Infected erythrocyte choline carrier inhibitors: exploring some potentialities inside Plasmodium phospholipid metabolism for eventual resistance acquisition

• Published in: Memórias do Instituto Oswaldo Cruz Vol. 89 Suppl 2; no. suppl 2; pp. 91 - 97
• Main Authors: Vial, H J, Ancelin, M L, Elabbadi, N, Orcel, H, Yeo, H J, Gumila, C
• Format: Journal Article
• Language: English; Portuguese
• Published: Brazil Instituto Oswaldo Cruz, Ministério da Saúde 1994; Fundação Oswaldo Cruz (FIOCRUZ)
• Subjects: Animals; Antimalarials - pharmacology; Choline; choline carrier; Erythrocytes - parasitology; malaria; PARASITOLOGY; phospholipid metabolism; Phospholipids - metabolism; Phospholipids - pharmacology; Plasmodium - drug effects; Plasmodium - metabolism; Plasmodium - parasitology; resistance; serine lipidic metabolism; TROPICAL MEDICINE; phospholipid metabolism; serine lipidic metabolism; malaria; resistance; choline carrier
• ISSN: 0074-0276; 1678-8060; 0074-0276; 1678-8060
• DOI: 10.1590/S0074-02761994000600021

We have developed a model for designing antimalarial drugs based on interference with an essential metabolism developed by Plasmodium during its intraerythrocytic cycle, phospholipid (PL) metabolism. The most promising drug interference is choline transporter blockage, which provides Plasmodium with a supply of precursor for synthesis of phosphatidylcholine (PC), the major PL of infected erythrocytes. Choline entry is a limiting step in this metabolic pathway and occurs by a facilitated-diffusion system involving an asymmetric carrier operating according to a cyclic model. Choline transport in the erythrocytes is not sodium dependent nor stereospecific as demonstrated using stereoisomers of alpha and beta methylcholine. These last two characteristics along with distinct effects of nitrogen substitution on transport rate demonstrate that choline transport in the infected erythrocyte possesses characteristics quite distinct from that of the nervous system. This indicates a possible discrimination between the antimalarial activity (inhibition of choline transport in the infected erythrocyte) and a possible toxic effect through inhibition of choline entry in synaptosomes. Apart from the de novo pathway of choline, PC can be synthesized by N-methylation from phosphatidylethanolamine (PE). There is a de novo pathway for PE biosynthesis from ethanolamine in infected cells but phosphatidylserine (PS) decarboxylation also occurs. In addition, PE can be directly and abundantly synthesized from serine decarboxylation into ethanolamine, a pathway which is absent from the host. The variety of the pathways that exist for the biosynthesis of one given PL led us to investigate whether an equilibrium can occur between all PL metabolic pathways.