Pierandrea Vinci scite author profile

Excess reactive oxygen species (ROS) generation and inflammation may contribute to obesity-associated skeletal muscle insulin resistance. Ghrelin is a gastric hormone whose unacylated form (UnAG) is associated with whole-body insulin sensitivity in humans and may reduce oxidative stress in nonmuscle cells in vitro. We hypothesized that UnAG 1) lowers muscle ROS production and inflammation and enhances tissue insulin action in lean rats and 2) prevents muscle metabolic alterations and normalizes insulin resistance and hyperglycemia in high-fat diet (HFD)-induced obesity. In 12-week-old lean rats, UnAG (4-day, twice-daily subcutaneous 200-mg injections) reduced gastrocnemius mitochondrial ROS generation and inflammatory cytokines while enhancing AKT-dependent signaling and insulinstimulated glucose uptake. In HFD-treated mice, chronic UnAG overexpression prevented obesity-associated hyperglycemia and whole-body insulin resistance (insulin tolerance test) as well as muscle oxidative stress, inflammation, and altered insulin signaling. In myotubes, UnAG consistently lowered mitochondrial ROS production and enhanced insulin signaling, whereas UnAG effects were prevented by small interfering RNA-mediated silencing of the autophagy mediator ATG5. Thus, UnAG lowers mitochondrial ROS production and inflammation while enhancing insulin action in rodent skeletal muscle. In HFDinduced obesity, these effects prevent hyperglycemia and insulin resistance. Stimulated muscle autophagy could contribute to UnAG activities. These findings support UnAG as a therapeutic strategy for obesity-associated metabolic alterations.Clustered metabolic abnormalities, including excess reactive oxygen species (ROS) generation and inflammation activation, are proposed contributors to the onset of skeletal muscle insulin resistance (1-5). Excess muscle ROS production and inflammation are indeed linked at the level of inhibitor of kB (IkB)/nuclear factor-kB (NF-kB) activation and may cause insulin resistance by inhibiting insulin signaling downstream of insulin receptor (2,3,5). Ghrelin is a peptide hormone predominantly secreted by the stomach, and its acylated form (AG) is a major hypothalamic orexigenic signal (6,7). Sustained AG administration causes weight gain and hyperglycemia despite enhanced muscle mitochondrial oxidative capacity (8,9) by increasing food intake, hepatic gluconeogenesis, and fat deposition in rodents (10,11). A comprehensive understanding of the metabolic impact of ghrelin, however, has recently been allowed by reports of independent, more favorable effects of its unacylated form (UnAG). Although no specific UnAG receptor has yet been identified, UnAG counteracts glucogenic effects of AG as well as

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Ghrelin Enhances in Vivo Skeletal Muscle But Not Liver AKT Signaling in Rats

Barazzoni¹,

Zanetti²,

Cattin³

et al. 2007

Obesity

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BARAZZONI, ROCCO, MICHELA ZANETTI, MARIA ROSA CATTIN, LUCA VISINTIN, PIERANDREA VINCI, LUIGI CATTIN, MARCO STEBEL, AND GIANFRANCO GUARNIERI. Ghrelin enhances in vivo skeletal muscle but not liver AKT signaling in rats. Obesity. 2007;15:2614-2623. Objective: Ghrelin administration can induce fat weight gain and hyperglycemia (potentially through ghrelin-induced hepatic glucose production), but plasma ghrelin is positively associated with whole-body insulin sensitivity (mainly reflecting muscle insulin action) being increased in lean individuals or after diet-induced weight loss and reduced in obesity or after diet-induced weight gain. To investigate potential mechanisms, we measured in vivo effects of sustained ghrelin administration at a non-orexigenic dose on skeletal muscle and liver insulin signaling at the AKT level and adipokine expression changes. Research Methods and Procedures: Young-adult male rats received 4-day, twice daily subcutaneous ghrelin (200 g/ injection) or saline. We measured skeletal muscle (mixed, gastrocnemius; oxidative, soleus) and liver protein levels of activated [phosphorylated (P)] and total (T) AKT and glycogen synthase kinase (GSK; reflecting AKT-dependent GSK inactivation) and epididymal adipose tissue adipokine mRNA. Results: Ghrelin increased body weight (ϩ1.4%) and blood glucose (both p Ͻ 0.05 vs. saline) but not food intake, plasma insulin, or free fatty acids. Ghrelin, however, enhanced P/T/AKT and P/T/GSK ratios and glucose transporter-4 mRNA in soleus (p Ͻ 0.05), but not in gastrocnemius, muscle. In contrast, ghrelin reduced hepatic P/T-AKT and P/T-GSK. No alterations occurred in adiponectin, leptin, or resistin transcripts or plasma adiponectin. Discussion: Despite moderate weight gain and in the absence of insulin-free fatty acid changes, sustained ghrelin administration enhanced oxidative muscle AKT activation. Reduced liver AKT signaling could potentially contribute to concomitant blood glucose increments. These findings support ghrelin as a novel tissue-specific modulator of lean tissue AKT signaling with insulin-sensitizing effects in skeletal muscle but not in liver in vivo.

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Circulating pentraxin 3 levels are higher in metabolic syndrome with subclinical atherosclerosis: evidence for association with atherogenic lipid profile

et al. 2009

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Metabolic syndrome is characterized by increased cardiovascular risk. Pentraxin 3 (PTX3), an acute phase protein, is involved in atherosclerosis. No information is available on PTX3 plasma concentrations in metabolic syndrome and on its associations with metabolic alterations and subclinical atherosclerosis. The aim of this study was to assess PTX3 plasma levels in metabolic syndrome patients compared to control subjects and their potential associations with anthropometric and clinical components of the syndrome as well as with carotid artery intima-media thickness (cIMT), a marker of subclinical atherosclerosis. Plasma was obtained from metabolic syndrome patients (NCEP-ATP III criteria n = 41, 20 M/21F) and by age-matched control subjects (n = 32, 16 M/16F). PTX3 was measured using sandwich ELISA and cIMT with ultrasound. Compared to those of the control subjects, plasma levels of PTX3 were higher (? * 100%, P = 0.0009) in metabolic syndrome patients. In univariate analysis, plasma PTX3 was negatively (P = 0.005) associated with high-density lipoprotein (HDL) cholesterol and positively (P = 0.046) with plasma triglycerides and with cIMT (P = 0.045) in the patients (n = 41). In multivariate analysis the direct association between PTX3 and cIMT was no longer significant after correction for HDL. None of these associations were detected in the control patients. These data demonstrate that PTX3, a novel marker of vascular disease, is higher in patients with metabolic syndrome associated with subclinical atherosclerosis. In addition, PTX3 is significantly independently correlated with low HDL cholesterol, but not with cIMT, suggesting a novel association between PTX3 and atherogenic lipid profile.

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Inverse relationship between “a body shape index” (ABSI) and fat-free mass in women and men: Insights into mechanisms of sarcopenic obesity

et al. 2015

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