Liver metabolic reactions: tertiary amine N-dealkylation, tertiary amine N-oxidation, N-oxide reduction, and N-oxide N-dealkylation. II. N,N-dimethylaniline

Rat liver microsomal preparations enzymatically catalyze the N-demethylation and N-oxidation of dimethylaniline as well as the N-demethylation of dimethylaniline-N-oxide. Both compounds were used as substrates and the formation of formaldehyde and N-oxide were determined.Both demethylation and N-oxidation of dimethylaniline are dependent on NADPH. This cofactor also increases the demethylation of dimethylaniline-N-oxide, although it is not an absolute requirement. Nicotinamide increases the rate of formation of formaldehyde and N-oxide from dimethylaniline by a factor of about 4 and decreases the N-oxide demethylation by the same factor. The cofactor optimum consists of NADPH, nicotinamide, and magnesium ions for the demethylation and N-oxidation of dimethylaniline, and of NADPH alone for the demethylation of its N-oxide. The kinetic constants of the three test reactions have been determined under these optimal cofactor requirements.Various agents strongly influence the rates of product formation of the three test reactions studied. SH-blocking agents, the chelating agent EGTA, as well as nicotinamide influence the rates of formaldehyde formation from dimethylaniline and N-oxide demethylation in an opposite way. This demonstrates that, in the tertiary amine demethylation of dimethylaniline, a C-oxidation pathway is operative in addition to an N-oxidation pathway with subsequent N-oxide demethylation. The following influences on the actual metabolic reactions could be deduced from the effects of agents on the test reactions: SKF 525-A inhibits and phenobarbital pretreatment stimulates N-oxide demethylation; EDTA inhibits both the latter reaction and N-oxidation; EGTA and nicotinamide stimulate C-oxidation and inhibit N-oxide demethylation; SH-blocking agents inhibit C-oxidation and stimulate both N-oxidation and N-oxide demethylation.Quantitative and qualitative species differences with respect to cofactor requirement and effect of SKF 525-A have been observed between rat and pig liver microsomes. In addition, profound differences in subcellular localization and metabolic rates between dimethylaniline and other substrates are known. Thus it is unlikely that the three metabolic reactions dealt with in this report are characteristic of tertiarr amine N-dealkylation in general.