Role of renald-amino-acid oxidase in pharmacokinetics ofd-leucine

Abstract

D-Amino acids are now recognized to be widely present in mammals. Renal d-amino-acid oxidase (DAO) is associated with conversion of d-amino acids to the corresponding α-keto acids, but its contribution in vivo is poorly understood because the α-keto acids and/or l-amino acids formed are indistinguishable from endogenous compounds. First, we examined whether DAO is indispensable for conversion of d-amino acids to their α-keto acids by using the stable isotope tracer technique. After a bolus intravenous administration of d-[²H₇]leucine to mutant mice lacking DAO activity (ddY/DAO⁻) and normal mice (ddY/DAO⁺), elimination of d-[²H₇]leucine and formation of α-[²H₇]ketoisocaproic acid ([²H₇]KIC) and l-[²H₇]leucine in plasma were determined. The ddY/DAO⁻mice, in contrast to ddY/DAO⁺mice, failed to convert d-[²H₇]leucine to [²H₇]KIC and l-[²H₇]leucine. This result clearly revealed that DAO was indispensable for the process of chiral inversion of d-leucine. We further investigated the effect of renal mass reduction by partial nephrectomy on elimination of d-[²H₇]leucine and formation of [²H₇]KIC and l-[²H₇]leucine. Renal mass reduction slowed down the elimination of d-[²H₇]leucine. The fraction of conversion of d-[²H₇]leucine to [²H₇]KIC in sham-operated rats was 0.77, whereas that in five-sixths-nephrectomized rats was 0.25. The elimination behavior of d-[²H₇]leucine observed in rats suggested that kidney was the principal organ responsible for converting d-leucine to KIC.