In vivo antimalarial activity and mechanisms of action of 4-nerolidylcatechol derivatives

4-Nerolidylcatechol (1) is an abundant antiplasmodial metabolite that is isolated from Piper peltatum roots. O-Acylation or O-alkylation of compound 1 provides derivatives exhibiting improved stability and significant in vitro antiplasmodial activity. The aim of this work was to study the in vitro inhibition of hemozoin formation, inhibition of isoprenoid biosynthesis in Plasmodium falciparum cultures, and in vivo antimalarial activity of several 4-nerolidylcatechol derivatives. 1,2-O,O-Diacetyl-4-nerolidylcatechol (2) inhibited in vitro hemozoin formation by up to 50%. In metabolic labeling studies using [1-(n)-3H]geranylgeranyl pyrophosphate, diester 2 significantly inhibited the biosynthesis of isoprenoid metabolites ubiquinone 8, menaquinone 4, and dolichol 12 in cultures of P. falciparum 3D7. Similarly, 2-O-benzyl-4-nerolidylcatechol (3) significantly inhibited the biosynthesis of dolichol 12. P. falciparum in vitro protein synthesis was not affected by compounds 2 or 3. At oral doses of 50 mg per kg of body weight per day, compound 2 suppressed Plasmodium berghei NK65 in infected BALB/c mice by 44%. This in vivo result for derivative 2 represents marked improvement over that obtained previously for natural product 1. Compound 2 was not detected in mouse blood 1 h after oral ingestion or in mixtures with mouse blood/blood plasma in vitro. However, it was detected after in vitro contact with human blood or blood plasma. Derivatives of 4-nerolidylcatechol exhibit parasite-specific modes of action, such as inhibition of isoprenoid biosynthesis and inhibition of hemozoin formation, and they therefore merit further investigation for their antimalarial potential. Copyright © 2015, American Society for Microbiology. All Rights Reserved

Vitamin E biosynthesis in intraerythrocytic stages of Plasmodium falciparum.

O estudo da biossíntese de isoprenóides em P. falciparum por meio da via 2C-metil-D-eritritol-4-fosfato (MEP) é apontado como possível alvo terapêutico, visto a via ser ausente em humanos. Foi descrito que nos estágios intraeritrocitários de P. falciparum a via essencial de biossíntese de isoprenóides é a via MEP. As vias do Chiquimato e MEP são precursoras da biossíntese de vitamina E e ambas já foram descritas em P. falciparum. É sugerido que a biossíntese de vitamina E possa ocorrer no parasita, representando um possível alvo para o desenvolvimento de novas drogas antimaláricas. Empregando marcações metabólicas com precursores radioativos, três diferentes métodos de RP-HPLC e análises por espectrometria de massas confirmamos a biossíntese de vitamina E nos três estágios intraeritrocíticos do parasita. O tratamento com ácido úsnico, mostrou inibição dessa biossíntese no estágio esquizonte e do crescimento do parasita. Demonstramos por meio de uma sonda fluorescente, ácido Parinárico, que a vitamina E atua como antioxidante lipofílico, protegendo a lipoperoxidação. Esses resultados não só contribuem para a compreensão da biologia de P. falciparum, mas também elucidam partes das vias MEP e do Chiquimato que podem servir como alvos terapêuticos.The study of isoprenoid biosynthesis in Plasmodium falciparum by 2C-methyl-D-erythritol-4-phosphate pathway (MEP) it is presented as a therapeutic target once that it is absent in humans. It was found in intraerythrocytic stages of P. falciparum the biosynthesis of isoprenoids by the MEP pathway. The shikimate and MEP pathways are the precursors of biosynthesis of vitamin E and both pathways have already been described in P. falciparum. It is suggested that the biosynthesis of vitamin E might occur in the parasite, representing a possible target for developing new antimalarial drugs. Using metabolic labelling with radiolabelled precursors, three different methods of RP-HPLC and mass spectrometry analyses confirmed the biosynthesis of vitamin E in the three intraerythrocytic stages of parasite. The treatment with usnic acid showed an inhibition of this biosynthesis and of the growth of parasite. We demonstrated by means of a fluorescent probe, the acid Parinaric, that vitamin E acts as a lipophilic antioxidant protecting the membrane of lipoperoxidation. These findings not only contribute to the current understanding of P. falciparum biology but shed light on a pathway that could serve as a chemotherapeutic target

Estudy of vitamin E function and of vitamin K1 biosynthesis in Plasmodium falciparum.

A malária apresenta um alto índice de mortalidade com mais de 500 mil mortes registradas em 2013. Para agravar a situação de saúde pública, foi descrito o surgimento de resistência às drogas usadas na terapêutica da doença. Torna-se necessário a identificação e o estudo de novos alvos antimaláricos. A via MEP se mostra como um potencial alvo para o desenvolvimento de drogas contra P. falciparum uma vez que está ausente em humanos. Nossos objetivos foram avaliar a função da vitamina E biossintetizada pelo parasita, caracterizar a biossíntese de vitamina K1 e o metabolismo de fitol. Esse estudo determinou que a vitamina E biossintetizada pelo parasita atua no sistema redox do parasita. Por outro lado, mostramos que a biossíntese de vitamina K1 é ativa no parasita e detectamos sua forma reduzida. Por fim, observamos que existe uma via de reaproveitamento de fitol em P. falciparum assim como em plantas. O estudo abre oportunidades para um desenvolvimento racional de novos antimaláricos e aprofunda o conhecimento na biologia do parasita.Malaria has the highest mortality rate with more than 500 000 deaths in 2013. The public health situation gets worse because it has been described the emergence of resistance to common drugs used in the treatment of disease. It is necessary to identify and study of new antimalarial targets. The MEP pathway is a potential target for drug development against Plasmodium falciparum once it is absent in humans. Our objectives were to evaluate the function of vitamin E biosynthesized by the parasite and characterize the biosynthesis of vitamin K1 and the phytol metabolism. This study determined that vitamin E biosynthesized by the parasite operates in the redox system of the parasite. We show the biosynthesis of vitamin K1 is active on parasite and we detected its reduced form. Finally, we demonstrate that there is a phytol salvage pathway in P. falciparum as well as plants. The study opens opportunities for the rational development of new antimalarials and deepens knowledge on parasite biology