Role of placental barrier integrity in infection by Trypanosoma cruzi.

American trypanosomiasis has long been a neglected disease endemic in LatinAmerica, but congenital transmission has now spread Chagas disease to cause a global health problem. As the early stages of the infection of placental tissue and the vertical transmission by Trypanosoma cruzi are still not well understood, it is important to investigate the relevance of the first structure of the placental barrier in chorionic villi infection by T. cruzi during the initial stage of the infection. Explants of human chorionic villi from healthy pregnant women at term were denuded of their syncytiotrophoblast and co-cultured for 3h, 24h and 96h with 800,000 trypomastigotes (simulating acute infection). T. cruzi infected cells were identified by immunohistochemistry for cytokeratin-7 (+cytotrophoblast) and CD68 (+macrophages), and the infection was quantified. In placental tissue, the parasite load was analyzed by qPCR and microscopy, and the motile trypomastigotes were quantified in culture supernatant. In denuded chorionic villous, the total area occupied by the parasite (451.23µm2, 1.33%) and parasite load (RQ: 87) was significantly higher (p<0.05) than in the entire villous (control) (5.98µm2, 0.016%) (RQ:1) and with smaller concentration of nitric oxide. Stromal non-macrophage cells were infected as well as cytotrophoblasts and some macrophages, but with significant differences being observed. The parasite quantity in the culture supernatant was significantly higher (p<0.05) in denuded culture explants from 96h of culture. Although the human complete chorionic villi limited the infection, the detachment of the first structure of the placenta barrier (syncytiotrophoblast) increased both the infection of the villous stroma and the living trypomastigotes in the culture supernatant. Therefore structural and functional alterations to chorionic villi placental barrier reduce placental defenses and may contribute to the vertical transmission of Chagas.

Differential susceptibility of isolated human trophoblasts to infection by Trypanosoma cruzi.

The aim of the work was to analyze the susceptibility of the placental syncytiotrophoblast (STB) and cytotrophoblast (CTB) cells to infection by the causal agent of congenital Chagas' disease, Trypanosoma cruzi, and the possible parasite route for placental invasion. Monolayers of CTB and STB and VERO as control cells were used. The infection of STB was significantly lower that of the CTB and Vero cells (p < 0.05) which coincided with a significantly increased mortality of parasite cells in the culture medium and trypanocidal levels of nitric oxide. We conclude that the syncytiotrophoblast, the first placental barrier, is the main barrier of the chorionic villous that limits the infection by T. cruzi. This work opens the possibility of a new mechanism for placental infection when there are discontinuities in the first placental barrier.

Trypanosoma cruzi: altered parasites after in vitro treatment with gangliosides, a therapeutic agent in experimental Chagas' disease.

Biochemical and structural modifications were investigated in axenic cultured Trypanosoma cruzi after treatment with gangliosides. Fluorescence anisotropy showed dose dependent increments in parasite membranes of ganglioside treated epimastigotes. NADP-GDH activity increased in parasites treated at day 4 (13%), 7 (137.2%), and 14 (28.50%) while NAD-MDH but decreased from day 7 to 21 (-5.74%, -32.22%, -27.92%). Treated parasites presented electron-lucent vacuoles opposite to the cytostoma, multilamellar bodies and dilated mitochondrion cristae, disorganized kinetoplast and altered heterochromatin structure. Gangliosides inhibited fusogenic ability (80%) and PLA2 activity (>75%) from the parasite. The same occurred with anti-PLA2 antibodies. Trypomastigotes suffered loss of cytoplasmic material and organelles when GM1 was present in culture medium. We propose that exogenous gangliosides produced: altered lipid order, inhibited membrane enzymes, the parasite energy source shifted from glucose to amino acids, ending on a structural transformation which signals parasite cell death.