posted on 2019-03-29, 00:00authored byMary A. Davis, Dustyn A. Barnette, Noah R. Flynn, Anirudh S. Pidugu, S. Joshua Swamidass, Gunnar Boysen, Grover P. Miller
Lamisil (terbinafine)
is an effective, widely prescribed antifungal
drug that causes rare idiosyncratic hepatotoxicity. The proposed toxic
mechanism involves a reactive metabolite, 6,6-dimethyl-2-hepten-4-ynal
(TBF-A), formed through three N-dealkylation pathways. We were the
first to characterize them using in vitro studies
with human liver microsomes and modeling approaches, yet knowledge
of the individual enzymes catalyzing reactions remained unknown. Herein,
we employed experimental and computational tools to assess terbinafine
metabolism by specific cytochrome P450 isozymes. In vitro inhibitor phenotyping studies revealed six isozymes were involved
in one or more N-dealkylation pathways. CYP2C19 and 3A4 contributed
to all pathways, and so, we targeted them for steady-state analyses
with recombinant isozymes. N-Dealkylation yielding TBF-A directly
was catalyzed by CYP2C19 and 3A4 similarly. Nevertheless, CYP2C19
was more efficient than CYP3A4 at N-demethylation and other steps
leading to TBF-A. Unlike microsomal reactions, N-denaphthylation was
surprisingly efficient for CYP2C19 and 3A4, which was validated by
controls. CYP2C19 was the most efficient among all reactions. Nonetheless,
CYP3A4 was more selective at steps leading to TBF-A, making it more
effective in terbinafine bioactivation based on metabolic split ratios
for competing pathways. Model predictions did not extrapolate to quantitative
kinetic constants, yet some results for CYP3A4 and CYP2C19
agreed qualitatively with preferred reaction steps and pathways. Clinical
data on drug interactions support the CYP3A4 role in terbinafine metabolism,
while CYP2C19 remains understudied. Taken together, knowledge of P450s
responsible for terbinafine metabolism and TBF-A formation provides
a foundation for investigating and mitigating the impact of P450 variations
in toxic risks posed to patients.