Histone Methyltransferase Inhibitors Are Orally Bioavailable, Fast-Acting Molecules with Activity against Different Species Causing Malaria in Humans

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Malmquist, Nicholas | Sundriyal, Sandeep | Caron, Joachim | Chen, Patty | Witkowski, Benoit | Ménard, Didier | Suwanarusk, Rossarin | Renia, Laurent | Nosten, François | Jiménez-Díaz, María Belén | Angulo-Barturen, Iñigo | Santos Martínez, María | Ferrer, Santiago | Sanz, Laura | Gamo, Francisco-Javier | Wittlin, Sergio | Duffy, Sandra | Avery, Vicky | Ruecker, Andrea | Delves, Michael | Sinden, Robert | Fuchter, Matthew, J | Scherf, Artur

Edité par CCSD ; American Society for Microbiology -

International audience. Current antimalarials are under continuous threat due to the relentless development of drug resistance by malaria parasites. We previously reported promising in vitro parasite-killing activity with the histone methyltransferase inhibitor BIX-01294 and its analogue TM2-115. Here, we further characterize these diaminoquinazolines for in vitro and in vivo efficacy and pharmacokinetic properties to prioritize and direct compound development. BIX-01294 and TM2-115 displayed potent in vitro activity, with 50% inhibitory concentrations (IC50s) of <50 nM against drug-sensitive laboratory strains and multidrug-resistant field isolates, including artemisinin-refractory Plasmodium falciparum isolates. Activities against ex vivo clinical isolates of both P. falciparum and Plasmodium vivax were similar, with potencies of 300 to 400 nM. Sexual-stage gametocyte inhibition occurs at micromolar levels; however, mature gametocyte progression to gamete formation is inhibited at submicromolar concentrations. Parasite reduction ratio analysis confirms a high asexual-stage rate of killing. Both compounds examined displayed oral efficacy in in vivo mouse models of Plasmodium berghei and P. falciparum infection. The discovery of a rapid and broadly acting antimalarial compound class targeting blood stage infection, including transmission stage parasites, and effective against multiple malaria-causing species reveals the diaminoquinazoline scaffold to be a very promising lead for development into greatly needed novel therapies to control malaria.

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