Lithium attenuates behavioral and biochemical effects of neuropeptide S in mice.

Neuropeptide S (NPS) and its receptor NPSR comprise a recently deorphaned G-protein-coupled receptor system. There is a body of evidence suggesting the involvement of NPS in wakefulness, anxiety, locomotor activity and oxidative stress damage. Considering that mood stabilizers block the stimulatory effect of psychostimulants in rodents, the present study aimed to investigate the effects of the pretreatment with lithium and valproate on the hyperlocomotion evoked by NPS. Another relevant action induced by lithium and valproate is the neuroprotection against oxidative stress. Thus, aiming to get further information about the mechanisms of action of NPS, herein we evaluated the effects of NPS, lithium and valproate, and the combination of them on oxidative stress damage. Behavioral studies revealed that the pretreatment with lithium (100 mg/kg, i.p.) and valproate (200 mg/kg, i.p.) prevented hyperlocomotion evoked by NPS 0.1 nmol. Importantly, the dose of valproate used in this study reduced mouse locomotion, although it did not reach the statistical significance. Biochemical analyses showed that lithium attenuated thiobarbituric reactive species (TBARS) formation in the striatum, cerebellum and hippocampus. NPS per se reduced TBARS levels only in the hippocampus. Valproate did not significantly affect TBARS levels in the brain. However, the combination of mood stabilizers and NPS blocked, instead of potentiate, the neuroprotective effects of each one. No relevant alterations were observed in carbonylated proteins after all treatments. Altogether, the present findings suggested that mainly the mood stabilizer lithium evoked antagonistic effects on the mediation of hyperlocomotion and protection against lipid peroxidation induced by NPS.

Neuropeptide S produces hyperlocomotion and prevents oxidative stress damage in the mouse brain: a comparative study with amphetamine and diazepam.

Neuropeptide S (NPS) is a recently discovered peptide which induces hyperlocomotion, anxiolysis and wakefulness. This study aimed to compare behavioral and biochemical effects of NPS with amphetamine (AMPH), and diazepam (DZP). To this aim, the effects of NPS (0.01, 0.1 and 1 nmol, ICV), AMPH (2 mg/kg, IP) and DZP (1 mg/kg, IP) on locomotion and oxidative stress parameters were assessed in mouse brain structures. The administration of NPS and AMPH, but not DZP, increased locomotion compared to control. Biochemical analyses revealed that AMPH increased carbonylated proteins in striatum, but did not alter lipid peroxidation. DZP increased lipid peroxidation in the cortex and cerebellum, and increased protein carbonyl formation in the striatum. In contrast, NPS reduced carbonylated protein in the cerebellum and striatum, and also lipid peroxidation in the cortex. Additionally, the treatment with AMPH increased superoxide dismutase (SOD) activity in the striatum, while it did not affect catalase (CAT) activity. DZP did not alter SOD and CAT activity. NPS inhibited the increase of SOD activity in the cortex and cerebellum, but little influenced CAT activity. Altogether, this is the first evidence of a putative role of NPS in oxidative stress and brain injury.