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Vol. 53, Issue 6, 999-1008, June 1998
Faculties of Pharmacy (I.G., N.Z., T.C., J.P.U.) and
Medicine
(J.P.U.), University of Toronto, Toronto, Canada, and
Department of
Pharmacy, Children's Mercy Hospital (J.S.L.), Kansas City, Missouri
Covalent binding of a reactive metabolite of clozapine to neutrophils
or their precursors is thought to play a role in the development of
clozapine-induced agranulocytosis. Immunoblotting studies with an
anti-clozapine antiserum detected covalent binding of clozapine to
human neutrophils in vitro when HOCl was used to
generate clozapine reactive metabolite (major clozapine adducts of 31, 49, 58, 78, 86, 126, 160, and 204 kDa). In addition, incubating neutrophils with clozapine and H2O2 (major
clozapine adducts of 49 and 58 kDa) or clozapine,
H2O2, and human myeloperoxidase (major clozapine adducts of 31, 49, 58, and 126 kDa) also resulted in covalent
binding of clozapine to the neutrophils. The covalent binding of
clozapine to neutrophils was inhibited by extracellular glutathione
when HOCl, but not H2O2 was used to generate
reactive metabolite. We found that the antiserum against clozapine also recognized olanzapine, an antipsychotic drug that forms a similar reactive metabolite to clozapine but has not been associated with induction of agranulocytosis. Repeating the in vitro
experiments with olanzapine revealed that the major olanzapine-modified
polypeptides had molecular masses of 96, 130-170, and 218 kDa. Only
relatively low levels of 31, 49, and 58 kDa adducts were observed.
Clozapine-modified polypeptides also were detected in neutrophils from
patients being treated with clozapine. A major 58-kDa
clozapine-modified polypeptide was detected in all patients tested. In
contrast, no drug-modified polypeptides were detected in neutrophils
from patients taking olanzapine. The differences in covalent binding
exhibited by the two compounds and, in particular, the lack of
olanzapine binding to human neutrophils in vivo may help
to explain the difference in toxicity of these two drugs.
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  H. Takakusa, H. Masumoto, H. Yukinaga, C. Makino, S. Nakayama, O. Okazaki, and K. Sudo Covalent Binding and Tissue Distribution/Retention Assessment of Drugs Associated with Idiosyncratic Drug Toxicity Drug Metab. Dispos., September 1, 2008; 36(9): 1770 - 1779. [Abstract] [Full Text] [PDF]
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 D. P. Williams, M. Pirmohamed, D. J. Naisbitt, J. P. Uetrecht, and B. K. Park Induction of Metabolism-Dependent and -Independent Neutrophil Apoptosis by Clozapine Mol. Pharmacol., July 1, 2000; 58(1): 207 - 216. [Abstract] [Full Text]
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W. G. Lai, I. Gardner, N. Zahid, and J. P. Uetrecht Bioactivation and Covalent Binding of Hydroxyfluperlapine in Human Neutrophils: Implications for Fluperlapine-Induced Agranulocytosis Drug Metab. Dispos., March 1, 2000; 28(3): 255 - 263. [Abstract] [Full Text] [PDF]
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I. Gardner, N. Zahid, D. MacCrimmon, and J. P. Uetrecht A Comparison of the Oxidation of Clozapine and Olanzapine to Reactive Metabolites and the Toxicity of these Metabolites to Human Leukocytes Mol. Pharmacol., June 1, 1998; 53(6): 991 - 998. [Abstract] [Full Text]
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