The redox state of the host-parasite unit has been hypothesized to play a central role for the fitness of the intraerythrocytic blood stages of the human malaria parasite Plasmodium falciparum. In particular, hemoglobinopathies have been suggested to cause a more oxidizing environment, thereby protecting from severe malaria. Here we determined the redox potential of infected wild-type (hemoglobin AA) or sickle trait (hemoglobin AS) erythrocytes using parasite-encoded variants of the redox-sensitive green-fluorescent protein 2 (roGFP2). Our non-invasive roGFP2 single-cell measurements revealed a reducing steady-state redox potential of -304 ± 11 mV for the erythrocyte cytosol during ring-stage development and a rather sudden oxidation to -278 ± 12 mV during trophozoite-stage development around 28 h post invasion. There was no significant difference between wild-type or sickle trait erythrocytes regarding the stage dependence and the detected increase of the redox potential during the intraerythrocytic life cycle. The steady-state redox potential of the parasite cytosol, between -304 and -313 mV, was highly reducing throughout the life cycle. The redox potential in the parasitophorous vacuole at the interface between the secretory pathway and the erythrocyte was -284 ± 10 mV and remained stable during trophozoite-stage development with implications for the export of disulfide-containing proteins. In summary, P. falciparum blood stage development from the late ring to the early trophozoite stage causes a physiological jump in erythrocyte redox potential irrespective of the presence or absence of hemoglobin S.
【저자키워드】 glutathione, sickle cell trait, reduction, Oxidation, secretory pathway, Erythrocyte redox potential, Genetically encoded redox sensors, Plasmodium falciparum infected red blood cells, roGFP2,