Evaluation of neuroprotective effects of insulin on immuno-inflammatory and systemic disorders induced by kaliotoxin, a Kv1.3 channel blocker.

OBJECTIVE: Kaliotoxin2 (KTX2) is a highly selective blocker of voltage-dependent potassium channels Kv1.3 containing 37 amino acid residues. It is purified from Androctonus australis scorpion venom. The binding of KTX2 to its targets is able to alter the neuronal excitability leading to neurological disorders, accompanied by an inflammatory response. In brain, activation of insulin receptor signaling pathway by insulin induces current suppression and concomitant tyrosine phosphorylation of Kv1.3 channel. The aim of this study is to evaluate the effect of insulin injected by i.c.v. route on the neuro-pathophysiological and systemic disorders induced by KTX2. MATERIALS AND METHODS: Tissue damage, inflammatory response and oxidative stress biomarkers were assessed in NMRI mice at 24 h after co-injection of KTX2 and insulin by intracerebroventricular route. RESULTS: Obtained results revealed that the central administration of insulin prevents cerebral cortex injury, brain edema and blood-brain barrier alteration induced by KTX2, these are accompanied by significant decrease of systemic disorders including serum cytokines, inflammatory and oxidative stress markers and tissue damage. CONCLUSION: These results indicate that insulin is able to reduce neuro-immunological effects and systemic disorders induced by KTX2. The neuroprotective effect of insulin may be due to its crucial role in the regulation of inflammation response and its properties to modulate the activity of Kv1.3 channels in brain.

Effect of cytokine antibodies in the immunomodulation of inflammatory response and metabolic disorders induced by scorpion venom.

Androctonus australis hector (Aah) venom and its neurotoxins may affect the neuro-endocrine immunological axis due to their binding to ionic channels of axonal membranes. This binding leads to the release of neurotransmitters and immunological mediators accompanied by pathophysiological effects. Although the hyperglycemia induced by scorpion venom is clearly established, the involved mediators in these deregulations are unknown. The strong relationship between inflammation and the wide variety of physiological processes can suggest that the activation of the inflammatory response and the massive release of IL-6 and TNF-α release induced by the venom may induce hyperglycemia and various biological disorders. We therefore investigated in this study the contribution of IL-6 and TNF-α in the modulation of inflammatory response and metabolic disorder induced by Aah venom. Obtained results revealed that Aah venom induced inflammatory response characterized by significant increase of inflammatory cells in sera and tissues homogenates accompanied by hyperglycemia and hyperinsulinemia, suggesting that the venom induced insulin resistance. It also induced severe alterations in hepatic parenchyma associated to metabolic disorders and imbalanced redox status. Cytokine antagonists injected 30 min prior to Aah venom allowed a significant reduction of inflammatory biomarker and plasma glucose levels, they also prevented metabolic disorders, oxidative stress and hepatic tissue damage induced by Aah venom. In conclusion, IL-6 and TNF-α appear to play a crucial role in the inflammatory response, hyperglycemia and associated complications to glucose metabolism disorders (carbohydrate and fat metabolism disorders, oxidative stress and hepatic damage) observed following scorpion envenoming.

Systemic responses following brain injuries and inflammatory process activation induced by a neurotoxin of Androctonus scorpion venom.

OBJECTIVE: Kaliotoxin 2 (KTX2), a neurotoxin isolated from Androctonus australis hector scorpion venom, presents a high affinity with the voltage-gated potassium channels. The targets of KTX2 in the brain and its toxic effects on the cerebral cortex have been extensively studied; however, its deleterious systemic effects on other organ systems have not yet been investigated. Inflammatory response induced by KTX2 is supported by cytokine release which could provoke multiple organ dysfunction and diverse biological disorders in mammals. The possibility that inflammatory response and brain injuries induced by KTX2 may lead to functional disturbances, e.g. in the pancreas and the liver, were investigated. The contribution of IL-6 and TNF-α to the modulation of pathophysiological effects induced by KTX2 was also tested. METHODS: NMRI mice were injected by the intracerebroventricular route with a sublethal dose of KTX2 or saline solution. Inflammatory response and oxidative stress were assessed in sera and tissue homogenates. Biomarkers of pancreatic and hepatic functions and the correlation with tissue damage in the brain, liver and pancreas were also analyzed. RESULTS: The obtained results revealed that KTX2 injection induced an inflammatory process activation and imbalanced redox status. It also induced severe alterations in cerebral cortex, hepatic and pancreatic tissues associated with a significant increase in pancreatic and hepatic pathological biomarkers. Cytokine antagonists injected 30 min prior to KTX2 led to a significant reduction of all disturbances induced by KTX2. CONCLUSION: In addition to its significant toxicity on the central nervous system, KTX2 can also affect pancreatic and hepatic functions, probably by an indirect mechanism involving activation of the inflammatory response with release of IL-6 and TNF-α.