Reversible oxidation/reduction steps in the metabolic degradation of the glycerol side chain of the S1P1 modulator ponesimod

Abstract

1. Ponesimod is a selective modulator of the sphingosine 1-phosphate receptor 1 (S1P1) approved for the treatment of active relapsing forms of multiple sclerosis. The chemical structure of ponesimod contains a glycerol side chain which is the major target of drug metabolism in humans. 2. The two major metabolic pathways give the acids M12 (-OCH2CH(OH)COOH) and M13 (-OCH2COOH). While the former results from oxidation of the terminal alcohol, the mechanism yielding the chain-shortened acid M13 is less obvious. A detailed mechanistic study with human liver microsomes and hepatocytes using ponesimod, M12 and some of the suspected intermediates revealed an unexpectedly complex pattern of enzyme-mediated and chemical reactions. 3. Metabolic pathways for both acids were not independent and several of the transformations were reversible, depending on reaction conditions. Formation of M13 occurred either via initial oxidation of the secondary alcohol, or as a downstream process starting from M12. 4. The phenol metabolite M32 was produced as part of several pathways. Control experiments at various pH values and in the absence of metabolizing enzymes support the conclusion that its formation resulted from chemical degradation rather than from metabolic processes.