Your search keyword '"Marfurt, Jutta"' showing total 2 results

1. Emergence of artemisinin-resistant Plasmodium falciparum with kelch13 C580Y mutations on the island of New Guinea.

Author

Miotto, Olivo, Sekihara, Makoto, Tachibana, Shin-Ichiro, Yamauchi, Masato, Pearson, Richard D., Amato, Roberto, Gonçalves, Sonia, Mehra, Somya, Noviyanti, Rintis, Marfurt, Jutta, Auburn, Sarah, Price, Ric N., Mueller, Ivo, Ikeda, Mie, Mori, Toshiyuki, Hirai, Makoto, Tavul, Livingstone, Hetzel, Manuel W., Laman, Moses, and Barry, Alyssa E.

Subjects

PLASMODIUM falciparum, ARTEMISININ derivatives, SURVIVAL analysis (Biometry), GENETIC mutation, ARTEMISININ, ISLANDS, MALARIA

Abstract

The rapid and aggressive spread of artemisinin-resistant Plasmodium falciparum carrying the C580Y mutation in the kelch13 gene is a growing threat to malaria elimination in Southeast Asia, but there is no evidence of their spread to other regions. We conducted cross-sectional surveys in 2016 and 2017 at two clinics in Wewak, Papua New Guinea (PNG) where we identified three infections caused by C580Y mutants among 239 genotyped clinical samples. One of these mutants exhibited the highest survival rate (6.8%) among all parasites surveyed in ring-stage survival assays (RSA) for artemisinin. Analyses of kelch13 flanking regions, and comparisons of deep sequencing data from 389 clinical samples from PNG, Indonesian Papua and Western Cambodia, suggested an independent origin of the Wewak C580Y mutation, showing that the mutants possess several distinctive genetic features. Identity by descent (IBD) showed that multiple portions of the mutants' genomes share a common origin with parasites found in Indonesian Papua, comprising several mutations within genes previously associated with drug resistance, such as mdr1, ferredoxin, atg18 and pnp. These findings suggest that a P. falciparum lineage circulating on the island of New Guinea has gradually acquired a complex ensemble of variants, including kelch13 C580Y, which have affected the parasites' drug sensitivity. This worrying development reinforces the need for increased surveillance of the evolving parasite populations on the island, to contain the spread of resistance. Author summary: Artemisinin is the most widely used drug against Plasmodium falciparum malaria. In southeast Asia, parasites have evolved genetic changes making them resistant to artemisinin. The elimination of resistant strains is a global priority, since their global spread could result in massive loss of lives. In Papua New Guinea, we found three patients infected with parasites carrying the most widespread resistant variant in southeast Asia, and they were confirmed to be artemisinin resistant. We established that the mutations were not imported from southeast Asia, and found other drug resistance variants in their genetic background, including some shared with parasites in Indonesia. This indicates that artemisinin resistance has emerged in New Guinea separately from southeast Asia, not by a chance event, but by a gradual process of evolution which may still be ongoing undetected on the island. These resistant strains could undermine malaria local control efforts, and constitute a global threat. [ABSTRACT FROM AUTHOR]

Published

2020

2. Molecular surveillance over 14 years confirms reduction of Plasmodium vivax and falciparum transmission after implementation of Artemisinin-based combination therapy in Papua, Indonesia.

Author

Pava, Zuleima, Puspitasari, Agatha M., Rumaseb, Angela, Handayuni, Irene, Trianty, Leily, Utami, Retno A. S., Tirta, Yusrifar K., Burdam, Faustina, Kenangalem, Enny, Wirjanata, Grennady, Kho, Steven, Trimarsanto, Hidayat, Anstey, Nicholas M., Poespoprodjo, Jeanne Rini, Noviyanti, Rintis, Price, Ric N., Marfurt, Jutta, and Auburn, Sarah

Subjects

PLASMODIUM vivax, PLASMODIUM falciparum, GENETIC epidemiology, TRYPANOSOMA, DRUG control, MALARIA

Abstract

Genetic epidemiology can provide important insights into parasite transmission that can inform public health interventions. The current study compared long-term changes in the genetic diversity and structure of co-endemic Plasmodium falciparum and P. vivax populations. The study was conducted in Papua Indonesia, where high-grade chloroquine resistance in P. falciparum and P. vivax led to a universal policy of Artemisinin-based Combination Therapy (ACT) in 2006. Microsatellite typing and population genetic analyses were undertaken on available isolates collected between 2004 and 2017 from patients with uncomplicated malaria (n = 666 P. falciparum and n = 615 P. vivax). The proportion of polyclonal P. falciparum infections fell from 28% (38/135) before policy change (2004–2006) to 18% (22/125) at the end of the study (2015–2017); p<0.001. Over the same period, polyclonal P. vivax infections fell from 67% (80/119) to 35% (33/93); p<0.001. P. falciparum strains persisted for up to 9 years compared to 3 months for P. vivax, reflecting higher rates of outbreeding in the latter. Sub-structure was observed in the P. falciparum population, but not in P. vivax, confirming different patterns of outbreeding. The P. falciparum population exhibited 4 subpopulations that changed in frequency over time. Notably, a sharp rise was observed in the frequency of a minor subpopulation (K2) in the late post-ACT period, accounting for 100% of infections in late 2016–2017. The results confirm epidemiological evidence of reduced P. falciparum and P. vivax transmission over time. The smaller change in P. vivax population structure is consistent with greater outbreeding associated with relapsing infections and highlights the need for radical cure to reduce recurrent infections. The study emphasizes the challenge in disrupting P. vivax transmission and demonstrates the potential of molecular data to inform on the impact of public health interventions. Author summary: Genetic epidemiology is gaining widespread interest as a tool that can enhance conventional malaria surveillance. However, few studies have assessed the utility of molecular analyses in quantifying long-term changes in malaria transmission. The current study compared changes in the genetic diversity and structure of co-endemic P. vivax and P. falciparum populations sampled over 14 years (2004–2017) in Papua Indonesia, during which the incidence of both P. falciparum and P. vivax malaria halved. The study found larger genetic changes in P. falciparum than P. vivax, reflecting a greater impact of local interventions, including the implementation of a new drug policy (universal Artemisinin-Based Combined Therapy) in 2006, on P. falciparum. Both species exhibited decreasing complexity of infections over time, consistent with declining transmission. However, the P. falciparum population showed greater evidence of a recent bottleneck than the P. vivax population. Four subpopulations were observed amongst the P. falciparum isolates, one of which predominated in 2016–2017, potentially reflecting recent adaptation. The results concur with epidemiological studies performed in the same area, that found declining transmission in both species, with less impact on P. vivax infections. Radical cure to treat the dormant liver stages may enable larger reductions in P. vivax transmission. The results support the great potential of molecular surveillance in complementing traditional malariometric approaches. [ABSTRACT FROM AUTHOR]

Published

2020