Modification of substrate specificity of L-arginine oxidase for detection of L-citrulline

Enzymatic detection of citrulline, a potential biomarker for various diseases, is beneficial. However, determining citrulline levels requires expensive instrumental analyses and complicated colorimetric assays. Although L-amino acid oxidase/dehydrogenase is widely used to detect L-amino acids, an L-citrulline-specific oxidase/dehydrogenase has not been reported. Therefore, in this study, we aimed to develop an L-citrulline-specific enzyme by introducing a mutation into L-arginine oxidase (ArgOX) derived from Pseudomonas sp. TPU 7192 to provide a simple enzymatic L-citrulline detection system. The ratio of the oxidase activity against L-arginine to that against L-citrulline (Cit/Arg) was 1.2%, indicating that ArgOX could recognize L-citrulline as a substrate. In the dehydrogenase assay, the specific dehydrogenase activity towards L-arginine was considerably lower than the specific oxidase activity. However, the specific dehydrogenase activity towards L-citrulline was only slightly lower than the oxidase activity, resulting in improved substrate specificity with a Cit/Arg ratio of 49.5%. To enhance the substrate specificity of ArgOX, we performed site-directed mutagenesis using structure-based engineering. The 3D model structure indicated that E486 interacted with the L-arginine side chain. By introducing the E486 mutation, the specific dehydrogenase activity of ArgOX/E486Q for L-citrulline was 3.25 ± 0.50 U/mg, which was 3.8-fold higher than that of ArgOX. The Cit/Arg ratio of ArgOX/E486Q was 150%, which was higher than that of ArgOX. Using ArgOX/E486Q, linear relationships were observed within the range of 10-500 μM L-citrulline, demonstrating its suitability for detecting citrulline in human blood. Consequently, ArgOX/E486Q can be adapted as an enzymatic sensor in the dehydrogenase system.

Characterization and application of l-methionine γ-lyase Q349S mutant enzyme with an enhanced activity toward l-homocysteine

l-Methionine γ-lyse (MGL), a pyridoxal 5'-phosphate-dependent enzyme, catalyzes the α,γ-elimination of l-methionine (l-Met) and l-homocysteine (l-Hcy) to produce α-keto acids, thiols, and ammonia. Previously, various mutant enzymes of Pseudomonas putida MGL (PpMGL) were prepared to identify a homocysteine (Hcy)-specific enzyme that would assist the diagnosis of homocystinuria. Among the mutat enzymes the Q349S mutant exhibited high degradation activity toward l-Hcy. In the present study, PpMGL Q349S was characterized; the results suggested that it could be applied to determine the amount of l-Hcy. Compared to the wild-type PpMGL, specific activities of the Q349S mutant with l-Hcy and l-Met were 1.5 and 0.7 times, respectively. Additionally, we confirmed that l-Hcy in plasma samples could be accurately detected using the Q349S mutant by preincubating it with cysteine desulfurase (CsdA). Furthermore, we determined the X-ray crystal structure of PpMGL Q349S l-Met or l-Hcy complexes Michaelis complex, germinal diamine, and external aldimine at 2.25-2.40 Å. These 3D structures showed that the interaction partner of the β-hydroxyl group of Thr355 in the wild-type PpMGL was changed to the carboxyl group of the Hcy-PLP external aldimine in the Q349S mutant. The interaction of Ser349 and Arg375 was different between l-Met and l-Hcy recognition, indicating that it was important for the recognition of the carboxyl group of the substrate.