ABSTRACT
Triclabendazole (TCBZ) is a halogenated benzimidazole compound that possesses high activity against immature and adult stages of the liver fluke, Fasciola hepatica. The intensive use of TCBZ in endemic areas of fascioliasis has resulted in the development of liver flukes resistant to this compound. TCBZ sulphoxide (TCBZSO) and TCBZ sulphone (TCBZSO2) are the main molecules recovered in the bloodstream of TCBZ-treated animals. In order to gain some insight into the possible mechanisms of resistance to TCBZ, the goals of the work described here were: to compare the ex vivo transtegumental diffusion of TCBZ parent drug and its sulpho-metabolites (TCBZSO and TCBZSO2) into TCBZ-susceptible and -resistant liver flukes; and to assess the comparative pattern of TCBZ biotransformation by TCBZ-susceptible and -resistant F. hepatica. For the tegumental diffusion studies, TCBZ-susceptible (Cullompton) and -resistant (Sligo) adult flukes collected from untreated infected sheep were incubated (15-180 min) in KRT buffer containing either TCBZ, TCBZSO or TCBZSO2 (5 nmol.ml-1). For the metabolism studies, microsomal fractions obtained from TCBZ-susceptible and -resistant flukes were incubated for 60 min with TCBZ (40 microM), and the amount of the formed metabolic product (TCBZSO) was measured. Drug/metabolite concentrations were quantified by HPLC. All the assayed TCBZ-related molecules penetrated through the tegument of both TCBZ-susceptible and -resistant flukes. However, significantly lower (approximately 50%) concentrations of TCBZ and TCBZSO were recovered within the TCBZ-resistant flukes compared to the TCBZ-susceptible ones over the 180 min incubation period. The rate of TCBZ sulphoxidative metabolism into TCBZSO was significantly higher (39%) in TCBZ-resistant flukes. The flavin-monooxigenase (FMO) enzyme system appears to be the main metabolic pathway involved in the formation of TCBZSO in both TCBZ-susceptible and -resistant flukes. The altered drug influx/efflux and enhanced metabolic capacity identified in TCBZ-resistant liver flukes may account for the development of resistance to TCBZ.
Subject(s)
Anthelmintics/pharmacokinetics , Benzimidazoles/pharmacokinetics , Fasciola hepatica/metabolism , Animals , Anthelmintics/chemistry , Anthelmintics/pharmacology , Benzimidazoles/chemistry , Benzimidazoles/pharmacology , Biotransformation , Cells, Cultured , Diffusion , Drug Resistance , Fasciola hepatica/drug effects , Fascioliasis/drug therapy , Fascioliasis/parasitology , Metabolic Clearance Rate , Parasitic Sensitivity Tests , Sheep , TriclabendazoleABSTRACT
The pharmacological effect of the active albendazole metabolite, albendazole sulphoxide (ABZSO), depends on its sustained presence at the site of parasite location and its binding to helmith beta-tubulin. ABZSO is found in the plasma and tissues of albendazole-treated animals in two enantiomeric forms: (+)ABZSO and (-)ABZSO. Knowledge of enantioselectivity in drug action is necessary, since any difference in target proteins affinity between enantiomers may have implications on the pharmacological effect of this anthelmintic molecule. The binding of ABZSO to mammalian and helminth parasites cytosolic proteins, as well as the differential binding of both enantiomers, were studied. Cytosolic proteins from Moniezia expansa (cestode), Ascaris suum (nematode), Fasciola hepatica (trematode), rat liver and brain as well as purified porcine brain tubulin were used. Drug analysis was performed by HPLC using both C18 and chiral columns. ABZSO protein binding was quantitatively different between parasite species (4.17, 2.5 and 1.07 ng/mg for cestode, nematode and trematode, respectively); this binding to helminth cytosolic proteins was enantioselective. Enantiomeric ratios of (-)ABZSO/(+)ABZSO as a percentage were: 43/57 (Ascaris), 36/64 (Moniezia) and 91/9 (Fasciola). Conversely, the binding of ABZSO to mammalian cytosolic proteins showed no enantioselectivity. The overall binding affinity of ABZSO for mammalian cytosolic proteins was lower than that observed in helminth proteins. The characterization of the comparative binding pattern of ABZSO enantiomers to cytosolic proteins from helminth parasites and mammalian tissues may contribute to understanding the pharmacological properties of this chiral anthelmintic molecule.
Subject(s)
Albendazole/analogs & derivatives , Albendazole/metabolism , Anthelmintics/metabolism , Ascaris suum/metabolism , Cestoda/metabolism , Cytosol/metabolism , Fasciola hepatica/metabolism , Animals , Ascaris suum/isolation & purification , Binding, Competitive , Brain/metabolism , Cattle , Cestoda/isolation & purification , Fasciola hepatica/isolation & purification , Helminthiasis, Animal/parasitology , Liver/metabolism , Rats , Sheep , Sheep Diseases/parasitology , Stereoisomerism , Swine , Swine Diseases/parasitology , Tubulin/metabolismABSTRACT
Albendazole (ABZ) is a broad-spectrum benzimidazole anthelmintic widely used in human and veterinary medicine. The aim of the current work was to characterise the sulphoxidative metabolism of ABZ, and the sulphoreduction of ABZ sulphoxide (ABZSO), by microsomal (Ms) and cytosolic (Cyt) fractions of three different helminth species: Fasciola hepatica, Moniezia expansa and Ascaris suum. After the incubation assays, parasite material was analysed by HPLC to characterise the metabolic product formed. Both the Ms and Cyt fractions of the three parasites studied were able to oxidise ABZ into ABZSO in a non-enantioselective fashion. Oxidation of ABZ was greater in the Ms fraction of the trematode (50%) than in both cestode (19%) and nematode (14%) parasites. Only the incubation of ABZSO with both subcellular fractions of M. expansa generated ABZ as a metabolic product. The results obtained here indicate that helminths have the capacity to biotransform benzimidazole compounds; however, this metabolic activity differs qualitatively and quantitatively among helminth species.
Subject(s)
Albendazole/analogs & derivatives , Albendazole/metabolism , Anthelmintics/metabolism , Ascaris suum/metabolism , Cestoda/metabolism , Fasciola hepatica/metabolism , Animals , Cytosol/metabolism , Helminthiasis, Animal/parasitology , Microsomes/metabolism , Oxidation-Reduction , Sheep , Sheep Diseases/parasitology , Swine , Swine Diseases/parasitologyABSTRACT
The aim of the present work was to evaluate the effects of methimazole (MTZ) on the enantioselective sulphoxidation of albendazole (ABZ) by rat liver microsomes and tissue slices. Albendazole sulphoxide (ABZSO) was the metabolite recovered after the incubation with ABZ in both liver preparations. MTZ significantly reduced ABZSO production both in microsomes and slices. ABZSO production decreased as a function of MTZ concentration. The sulphoxidation reaction performed by rat liver explants in the presence of MTZ was 65% lower than that observed in controls. The reduction in the production of ABZSO in the presence of MTZ was mainly due to a lower production of (+) ABZSO. The results reported further contribute to the understanding of the enantioselective metabolism of ABZ. In addition, the work presented provides information on the comparison of two different liver tissue preparations for the evaluation of xenobiotic metabolism.
Subject(s)
Albendazole/metabolism , Anthelmintics/metabolism , Antithyroid Agents/pharmacology , Liver/metabolism , Methimazole/pharmacology , Sulfoxides/metabolism , Animals , Microsomes, Liver/metabolism , Rats , Rats, Wistar , StereoisomerismABSTRACT
Albendazole (ABZ) is an anthelmintic benzimidazole drug widely used in human and veterinary medicine. ABZ has binding affinity to both mammalian and helminth parasite tubulin. In the current work, we have performed in vitro assays and in vivo experiments in which rats were given ABZ orally to better characterize the action of the drug on the polymerization of rat brain microtubules and on the detyrosination/tyrosination cycle that occurs on the COOH-terminal end of alpha-tubulin. The results showed that ABZ inhibits brain microtubule polymerization in vitro, and significantly delayed microtubule assembly in vivo. The tyrosination reaction cycle was not affected in vitro; however, in rats to which the drug was administered orally, the levels of in vitro tyrosination were reduced when compared to the controls with mock treatment. These results suggest that this apparent inhibition would be due to a decrease in the amount of substrate caused by the depolymerizing effect of ABZ and the subsequent tyrosination in the intact brain with endogenous tyrosine. In conclusion, ABZ strongly affects tubulin dynamics both in vivo and in vitro. The outcome of these experiments is a contribution to the understanding of the molecular mechanisms involved in the antimicrotubular action of benzimidazole compounds.
Subject(s)
Albendazole/pharmacology , Anthelmintics/pharmacology , Brain/cytology , Microtubules/drug effects , Microtubules/metabolism , Tubulin/metabolism , Tyrosine/metabolism , Animals , Brain/drug effects , Rats , Rats, Wistar , Tyrosine/drug effectsABSTRACT
Albendazole (ABZ) is an anthelmintic benzimidazole drug widely used in human and veterinary medicine. ABZ has binding affinity to both mammalian and helminth parasite tubulin. In the current work, we have performed in vitro assays and in vivo experiments in which rats were given ABZ orally to better characterize the action of the drug on the polymerization of rat brain microtubules and on the detyrosination/tyrosination cycle that occurs on the COOH-terminal end of alpha-tubulin. The results showed that ABZ inhibits brain microtubule polymerization in vitro, and significantly delayed microtubule assembly in vivo. The tyrosination reaction cycle was not affected in vitro; however, in rats to which the drug was administered orally, the levels of in vitro tyrosination were reduced when compared to the controls with mock treatment. These results suggest that this apparent inhibition would be due to a decrease in the amount of substrate caused by the depolymerizing effect of ABZ and the subsequent tyrosination in the intact brain with endogenous tyrosine. In conclusion, ABZ strongly affects tubulin dynamics both in vivo and in vitro. The outcome of these experiments is a contribution to the understanding of the molecular mechanisms involved in the antimicrotubular action of benzimidazole compounds.
Subject(s)
Rats , Animals , Humans , Albendazole/pharmacology , Anthelmintics/pharmacology , Brain/cytology , Microtubules/drug effects , Tubulin/metabolism , Tyrosine/metabolism , Brain/drug effects , Microtubules/metabolism , Rats, Wistar , Tyrosine/drug effectsABSTRACT
Albendazole (ABZ) is an anthelmintic benzimidazole drug widely used in human and veterinary medicine. ABZ has binding affinity to both mammalian and helminth parasite tubulin. In the current work, we have performed in vitro assays and in vivo experiments in which rats were given ABZ orally to better characterize the action of the drug on the polymerization of rat brain microtubules and on the detyrosination/tyrosination cycle that occurs on the COOH-terminal end of alpha-tubulin. The results showed that ABZ inhibits brain microtubule polymerization in vitro, and significantly delayed microtubule assembly in vivo. The tyrosination reaction cycle was not affected in vitro; however, in rats to which the drug was administered orally, the levels of in vitro tyrosination were reduced when compared to the controls with mock treatment. These results suggest that this apparent inhibition would be due to a decrease in the amount of substrate caused by the depolymerizing effect of ABZ and the subsequent tyrosination in the intact brain with endogenous tyrosine. In conclusion, ABZ strongly affects tubulin dynamics both in vivo and in vitro. The outcome of these experiments is a contribution to the understanding of the molecular mechanisms involved in the antimicrotubular action of benzimidazole compounds. (AU)
