Artemisinin-resistant K13 mutations rewire Plasmodium falciparum’s intra-erythrocytic metabolic program to enhance survival

Sachel Mok; Barbara H. Stokes; Nina F. Gnädig; Leila S. Ross; Tomas Yeo; Chanaki Amaratunga; Erik Allman; Lev Solyakov; Andrew R. Bottrill; Jaishree Tripathi; Rick M. Fairhurst; Manuel Llinás; Zbynek Bozdech; Andrew B. Tobin; David A. Fidock

doi:10.1038/s41467-020-20805-w

Artemisinin-resistant K13 mutations rewire Plasmodium falciparum’s intra-erythrocytic metabolic program to enhance survival

Sachel Mok
, Barbara H. Stokes
, Nina F. Gnädig
, Leila S. Ross
, Tomas Yeo
, Chanaki Amaratunga
, Erik Allman
, Lev Solyakov
, Andrew R. Bottrill
, Jaishree Tripathi
, Rick M. Fairhurst
, Manuel Llinás
, Zbynek Bozdech
, Andrew B. Tobin
, David A. Fidock

Research output: Contribution to journal › Article › peer-review

106 Scopus citations

Abstract

The emergence and spread of artemisinin resistance, driven by mutations in Plasmodium falciparum K13, has compromised antimalarial efficacy and threatens the global malaria elimination campaign. By applying systems-based quantitative transcriptomics, proteomics, and metabolomics to a panel of isogenic K13 mutant or wild-type P. falciparum lines, we provide evidence that K13 mutations alter multiple aspects of the parasite’s intra-erythrocytic developmental program. These changes impact cell-cycle periodicity, the unfolded protein response, protein degradation, vesicular trafficking, and mitochondrial metabolism. K13-mediated artemisinin resistance in the Cambodian Cam3.II line was reversed by atovaquone, a mitochondrial electron transport chain inhibitor. These results suggest that mitochondrial processes including damage sensing and anti-oxidant properties might augment the ability of mutant K13 to protect P. falciparum against artemisinin action by helping these parasites undergo temporary quiescence and accelerated growth recovery post drug elimination.

Original language	English (US)
Article number	530
Journal	Nature communications
Volume	12
Issue number	1
DOIs	https://doi.org/10.1038/s41467-020-20805-w
State	Published - Dec 1 2021

All Science Journal Classification (ASJC) codes

General Chemistry
General Biochemistry, Genetics and Molecular Biology
General Physics and Astronomy

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Mok, S., Stokes, B. H., Gnädig, N. F., Ross, L. S., Yeo, T., Amaratunga, C., Allman, E., Solyakov, L., Bottrill, A. R., Tripathi, J., Fairhurst, R. M., Llinás, M., Bozdech, Z., Tobin, A. B., & Fidock, D. A. (2021). Artemisinin-resistant K13 mutations rewire Plasmodium falciparum’s intra-erythrocytic metabolic program to enhance survival. Nature communications, 12(1), Article 530. https://doi.org/10.1038/s41467-020-20805-w

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title = "Artemisinin-resistant K13 mutations rewire Plasmodium falciparum{\textquoteright}s intra-erythrocytic metabolic program to enhance survival",

abstract = "The emergence and spread of artemisinin resistance, driven by mutations in Plasmodium falciparum K13, has compromised antimalarial efficacy and threatens the global malaria elimination campaign. By applying systems-based quantitative transcriptomics, proteomics, and metabolomics to a panel of isogenic K13 mutant or wild-type P. falciparum lines, we provide evidence that K13 mutations alter multiple aspects of the parasite{\textquoteright}s intra-erythrocytic developmental program. These changes impact cell-cycle periodicity, the unfolded protein response, protein degradation, vesicular trafficking, and mitochondrial metabolism. K13-mediated artemisinin resistance in the Cambodian Cam3.II line was reversed by atovaquone, a mitochondrial electron transport chain inhibitor. These results suggest that mitochondrial processes including damage sensing and anti-oxidant properties might augment the ability of mutant K13 to protect P. falciparum against artemisinin action by helping these parasites undergo temporary quiescence and accelerated growth recovery post drug elimination.",

author = "Sachel Mok and Stokes, \{Barbara H.\} and Gn{\"a}dig, \{Nina F.\} and Ross, \{Leila S.\} and Tomas Yeo and Chanaki Amaratunga and Erik Allman and Lev Solyakov and Bottrill, \{Andrew R.\} and Jaishree Tripathi and Fairhurst, \{Rick M.\} and Manuel Llin{\'a}s and Zbynek Bozdech and Tobin, \{Andrew B.\} and Fidock, \{David A.\}",

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doi = "10.1038/s41467-020-20805-w",

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Mok, S, Stokes, BH, Gnädig, NF, Ross, LS, Yeo, T, Amaratunga, C, Allman, E, Solyakov, L, Bottrill, AR, Tripathi, J, Fairhurst, RM, Llinás, M, Bozdech, Z, Tobin, AB & Fidock, DA 2021, 'Artemisinin-resistant K13 mutations rewire Plasmodium falciparum’s intra-erythrocytic metabolic program to enhance survival', Nature communications, vol. 12, no. 1, 530. https://doi.org/10.1038/s41467-020-20805-w

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AU - Mok, Sachel

AU - Stokes, Barbara H.

AU - Gnädig, Nina F.

AU - Ross, Leila S.

AU - Yeo, Tomas

AU - Amaratunga, Chanaki

AU - Allman, Erik

AU - Solyakov, Lev

AU - Bottrill, Andrew R.

AU - Tripathi, Jaishree

AU - Fairhurst, Rick M.

AU - Llinás, Manuel

AU - Bozdech, Zbynek

AU - Tobin, Andrew B.

AU - Fidock, David A.

PY - 2021/12/1

Y1 - 2021/12/1

N2 - The emergence and spread of artemisinin resistance, driven by mutations in Plasmodium falciparum K13, has compromised antimalarial efficacy and threatens the global malaria elimination campaign. By applying systems-based quantitative transcriptomics, proteomics, and metabolomics to a panel of isogenic K13 mutant or wild-type P. falciparum lines, we provide evidence that K13 mutations alter multiple aspects of the parasite’s intra-erythrocytic developmental program. These changes impact cell-cycle periodicity, the unfolded protein response, protein degradation, vesicular trafficking, and mitochondrial metabolism. K13-mediated artemisinin resistance in the Cambodian Cam3.II line was reversed by atovaquone, a mitochondrial electron transport chain inhibitor. These results suggest that mitochondrial processes including damage sensing and anti-oxidant properties might augment the ability of mutant K13 to protect P. falciparum against artemisinin action by helping these parasites undergo temporary quiescence and accelerated growth recovery post drug elimination.

AB - The emergence and spread of artemisinin resistance, driven by mutations in Plasmodium falciparum K13, has compromised antimalarial efficacy and threatens the global malaria elimination campaign. By applying systems-based quantitative transcriptomics, proteomics, and metabolomics to a panel of isogenic K13 mutant or wild-type P. falciparum lines, we provide evidence that K13 mutations alter multiple aspects of the parasite’s intra-erythrocytic developmental program. These changes impact cell-cycle periodicity, the unfolded protein response, protein degradation, vesicular trafficking, and mitochondrial metabolism. K13-mediated artemisinin resistance in the Cambodian Cam3.II line was reversed by atovaquone, a mitochondrial electron transport chain inhibitor. These results suggest that mitochondrial processes including damage sensing and anti-oxidant properties might augment the ability of mutant K13 to protect P. falciparum against artemisinin action by helping these parasites undergo temporary quiescence and accelerated growth recovery post drug elimination.

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Artemisinin-resistant K13 mutations rewire Plasmodium falciparum’s intra-erythrocytic metabolic program to enhance survival

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