Site-Directed Mutagenesis at the Molybdenum Pterin Cofactor Site of the Human Aldehyde Oxidase: Interrogating the Kinetic Differences Between Human and Cynomolgus Monkey.

The estimation of the drug clearance by aldehyde oxidase (AO) has been complicated because of this enzyme's atypical kinetics and species and substrate specificity. Since human AO (hAO) and cynomolgus monkey AO (mAO) have a 95.1% sequence identity, cynomolgus monkeys may be the best species for estimating AO clearance in humans. Here, O6-benzylguanine (O6BG) and dantrolene were used under anaerobic conditions, as oxidative and reductive substrates of AO, respectively, to compare and contrast the kinetics of these two species through numerical modeling. Whereas dantrolene reduction followed the same linear kinetics in both species, the oxidation rate of O6BG was also linear in mAO and did not follow the already established biphasic kinetics of hAO. In an attempt to determine why hAO and mAO are kinetically distinct, we have altered the hAO V811 and F885 amino acids at the oxidation site adjacent to the molybdenum pterin cofactor to the corresponding alanine and leucine in mAO, respectively. Although some shift to a more monkey-like kinetics was observed for the V811A mutant, five more mutations around the AO cofactors still need to be investigated for this purpose. In comparing the oxidative and reductive rates of metabolism under anaerobic conditions, we have come to the conclusion that despite having similar rates of reduction (4-fold difference), the oxidation rate in mAO is more than 50-fold slower than hAO. This finding implies that the presence of nonlinearity in AO kinetics is dependent upon the degree of imbalance between the rates of oxidation and reduction in this enzyme. SIGNIFICANCE STATEMENT: Although they have as much as 95.1% sequence identity, human and cynomolgus monkey aldehyde oxidase are kinetically distinct. Therefore, monkeys may not be good estimators of drug clearance in humans.

Intestinal absorption of drugs. I: The influence of taurocholate on the absorption of dantrolene in the small intestine of the rat.

The influence of sodium taurocholate (1) on the intestinal absorption of the lipophilic drug dantrolene (2) was studied in vivo in a chronically isolated internal loop in the rat. Concentrations of 2 were kept below the saturation concentration in saline. Absorption kinetics of 2 were evaluated on the basis of steady-state blood levels, which develop during single-pass perfusions, and on the basis of the rate of disappearance of the drug from the perfusate during recirculating perfusions. Compound 1 at a concentration of 10 mM in the perfusate induced a twofold reduction of the absorption rate compared with the same concentration of 2 in saline. Pretreatment of the absorptive surface with a 10 mM solution of 1 had no detectable effect on the absorption rate of 2 in saline. After perfusions with 10 mM solutions of 1, the perfusate concentration of proteins, phosphorus, and hexoses in the effluent was increased. The reduction of the absorption rate can be ascribed mainly to a reduction of the thermodynamically active concentration of 2 as calculated from the phase-separation model. In addition, 10 mM 1 seems to temporarily increase the barrier function of the mucous layer.