Assessment of benzimidazole binding to individual recombinant tubulin isotypes from Haemonchus contortus.

One a- and 2 beta-tubulin isotypes (isotypes 1 and 2) from the parasitic nematode Haemonchus contortus were artificially expressed in E. coli and purified to obtain tubulin that was capable of polymerizing into microtubules. Binding of [14C] mebendazole (MBZ), a benzimidazole compound, to each individual unpolymerized isotype and to microtubules polymerized from recombinant alpha- and beta-tubulin was assessed and Kd and Bmax values determined. Mebendazole bound to the individual tubulin isotypes with a stoichiometry of 1:1. Binding occurred with highest affinity to alpha-tubulin followed by beta-tubulin isotype 2 and beta-tubulin isotype 1 indicating that alpha-tubulin may play a role in benzimidazole binding to microtubules. Upon polymerization of alpha- and beta-tubulin isotype 2 into microtubules the stoichiometry of binding increased to 2:1 (mebendazole : tubulin) while binding affinity remained the same. Mebendazole binding to alpha/beta-isotype 1 microtubules remained unchanged following polymerization. The increase in the number of benzimidazole receptors on alpha/beta-isotype 2 microtubules suggests the formation of a new benzimidazole receptor upon polymerization.

Individual expression of recombinant alpha- and beta-tubulin from Haemonchus contortus: polymerization and drug effects.

Three tubulin isotypes from the parasitic nematode Haemonchus contortus were individually expressed in Escherichia coli, purified, and induced to polymerize into microtubules in the absence of microtubule-associated proteins. The effect of different conditions on the rate of polymerization of pure tubulin was assessed. This is the first time that recombinant alpha-tubulin has been shown to be capable of polymerization into microtubule-like structures when incubated with recombinant beta-tubulin. In addition, the present study has shown that: (1) microtubule-associated proteins are not required for tubulin polymerization; and (2) pure beta-tubulin isotype, beta12-16, alone was capable of forming microtubule-like structures in the absence of alpha-tubulin. Polymerization of the recombinant invertebrate tubulin, as measured by a spectrophotometric assay, was found to be enhanced by a concentration of tubulin >0.25 mg/mL; temperature > or =20 degrees C; 2 mM GTP; glycerol; EGTA; and Mg(2+). Polymerization was inhibited by GTP (>2 mM) and albendazole. Calcium ions and a pH range of 6 to 8.5 had no measurable effect on polymerization. Individual isotypes of tubulin polymerized to approximately the same extent as an alpha-/beta-tubulin mixture. Samples of tubulin assembled under the above conditions for 60 min were also examined under a transmission electron microscope. Although the spectrophotometric assay indicated polymerization, it did not predict the structure of the polymer. In many cases tubulin sheets, folded sheets, and rings were observed in addition to, or instead of, microtubule-like structures.

The binding and distribution of albendazole and its principal metabolites in Giardia duodenalis.

Trophozoites of the protozoan parasite Giardia duodenalis were exposed to various albendazole concentrations for 4 h, washed, fixed and incubated with antibodies raised against albendazole and its two major metabolites albendazole sulphoxide and albendazole sulphone. Tubulin antibodies were also used. A peroxidase- or FITC-conjugated secondary antibody was used to detect the primary antibody with transmission electron microscopy or confocal laser scanning microscopy, respectively. Albendazole, a benzimidazole compound, was detected in the mid-dorsal region of trophozoites, albendazole sulphoxide in the posterior-dorsal region and albendazole sulphone in clusters above the median bodies. Tubulin was recognised in the ventral disk. This is the first indication that G. duodenalis may be capable of metabolising albendazole and the potential path of the metabolised drug traced within the trophozoite. Fluorescence measurements revealed that albendazole sulphoxide binding decreased and albendazole sulphone binding increased with exposure of the trophozoites to increasing albendazole concentration. This indicates that if albendazole was being metabolised by trophozoites, it occurred to a greater extent following exposure to higher albendazole concentrations.

Evaluation of the effects of albendazole and metronidazole on the ultrastructure of Giardia duodenalis, Trichomonas vaginalis and Spironucleus muris using transmission electron microscopy.

The three closely related parasitic protozoa, Giardia duodenalis, Trichomonas vaginalis and Spironucleus muris, all have very different sensitivities to albendazole and metronidazole. Ultrastructural studies reveal that the cytoskeletal elements of the ventral disk in G. duodenalis are affected by albendazole, whereas the other two parasites, neither of which possess this structure, are not affected by albendazole to the same extent. This suggests that albendazole may be having its primary affect on G. duodenalis by binding to cytoskeletal proteins and ultimately causing death of the parasite. Death may be occurring as the parasite loses its ability to adhere to the intestinal villi and obtain nutrients. Metronidazole showed a different pattern of activity against the three parasites. The evidence obtained from these ultrastructural studies supports the current theory that metronidazole adversely affects protozoa by disrupting inner cell membranes.