In vitro activity of anti-malarial ozonides against an artemisinin-resistant isolate

Baumgärtner, Fabian; Jourdan, Joëlle; Scheurer, Christian; Blasco, Benjamin; Campo, Brice; Mäser, Pascal; Wittlin, Sergio

doi:10.1186/s12936-017-1696-0

Cited by 29 publications

(36 citation statements)

References 57 publications

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“…Recent reports on K13-modified isogenic lines have provided evidence that the C580Y mutation does not mediate cross-resistance to OZ439 (refs. 30,89), whereas the rare R539T mutation, in some studies, mediated partial cross-resistance 30,89–91 . Of note, a recent phase 2 clinical trial with OZ439 showed a nonstatistically significant trend toward slightly longer parasite clearance half-lives in individuals harboring K13-mutant infections, as compared to those with wild-type K13.…”

Section: Next-generation Antimalarialsmentioning

confidence: 99%

“…Ongoing clinical studies should clarify whether OZ439 can be effective at treating K13-mutant infections, and whether specific K13 mutations such as R539T might reduce drug efficacy. Importantly, the earlier-generation ozonide OZ277, which is licensed for clinical use in India in combination with piperaquine (Synriam), was recently observed in several studies to lose potency against mutant K13 parasites 30,89–91 . These data argue for close pharmacovigilance of treatment outcomes of the OZ277-containing combination, especially given that K13 mutations have been identified in India or near its borders with Myanmar and Bangladesh 93,94 .…”

Section: Next-generation Antimalarialsmentioning

confidence: 99%

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Antimalarial drug resistance: linking Plasmodium falciparum parasite biology to the clinic

Blasco

Leroy

Fidock

2017

Nat Med

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459

419

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The global adoption of artemisinin-based combination therapies (ACTs) in the early 2000s heralded a new era in effectively treating drug-resistant Plasmodium falciparum malaria. However, several Southeast Asian countries have now reported the emergence of parasites that have decreased susceptibility to artemisinin (ART) derivatives and ACT partner drugs, resulting in increasing rates of treatment failures. Here we review recent advances in understanding how antimalarials act and how resistance develops, and discuss new strategies for effectively combatting resistance, optimizing treatment and advancing the global campaign to eliminate malaria.

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Section: Next-generation Antimalarialsmentioning

confidence: 99%

Section: Next-generation Antimalarialsmentioning

confidence: 99%

Antimalarial drug resistance: linking Plasmodium falciparum parasite biology to the clinic

Blasco

Leroy

Fidock

2017

Nat Med

Self Cite

459

419

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“…Recent in vitro studies have used drug pulse activity assays to examine the exposure time dependence of parasite response to selected peroxide antimalarials (34)(35)(36) across the asexual parasite life cycle. The extent of parasite killing was found to be dependent on parasite strain and life cycle stage, drug concentration, and drug exposure time.…”

mentioning

confidence: 99%

Parasite-Mediated Degradation of Synthetic Ozonide Antimalarials Impacts In Vitro Antimalarial Activity

Giannangelo

Stingelin

Yang

et al. 2018

Antimicrob Agents Chemother

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The peroxide bond of the artemisinins inspired the development of a class of fully synthetic 1,2,4-trioxolane-based antimalarials, collectively known as the ozonides. Similar to the artemisinins, heme-mediated degradation of the ozonides generates highly reactive radical species that are thought to mediate parasite killing by damaging critical parasite biomolecules. We examined the relationship between parasite dependent degradation and antimalarial activity for two ozonides, OZ277 (arterolane) and OZ439 (artefenomel), using a combination of drug stability and pulsed-exposure activity assays. Our results showed that drug degradation is parasite stage dependent and positively correlates with parasite load. Increasing trophozoite-stage parasitemia leads to substantially higher rates of degradation for both OZ277 and OZ439, and this is associated with a reduction in antimalarial activity. Under conditions of very high parasitemia (∼90%), OZ277 and OZ439 were rapidly degraded and completely devoid of activity in trophozoite-stage parasite cultures exposed to a 3-h drug pulse. This study highlights the impact of increasing parasite load on ozonide stability and antimalarial activity and should be considered when investigating the antimalarial mode of action of the ozonide antimalarials under conditions of high parasitemia.

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“…It was observed that the ringstage parasites were able to develop a quiescent state, which was associated with a mutation in the Kelch 13 propeller domain [3]. In reality, the use of conventional in vitro methods to evaluate the IC 50 of drugs cannot discriminate an artemisinin partially resistant strain from a susceptible one after exposure to DHA, the active metabolite [24]. In order to correlate survival of parasites in vitro with the time of parasitic clearance observable in vivo, the ring-stage survival assay [25] was used where a short pulse of DHA treatment during the early ring stage of the erythrocyte phase allows for observing differences in susceptibility between the sensitive and resistant strain [25].…”

Section: Heparin Quantificationmentioning

confidence: 99%

“…The results show a decrease of toxicity and an improvement in effectiveness. The RSA 0-3 h , which is able to predict the potency of compounds against artemisinin-resistant parasites in malaria patients [24], demonstrated the potent activity of the heparin-targeted liposomes towards an artemisinin-resistant isolate compared to poupartone B alone. Furthermore, it confirmed that this formulation was able to kill resistant parasites, even with a short contact time.…”

Section: Heparin Quantificationmentioning

confidence: 99%

Heparin-Coated Liposomes Improve Antiplasmodial Activity and Reduce the Toxicity of Poupartone B

Ledoux

Mamede

Palazzo

et al. 2020

Planta Medica International Open

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Poupartone B is an alkyl cyclohexenone derivative isolated from Poupartia borbonica. This compound demonstrated promising antimalarial activity (IC50 < 1 µg/mL), however, it was not devoid of toxicity. Thus, to reduce the adverse side effects of this natural bioactive molecule, a delivery strategy involving a nanostructure was formulated. Additionally, poupartone B-loaded liposomes were coated with heparin, a glycosaminoglycan that is known to target proteins on the surface of Plasmodium falciparum-infected red blood cells. The quantification of the compound in the formulation was performed by HPLC-DAD, while heparin was quantitated by 1H NMR spectroscopy. The liposomes’ antiplasmodial activity was tested on artemisinin-resistant P. falciparum isolate, and toxicity was evaluated on human HeLa cells and zebrafish embryos. Throughout this research, the formulation demonstrated higher antiplasmodial activities against both P. falciparum strains and a significant decrease of in vitro toxicity. The formulation improved the selectivity index 2 times in vitro and proved to be 3 times less toxic than the compound alone in the zebrafish embryo acute toxicity test. Hence, the use of this strategy to deliver natural products in Plasmodium-infected cells, particularly those with a narrow therapeutic margin, is proposed.

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In vitro activity of anti-malarial ozonides against an artemisinin-resistant isolate

Cited by 29 publications

References 57 publications

Antimalarial drug resistance: linking Plasmodium falciparum parasite biology to the clinic

Antimalarial drug resistance: linking Plasmodium falciparum parasite biology to the clinic

Parasite-Mediated Degradation of Synthetic Ozonide Antimalarials Impacts In Vitro Antimalarial Activity

Heparin-Coated Liposomes Improve Antiplasmodial Activity and Reduce the Toxicity of Poupartone B

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