Malaria: parasite resistance to artemisinin derivatives now affecting Africa

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Resistance to artemisinin, the main component of the current antimalarial treatments recommended by WHO, is already widespread in South-East Asia, but it had not previously been described in Africa. Scientists from the Institut Pasteur, in collaboration with the National Malaria Control Program in Rwanda (Rwanda Biomedical Center), the World Health Organization (WHO), Cochin Hospital and Columbia University (New York, USA), recently detected the emergence and spread of malaria parasites capable of resisting artemisinin derivatives for the first time in Rwanda. The results of the research were published on August 3, 2020 in Nature Medicine.

Malaria, caused by parasites of the genus Plasmodium, represents a major public health problem. Almost 3.2 billion people (virtually half the world's population) in 89 countries are at risk of contracting the disease, for which there is currently no vaccine. Every year, over 200 million cases and over 400,000 deaths are recorded.

For more than 15 years, treatment of malaria episodes (typical cycles of the disease alternating between fever, shivering and chills, and severe sweating) caused by Plasmodium falciparum has depended on artemisinin-based combination therapies (ACTs), which combine a fast-acting artemisinin derivative and a partner drug with a long half-life. Since 2008, parasites capable of resisting artemisinin derivatives in South-East Asia (Cambodia, Thailand, Vietnam, Myanmar and Laos) have become increasingly prevalent. This resistance, which leads to a delay in the clearance of parasites from the bloodstream of individuals treated with an ACT, is currently a serious threat that may hinder efforts to tackle the disease. A major concern is that these resistant parasites will spread through Sub-Saharan Africa, the continent most affected by malaria (>90% of cases), as was the case with previous generations of antimalarial treatments (chloroquine and folic acid antagonists). In the 1980s, the reduced efficacy of chloroquine is thought to have contributed to several million additional deaths from malaria in young African children.

Since 2014, the geographical distribution of artemisinin resistance has been monitored based on the detection of mutations in the Kelch13 gene in parasites. These mutations are believed to reduce the function of the Kelch13 protein, thought to be involved in hemoglobin degradation in infected red blood cells. Currently, the most widespread resistant parasites in South-East Asia have the C580Y mutation. Recently, C580Y mutant parasites have also been detected in Guyana and Papua New Guinea. In Africa, where ACTs remain very effective, Kelch13 mutant parasites have remained rare. For instance, the KARMA study, the first global map of artemisinin resistance, showed that less than 5% of African samples had mutations and that more than 50% of the mutants detected had only been observed once. Scientists also demonstrated that the most frequently observed mutation in Africa (A578S) did not confer artemisinin resistance to gene-edited Asian parasites.

Scientists from the Institut Pasteur, involved in a WHO-supported project on molecular monitoring of resistance in Africa, recently identified the first signs of emergence of artemisinin-resistant Kelch13 mutant parasites in Africa. The results describe significant proportions of parasites carrying the R561H mutation in two locations 100km apart (prevalences of 7.4% in Masaka and 0.7% in Rukara, respectively). Whole-genome sequencing of these parasites indicates that the R561H mutants were selected from Rwandan parasite populations and that they had not spread from Asian parasites (from Thailand or Myanmar, where the R561H mutation has previously been observed). "These unexpected results contrast with previous scenarios in which the emergence of chloroquine- or pyrimethamine-resistant parasites in Africa was caused by the spread of resistant parasites from South-East Asia. It was thought that a similar scenario would apply for the emergence of artemisinin-resistant parasites in Africa," explains Didier Ménard, Head of the Malaria Genetics and Resistance Unit at the Institut Pasteur. The fact that this resistant strain has spread between several places in Rwanda and its ability to resist artemisinin in vitro have major public health implications. In the absence of effective measures to contain the spread of resistant parasites in Rwanda and neighboring countries, there is a risk that over time they will acquire the ability to resist the partner drugs used in ACTs. This would mean that the only available treatments would become ineffective, as has occurred in South-East Asia. A model of this scenario, in which no measures are taken, recently predicted that the inefficacy of ACTs in Africa could be responsible for 78 million additional cases and 116,000 additional deaths over a five-year period.

This research was supported by the Institut Pasteur, the World Health Organization, the World Bank (via the East African Public Health Laboratory Networking Project), the Bill & Melinda Gates Foundation (Grant OPP1140599), the United States Department of Defense (W81XWH-19-1-0086) and the National Institutes of Health (R01 AI109023).


Source

Emergence and clonal expansion of in vitro artemisinin-resistant Plasmodium falciparum Kelch13 R561H mutant parasites in Rwanda, Nature Medicine, August 3, 2020

Aline Uwimana1#*, Eric Legrand2#, Barbara H. Stokes3, Jean-Louis Mangala Ndikumana1, Marian Warsame4, Noella Umulisa5,6, Daniel Ngamije7, Tharcisse Munyaneza8, Jean-Baptiste Mazarati8, Kaendi Munguti9, Pascal Campagne10, Alexis Criscuolo10, Frédéric Ariey11, Monique Murindahabi12, Pascal Ringwald13, David A. Fidock3,14, Aimable Mbituyumuremyi1, Didier Menard2*

1 Malaria and Other Parasitic Diseases Division, Rwanda Biomedical Centre (RBC), Kigali, Rwanda

2 Malaria Genetics and Resistance Unit, Institut Pasteur, Paris, France,

3 Department of Microbiology and Immunology, Columbia University Irving Medical Center, New York, USA 

4 University of Gothenburg, Gothenburg, Sweden

5 Maternal and Child Survival Program/JHPIEGO, Baltimore MD, USA

6 Impact Malaria Rwanda, Kigali, Rwanda

7 Minister of Health, Kigali, Rwanda

8 National Reference Laboratory (NRL), BIOS /Rwanda Biomedical Centre (RBC), Kigali, Rwanda

9 US President’s Malaria Initiative, Kigali, Rwanda

10 Hub de Bioinformatique et Biostatistique – Département Biologie Computationnelle, USR 3756 , Institut Pasteur, Paris, France

11 Université de Paris, INSERM 1016, Institut Cochin, Service de Parasitologie-Mycologie Hôpital Cochin, Paris, France.

12 Roll Back Malaria for West and Central Africa, Kigali, Rwanda

13 Global Malaria Programme, World Health Organization, Geneva, Switzerland

14 Division of Infectious Diseases, Department of Medicine, Columbia University Irving Medical Center, New York, USA

 

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