Evaluation of amidoxime derivatives as prodrug candidates of potent bis-cationic antimalarials.

Plasmodium falciparum is responsible for most of the cases of malaria and its resistance to established antimalarial drugs is a major issue. Thus, new chemotherapies are needed to fight the emerging multi-drug resistance of P. falciparum malaria, like choline analogues targeting plasmodial phospholipidic metabolism. Here we describe the synthesis of amidoxime derivatives as prodrug candidates of reverse-benzamidines and hybrid compounds able to mimic choline, as well as the design of a new series of asymmetrical bis-cationic compounds. Bioconversion studies were conducted on amidoximes in asymmetrical series and showed that amidoxime prodrug strategy could be applied on C-alkylamidine moieties, like benzamidines and that N-substituents did not alter the bioconversion of amidoximes. The antimalarial activity of the three series of compounds was evaluated in vitro against P. falciparum and in vivo against P. vinckei petteri in mice.

Symmetrical choline-derived dications display strong anti-kinetoplastid activity.

OBJECTIVES: to investigate the anti-kinetoplastid activity of choline-derived analogues with previously reported antimalarial efficacy. METHODS: from an existing choline analogue library, seven antimalarial compounds, representative of the first-, second- and third-generation analogues previously developed, were assessed for activity against Trypanosoma and Leishmania spp. Using a variety of techniques, the effects of choline analogue exposure on the parasites were documented and a preliminary investigation of their mode of action was performed. RESULTS: the activities of choline-derived compounds against Trypanosoma brucei and Leishmania mexicana were determined. The compounds displayed promising anti-kinetoplastid activity, particularly against T. brucei, to which 4/7 displayed submicromolar EC(50) values for the wild-type strain. Low micromolar concentrations of most compounds cleared trypanosome cultures within 24-48 h. The compounds inhibit a choline transporter in Leishmania, but their entry may not depend only on this carrier; T. b. brucei lacks a choline carrier and the mode of uptake remains unclear. The compounds had no effect on the overall lipid composition of the cells, cell cycle progression or cyclic adenosine monophosphate production or short-term effects on intracellular calcium levels. However, several of the compounds, displayed pronounced effects on the mitochondrial membrane potential; this action was not associated with production of reactive oxygen species but rather with a slow rise of intracellular calcium levels and DNA fragmentation. CONCLUSIONS: the choline analogues displayed strong activity against kinetoplastid parasites, particularly against T. b. brucei. In contrast to their antimalarial activity, they did not act on trypanosomes by disrupting choline salvage or phospholipid metabolism, instead disrupting mitochondrial function, leading to chromosomal fragmentation.

Reverse-benzamidine antimalarial agents: design, synthesis, and biological evaluation.

In the frame of the development of bis-cationic choline analogs, the RSA of bis-N-alkylamidines were studied and a new series of reverse-benzamidine derivatives was designed. Contrary to the lipophilicity, the basicity of alkylamidine compounds directly influences their antimalarial potencies.

N-substituted bis-C-alkyloxadiazolones as dual effectors: efficient intermediates to amidoximes or amidines and prodrug candidates of potent antimalarials.

A convenient route to N-substituted bis-C-alkylamidines possessing antiplasmodial activity and their oxadiazolone and amidoxime prodrug candidates, is described. These three families of compounds were available after a key N-alkylation step of the parent oxadiazolone 1a. Testing of the three compound classes in vitro and in vivo is also presented.

Design and synthesis of amidoxime derivatives for orally potent C-alkylamidine-based antimalarial agents.

Within the frame of the design of prodrug candidates to deliver a C-alkylamidine antimalarial agent, we showed that specific O-substitutions were needed on the alkylamidoxime structure. Among the newly synthesized molecules, bis-oxadiazolone and bis-O-methylsulfonylamidoxime derivatives induced a complete clearance of parasitemia in mice after oral administration.

Potent antimalarial activity of 2-aminopyridinium salts, amidines, and guanidines.

We describe the design, synthesis, and antimalarial activity of 60 bis-tertiary amine, bis-2(1 H)-imino-heterocycle, bis-amidine, and bis-guanidine series. Bis-tertiary amines with a linker from 12 to 16 methylene groups were active against the in vitro growth of Plasmodium falciparum within the 10 (-6)-10 (-7) M concentration range. IC 50 decreased by 2 orders of magnitude for bis-2-aminopyridinium salts, bis-amidines, and bis-guanidines (27 compounds with IC 50 < 10 nM). Increasing the alkyl chain length from 6 to 12 methylene groups led to increased activity, while beyond this antimalarial activity decreased. Antimalarial activities appear to be strictly related to the basicity of the cationic head with an optimal p K a over 12.5. Maximal activity occurs for bis-2-aminopyridinium, two C-duplicated bis-amidines, and three bis-guanidines, with IC 50 values lower than 1 nM. In comparison to similar quaternary ammonium salts, amidinium compounds have distinct structural requirements for antimalarial activity and likely additional binding opportunities on account of their hydrogen-bond-forming properties.

Development of the first oral bioprecursors of bis-alkylguanidine antimalarial drugs.

Plasmodium falciparum is responsible of the most severe form of malaria, and new targets and novel chemotherapeutic scaffolds are needed to fight emerging multidrug-resistant strains of this parasite. Bis-alkylguanidines have been designed to mimic choline, resulting in the inhibition of plasmodial de novo phosphatidylcholine biosynthesis. Despite potent in vitro antiplasmodial and in vivo antimalarial activities, a major drawback of these compounds for further clinical development is their low oral bioavailability. To solve this issue, various modulations were performed on bis-alkylguanidines. The introduction of N-disubstituents on the guanidino motif improved both in vitro and in vivo activities. On the other hand, in vivo pharmacological evaluation in a mouse model showed that the N-hydroxylated derivatives constitute the first oral bioprecursors in bis-alkylguanidine series. This study paves the way for bis-alkylguanidine-based oral antimalarial agents targeting plasmodial phospholipid metabolism.

Evaluation of bis-alkylamidoxime O-alkylsulfonates as orally available antimalarials.

The main threat to controlling malaria is the emerging multidrug resistance of Plasmodium sp. parasites. Bis-alkylamidines were developed as a potential new chemotherapy that targets plasmodial phospholipid metabolism. Unfortunately, these compounds are not orally available. To solve this absorption issue, we investigated a prodrug strategy based on sulfonate derivatives of alkylamidoximes. A total of 25 sulfonates were synthesized as prodrug candidates of one bis-N-alkylamidine and of six N-substituted bis-C-alkylamidines. Their antimalarial activities were evaluated in vitro against P. falciparum and in vivo against P. vinckei in mice to define structure-activity relationships. Small alkyl substituents on the sulfonate group of both C-alkyl- and N-alkylamidines led to the best oral antimalarial activities; alkylsulfonate derivatives are chemically transformed into the corresponding alkylamidines.

Pharmacokinetic properties and metabolism of a new potent antimalarial N-alkylamidine compound, M64, and its corresponding bioprecursors.

Antimalarial activities and pharmacokinetics of the bis-alkylamidine, M64, and its amidoxime, M64-AH, and O-methylsulfonate, M64-S-Me, derivatives were investigated. M64 and M64-S-Me had the most potent activity against the Plasmodium falciparum growth (IC(50)<12nM). The three compounds can clear the Plasmodium vinckei infection in mice (ED(50)<10mg/kg). A liquid chromatography-mass spectrometry method was validated to simultaneously quantify M64 and M64-AH in human and rat plasma. M64 is partially metabolized to M64-monoamidoxime and M64-monoacetamide by rat and mouse liver microsomes. The amidoxime M64-AH undergoes extensive metabolism forming M64, M64-monoacetamide, M64-diacetamide and M64-monoamidoxime. Strong interspecies differences were observed. The pharmacokinetic profiles of M64, M64-AH and M64-S-Me were studied in rat after intravenous and oral administrations. M64 is partially metabolized to M64-AH; while M64-S-Me is rapidly and totally converted to M64 and M64-AH. M64-AH is mostly oxidized to the inactive M64-diacetamine while its N-reduction to the efficient M64 is a minor metabolic pathway. Oral dose of M64-AH was well absorbed (38%) and converted to M64 and M64-diacetamide. This study generated substantial information about the properties of this class of antimalarial drugs. Other routes of synthesis will be explored to prevent oxidative transformation of the amidoxime and to favour the N-reduction.

Synthesis and antimalarial activity of new 1,12-bis(N,N'-acetamidinyl)dodecane derivatives.

Amidoxime and O-substituted derivatives of the bis-alkylamidine 1,12-bis(N,N'-acetamidinyl)dodecane were synthesized and evaluated as in vitro and in vivo antimalarial prodrugs. The bis-O-methylsulfonylamidoxime 8 and the bis-oxadiazolone 9 derivatives show relatively potent antimalarial activity after oral administration.