Is rat an appropriate animal model to study the involvement of d‐serine catabolism in schizophrenia? insights from characterization of d‐amino acid oxidase

d‐Amino acid oxidase (DAAO; EC1.4.3.3) has been proposed to play a main role in the degradation of d‐serine, an allosteric activator of the N‐methyl‐d‐aspartate‐type glutamate receptor in the human brain, and to be associated with the onset of schizophrenia. To prevent excessive d‐serine degradation, novel drugs for schizophrenia treatment based on DAAO inhibition were designed and tested on rats. However, the properties of rat DAAO are unknown and various in vivo trials have demonstrated the effects of DAAO inhibitors on d‐serine concentration in rats. In the present study, rat DAAO was efficiently expressed in Escherichia coli. The recombinant enzyme was purified as an active, 40 kDa monomeric flavoenzyme showing the basic properties of the dehydrogenase‐oxidase class of flavoproteins. Rat DAAO differs significantly from the human counterpart because: (a) it possesses a different substrate specificity; (b) it shows a lower kinetic efficiency, mainly as a result of a low substrate affinity; (c) it differs in affinity for the binding of classical inhibitors; (d) it is a stable monomer in the absence of an active site ligand; and (e) it interacts with the mammalian protein modulator pLG72 yielding a ∼ 100 kDa complex in addition to the ∼ 200 kDa one, as formed by the human DAAO. Furthermore, the concentration of endogenous d‐serine in U87 glioblastoma cells was not affected by transfection with rat DAAO, whereas it was significantly decreased when expressing the human homologue. These results raise doubt on the use of the rat as a model system for testing new drugs against schizophrenia and indicate a different physiological function of DAAO in rodents and humans. Structured digital • pLG72 binds rDAAO by molecular sieving (View interaction) Novel drugs for schizophrenia treatment based on D‐amino acid oxidase (DAAO) inhibition were designed and tested on rats but the properties of rat DAAO are unknown. We demonstrated that rat DAAO differs from the human counterpart because it possesses a different substrate specificity; shows a lower substrate and ligand affinity; is a stable monomer and binds the modulator pLG72 yielding a different complex