Sulphotransferase-dependent dehydration of atropine and scopolamine in guinea pig.

1. Enzymatic dehydration of atropine and scopolamine was studied in guinea pig. 2. The incubation of these alkaloids with guinea pig liver cytosol in the absence of cofactors gave no dehydrated metabolite. However, when atropine and scopolamine were incubated with cytosol supplemented with ATP and sodium sulphate, dehydrated metabolites, apoatropine and aposcopolamine were formed. The formation of these metabolites was confirmed by gas chromatography-mass spectrometry. 3. The reaction required ATP as well as cytosol as the obligatory factors. Deletion of sodium sulphate from the reaction mixture also resulted in a decrease of the activities, although this treatment showed limited effect when the low concentration of atropine was used. Furthermore, dehydroepiandrosterone, an excellent substrate for hydroxysteroid-sulphotransferase, effectively inhibited the in vitro activity of atropine dehydration. 4. Administration of dehydroepiandrosterone to guinea pig followed by atropine treatment caused decreased urinary excretion of apoatropine. 5. These results strongly suggested that the dehydration of atropine and scopolamine takes place via the sulphate conjugate intermediates produced from the sulphotransferase-catalysed reaction. The present finding is the first example of the sulphotransferase-dependent dehydration of a drug, and its generality in drug metabolism is discussed.

Metabolic formation of dimethylamine and methylamine from basic drugs containing N-methyl group: a newly established chromatographic assay and its application to the determination of deaminase activity.

A new method of assaying deaminase activity was established in which methylamine and/or dimethylamine formed from drugs containing N,N-dimethyl or N-methyl group were derivatized with phenylisothiocyanate to phenylthiourea derivatives. After purification with Sep-PAK C18 cartridge, the derivatives were separated by a reversed phase high-performance liquid chromatography monitored by ultraviolet absorption. The recoveries and determination limits of methylamine and dimethylamine were over 55% and about 0.4 nmol/ml of incubation mixture, respectively. The method was used to measure the deaminase activities of liver microsomes of rats, rabbits and guinea pigs for 11 drugs. Of the compounds tested, diphenhydramine and diltiazem are deaminated with microsomes from all the above animal species; rat and rabbit liver microsomes also well deaminated promethazine. Most other drugs such as chlorpromazine, promazine, imipramine, amitriptyline and tetracaine were found to be poor substrates. In general, dimethylamine but not methylamine was the predominant metabolite formed from drugs containing N,N-dimethylamino group. The results also suggested that the deamination of these compounds takes place mainly via a one step mechanism, thus implying that the sequential reaction consisting of N-demethylation and elimination of ammonia is of minor importance. The relation between in vitro deaminase activity and the extent of the in vivo deamination for drugs is discussed.