Trypanosomiasis: an approach to chemotherapy by the inhibition of carbohydrate catabolism.

When the infected mammalian host of Trypanosoma brucei brucei is injected with a solution of the iron chelator salicyl hydroxamic acid and glycerol, the aerobic and anaerobic glucose catabolism of the parasite is blocked and the parasite is rapidly destroyed.

Trypanosoma brucei brucei: patterns of glycolysis at 37 degrees C in vitro.

In the absence of mammalian cells, freshly isolated monomorphic bloodstream forms of Trypanosoma brucei brucei maintain a constant and high level of aerobic glycolysis in vitro for at least 4 h at 37 degrees C when suspended in RPMI medium 1640 containing 20% heat-inactivated and dialyzed fetal calf serum and 25 mM Hepes at an initial pH of 8. In the absence of nutrients other than glucose, salts and protein, some cell death and a decrease in the rate of glycolysis are observed. In the absence of protein, extensive cell death and a decrease in the rate of glycolysis are seen. These observations may be useful in the design of short-term in vitro metabolic studies with T. b. brucei.

Trypanosoma brucei brucei: a systematic screening for alternatives to the salicylhydroxamic acid-glycerol combination.

Salicylhydroxamic acid (SHAM) and glycerol, when administered together, cause destruction of bloodstream forms of Trypanosoma brucei brucei, both in vitro and in vivo, but the dose required is exceedingly high. In an attempt to improve the efficacy of this drug combination, we examined the ability of various polyols and hydroxamic acids to substitute for glycerol and SHAM, respectively. No satisfactory substitute for glycerol was found. The inhibition of the trypanosomal alpha-glycerophosphate oxidase system (GPO) by SHAM (Ki 21 microM) was uncompetitive. Only primary and secondary aromatic hydroxamates were inhibitory. Among a series of 19 benzhydroxamates, no correlation existed between their acidity or their affinity for iron and their inhibition of the GPO in a cell free preparation. The Ki's of most of the primary hydroxamates ranged from 10 to 24 microM, with the more lipophilic derivatives being slightly more active. The Ki's of secondary hydroxamates were more variable, the best having Ki's of about 10 microM. Several other classes of iron chelators were also evaluated. Tropolones were active with 3-bromo-4,5-benzotropolone being as active as SHAM. 3,4-Dihydroxybenzaldehyde (Ki 15 microM) also inhibited the GPO. On the other hand, diphenylamine and 8-hydroxyquinoline, known inhibitors of the GPO, were 30 to 50 times less active. The results suggest that a lipophilic aromatic iron-chelating agent may be useful as a substitute for SHAM in combination therapy.

Quantitative effects of salycylhydroxamic acid and glycerol on Trypanosoma brucei glycolysis in vitro and in vivo.

During anaerobic glycolysis in vitro in the presence of salicylhydroxamic acid, Trypanosoma brucei brucei converts glucose to equimolar amounts of glycerol and pyruvate as end products. Glycerol, whether generated endogenously and pyruvate as end products. Glycerol, whether generated endogenously or added exogenously, can inhibit anaerobic glycolysis sufficiently in vitro to result in cell death. The concomitant administration of salicylhydroxamic acid and glycerol to rats infected with T. brucei brucei results in a rapid clearance of parasitemia. Our results clearly demonstrate a new and approachable chemotherapeutic target for African trypanosomes.

Coezyme A requirement of malaria parasites: effects of coenzyme A precursors on extracellular development in vitro of Plasmodium lophurae.

The extracellular development in vitro of the avian malaria Plasmodium lophurae is favored by addition to the medium of coenzyme A at 0.05 mM. Coenzyme A can be replaced by dephospho-coenzyme A and to some extent by phosphopantetheine, but not by phosphopantothenoylcysteine or by phosphopantothenic acid. The activity of the two former precursors results from their conversion to coenzyme A by enzymes in the erythrocyte extract of the culture medium in the presence of ATP, also an essential ingredient of the medium. Hence, P. lophurae in its erythrocytic stage has an absolute requirement for an exogenous source of coenzyme A.

Coenzyme A requirement of malaria parasites: enzymes of coenzyme A biosynthesis in normal duck erythrocytes and erythrocytes infected with Plasmodium lophurae.

Normal duck erythrocytes and erythrocytes infected with Plasmodium lopharae have all of the enzymes for coenzyme A biosynthesis, whereas parasites freed from their host cells have non. Since erythrocytefree cultivation of P. lophurae requires an exogenous source of coenzyme A, this parasite must obtain its coenzyme A entirely from the host cell during infection.

Sporozoites of rodent and simian malaria, purified by anion exchangers, retain their immunogenicity and infectivity.

Sporozoites of rodent malaria, Plasmodium berghei, and simian malaria, Plasmodium knowlesi and Plasmodium cynomolgi, were partially separated from mosquito debris and microbial contaminants by passage of Anopheles material through a DEAE-cellulose column. In addition to eliminating most of the contaminants (80-90%), this simple technic has made it possible to recover rapidly large numbers of viable sporozoites (55-75% yield), which have retained their infectivity, immunogenicity, and capacity to react with known antisera. Mice injected with varying doses of column-purified sporozoites (CS) of P. berghei produced infections which paralleled those seen in the controls. Total protection against challenge with a potentially lethal dose of viable sporozoites was acquired by mice inoculated twice with irradiated CS of P. berghei CS of P. berghei and P. cynomolgi gave positive circumsporozoite precipitation (CSP) reactions, upon inoculation with the respective immune sera. The preservation of the surface antigens of CS was documented by immunofluorescence. It was shown that differences in elution behavior exist among sporozoites of certain species of Plasmodium as well as among sporozoiters of the same species derived from different organs of the mosquito. These results may be attributed to differences in the surface charge of the sporozoites or conditions in sample media. Purified sporozoites obtained by the method described in this report provide an adequate source of parasites for a variety of in vitro studies.