M. Boschelle scite author profile

Aims/hypothesis Insulin effects reportedly involve reactive oxygen species (ROS) and oxidative stress in vitro, but skeletal muscle oxidative stress is an emerging negative regulator of insulin action following high-fat feeding. NEFA may enhance oxidative stress and insulin resistance. We investigated the acute impact of insulin with or without NEFA elevation on muscle ROS generation and insulin signalling, and the potential association with altered muscle mitochondrial function. Methods We used hyperinsulinaemic-euglycaemic clamping, 150 min, without or with lipid infusion to modulate plasma NEFA concentration in lean rats. Results Insulin and glucose (Ins) infusion selectively enhanced xanthine oxidase-dependent muscle ROS generation. Ins with lipid infusion (Ins+NEFA) lowered whole-body glucose disposal and muscle insulin signalling, and these effects were associated with high muscle mitochondrial ROS generation and activation of the proinflammatory nuclear factor-κB inhibitor (IκB)-nuclear factor-κB (NFκB) pathway. Antioxidant infusion prevented NEFA-induced systemic insulin resistance and changes in muscle mitochondrial ROS generation, IκB-NFκB pathway and insulin signalling. Changes in insulin sensitivity and signalling were independent of changes in mitochondrial enzyme activity and ATP production, which, in turn, were not impaired by changes in ROS generation under any condition. Conclusions/interpretation Acute muscle insulin effects include enhanced ROS generation through xanthine oxidase. Additional NEFA elevation enhances mitochondrial ROS generation, activates IκB-NFκB and reduces insulin signalling. These alterations are not associated with acute reductions in mitochondrial enzyme activity and ATP production, and are reversed by antioxidant infusion. Thus, NEFA acutely cause systemic and muscle insulin resistance by enhancing muscle oxidative stress through mitochondrial ROS generation and IκB-NFκB activation.

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An Animal Model for the Juvenile Non-Alcoholic Fatty Liver Disease and Non-Alcoholic Steatohepatitis

Marin

Rosso

Ben

et al. 2016

PLoS ONE

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Non Alcoholic Fatty Liver Disease (NAFLD) and Non-Alcoholic Steatohepatitis (NASH) are the hepatic manifestations of the metabolic syndrome; worrisome is the booming increase in pediatric age. To recreate the full spectrum of juvenile liver pathology and investigate the gender impact, male and female C57Bl/6 mice were fed with high fat diet plus fructose in the drinking water (HFHC) immediately after weaning (equal to 3-years old human), and disease progression followed for 16 weeks, until adults (equal to 30-years old human). 100% of subjects of both genders on HFHC diet developed steatosis in 4weeks, and some degree of fibrosis in 8weeks, with the 86% of males and 15% of females presenting a stage 2 fibrosis at 16weeks. Despite a similar final liver damage both groups, a sex difference in the pathology progression was observed. Alterations in glucose homeostasis, dyslipidemia, hepatomegaly and obese phenotype were evident from the very beginning in males with an increased hepatic inflammatory activity. Conversely, such alterations were present in females only at the end of the HFHC diet (with the exception of insulin resistance and the hepatic inflammatory state). Interestingly, only females showed an altered hepatic redox state. This juvenile model appears a good platform to unravel the underlying gender dependent mechanisms in the progression from NAFLD to NASH, and to characterize novel therapeutic approaches.

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Can the interaction between the antimicrobial peptide LL-37 and alginate be exploited for the formulation of new biomaterials with antimicrobial properties?

Toppazzini

Coslovi

Boschelle

et al. 2011

Carbohydrate Polymers

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Op028 the Impact of Insulin-Induced Oxidative Stress on Inflammation and Mitochondrial Oxidative Capacity Is Modulated by Free Fatty Acid Availability in Rat Skeletal Muscle in Vivo

Barazzoni¹,

Zanetti²,

Semolic³

et al. 2010

Clinical Nutrition Supplements

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Pp207-Sun Free Fatty Acids Acutely Enhance Insulin-Induced Oxidative Stress and Cause Insulin Resistance by Increasing Mitochondrial Ros Generation in Rat Skeletal Muscle

Cappellari¹,

Zanetti²,

Semolic³

et al. 2011

Clinical Nutrition Supplements

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M. Boschelle

Fatty acids acutely enhance insulin-induced oxidative stress and cause insulin resistance by increasing mitochondrial reactive oxygen species (ROS) generation and nuclear factor-κB inhibitor (IκB)–nuclear factor-κB (NFκB) activation in rat muscle, in the absence of mitochondrial dysfunction

An Animal Model for the Juvenile Non-Alcoholic Fatty Liver Disease and Non-Alcoholic Steatohepatitis

Can the interaction between the antimicrobial peptide LL-37 and alginate be exploited for the formulation of new biomaterials with antimicrobial properties?

Op028 the Impact of Insulin-Induced Oxidative Stress on Inflammation and Mitochondrial Oxidative Capacity Is Modulated by Free Fatty Acid Availability in Rat Skeletal Muscle in Vivo

Pp207-Sun Free Fatty Acids Acutely Enhance Insulin-Induced Oxidative Stress and Cause Insulin Resistance by Increasing Mitochondrial Ros Generation in Rat Skeletal Muscle

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