Biological characterization of Trypanosoma cruzi strains from different zymodemes and schizodemes.

The development in C3H mice of thirteen strains of Trypanosoma cruzi belonging to different zymodemes and schizodemes was studied. Host mortality, virulence, histiotropism, parasitemia and polymorphism of the parasites were recorded. The strains were grouped into: a) high virulence--causing 100% mortality and characterized by predominance of very broad trypomastigotes in the bloodstream at the end of infection; b) medium virulence--causing no mortality and with a predominance of broad trypomastigotes; c) low virulence--causing no mortality with blood forms not described due to the very low parasitemia. During 18 months maintenance the parasitemia curves were kept constant for all strains except one. A direct correlation between either zymodeme or schizodeme and experimental biological properties of T. cruzi strains was not found. However, the parasitemia was subpatent and patent for strains from zymodeme C and the others respectively. Furthermore the high virulence seems to be related to one of two schizodemes found within zymodeme B strains. All strains presenting patent parasitemia independent of shizodeme and zymodeme showed a myotropism towards heart and skeletal muscle with variable inflammatory intensity. The present study confirmed the heterogeneity found by isoenzyme and k-DNA patterns among the strains of T. cruzi isolated from chagasic patients in Bambuí, Minas Gerais State, Brasil.     

Delimitation of Trypanosoma cruzi zymodemes by numerical taxonomy

Summary Based on the absence or presence of 24 isoenzyme characters, Brazilian Trypanosoma cruzi stocks can be separated by methods of numerical taxonomy into three principal, distinct groups; these groups correspond to the three T. cruzi zymodemes previously reported from north Brazil. A distinction is drawn between taxonomy, which may be of zoological interest only, and identification of medically important groups according to one or a few distinguishing characters.This paper is reprinted from Transactions of the Royal Society of Tropical Medicine and Hygiene, 74, 238–242.This paper is reprinted from Transactions of the Royal Society of Tropical Medicine and Hygiene, 74, 238–242.     

Schizodeme analyses of Trypanosoma cruzi zymodemes from Chile

Kinetoplast DNA was isolated from Chilean Trypanosoma cruzi populations and digested with the restriction endonucleases EcoRI, HinfI, HpaII, MspI, and HaeIII. Three major schizodeme groups were discriminated. There was a correlation between the Chilean schizodeme groups (S1, S2, or S3) and the zymodemes known to occur in Chile (Z1, Brazilian Z2 and Bolivian Z2, respectively), although heterogeneity was seen within the schizodeme groups S2 and S3. Standard Brazilian and Bolivian T. cruzi clones (X10 clone 1, Esmeraldo clone 3, SC43 clone 1, and CAN III clone 1) and laboratory strains (Tulahuen and Y) were included in the schizodeme comparisons. SC43 clone 1 had obvious affinities with S3 and X10 clone 1 shared some features with S1 but the other reference stocks could not be definitely assigned to S1, S2, or S3. Fragment patterns and densitometric traces following digestion with HpaII or MspI suggested that kDNA sequences were not methylated.     

Characterization of a Trypanosoma cruzi antigen with homology to intracellular mammalian lectins

Two cDNAs, isolated from a Trypanosoma cruzi amastigote library immunoscreened with sera from patients with Chagas disease, encode proteins with sequence homology to eukaryotic components of the cellular sorting and recycling machinery. These proteins, denominated TcAGL, present an N-terminal lectin domain and a C-terminal region containing repetitive amino acids and a poly-glutamine tract. They are products of polymorphic alleles of a single copy gene constitutively expressed during the parasite life cycle. Polyclonal antibodies obtained from mice immunized with the recombinant antigen recognize proteins with apparent molecular weight ranging from 95 to 120 kDa in cell lysates from all three life stages and in various strains of the parasite. Sera from Chagas disease patients recognize the recombinant antigen in ELISA and immunoprecipitation assays but not in Western blot assays under denaturing conditions. Consistent with its proposed role in the glycoprotein secreting pathway, immunofluorescence analyses and expression of a green fluorescent protein-tagged TcAGL protein indicate a sub-cellular localization in the vicinity of the flagellar pocket membrane and the Golgi complex of the parasite.     

Congenital co-infection with different Trypanosoma cruzi lineages

Variability of mixed Trypanosoma cruzi congenital infection in Chile in twenty one congenital samples of Chagas disease is reported. Recognition of infecting strains was performed by minicircle hybridization tests. Seven newborns with double infection were found. Trypanosoma cruzi TcII and TcV lineages were the most frequent in single and mixed infections. With these results we pretend to understand the epidemiological significance of the T. cruzi lineages for which the placenta does not seem to represent an actual barrier in congenital infections.     

Application of fluorescein-labelled lectins with different glycan-binding specificities to the studies of cellular glycoconjugates in human full-term placenta

In the present study 13 lectins of plant, fungal and animal origin, characterised by different glycan-binding specificities were used to examine the structure and distribution of specific glycans in the tissues of human placenta. Histochemical analysis was focused on villi (villous syncytiotrophoblast and stroma), cytotrophoblast of the basal plate and amniotic epithelium. It was found that glycoconjugates containing mannose and N-acetyl glucosamine were widely expressed while external fucosyl residues were absent on all studied structures of placenta. Lectins GNA (revealing non-reducing terminal mannosyl residues) and LPA (revealing sialic acid) bound selectively to the villus structures. The presence of sialic acid residues was observed in the superficial plasmalemma of syncytiotrophoblast and on the surface of the foetal capillary endothelium. Lectins LCA and PSA showed specific affinity to the plasmalemma of the cytotrophoblast and to the amniotic epithelium basement membrane. N-acetyl lactosamine-specific fungal lectin PSL selectively labelled amniotic epithelial and cytotrophoblast cell membranes and superficial plasmalemma of the syncytiotrophoblast.     

Immunochemical studies on the interaction between synthetic glycoconjugates and alpha-L-fucosyl binding lectins

Evonymus europaea lectin precipitated with alpha DGal(1----3) beta DGal(1----4)beta DGlcNAc-bovine serum albumin (BSA), alpha LFuc(1----2)beta DGal(1----3)beta DGlcNAc-BSA, alpha LFuc(1----2)beta DGal(1----4)DGlcNAc, and alpha DGal(1----3)[alpha LFuc(1----2)]beta DGal-BSA. However, the lectin neither precipitated with alpha LFuc(1----2)-beta DGal-BSA, alpha DGal(1----3)beta DGal-BSA, or beta DGal(1----4)beta DGlcNAc-BSA nor agglutinated erythrocytes of Oh phenotype having multiple terminal beta DGal(1----4)beta DGlcNAc residues. These results indicate that the minimal structural requirement for glycoprotein precipitation or cell agglutination by the lectin includes any of the three trisaccharides (fucosylated or nonfucosylated) derived from the blood group B tetrasaccharide. The monosaccharides linked to the beta-D-galactosyl residue in the blood group B tetrasaccharide, namely, alpha-D-galactose, alpha-L-fucose, and N-acetyl-beta-D-glucosamine, participate almost equally in binding to the lectin in as much as removal of any one of these sugars reduces the inhibiting potency of the resulting trisaccharide. alpha LFuc(1----2)beta DGal(1----3)beta DGlcNAc-BSA (H type 1) and alpha LFuc(1----2)beta DGal(1----4)beta DGlcNAc (H type 2) were precipitated to the same extent. The E. europaea lectin neither precipitated alpha DGal(1----4)-beta DGal(1----4)beta DGlcNAc-BSA, Lea-BSA, Leb-BSA, or beta DGlcNAc(1----4)[alpha LFuc(1----6)]beta DGlcNAc-BSA nor agglutinated Oh,Lea and Oh,Leb erythrocytes, demonstrating that terminal D-galactose linked alpha-(1----4) to subterminal beta-D-galactose, or alpha-L-fucose linked to N-acetylglucosamine, prevents lectin binding. Corey-Pauling-Koltun molecular models, built on the basis of data from 1H NMR and hard-sphere exo-anomeric (HSEA) calculations provided by Lemieux and co-workers [Lemieux, R. U., Bock, K., Delbaere, L. T. J., Koto, S., & Rao, V. S. (1980) Can. J. Chem. 58, 631-653], show that these alpha-D-galactosyl and alpha-L-fucosyl groups act to sterically hinder lectin binding to these oligosaccharides; these observations also suggest that the lectin binds to the beta-side of these oligosaccharides. These sides, on both blood group H type 1 and blood group H type 2 oligosaccharides, provide a similar contour which can fully account for their equal reactivity with E. europaea lectin. The only difference found between Lotus and Ulex I lectins in precipitating ability was that only Lotus precipitated with beta DGlcNAc(1----4)[alpha LFuc(1----6)]beta DGlcNAc-BSA.(ABSTRACT TRUNCATED AT 400 WORDS)     

Glycoprofiling with micro-arrays of glycoconjugates and lectins

To facilitate deciphering the information content in the glycome, thin film-coated photoactivatable surfaces were applied for covalent immobilization of glycans, glycoconjugates, or lectins in microarray formats. Light-induced immobilization of a series of bacterial exopolysaccharides on photoactivatable dextran-coated analytical platforms allowed covalent binding of the exopolysaccharides. Their specific galactose decoration was detected with fluorescence-labeled lectins. Similarly, glycoconjugates were covalently immobilized and displayed glycans were profiled for fucose, sialic acid, galactose, and lactosamine epitopes. The applicability of such platforms for glycan profiling was further tested with extracts of Caco2 epithelial cells. Following spontaneous differentiation or on pretreatment with sialyllactose, Caco2 cells showed a reduction of specific glycan epitopes. The changed glycosylation phenotypes coincided with altered enteropathogenic E. coli adhesion to the cells. This microarray strategy was also suitable for the immobilization of lectins through biotin-neutravidin-biotin bridging on platforms functionalized with a biotin derivatized photoactivatable dextran. All immobilized glycans were specifically and differentially detected either on glycoconjugate or lectin arrays. The results demonstrate the feasibility and versatility of the novel platforms for glycan profiling.     

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.     

Development and interactions of Trypanosoma cruzi within the insect vector

Transmission of Chagas disease or American trypanosomiasis depends on Trypanosoma cruzi development and differentiation within its triatomine insect vector. In this review, Eloi Garcia and Patricia de Azambuja aim to outline the current areas of research that may explain aspects of the parasite-vector interaction.     

Parasite-host glycan interactions during Trypanosoma cruzi infection: trans-Sialidase rides the show

Many important pathogen-host interactions rely on highly specific carbohydrate binding events. In the case of the protozoan Trypanosoma cruzi, the causative agent of Chagas disease, glycointeractions involving sialic acid (SA) residues are pivotal for parasite infectivity, escape from immune surveillance and pathogenesis. Though unable to synthesize SA de novo, T. cruzi displays a unique trans-Sialidase (TS) enzyme, which is able to cleave terminal SA residues from host donor glycoconjugates and transfer them onto parasite surface mucins, thus generating protective/adhesive structures. In addition, this parasite sheds TS into the bloodstream, as a way of modifying the surface SA signature, and thereby the signaling/functional properties of mammalian host target cells on its own advantage. Here, we discuss the pathogenic aspects of T. cruzi TS: its molecular adaptations, the multiplicity of interactions in which it is involved during infections, and the array of novel and appealing targets for intervention in Chagas disease provided by TS-remodeled sialoglycophenotypes.     

Biological characterization of Trypanosoma cruzi zymodemes: in vitro differentiation of epimastigotes and infectivity of culture metacyclic trypomastigotes to mice

Thirty-one Trypanosoma cruzi isolates from Chile, Peru, and Bolivia were studied in their capacity to differentiate in vitro from epimastigotes to metacyclic trypomastigotes on TAU-3AAG medium. Zymodeme 1 parasites displayed the best level of differentiation, which ranges from 60 to 90% depending on the isolate. Zymodeme 2 parasites exhibited highly heterogenous differentiation rates. This differentiation method permits the obtention of large amounts of metacyclic trypomastigotes from zymodeme 1 parasites. Metacyclic trypomastigotes obtained in vitro were infective to nude Balb/c hybrid mice. Zymodeme 1 parasites produced high parasitemias in this murine model; in contrast, zymodeme 2 parasites displayed lower parasitemias. Of a total of 27 T. cruzi isolates, 20 proved to be infective to mice, 12 gave enough parasites for further studies, and 8 of these were used for biological characterization. Results are compared with the infective clone Dm28 and Tulahuén strains maintained since 1954 in mice.     

Trypanosoma cruzi: amastigotes and trypomastigotes interact with different structures on the surface of HeLa cells

It is generally accepted that Trypanosoma cruzi trypomastigotes represent the infective forms of the etiological agent of Chagas' disease. However, the invasive capacity of amastigotes and their ability to sustain a complete infective cycle in mammalian cultured cells and hosts has been recently demonstrated. In order to compare the process of cell invasion by these different infective forms, I examined the interactions of trypomastigotes and amastigotes with HeLa cells using a new and simple method that improves parasite-cell interactions and significantly reduces incubation periods. T. cruzi forms were centrifuged onto HeLa cells grown on coverslips and parasite-cell interactions were examined by fluorescence and scanning electron microscopy. As expected, it was observed that all parasite forms attach and eventually enter the cells. However, whereas trypomastigotes preferentially invade HeLa cells at the edges, as has recently been demonstrated for other cell types, the initial steps of amastigote-HeLa cell interaction involve binding and entangling of the parasite to surface microvilli. Thus, different T. cruzi infective forms interact with different cell surface structures that could express different receptors at the HeLa cell membrane.