to the antibody with many cells being intensely labeled at the cell surface, including the membrane lining the cell body, the flagellum and the flagellar pocket. Parasites with poor labeling at the cell surface generally had several gold particles within the cell, mostly in cytoplasmic vacuoles. The Golgi complex of trypomastigotes was strongly labeled. Intracellular parasites were labeled at the parasite cell surface or within vacuolar structures. The expression in T. cruzi -infected Vero cells of α-galactosyl antigenic structures acquired from the parasite was shown by moderate labeling with Chagasic anti-Gal of the membrane lining parasite-free outward cell projections. The reactivity with purified anti-Gal from healthy individuals at the same concentrations of Chagasic anti-Gal was poor, with gold particles appearing in the nucleus and cytoplasm but not at the cell surface. It paralleled the labeling with Bandeireae simplicifolia IB-4 lectin. The results provide a basis for autoimmune reactions involving anti-Gal from chronic Chagasic patients.     

Evolutionary implications of Leishmania amastigotes in circulating blood cells of lizards

Amastigotes of 2 Leishmania species are reported from the Pakistani lizards Teratoscincus scincus (Gekkonidae) and Agama agilis (Agamidae) collected in western Baluchistan and north-central Sind, respectively. Parasites were seen only in blood cells primarily within thrombocytes, and were detected on smears of peripheral blood. Slides made at 3-day intervals for 38 days from an infected hatchling T. scincus demonstrated an increase with time in the mean number of amastigotes/infected thrombocyte. No evidence of an infection focus in fixed cells of the viscera was found. It is suggested, in view of reports of amastigotes in circulating blood cells of hosts belonging to 5 genera, collected in 5 countries from India to France, that saurian Leishmania may behave simply as parasites of circulating blood cells, thus illustrating an early stage in the adaptation of leishmanias to the vertebrate host.     

A Trypanosoma cruzi monoclonal antibody that recognizes a superficial tubulin-like antigen

A monoclonal antibody (MAB 10), obtained from mice infected with Trypanosoma cruzi, was found to recognize a superficial antigen in living or fixed parasites. It reacted more strongly with T. cruzi than with related parasites such as T. brucei and Leishmania. In immunoblots it recognized a single trypanosoma polypeptide and also brain tubulin, both of which had the same electrophoretic mobility. Further analysis suggested that the alpha-tubulin subunit contained the epitope recognized by MAB 10. These results suggest that a surface tubulin-like protein is present is T. cruzi.     

Separation of amastigotes and trypomastigotes of Trypanosoma cruzi from cultured cells

A method is described for the isolation and purification of trypomastigotes and amastigotes of Trypanosoma cruzi from cell cultures. L-A9, a transformed fibroblast cell line, and J774G8, a macrophage-like cell line of tumor origin, were used. Both cell lines were infected with bloodstream trypomastigotes of T. cruzi, which once within host cells transform into dividing amastigotes. After 6--8 days infection the host cells ruptured, spontaneously liberating parasites into the culture medium. L-A9 cells liberated mainly trypomastigotes while J774G8 cells liberated amastigotes. The parasites were collected and purified by centrifugation in a gradient of metrizamide. The purity of the preparation as well as the morphology of the parasites and the host cells were analysed by electron microscopy.     

Leishmania mexicana amazonensis: Surface charge of amastigote and promastigote forms

The surface charge of Leishmania mexicana amazonensis was evaluated by means of the binding of colloidal iron hydroxyde particles at pH 1.8 and cationized ferritin particles at pH 7.2 to the cell surface, visualizated by electron microscopy and by direct measurements of the electrophoretic mobility of cells suspended in solutions of different pH. The following forms of the parasite were analysed: amastigotes (surrounded or not by the membrane of the endocytic vacuole, isolated from lesions), transitional forms, and infective (5 passages) and noninfective (176 passages) promastigotes. The results obtained indicate that the surface of L. m. amazonensis contains both negatively and positively charged dissociating groups and that changes occur in the surface charge during amastigote-promastigote transformation. Treatment of the parasite with neuraminidase significantly reduced the electrophoretic mobility of the cells. Neuraminidase-treated cells recovered their normal electrophoretic mobility when incubated for 8 hr in fresh culture medium by a process that is inhibited by puromycin.     

Trypanosoma cruzi: expression of antigens on the membrane surface of parasitized cells

A direct immunofluorescent antibody test with an anti-Trypanosoma cruzi F(ab')2 conjugate was used to demonstrate antigens of T. cruzi on the membrane surface of intact live or fixed macrophages and L929 mouse fibroblasts infected with the organism. Antigens were demonstrated in 5 to 50% of infected cells, and their presence was not directly related to the number of intracellular organisms. Cells with as few as four intracellular amastigotes had demonstrable surface antigens, whereas some cells with as many as twelve or more organisms did not. Capping of antigen-antibody complexes was noted to begin a few minutes after the addition of the anti-T cruzi F(ab')2 conjugate; by 30 min, most of the parasitized cells had eliminated the complexes, and no surface antigen of parasitic nature could be demonstrated. Although capping may have caused a negative result in a previously positive cell, other mechanisms may be involved, because antigens were not demonstrated in some heavily parasitized cells examined immediately after completion of the test. Treatment of the infected cells with trypsin or chymotrypsin resulted in the absence of demonstrable parasite antigens on the cell membrane surface. However, the antigens were again demonstrated 12 hr after the enzymes were removed. The reappearance of parasite antigens on the surface of infected cells was prevented by treatment of the monolayers with puromycin or tunicamycin. A T cell-enriched population of spleen lymphocytes from mice chronically infected with T. cruzi recognized the membrane-bound antigens and proceeded to destroy the host cell and the intracellular organisms. In this process, noninfected cells were also destroyed, possibly because they were coated with antigens released from intact infected cells or from infected cells that had been lysed by the action of the sensitized lymphocytes or their products.     

Stage-specific surface antigens expressed during the morphogenesis of vertebrate forms of Trypanosoma cruzi

The origin of Trypanosoma cruzi slender and broad forms found in the circulation of the mammalian host has remained obscure and, unlike what has been proposed for African trypanosomes, no precise form-function relationship has been ascribed to them. We show here that parasites circulating in the blood of infected animals display a high degree of polymorphism. Around 10% of the forms found circulating in mice during the acute phase of infection were amastigotes, and the other 90% included slender and broad trypomastigotes and intermediate forms between amastigotes and trypomastigotes. Slender trypomastigotes, from blood or cell culture, undergo extracellularly morphological rearrangements in which the parasites become gradually broader and transform into amastigotes. By scanning electron microscopy a progressive internalization of the flagellum and reorganization of the cell shape in a helical fashion were observed in parasites undergoing transformation. After 48 hr of extracellular incubation the parasite population consisted exclusively of amastigotes with a short protruding flagellum. The morphological changes were associated with the expression of different surface antigens defined by monoclonal antibodies: the trypomastigote-specific antigens Ssp-1 (a 100-120-150-Mr glycoprotein), Ssp-2 (a 70-Mr glycoprotein), Ssp-3 (undefined), and Ssp-4, an amastigote-specific surface antigen. Ssp-4 was also detected on intracellular amastigotes (in vitro and in vivo). We conclude that trypomastigotes are programmed to develop into amastigotes whether or not they enter cells, and that the differentiation can occur in the blood of the vertebrate host. These findings raise some questions regarding conventional views on the life cycle of T. cruzi.     

First report on Neotoma micropus (Rodentia) as a reservoir of Trypanosoma cruzi in Mexico]

Using xenodiagnosis, two (8.0%) of 25 woodrats Neotoma micropus were found infected with tripanosome parasite in Vaquerias, a village in Nuevo Leon State, Mexico. The triatomine species developing infective metacyclic trypanosomes at week 12th were Triatoma pallidipennis, T. infestans and T. gerstaeckeri. Experimental infections using infected dejections were successfully conducted on laboratory mice (CD1 strain) confirming the vertebrate cycle of Trypanosome cruzi. The biological characterization of T. cruzi strains was demonstrated based on: 1) Triatomine developmental cycle. 2) A vertebrate host parasitic period up to 25-33 post-infection days, and. 3) Typical morphology of bloodstream trypomastigotes and amastigotes from myocardial nest. This is the first report of T. cruzi biologically characterized in Nuevo Leon, as well as a new report of N. micropus, increasing the list of reservoir hosts in Mexico.     

Trypanosoma cruzi: in vitro interactions between cultured amastigotes and human skin-muscle cells.

Established cultures of human skin-muscle cells were used for determining the parasite—host cell relationship of Trypanosoma cruzi amastigotes (12–16 passages) cultured in a cell-free medium (F-69) at 37 C. The medium used for this experiment was tissue culture fluid M-199 enriched with 10% fetal bovine serum and relatively high concentrations of ATP, ADP and AMP. Amastigotes entered skin-muscle cells incubated at 32 or 35 C, multiplied and completed their intracellular life cycle in about 7 days. At 35 C, 23.6% of cells became infected in 7 days and at 32 C, 43.6% were infected in 5 days. The higher infection rate of cultured cells at 32 C was probably due to more frequent and prolonged cell-parasite contact, as amastigotes multiplied in the tissue culture medium and remained viable for a longer period at the lower temperature. As a control, epimastigotes were used to infect skinmuscle cells. Epimastigotes transformed into metacyclic trypomastigotes before entering host cells, multiplied, and completed the intracellular life cycle. We conclude that the amastigotes cultured in F-69 at 37 C are biologically similar to intracellular amastigotes from the vertebrate host, in that both can multiply and complete the life cycle intracellulary.     

Extracellular Killing of Trypanosoma cruzi Amastigotes by Human Eosinophils1

Granules released from human eosinophils upon interaction with Trypanosoma cruzi amastigotes in vitro were seen attached to the surface of non-internalized parasites by electron microscopy. Amastigote damage was preceded by the binding of eosinophil granule material to its membrane, and eosinophil granule major basic protein (MBP) bound to the parasite surface was readily detectable. Additional evidence of eosinophil cytotoxicity for extracellular amastigotes was the observation that amastigotes trapped between two eosinophils, without being ingested by either one, were destroyed at the interface. Amastigotes isolated from the spleens of infected mice or grown in culture were similarly sensitive to the lytic effects of purified MBP. These results demonstrate the ability of human eosinophils to lyse T. cruzi amastigotes extracellularly in the absence of antibody and suggest that MBP may be involved in the effect. Thus, eosinophils, known to be capable of destroying phagocytosed amastigotes, could also contribute to the clearance of these parasites through extracellular killing.