Surface Charge of Trypanosoma cruzi. Binding of Cationized Ferritin and Measurement of Cellular Electrophoretic Mobility*

SYNOPSIS The surface charge of epimastigote and trypomastigote forms of Trypanosoma cruzi was evaluated by means of binding of cationized ferritin to the cell surface as visualized by electron microscopy, and by direct measurements of the cellular microelectrophoretic mobility (EPM). Epimastigote forms had a mean EPM of -0.52 μm^.s^-1.V^-1.cm and were lightly labeled with cationized ferritin. In contrast, bloodstream trypomastigotes had a much higher EPM (-1.14), and the surface was heavily labeled with cationized ferritin. When trypomastigotes from stationary phase cultures were isolated on DEAE cellulose columns, the mean EPM was found to be significantly lower (-0.63), and labeling with cationized ferritin decreased. With a mixed population containing epimastigote, trypomastigote, and intermediate forms, EPM values ranging between -0.70 to -1.14 were found. From these observations we conclude that there is a definite increase in negative surface charge during development from epi- to trypomastigote forms of T. cruzi.     

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.     

Trypanosoma cruzi: differences in cell surface interaction of circulating (trypomastigote) and culture (epimastigote) forms with macrophages

Characteristics of the association of circulating (trypomastigote) and cultured (epimastigote) forms of Trypanosoma cruzi with macrophages were studied. Treatment of mouse macrophages with the anti-microfilament drug cytochalasin D severely reduced the ability of these cells to bind either trypomastigotes or epimastigotes. Instead, treatment with the antimicrotubule drug colchicine or 2-deoxyglucose afforded differential effects because epimastigote but not trypomastigote association with the macrophages was significantly inhibited. Prior treatment of epimastigotes with either trypsin or neuraminidase decreased their uptake by macrophages whereas treatment of trypomastigotes with either enzyme increased it. Pretreatment of macrophages with neuraminidase did not affect epimastigote uptake but reduced that of trypomastigotes. Pretreatment of macrophages with trypsin reduced the uptake of both forms of the parasite. However, quantitative differences in the extent of such reduction were noted when varying concentrations of trypsin were used, epimastigote uptake being more drastically affected. These results suggest that the initial interaction of virulent circulating trypomastigote and the attenuated cultured epimastigote forms of T. cruzi to macrophages may involve attachment via different surface structures.     

Biological aspects of the Dm 28c clone of Trypanosoma cruzi after metacyclogenesis in chemically defined media

The biological characterization of the Trypanosoma cruzi clone Dm 28c in terms of its growth in LIT medium, cell-cycle, infectivity to mice and interaction with professional and non-professional phagocytic cells shows that it behaves as a bona fide T. cruzi representant. The biological properties of this myotropic clone do not change according to the origin of the trypomastigote forms (i. e., from triatomines, infected mice, cell-culture or from the chemically defined TAUP and TAU3AAG media). In addition Dm 28c metacyclic trypomastigotes from TAU3AAG medium display a high infectivity level to fibroblasts and muscle cells. Experiments on binding of cationized ferritin to trypomastigotes surface show the existence of cap-like structures of ferritin in regions near the kinetoplast, however the nature and role of these anionic sites remain to be determined. The results indicate that metacyclic trypomastigotes from the Dm 28c clone obtained under chemically defined conditions reproduce the biological behaviour of T. cruzi, rendering this system very suitable for the study of cell-parasite interactions and for the isolation of trypanosome relevant macromolecules.     

Biological action of pyrazolopyrimidine derivatives against Trypanosoma cruzi. Studies in vitro and in vivo

The capacity of 54 different pyrazolo(3,4-d) or (4,3-d)pyrimidine derivatives to inhibit Trypanosoma cruzi epimastigote and trypomastigote multiplication, and for some of them its chemotherapeutic activity, was evaluated. Six pyrazolo(3,4-d)pyrimidines showed inhibitory activity against epimastigote forms, 4-aminopyrazolo(3,4-d)pyrimidine being the most active, 5-fold more so than 4-hydroxypyrazolo(3,4-d)-pyrimidine. Neither compound was active against freshly isolated trypomastigotes, suggesting biochemical differences between culture and bloodstream forms of T. cruzi. On both epimastigote and trypomastigote forms, 7-amino-3-beta-D-ribofuranosylpyrazolo-(4,3-d)pyrimidine (FoA) was about 2-fold more active than 7-hydroxy-3-beta-D-ribofuranosylpyrazolo-(4,3-d)pyrimidine (FoB); however, when tested on T. cruzi-infected mice, only FoB exhibited significant chemotherapeutic activity. Previous results suggest that, except for FoB and FoA: (a) pyrazolopyrimidine insensitivity is trypomastigote-specific and (b) drug-insensitivity is lost when trypomastigotes transform into epimastigotes and vice versa.     

Interaction of Trypanosoma cruzi with macrophages: effect of previous incubation of the parasites or the host cells with lectins

The effect of incubation with lectins of the macrophages or two evolutive stages of Trypanosoma cruzi (noninfective epimastigotes and infective trypomastigotes) on the ingestion of the parasites by mouse peritoneal macrophages was studied. Lectins which bind to residues of mannose (Lens culinaris, LCA), N-acetyl-D-glucosamine or N-acetylneuraminic acid (Triticum vulgaris, WGA), beta-D-galactose (Ricinus communis, RCA), N-acetyl-D-galactosamine (Phaseolus vulgaris, PHA; Dolichos biflorus, DBA; and Wistaria floribunda, WFA), fucose (Lotus tetragonolobus, LTA), and N-acetylneuraminic acid (Limulus polyphemus, LPA) were used. By lectin blockage we concluded that, alpha-D-mannose-like, beta-D-galactose and N-acetyl-D-galactosamine (PHA, reagent) residues, located on the macrophage's surface are required for both epi- and trypomastigote uptake, while N-acetylneuraminic acid and fucose residues, impede trypomastigote ingestion but do not interfere with epimastigote interiorization. Macrophages' N-acetyl-D-glucosamine residues are required for epimastigote uptake. On the other hand, from the T. cruzi surface, mannose residues prevent ingestion of epi- and trypomastigotes. Galactose residues participate in endocytosis of trypomastigotes, but hinder epimastigote interiorization. Exposed N-acetyl-D-glucosamine residues are required for uptake of the two evolutive forms. N-acetylneuraminic acid residues on the trypomastigote membrane prevent their endocytosis by macrophages. These results together with those reported previously showing the effect of monosaccharides on the T. cruzi-macrophage interaction, indicate that (a) sugar residues located on the parasite and on macrophage surface play some role in the process of recognition of T. cruzi, (b) different macrophage carbohydrate-containing receptors are involved in the recognition of epimastigotes and trypomastigotes forms of T. cruzi, (c) N-acetylneuraminic acid residues located on the surface of trypomastigotes or macrophages impede the interaction of the parasite with these host cells, and suggest that (d) sugar-binding proteins located on the macrophage surface participate in the recognition of beta-D-galactose and N-acetyl-D-galactosamine residues located on the surface of trypomastigotes and exposed after blockage or splitting off of N-acetylneuraminic acid residues. Some lectins which bind to macrophages and block the ingestion of parasites did not interfere with their adhesion.     

Trypanosoma cruzi: flow cytometric analysis of developmental stage differences in DNA

Flow cytometry and DNA binding-specific fluorescent reagents were used to compare the total DNA, G-C, and A-T content of the epimastigote and trypomastigote stages of Trypanosoma cruzi stocks. Significant total DNA differences of 2-12% between epimastigotes and trypomastigotes were found in three of six stocks studied. The epimastigote G-C content of five of six stocks was 4-8% higher than trypomastigotes, whereas the trypomastigote A-T content was 2.5-13% higher than the epimastigote A-T content. Although no obvious developmental stage association between total DNA and base composition was found, intrastage associations do exist. These observations were unaffected by nucleoprotein extraction implying that the observed differences between trypomastigotes and epimastigotes are not a consequence of nucleoprotein interference with DNA-binding fluorochromes. The nuclei and kinetoplasts of four T. cruzi stocks were isolated and analyzed. Developmental stage differences in nuclear and kinetoplast DNA are stock-dependent and base composition-dependent; both organelles contribute to the observed differences in DNA of intact cells. We found a nearly linear association between the percentage of total kinetoplast DNA, G-C, and A-T content. During metacyclogenesis, the G-C content decreases by approximately 7% as epimastigotes transform into metacyclic trypomastigotes. The decrease in G-C content precedes changes in morphology or in complement resistance. If the DNA changes are causally connected to developmental stage transformations in T. cruzi remains to be determined. However, our results could facilitate studies of the molecular genetic processes the parasite uses to successfully complete various phases of its life cycle and, consequently, the disease process it evokes.     

Interaction of Trypanosoma cruzi with macrophages in vitro: dissociation of the attachment and internalization phases by low temperature and cytochalasin B

Chicken macrophages, obtained by cultivation of blood monocytes, were infected with epimastigote and bloodstream trypomastigote forms of Trypanosoma cruzi strain Y. The percentage of macrophages containing parasites within parasitophorous vacuoles and of flagellates attached to cell surfaces was determined. By incubation of the macrophages at 4 degrees C or in the presence of cytochalasin B it was possible to dissociate the attachment from the internalization phases in the process of infection of macrophages. Both treatments had a marked effect on the internalization of epimastigote and trypomastigote forms. Cytochalasin B treatment and placement of the macrophages at 4 degrees C before infection inhibited this process by about 99 and 96%, respectively. These results suggest that endocytosis is the principal mechanism of internalization of T. cruzi by macrophages. They show also that epimastigote and trypomastigote forms of T. cruzi have a different rate of adhesion to the macrophage surface.     

Internalization of components of the host cell plasma membrane during infection by Trypanosoma cruzi

Epimastigote and trypomastigote forms of Trypanosoma cruzi attach to the macrophage surface and are internalized with the formation of a membrane bounded vacuole, known as the parasitophorous vacuole (PV). In order to determine if components of the host cell membrane are internalized during formation of the PV we labeled the macrophage surface with fluorescent probes for proteins, lipids and sialic acid residues and then allowed the labeled cells to interact with the parasites. The interaction process was interrupted after 1 hr at 37 masculineC and the distribution of the probes analyzed by confocal laser scanning microscopy. During attachment of the parasites to the macrophage surface an intense labeling of the attachment regions was observed. Subsequently labeling of the membrane lining the parasitophorous vacuole containing epimastigote and trypomastigote forms was seen. Labeling was not uniform, with regions of intense and light or no labeling. The results obtained show that host cell membrane lipids, proteins and sialoglycoconjugates contribute to the formation of the membrane lining the PV containing epimastigote and trypomastigote T. cruzi forms. Lysosomes of the host cell may participate in the process of PV membrane formation.     

Trypanosoma cruzi: characterization of an intracellular epimastigote-like form.

Almeida-de-Faria, M., Freymüller, E., Colli, W., and Alves, M. J. M. 1999. Trypanosoma cruzi: Characterization of an intracellular epimastigote-like form. Experimental Parasitology 92, 263-274. A detailed study of transient epimastigote-like forms as intermediates in the differentiation of Trypanosoma cruzi amastigotes to trypomastigotes inside the host cell cytoplasm was undertaken using the CL-14 clone grown in cells maintained at 33 degrees C. Several parameters related to these forms have been compared with epimastigotes and other stages of the parasite. Consequently, the designation of intracellular epimastigotes is proposed for these forms. Despite being five times shorter (5.4 +/- 0.7 micrometer) than the extracellular epimastigote (25.2 +/- 2.1 micrometer), the overall morphology of the intracellular epimastigote is very similar to a bona fide epimastigote, when cell shape, position, and general aspect of organelles are compared by transmission electron microscopy. Epimastigotes from both sources are lysed by human complement and bind to DEAE-cellulose, in contrast to amastigotes and trypomastigote forms. A monoclonal antibody (3C5) reacts with both epimastigotes either isolated from axenic media or intracellular and very faintly with amastigotes, but not with trypomastigotes. Some differences of a quantitative nature are apparent between the two epimastigote forms when reactivities with lectins or stage-specific antibodies are compared, revealing the transient nature of the intracellular epimastigote. The epitope recognized by 3C5 monoclonal antibody reacts slightly more intensely with extracellular than with intracellular epimastigotes, as detected by immunoelectron microscopy. Also a very faint reaction of the intracellular epimastigotes was observed with monoclonal antibody 2C2, an antibody which recognizes a glycoprotein specific for the amastigote stage. Biological parameters as growth curves in axenic media and inhability to invade nonphagocytic tissue-cultured cells are similar in the epimastigotes from both origins. It is proposed that the epimastigote-like forms are an obligatory transitional stage in the transformation of amastigotes to trypomastigotes with a variable time of permanency in the host cell cytoplasm depending on environmental conditions.     

Trypanosoma cruzi: Flow Cytometric Analysis of Developmental Stage Differences in DNA

Flow cytometry and DNA binding-specific fluorescent reagents were used to compare the total DNA, G-C, and A-T content of the epimastigote and trypomastigote stages of Trypanosoma cruzi stocks. Significant total DNA differences of 2–12% between epimastigotes and trypomastigotes were found in three of six stocks studied. The epimastigote G-C content of five of six stocks was 4–8% higher than trypomastigotes, whereas the trypomastigote A-T content was 2.5–13% higher than the epimastigote A-T content. Although no obvious developmental stage association between total DNA and base composition was found, intrastage associations do exist. These observations were unaffected by nucleoprotein extraction implying that the observed differences between trypomastigotes and epimastigotes are not a consequence of nucleoprotein interference with DNA-binding fluorochromes. The nuclei and kinetoplasts of four T. cruzi stocks were isolated and analyzed. Developmental stage differences in nuclear and kinetoplast DNA are stock-dependent and base composition-dependent; both organelles contribute to the observed differences in DNA of intact cells. We found a nearly linear association between the percentage of total kinetoplast DNA, G-C, and A-T content. During metacyclogenesis, the G-C content decreases by approximately 7% as epimastigotes transform into metacyclic trypomastigotes. The decrease in G-C content precedes changes in morphology or in complement resistance. If the DNA changes are causally connected to developmental stage transformations in T. cruzi remains to be determined. However, our results could facilitate studies of the molecular genetic processes the parasite uses to successfully complete various phases of its life cycle and, consequently, the disease process it evokes.     

Trypanosoma cruzi: surface charge and freeze-fracture of amastigotes

Amastigotes of Trypanosoma cruzi, within vertebrate cells or isolated from the supernatant of vertebrate cell cultures (L-A9 fibroblast or J774G8 macrophage-like cell lines), possess glycoproteins or glycolipids on the cell surface according to the periodic acid-thiosemicarbazide-silver proteinate technique used in association with electron microscopy. The cell surface of isolated amastigotes is negatively charged, as evaluated by the binding of cationic particles (colloidal iron hydroxyde at pH 1.8 and cationized ferritin at pH 7.2) as well as by direct measurement of cellular electrophoretic mobility. Amastigotes (Y strain) isolated from the spleen of infected mice and amastigotes (Y and CL strains) from the supernatant of cell cultures previously infected with T. cruzi have the same mean electrophoretic mobility (-0.85 micron sec-1 V-1 cm). It is intermediate between the epimastigote and the trypomastigote forms (determined previously). Sialic acid is the important component responsible for the negative surface charge, as determined by the use of neuraminidase. Thus, it is possible to use the mean electrophoretic mobility as an indicator for identifying amastigotes of T. cruzi.     

Trypanosoma cruzi: serum antibody reactivity to the parasite antigens in susceptible and resistant mice

The specific antibody responses were compared among susceptible (A/Sn), moderately susceptible (Balb/c) and resistant (C57 BL/10J) mice infected with Trypanosoma cruzi (Y strain). Sera obtained during the second week of infection recognized a surface trypomastigote antigen of apparent Mr 80 kDa while displaying complex reactivity to surface epimastigote antigens. Complex trypomastigote antigens recognition was detected around the middle of the third week of infection. No major differences were observed along the infection, among the three strains of mice, neither in the patterns of surface antigen recognition by sera, nor in the titres of antibodies against blood trypomastigotes (lytic antibodies), tissue culture trypomastigotes or epimastigotes. On immunoblot analysis, however, IgG of the resistant strain displayed the most complex array of specificities against both trypo and epimastigote antigens, followed by the susceptible strain. IgM antibodies exhibited a more restricted antigen reactivity, in the three mouse strains studied. Balb/c sera (IgG and IgM) showed the least complex patterns of reactivity to antigens in the range of 30 kDa to 80 kDa. The onset of reactivity in the serum to trypomastigote surface antigens was also dependent on the parasite load to which the experimental animal was subjected.     

Aminothiol multidentate chelators against Chagas disease

Three compounds of an aminothiol family of iron chelators were examined for activity against trypomastigote (human) and epimastigote (vector) forms of Trypanosoma cruzi: tetraethyl and tetramethyl derivatives of ethane-1,2-bis (N-1-amino-3-ethyl butyl-3-thiol) (BAT-TE and BAT-TM) and N',N',N'-tris-(2-methyl-2-mercaptopriopyl)- 1,4,7-triazacyclonane (TAT). BAT-TE at 270 microM completely arrested the growth of trypomastigote forms in mouse blood stored at 4 degrees C for 24 h (IC(50) 67.7+/-7 microM), while BAT-TM arrested growth at 630 microM (IC(50) 158+/-17 microM) and TAT at concentrations >800 microM (IC(50) 415+/-55 microM). In T. cruzi-infected mice, BAT-TE and BAT-TM had no anti-trypanosomal activity in doses up to 200 mg/kg, whether the route of administration was intraperitoneal or oral, and TAT was not tested due to insufficient quantity. TAT had an IC(50) of 52+/-7 microM against the epimastigote forms while BAT-TM and BAT-TE were inhibitory only at concentrations >250 microM. The trypanocidal activity of BAT derivatives in blood stored at 4 degrees C makes these compounds potential candidates for the purpose of clearing donated blood of trypomastigotes.     

Ultrastructural localization of basic proteins in Trypanosoma cruzi.

The postformalin ammoniacal silver (AS) and the ethanolic phosphotungstic acid (EPTA) techniques were applied in epimastigote and trypomastigote forms of the pathogenic protozoa Trypanosoma cruzi to detect basic proteins at the ultrastructural level. With both techniques, reaction was observed in the nucleus and in some cytoplasmic vacuoles. In the kinetoplast of epimastigotes, reaction was observed only at its periphery. In trypomastigotes, however, an intense reaction was observed in the spherical kinetoplast. With the ethanolic phosphotungstic acid technique, reaction was also observed in ribosomes and at the peripheral doublet microtubules of the flagellum. The filaments which form the paraflagellar structure did not react.     

Parasite specific antibodies in three strains of mice after infection with Trypanosoma cruzi

Three inbred strains of mice (BALB/cJ, C3H/HeJ and NZB/BInJ) were infected with trypomastigotes of Trypanosoma cruzi. Sera were taken at different times after infection and radioimmunoprecipitation assays were used to detect antibodies against individual T. cruzi epimastigote and trypomastigote antigens. The mouse strains differed in regard to the spectrum of antibodies and the time after infection when the various epimastigote specific antibody species appeared. NZB mice had antibodies against at least 25 polypeptides ranging in molecular weight from 20,000 to 90,000 D at 3 wk after infection, and these persisted until at least 10 wk post-infection. C3H and BALB/c had antibodies against fewer than 5 antigens at 3 wk after infection; whereas by week 10, antibodies against at least 25 polypeptides were detected. C3H mice that were most susceptible to infection (but not NZB or BALB/c mice) had antibodies against a 25,000 D molecular weight epimastigote antigen. The antibody response against trypomastigote polypeptides was more uniform. Sera from all mouse strains at 3 wk after infection precipitated the same polypeptides and the radioimmunoprecipitation patterns did not change as a function of time after infection.     

Anti-Trypanosoma activity of some natural stilbenoids and synthetic related heterocyclic compounds

We report the anti-Chagasic activity of the natural dihydrostilbenoid isonotholaenic acid and several simple derivatives, as well as that of some representative compounds of related synthetic series, with basic structures of benzalphthalides, dihydrostilbamides, isoindoles, phthalazin-1-ones, imidazo[2,1-a]isoindoles and pyrimido[2,1-a]isoindoles. The evaluation was performed in vitro on cultures of epimastigote and trypomastigote forms of Trypanosoma cruzi. Some of the tested compounds resulted to be as potent as benznidazole (epimastigotes), and others were shown to be more active than gentian violet (trypomastigotes), used as reference drugs.     

Binding of complement to trypomastigotes of a Brazil strain of Trypanosoma cruzi: evidence for heterogeneity within the strain.

Binding of the complement components C3 and C5 to epimastigote and trypomastigote stages of the Brazil strain of Trypanosoma cruzi was examined using radioligand binding and flow cytometric assays. Fibroblast-derived trypomastigotes bound approximately 40% fewer molecules of [125I]C3 per parasite than did epimastigotes. The predominant molecular species of C3 deposited on fibroblast-derived trypomastigotes was the inactive form iC3b. Addition of parasite-specific antisera failed to enhance the number of molecules of [125I]C3 per parasite or the proportion of active to inactive C3b. Flow cytometric studies revealed that only 50% of trypomastigotes (fibroblast-derived or blood-form) bound C3. In contrast to results of the [125I]C3 binding studies, flow cytometric analysis showed that the percentage of trypomastigotes binding C3 actually increased upon incubation with parasite-specific antisera. C5 was found also to bind to only a percentage of trypomastigotes.     

Evidence supporting the existence of a host cell surface receptor for Trypanosoma cruzi

Membrane fragments from trypomastigote forms of Trypanosoma cruzi inhibited the association of intact trypomastigotes with rat heart myoblasts whereas a similar preparation from non-invasive epimastigotes did not. Furthermore, killed trypomastigotes bound to the host cell surface and prevented the attachment of living organisms. Conversely, the extent of association of killed parasites with the host cells was reduced by the presence of living flagellates. These results suggest the presence of a distinct structure(s) on the surface of rat heart myoblasts to which infective forms of T. cruzi can bind.     

Involvement of TSSA (trypomastigote small surface antigen) in Trypanosoma cruzi invasion of mammalian cells

TSSA (trypomastigote small surface antigen) is a polymorphic mucin-like molecule displayed on the surface of Trypanosoma cruzi trypomastigote forms. To evaluate its functional properties, we undertook comparative biochemical and genetic approaches on isoforms present in parasite stocks from extant evolutionary lineages (CL Brener and Sylvio X-10). We show that CL Brener TSSA, but not the Sylvio X-10 counterpart, exhibits dose-dependent and saturable binding towards non-macrophagic cell lines. This binding triggers Ca(2+)-based signalling responses in the target cell while providing an anchor for the invading parasite. Accordingly, exogenous addition of either TSSA-derived peptides or specific antibodies significantly inhibits invasion of CL Brener, but not Sylvio X-10, trypomastigotes. Non-infective epimastigote forms, which do not express detectable levels of TSSA, were stably transfected with TSSA cDNA from either parasite stock. Although both transfectants produced a surface-associated mucin-like TSSA product, epimastigotes expressing CL Brener TSSA showed a ~2-fold increase in their attachment to mammalian cells. Overall, these findings indicate that CL Brener TSSA functions as a parasite adhesin, engaging surface receptor(s) and inducing signalling pathways on the host cell as a prerequisite for parasite internalization. More importantly, the contrasting functional features of TSSA isoforms provide one appealing mechanism underlying the differential infectivity of T. cruzi stocks.