Plasmodium falciparum: multifaceted resistance to artemisinins.

Plasmodium falciparum resistance to artemisinins, the most potent and fastest acting anti-malarials, threatens malaria elimination strategies. Artemisinin resistance is due to mutation of the PfK13 propeller domain and involves an unconventional mechanism based on a quiescence state leading to parasite recrudescence as soon as drug pressure is removed. The enhanced P. falciparum quiescence capacity of artemisinin-resistant parasites results from an increased ability to manage oxidative damage and an altered cell cycle gene regulation within a complex network involving the unfolded protein response, the PI3K/PI3P/AKT pathway, the PfPK4/eIF2α cascade and yet unidentified transcription factor(s), with minimal energetic requirements and fatty acid metabolism maintained in the mitochondrion and apicoplast. The detailed study of these mechanisms offers a way forward for identifying future intervention targets to fend off established artemisinin resistance.

Multiple Phenotypic and Genotypic Artemisinin Sensitivity Evaluation of Malian Plasmodium falciparum Isolates.

We assessed the ex vivo/in vitro sensitivity of 54 Malian Plasmodium falciparum isolates to artemisinin for the monitoring of drug resistance in this area. The artemisinin sensitivity of parasites was evaluated using 1) the ex vivo and in vitro parasite recrudescence detection after treatment of the ring stage with 1-200 nM artemisinin for 48 hours and 2) the in vitro parasite recrudescence kinetics assay over 7 days after 6-hour treatment of the ring stage with 700 nM dihydroartemisinin (DHA). In addition, as recommended by the World Health Organization for artemisinin resistance characterization, the ring-stage survival assay (RSA0-3 h) was performed and the parasite isolates were sequenced at the kelch 13 propeller locus. No clinical and molecular evidence of artemisinin resistance was observed. However, these isolates present different phenotypic profiles in response to artemisinin treatments. Despite all RSA0-3 h values less than 1.5%, six out of 46 (13.0%) isolates tested ex vivo and four out of six (66.7%) isolates tested in vitro were able to multiply after 48-hour treatments with 100 nM artemisinin. Moreover, five out of eight isolates tested showed faster parasite recovery after DHA treatment in kinetic assays. The presence of such phenotypes needs to be taken into account in the assessment of the efficacy of artemisinins in Mali. The assays presented here appear as valuable tools for the monitoring of artemisinin sensitivity in the field and thus could help to evaluate the risk of emergence of artemisinin resistance in Africa.