The potential role of very small embryonic-like stem cells in the neuroinflammation induced by social isolation stress: Introduction of a new paradigm.

Lack of social contacts could induce psychiatric features and lead to various behavioral and neurochemical abnormalities in rodents. Social isolation stress (SIS) is a valid paradigm of depressive- and anxiety-like behaviors in animals. It has demonstrated that psychiatric disorder could affect the peripheral blood population of very small embryonic-like stem cells (VSELs). The aim of the current study is to evaluate the role of VSELs in behavioral impairments induced by SIS through neuroinflammation in mice. Behavioral experiments were evaluated by using forced swimming test (FST), open field test (OFT), and splash test in male NMRI mice. In addition, plasma and bone marrow samples, as well as hippocampus, were collected to evaluate the population of VSELs, nitrite level, and inflammatory cytokines by using flow cytometry and ELISA. Behavioral tasks showed that SIS could induce depressive- and anxiety-like behaviors in mice. Data obtained from flow cytometry showed that VSELs significantly increased in socially isolated animals in bone marrow, peripheral blood, and hippocampus. Also, TNF-α, IL-1ß, and IL-6 significantly increased in hippocampal and plasma samples in socially isolated animals. Correlation analysis indicated that mice with higher VSELs counts have better results in behavioral tasks, and lower pro-inflammatory cytokines as well as nitrite level in mice. In conclusion, VSELs could be used as a biological marker to enhance diagnostic accuracy as well as predicting the prognosis. Also, increment in the VSELs counts might decrease the neuro-inflammation and subsequently improve the behavioral impairments induced by SIS.

The possible role of nitric oxide in anti-convulsant effects of Naltrindole in seizure-induced by social isolation stress in male mice.

Social isolation stress (SIS) as a chronic model of early-life stress could induce proconvulsant effects in mice. In the current study, we evaluated the role of opioid receptors (OPRs) agonists and antagonists in pro-conversant effects of SIS and the common pathway between delta-opioid receptors (DORs) and nitric oxide (NO) in stress-induced seizure. For reaching to this goal, we used pentylenetetrazol (PTZ) model of clonic-seizure to measure seizure threshold and administrated selective and non-selective OPRs agonists and antagonists in both social condition (SC) and isolated condition (IC) animals. In the next step, we administrated sub effective dose of naltrindole (NLT, 0.3 mg/kg) with sub-effective doses of nitric oxide synthesis (NOS) inhibitors including L-NAME (10 mg/kg), aminoguanidine (50 mg/kg) and 7-NI (15 mg/kg). Also, we co-administrated sub-effective dose of SNC80 (0.5 mg/kg) with sub-effective dose of l-arg (25 mg/kg) to assess the seizure threshold. In addition, we measured nitrite levels of hippocampus following administration of mentioned drugs in both SC and IC mice. Our findings showed that L-NAME and 7-NI (but not AG) increased anti-convulsant activity of NLT and l-arg increased proconvulsant effects of SNC80 in IC animals. Nitrite assay showed that co-administration of NLT plus sub-effective doses of L-NAME and 7-NI (but not AG) decreased and co-administration of SNC80 with sub-effective dose of l-arg increased nitrite levels of hippocampus in IC mice. This study suggests the role of n-NOS in anti-convulsant effects of NLT and pro-convulsant effects of SNC80 in stress-induced seizure.

Protective effect of minocycline on LPS-induced mitochondrial dysfunction and decreased seizure threshold through nitric oxide pathway.

Lipopolysaccharide (LPS) increases inflammatory cytokines of the brain and deregulates the mitochondrial function, thus could increase the seizure susceptibility. Studies have shown that minocycline has neuroprotective and antioxidant properties. In this study, we aimed to evaluate the anticonvulsant properties of minocycline in LPS-treated animals and the possible involvement of nitric oxide and mitochondrial pathways. In a PTZ model of seizure in mice, minocycline was administrated to LPS-treated mice. Then followed by co-injection of its sub-effective dose and NOS inhibitors including 7-Nitroindazole (7-NI), aminoguanidine (AG) and L-NG-Nitroarginine methyl ester (L-NAME) to evaluate the changes in seizure threshold and the possible involvement of nitrergic system. Molecular assessments were used to evaluate the effects of each treatment on inflammation and mitochondrial function in the brain. LPS-treated animals had lower seizure threshold compared to intact animals; injection of minocycline (80 mg/kg) to LPS-treated mice reversed this effect. Co-injection of sub-effective doses of minocycline (40 mg/kg) and L-NAME to LPS-treated animals significantly increased seizure threshold. We observed that co-treatment of minocycline and AG dissimilar to 7-NI could increase the seizure threshold of LPS-treated animals. L-arginine reversed the anticonvulsant effect of minocycline. Also, molecular evaluations showed that LPS could increase the ATP levels, GSH levels, and reactive oxygen species formation. However, minocycline at both doses significantly reversed the effect of LPS. Minocycline counteracts the proconvulsant effects of LPS through regulating of mitochondrial function and decreasing of neuro-inflammation. Also, co-administration of minocycline and i-NOS inhibitors could intensify anticonvulsant effects of minocycline.