Blood schizontocidal activity of selected 1,2,4-trioxanes (Fenozans) against the multidrug-resistant strain of Plasmodium yoelii nigeriensis (MDR) in vivo.

Blood schizontocidal activity of 10 selected cis-fused cyclopenteno-1,2,4-trioxanes (namely Fenozan compound nos 6, 7, 11, 27, 32, 39, 44, 45, 48 and 51) have been re-investigated to establish their curative doses against the multidrug-resistant Plasmodium yoelii nigeriensis strain, which is lethal in Swiss mice. Freshly prepared formulations of these compounds prepared either in neutral groundnut (peanut) oil or in dimethyl sulfoxide (DMSO)-Tween-water, were compared for their antimalarial activity. Only 2 compounds, namely Fenozan derivatives 11 and 45, formulated in neutral groundnut oil for oral administration, showed highest activity with 100% cure rate in MDR P. yoelii nigeriensis-infected mice, while the DMSO-Tween-water formulations were inactive. Fenozan-48 produced 72.2% cure, when administered orally in groundnut oil (formulation) while its DMSO-Tween formulation was inactive. In the case of Fenozan 7, the oil and DMSO-Tween formulations produced 92.3 and 76.0% cures respectively. Fenozan derivatives nos 6, 27, 32, 39, 44 and 51 were not protective either in groundnut oil or DMSO-Tween oral formulations. The present study has applied more rigorous criteria for selection of active compounds, and has identified the 3,3-spirocyclopentane derivative Fenozan 11, and the 3,3-spirohydropyran derivative Fenozan 45, as potential blood schizontocides which can completely eliminate multidrug-resistant malaria infection in mice. Both these compounds are candidates for pre-clinical development. The present study advocates the preferred use of an oil vehicle for oral evaluation of potential antimalarial trioxanes/fenozans instead of the DMSO formulation, which gives inferior curative efficacy.

The chemotherapy of rodent malaria. LX. The importance of formulation in evaluating the blood schizontocidal activity of some endoperoxide antimalarials.

The activities of artemisinin (QHS) and a number of its semi-synthetic analogues, as well as Fenozan B07 (B07), a synthetic 1,2,4-trioxane, and arteflene (ATF), a synthetic surrogate of yingzhaosu, were compared in mice infected with drug-sensitive Plasmodium berghei or chloroquine-resistant P. yoelii ssp. NS. The studies were stimulated by the observation that B07, in certain aqueous preparations, appears to be equipotent by the subcutaneous (sc) or oral (po) routes in the rodent model but not in a simian model. In the rodent model, B07 was found to undergo rapid alteration (with a half-life of <24h) in an aqueous stock solution prepared using dimethyl sulphoxide (DMSO) to pre-dissolve the drug. Therefore, for all later experiments with aqueous preparations, the test material was newly formulated each day. In a carboxymethylcellulose formulation used as a 'standard suspending vehicle' (SSV), B07 and dihydroartemisinin (DIHYD) were found to be, respectively, one sixth and one 10th as active po as when the drugs were pre-dissolved in DMSO and then diluted with water. ATF in DMSO given po was less than one 20th as active as when used sc in the rodent model, and this drug in SSV was almost inactive po. The relatively low oral activity of these three compounds (especially DIHYD and ATF) may be attributable to extensive first-pass metabolism in the mouse. Oral beta-artemether (AM) and beta-arteether (AE) were highly active when used in SSV. ATF has been found to have low activity in simian models and clinical trials because of its poor absolute bio-availability. In in-vivo studies of the blood schizontocidal action of anti-malarials, in rodent malaria models, the data collected on the structure-activity relationships (SAR) of the drugs must be viewed critically when selecting specific compounds from a chemical series for further development. A study of the influence of drug formulation on the activity of other, novel antimalarials is crucial to the evaluation of the drugs, and merits high priority.

New bromoterpenes from the red alga Laurencia luzonensis.

Extraction of a sample of Laurencia luzonensis collected off the coast of Kudaka Island, Okinawa, yielded the known sesquiterpenes palisol (1), palisadin B (2), palisadin A (3), pacifigorgiol (4), and aplysistatin (5), together with five new bromosesquiterpenes, isopalisol (6), luzonensol (7), luzonensol acetate (8), luzonensin (9), and (3Z,6E)-1-bromo-2-hydroxy-3,7,11-trimethyldodeca-3,6,10-triene (10). In addition, a new bromoditerpene of unusual structure, 3-bromobarekoxide (11), possessing a seven-membered ring fused to trans-decalin, was isolated.

Why artemisinin and certain synthetic peroxides are potent antimalarials. Implications for the mode of action.

The discovery that the sesquiterpene peroxide yingzhaosu A (13) and 1,2,4-trioxane artemisinin (14) are active against chloroquine-resistant strains of Plasmodium falciparum, has opened a new era in the chemotherapy of malaria. In vitro and in vivo tests with synthetic structurally simpler trioxanes clearly demonstrate that much of the skeleton of 14 is redundant and that chirality is not required for activity. In addition, structure-activity relations and the search for the pharmacophore reveal that high antimalarial activity can be displayed by molecules which do not resemble the geometry of 13 and 14 at all. The possible mode of action of 13, 14, and synthetic peroxides is examined. They are believed to kill intraerythrocytic Plasmodium by interacting with the heme discarded by proteolysis of ingested hemoglobin. Complexation of heme with the peroxide bond followed by electron transfer generates an oxy radical that evolves to the ultimate parasiticidal agent. Experiments with ferrous reagents indicate that active peroxides including 14 and its congeners kill the parasite by alkylation with a sterically non-encumbered C-centered radical. However, another possibility is the involvement of a Fe(IV)=O species as the toxic agent. The review covers our own and other contributions to this timely topic and evaluates the different mechanisms proposed for the mode of action of peroxidic antimalarials.

Correlating the molecular electrostatic potentials of some organic peroxides with their antimalarial activities.

The molecular electrostatic potentials (MEPs) of artemisinin (also known as qinghaosu), yingzhaosu A, and some synthetic analogues have been calculated and studied as a means of distinguishing between high and low antimalarial activity. To facilitate comparison, the dimensionality of the MEP was reduced by Kohonen Neural Network transforms. The reduction revealed that peroxides exhibiting high antimalarial activity are characterized by a continuous strip of negative electric potential surrounding the molecule, whereas peroxides of lesser activity show a broken strip.

A QSAR study of the antimalarial activity of some synthetic 1,2,4-trioxanes.

The antimalarial activity of a series of synthetic 1,2,4-trioxanes is correlated with molecular structure by using a pharmacophore search method (CATALYST). The technique is shown to have predictive accuracy and confirms that docking between an active trioxane and the receptor, heme, is the crucial step for drug action.

Second-generation antimalarial endoperoxides.

Artemisinin, derived from a Chinese herbal remedy, is a potent peroxide-containing antimalarial. New types of peroxides, derived from this structure, as well as other naturally occurring antimalarial peroxides, have been synthesized and found to have potent antimalarial activities. Studies on the activities, modes of action, and toxicities of these compounds are discussed here by Steven Meshnick and colleagues.

The chemotherapy of rodent malaria. L. The activities of some synthetic 1,2,4-trioxanes against chloroquine-sensitive and chloroquine-resistant parasites. Part 3: Observations on 'Fenozan-50F', a difluorinated 3,3'-spirocyclopentane 1,2,4-trioxane.

A novel difluorinated 3,3'-spirocyclopentane 1,2,4-trioxane ('Fenozan-50F') is a potent blood schizontocide against drug-sensitive and drug-resistant rodent malaria parasites. It also exerts some action against pre-erythrocytic schizogony, is a potent gametocytocide, and exerts a direct sporontocidal effect in infected mosquitoes. In the '4-day test' the ED90s are 6.8 and 6.0 mg/kg/day for four consecutive days by the subcutaneous and oral routes respectively against drug-sensitive Plasmodium berghei N, and 6.3 and 25 mg/kg against chloroquine-resistant P. yoelii NS in vivo. By the oral route against P. berghei N infection in mice, Fenozan-50F is about half as active as arteether but nearly three times as active as sodium artesunate. The activity of Fenozan-50F is retained against a wide spectrum of drug-resistant parasite lines, although those highly resistant to quinine or to artemisinin are less responsive at the ED90 level. At the ultrastructural level the compound, when administered to infected mice, causes marked changes in the membranes and ribosomes of trophozoites and young schizonts and of immature gametocytes, although few changes are apparent in mature gametocytes. Its toxicity appears to be very low when it is administered to mice by either the oral or subcutaneous route. Fenozan-50F is considered to be a good candidate for eventual use as a therapeutic agent for infection with polyresistant malaria in man.

The chemotherapy of rodent malaria. XLVIII. The activities of some synthetic 1,2,4-trioxanes against chloroquine-sensitive and chloroquine-resistant parasites. Part 1: Studies leading to the development of novel cis-fused cyclopenteno derivatives.

The new Chinese antimalarial blood schizontocide, artemisinin, derived from the plant Artemisia annua, displays a high level of activity against polyresistant Plasmodium falciparum. Several synthetic 1,2,4-trioxanes were examined in a search for compounds that exhibit a similar type of action against drug-resistant parasites. This paper, the first of a series, describes the examination of these trioxanes against drug-sensitive and drug-resistant malaria parasites in a rodent model, using artemisinin and arteether as comparison standards. Cis-fused cyclohexeno-1,2,4-trioxanes (10-17) substituted with various side-chains revealed for the most part variable but weak antimalarial activity. On the other hand, cis-fused cyclopenteno-1,2,4-trioxanes (18-19) showed greater activity, 19 showing about 1/30th of the activity of arteether against drug-sensitive Plasmodium berghei in vivo, thereby providing a clue to the structure-activity relationship.

The chemotherapy of rodent malaria. XLIX. The activities of some synthetic 1,2,4-trioxanes against chloroquine-sensitive and chloroquine-resistant parasites. Part 2: Structure-activity studies on cis-fused cyclopenteno-1,2,4-trioxanes (fenozans) against drug-sensitive and drug-resistant lines of Plasmodium berghei and P. yoelii ssp. NS in vivo.

The activity of 51 synthetic cis-fused cyclopenteno-1,2,4-trioxanes has been examined against drug-sensitive and chloroquine-resistant malaria parasites in vivo. Some of them display high levels of blood schizontocidal activity when administered orally or subcutaneously. They retain their activity against lines of parasites that are resistant to widely differing antimalarials such as 4-aminoquinolines, aminoalcohols, dihydrofolate reductase inhibitors and artemisinin. The most potent compound of the present series is cis-(+/-)-4a,7a-dihydro-6,7a-di(p-fluorophenyl)spiro [cyclopentane-3,3'-7H-cyclopenta-1,2,4-trioxin], otherwise known as Fenozan-50F.

In vitro effects of three new 1,2,4-trioxanes (pentatroxane, thiahexatroxane, and hexatroxanone) on Toxoplasma gondii.

The in vitro effects of three synthetic, cis-fused, bicyclic 1,2,4-trioxanes (pentatroxane, thiahexatroxane, and hexatroxanone) against intracellular Toxoplasma gondii were studied. Unactivated peritoneal macrophages were infected with the virulent RH strain of T. gondii and exposed to the 1,2,4-trioxanes at different concentrations. The antitoxoplasmic activity of the drugs was first assessed with [3H]uracil, which is incorporated by the parasite but not the host cell. Pentatroxane and thiahexatroxane were the most active, exhibiting 90% inhibitory concentrations of 6.8 and 5.3 micrograms/ml, respectively. Furthermore, microscopic examination of the infected macrophages after treatment with pentatroxane, thiahexatroxane, and hexatroxanone at their respective 90% inhibitory concentrations confirmed the inhibition of intracellular growth of T. gondii. Their activities were comparable to those of pyrimethamine (1 micrograms/ml) and pyrimethamine (0.1 micrograms/ml) in combination with sulfadiazine (25 micrograms/ml). Pentatroxane and thiahexatroxane were also able to inhibit intracellular growth of T. gondii within nonprofessional phagocytes (HeLa cells), suggesting that the antitoxoplasmic activity was not caused by a macrophage-specific mechanism, such as macrophage activation. However, the 1,2,4-trioxanes were not active against extracellular T. gondii. Pentatroxane and thiahexatroxane are new, promising compounds that deserve further study to assess their usefulness for treating toxoplasmosis.

Evaluation of models for the mechanism of action of 4-hydroxyphenylpyruvate dioxygenase.

3-Hydroxyphenylpyruvic acid was oxygenated with various complexes of oxygen with Fe2+, superoxide ion, hydroperoxide anion, triplet and singlet oxygen. Oxidation occurred giving varying amounts of the 4-hydroxy derivatives of benzaldehyde, benzoic acid, phenol, phenylacetic acid and 4-carboxymethylquinone, but no homogentisic acid. 4-Hydroxyphenylperacetic acid was prepared and shown not to undergo self-oxidation. Its ferrous salt decomposed to 4-hydroxybenzyl alcohol. It is concluded that the alpha-keto carboxylic function is the site of oxygenation in the enzyme process and that a trioxalanone rather than a peracid intermediate may be implicated.