Critical role of the neuronal nitric-oxide synthase heme proximal side residue, Arg418, in catalysis and electron transfer

Design of fast-onset antidepressant by dissociating SERT from nNOS in the DRN

Major depressive disorder (MDD) is one of the most common mental disorders. We designed a fast-onset antidepressant that works by disrupting the interaction between the serotonin transporter (SERT) and neuronal nitric oxide synthase (nNOS) in the dorsal raphe nucleus (DRN). Chronic unpredictable mild stress (CMS) selectively increased the SERT-nNOS complex in the DRN in mice. Augmentation of SERT-nNOS interactions in the DRN caused a depression-like phenotype and accounted for the CMS-induced depressive behaviors. Disrupting the SERT-nNOS interaction produced a fast-onset antidepressant effect by enhancing serotonin signaling in forebrain circuits. We discovered a small-molecule compound, ZZL-7, that elicited an antidepressant effect 2 hours after treatment without undesirable side effects. This compound, or analogous reagents, may serve as a new, rapidly acting treatment for MDD.

Nitric oxide synthase (NOS) in the Japanese fireflies Luciola lateralis and Luciola cruciata

Species-specific flash patterns in firefly species are important for the investigation of the evolution of Lampyridae. Since nitric oxide synthase (NOS) is one of the key enzymes controlling flash patterns, we determined the cDNA sequences of NOS in the Japanese fireflies Luciola lateralis and L. cruciata. The identity of the NOS sequences was very high between these 2 species. Firefly NOS also exhibited a high identity with those of other insect species, and the cofactor-binding domains were particularly well conserved. Many negatively selected sites were detected throughout the NOS sequences; however, no positive selection was detected. The phylogenetic relationship of insect NOS was different from that of the general classification system, although the lineages corresponded to the major recognized taxonomic groups.

Identification of Crucial Histidines Involved in Carbon-Nitrogen Triple Bond Synthesis by Aldoxime Dehydratase

Aldoxime dehydratase (OxdA), which is a novel heme protein, catalyzes the dehydration of an aldoxime to a nitrile even in the presence of water in the reaction mixture. The combination of site-directed mutagenesis of OxdA (mutation of all conserved histidines in the aldoxime dehydratase superfamily), estimation of the heme contents and specific activities of the mutants, and CD and resonance Raman spectroscopic analyses led to the identification of the proximal and distal histidines in this unique enzyme. The heme contents and CD spectra in the far-UV region of all mutants except for the H299A one were almost identical to those of the wild-type OxdA, whereas the H299A mutant lost the ability of binding heme, demonstrating that His(299) is the proximal histidine. On the other hand, substitution of alanine for His(320) did not affect the overall structure of OxdA but caused loss of its ability of carbon-nitrogen triple bond synthesis and a lower shift of the Fe-C stretching band in the resonance Raman spectrum for the CO-bound form. Furthermore, the pH dependence of the wild-type OxdA closely followed the His protonation curves observed for other proteins. These findings suggest that His(320) is located in the distal heme pocket of OxdA and would donate a proton to the substrate in the aldoxime dehydration mechanism.