Population transcriptomics of human malaria parasites reveals the mechanism of artemisinin resistance

Sachel Mok; Elizabeth A. Ashley; Pedro Eduardo Ferreira; Lei Zhu; Zhaoting Lin; Tomas Yeo; Kesinee Chotivanich; Mallika Imwong; Sasithon Pukrittayakamee; Mehul Dhorda; Chea Nguon; Pharath Lim; Chanaki Amaratunga; Seila Suon; Tran Tinh Hien; Ye Htut; Mohammad Abul Faiz; Marie A. Onyamboko; Mayfong Mayxay; Paul N. Newton; Rupam Tripura; Charles J. Woodrow; Olivo Miotto; Dominic Kwiatkowski; François Nosten; Nicholas Day; Peter R. Preiser; Nicholas J. White; Arjen M. Dondorp; Rick M. Fairhurst; Zbynek Bozdech

doi:10.1126/science.1260403

Population transcriptomics of human malaria parasites reveals the mechanism of artemisinin resistance

Sachel Mok(Nanyang Technological University), Elizabeth A. Ashley(Mahidol University), Pedro Eduardo Ferreira(Nanyang Technological University), Lei Zhu(Nanyang Technological University), Zhaoting Lin(Nanyang Technological University), Tomas Yeo(Nanyang Technological University), Kesinee Chotivanich(Mahidol University), Mallika Imwong(Mahidol University), Sasithon Pukrittayakamee(Mahidol University), Mehul Dhorda(University of Maryland, Baltimore), Chea Nguon(Cambodia National Malaria Center), Pharath Lim(National Institutes of Health), Chanaki Amaratunga(National Institutes of Health), Seila Suon(Cambodia National Malaria Center), Tran Tinh Hien(Oxford University Clinical Research Unit), Ye Htut(Myanmar Oxford Clinical Research Unit), Mohammad Abul Faiz(Ild Care Foundation), Marie A. Onyamboko(Ministry of Public Health), Mayfong Mayxay(Mahosot Hospital), Paul N. Newton(Mahidol University), Rupam Tripura(Mahidol University), Charles J. Woodrow(Mahidol University), Olivo Miotto(Mahidol University), Dominic Kwiatkowski(Wellcome Sanger Institute), François Nosten(Mahidol University), Nicholas Day(Mahidol University), Peter R. Preiser(Nanyang Technological University), Nicholas J. White(Mahidol University), Arjen M. Dondorp(Mahidol University), Rick M. Fairhurst(National Institutes of Health), Zbynek Bozdech(Nanyang Technological University)

Science

December 12, 2014

10.1126/science.1260403

Cited by 459

Abstract

Artemisinin resistance in Plasmodium falciparum threatens global efforts to control and eliminate malaria. Polymorphisms in the kelch domain-carrying protein K13 are associated with artemisinin resistance, but the underlying molecular mechanisms are unknown. We analyzed the in vivo transcriptomes of 1043 P. falciparum isolates from patients with acute malaria and found that artemisinin resistance is associated with increased expression of unfolded protein response (UPR) pathways involving the major PROSC and TRiC chaperone complexes. Artemisinin-resistant parasites also exhibit decelerated progression through the first part of the asexual intraerythrocytic development cycle. These findings suggest that artemisinin-resistant parasites remain in a state of decelerated development at the young ring stage, whereas their up-regulated UPR pathways mitigate protein damage caused by artemisinin. The expression profiles of UPR-related genes also associate with the geographical origin of parasite isolates, further suggesting their role in emerging artemisinin resistance in the Greater Mekong Subregion.

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