Chromatophore organs are complex and unique structures responsible for the variety of body coloration patterns used by cephalopods to communicate and camouflage. They are formed by a pigment-containing cytoelastic sacculus, surrounded by muscle fibers directly innervated from the brain. Muscle contraction and relaxation are responsible for expansion and retraction of the pigment-containing cell. Their functioning depends on glutamate and Phe-Met-Arg-Phe-NH 2 -related peptides, which induce fast and slow cell expansion, respectively, and 5-hydroxytryptamine, which induces retraction. Apart from these three substances and acetylcholine, which acts presynaptically, no other neuroactive compounds have so far been found to be involved in the neuroregulation of chromatophore physiology, and the detailed signaling mechanisms are still little understood. Herein, we disclose the role of nitric oxide (NO) as mediator in one of the signaling pathways by which glutamate activates body patterning. NO and nitric-oxide synthase have been detected in pigment and muscle fibers of embryo, juvenile, and adult chromatophore organs from Sepia officinalis. NO-mediated Sepia chromatophore expansion operates at slower rate than glutamate and involves cGMP, cyclic ADP-ribose, and ryanodine receptor activation. These results demonstrate for the first time that NO is an important messenger in the long term maintenance of the body coloration patterns in Sepia.Chromatophore organ expansion is one of the many mechanisms underlying the multifaceted body patterning that Sepia and other cephalopods display for camouflage, in response to threatening situations, or for courtship (1-3). This mechanism is the result of the coordinated contraction of the radial striated muscle fibers attached to the margins of the chromatophore organs. With expansion, the pigment-containing cytoelastic sacculus is stretched, thus causing the visible color changes that characterize body patterns (4). After the original stimulus has ceased, relaxation of chromatophore muscles results in retraction of sacculus whereby the basal (resting) color pattern is restored (Fig. 1). Apart from extreme contraction/expansion situations, a range of intermediate states is possible as well as rapid mini-contraction/relaxation cycles, like those responsible for the "flickering" behavior, which stand witness to the unique dynamic features of the chromatophore system, which is under direct neural control.The pigment imparts color to the chromatophore organ: yellow, orange, red, brown, or black. The chromatophores of different species differ in color. Thus, for example, Loligo opalescens and Sepia officinalis have only yellow, red, and brown chromatophores, whereas Octopus vulgaris has yellow, orange, red, brown, and black chromatophores (1, 5). It is generally believed that chromatophore pigments are ommochromes, deriving from the oxidation of tryptophan along the kynurenine pathway in which the first and rate-limiting step is the conversion of tryptophan to N-formylkynurenine, catalyze...
