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Vol. 282, Issue 3, 1269-1279, 1997
Seattle Biomedical Research Institute, Seattle, Washington
The biogenic amine phenethylamine has been shown to be N-oxygenated by
human flavin-containing monooxygenase (FMO) (form 3) and human liver
microsomes and, to a much lesser extent, N-oxygenated by porcine liver
FMO1 and porcine liver microsomes but not by rabbit FMO2. Adult human
liver microsomes catalyze the NADPH-dependent N-oxygenation of
phenethylamine to the corresponding trans-oxime through the
intermediacy of phenethyl hydroxylamine. In addition to
trans-oxime formation, phenethyl hydroxylamine is
retroreduced to phenethylamine in the presence of human or porcine
liver microsomes. Studies on the biochemical mechanism of N-oxygenation
suggested that trans-oxime formation was dependent on the
human FMO (form 3) and that retroreduction was stimulated by superoxide
and dependent on a cytochrome P-450 system. These conclusions are based
on studies examining the effects of incubation conditions on
phenethylamine N-oxygenation and the effect of reactive oxygen species
on phenethyl hydroxylamine retroreduction, respectively. The
pharmacological activity of synthetic phenethyl hydroxylamine and
phenethyl oxime with a number of biogenic amine receptors and
transporters was examined in vitro. In all cases examined,
the affinity of phenethyl hydroxylamine and the corresponding oxime for
a biogenic transporter or receptors was very poor. The results suggest
that the biogenic amine phenethylamine is efficiently sequentially
N-oxygenated in the presence of human liver microsomes or
cDNA-expressed FMO (form 3) to phenethyl hydroxylamine and then to
oximes that are pharmacologically inactive and serve to terminate
biological activity. N-Oxygenation of phenethylamine to the
corresponding trans-oxime is a detoxication process that
abrogates pharmacological activity.
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