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30 results on '"Vettorazzi, Jean F."'

10. Vertical sleeve gastrectomy improves glucose-insulin homeostasis by enhancing β-cell function and survival via FGF15/19.

Author

Soares, Gabriela M., Balbo, Sandra L., Bronczek, Gabriela A., Vettorazzi, Jean F., Marmentini, Carine, Zangerolamo, Lucas, Velloso, Lício A., and Carneiro, Everardo M.

Subjects
HOMEOSTASIS, INSULIN, SLEEVE gastrectomy, FIBROBLAST growth factors, ISLANDS of Langerhans, ENDOPLASMIC reticulum, GENE expression
Abstract

Vertical sleeve gastrectomy (VSG) restores glucose homeostasis in obese mice and humans. In addition, the increased fibroblast growth factor (FGF)15/19 circulating level postsurgery has been implicated in this effect. However, the impact of FGF15/19 on pancreatic islets remains unclear. Using a diet-induced obese mice model, we demonstrate that VSG attenuates insulin hypersecretion in isolated pancreatic islets, likely due to morphological alterations in the endocrine pancreas such as reduction in islet, β-cell, and α-cell mass. In addition, VSG relieves gene expression of endoplasmic reticulum (ER) stress and inflammation markers in islets from obese mice. Incubation of INS-1E β-cells with serum from obese mice induced dysfunction and cell death, whereas these conditions were not induced with serum from obese mice submitted to VSG, implicating the involvement of a humoral factor. Indeed, VSG increased FGF15 circulating levels in obese mice, as well as the expression of FGF receptor 1 (Fgfr1) and its coreceptor β-klotho (Klb), both in pancreatic islets from VSG mice and in INS-1E cells treated with the serum from these mice. Moreover, exposing INS-1E cells to an FGFR inhibitor abolished the effects of VSG serum on insulin secretion and cell death. Also, recombinant FGF19 prevents INS-1E cells from dysfunction and death induced by serum from obese mice. These findings indicate that the amelioration of glucose-insulin homeostasis promoted by VSG is mediated, at least in part, by FGF15/19. Therefore, approaches promoting FGF15/19 release or action may restore pancreatic islet function in obesity. NEW & NOTEWORTHY Vertical sleeve gastrectomy (VSG) decreases insulin secretion, endoplasmic reticulum (ER) stress, and inflammation in pancreatic islets from obese mice. In addition, VSG increased fibroblast growth factor (FGF)15 circulating levels in obese mice, as well as the expression of FGF receptor 1 (Fgfr1) and its coreceptor b-klotho (Klb), both in pancreatic islets from VSG mice and in INS-1E b-cells treated with the serum from these mice. Serum from operated mice protects INS-1E cells from dysfunction and apoptosis, which was mediated by FGF15/19. [ABSTRACT FROM AUTHOR]

Published
2024
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20. Glucose intolerance in monosodium glutamate obesity is linked to hyperglucagonemia and insulin resistance in α cells

Author

Araujo, Thiago R., primary, da Silva, Joel A., additional, Vettorazzi, Jean F., additional, Freitas, Israelle N., additional, Lubaczeuski, Camila, additional, Magalhães, Emily A., additional, Silva, Juliana N., additional, Ribeiro, Elane S., additional, Boschero, Antonio C., additional, Carneiro, Everardo M., additional, Bonfleur, Maria L., additional, and Ribeiro, Rosane Aparecida, additional

Published
2018
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22. Coenzyme Q10 protects against β‐cell toxicity induced by pravastatin treatment of hypercholesterolemia.

Author

Lorza‐Gil, Estela, de Souza, Jane C., García‐Arévalo, Marta, Vettorazzi, Jean F., Marques, Ana Carolina, Salerno, Alessandro G., Trigo, Jose Roberto, and Oliveira, Helena C. F.

Subjects
UBIQUINONES, OXIDATIVE stress, CELL death
Abstract

New onset of diabetes is associated with the use of statins. We have recently demonstrated that pravastatin‐treated hypercholesterolemic LDL receptor knockout (LDLr−/−) mice exhibit reductions in insulin secretion and increased islet cell death and oxidative stress. Here, we hypothesized that these diabetogenic effects of pravastatin could be counteracted by treatment with the antioxidant coenzyme Q 10 (CoQ 10), an intermediate generated in the cholesterol synthesis pathway. LDLr −/− mice were treated with pravastatin and/or CoQ 10 for 2 months. Pravastatin treatment resulted in a 75% decrease of liver CoQ 10 content. Dietary CoQ 10 supplementation of pravastatin‐treated mice reversed fasting hyperglycemia, improved glucose tolerance (20%) and insulin sensitivity (>2‐fold), and fully restored islet glucose‐stimulated insulin secretion impaired by pravastatin (40%). Pravastatin had no effect on insulin secretion of wild‐type mice. In vitro, insulin‐secreting INS1E cells cotreated with CoQ 10 were protected from cell death and oxidative stress induced by pravastatin. Simvastatin and atorvastatin were more potent in inducing dose‐dependent INS1E cell death (10–15‐fold), which were also attenuated by CoQ 10 cotreatment. Together, these results demonstrate that statins impair β‐cell redox balance, function and viability. However, CoQ 10 supplementation can protect the statins detrimental effects on the endocrine pancreas. Statins impair β‐cell redox balance, function, and viability. CoQ10 supplementation can protect the statins detrimental effects on the endocrine pancreas. [ABSTRACT FROM AUTHOR]

Published
2019
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23. Hyperinsulinemia is associated with increasing insulin secretion but not with decreasing insulin clearance in an age‐related metabolic dysfunction mice model.

Author

Kurauti, Mirian A., Ferreira, Sandra M., Soares, Gabriela M., Vettorazzi, Jean F., Carneiro, Everardo M., Boschero, Antonio C., and Costa‐Júnior, José M.

Subjects
HYPERINSULINISM, TYPE 2 diabetes, METABOLIC disorders, INSULINASE, INSULIN resistance
Abstract

Human life expectancy is increasing faster lately and, consequently, the number of patients with age‐related diseases such as type 2 diabetes (T2D) is rising every year. Cases of hyperinsulinemia have been extensively reported in elderly subjects and this alteration in blood insulin concentration is postulated to be a cause of insulin resistance, which in some cases triggers T2D onset. Thus, it is important to know the underlying mechanisms of age‐dependent hyperinsulinemia to find new strategies to prevent T2D in elderly subjects. Two processes control blood insulin concentration: Insulin secretion by the endocrine portion of the pancreas and insulin clearance, which occurs mainly in the liver by the action of the insulin‐degrading enzyme (IDE). Here, we demonstrated that 10‐month‐old mice (old) display increased body and fat pad weight, compared with 3‐month‐old mice (control), and these alterations were accompanied by glucose and insulin intolerance. We also confirm hyperinsulinemia in the old mice, which was related to increased insulin secretion but not to reduced insulin clearance. Although no changes in insulin clearance were observed, IDE activity was lower in the liver of old compared with the control mice. However, this decreased IDE activity was compensated by increased expression of IDE protein in the liver, thus explaining the similar insulin clearance observed in both groups. In conclusion, at the beginning of aging, 10‐month‐old mice do not display any alterations in insulin clearance. Therefore, hyperinsulinemia is initiated primarily due to a higher insulin secretion in the age‐related metabolic dysfunction in mice. Age‐related metabolic dysfunction decreased the activity of the main enzyme responsible for insulin degradation, the insulin‐degrading enzyme (IDE), in the liver of mice. Decreased IDE activity in the liver of these mice is compensated by increased IDE protein expression, which could explain the unchanged insulin clearance. Hyperinsulinemia is initiated primarily by increased insulin secretion but not by decreased insulin clearance in the age‐related metabolic dysfunction in mice. [ABSTRACT FROM AUTHOR]

Published
2019
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24. Glucose intolerance in monosodium glutamate obesity is linked to hyperglucagonemia and insulin resistance in α cells.

Author

Araujo, Thiago R., da Silva, Joel A., Vettorazzi, Jean F., Freitas, Israelle N., Lubaczeuski, Camila, Magalhães, Emily A., Silva, Juliana N., Ribeiro, Elane S., Boschero, Antonio C., Carneiro, Everardo M., Bonfleur, Maria L., and Ribeiro, Rosane Aparecida

Subjects
GLUCOSE intolerance, MONOSODIUM glutamate, OBESITY, INSULIN resistance, CYCLIC-AMP-dependent protein kinase
Abstract

Obesity predisposes to glucose intolerance and type 2 diabetes (T2D). This disease is often characterized by insulin resistance, changes in insulin clearance, and β‐cell dysfunction. However, studies indicate that, for T2D development, disruptions in glucagon physiology also occur. Herein, we investigated the involvement of glucagon in impaired glycemia control in monosodium glutamate (MSG)‐obese mice. Male Swiss mice were subcutaneously injected daily, during the first 5 days after birth, with MSG (4 mg/g body weight [BW]) or saline (1.25 mg/g BW). At 90 days of age, MSG‐obese mice were hyperglycemic, hyperinsulinemic, and hyperglucagonemic and had lost the capacity to increase their insulin/glucagon ratio when transitioning from the fasting to fed state, exacerbating hepatic glucose output. Furthermore, hepatic protein expressions of phosphorylated (p)‐protein kinase A (PKA) and cAMP response element‐binding protein (pCREB), and of phosphoenolpyruvate carboxykinase (PEPCK) enzyme were higher in fed MSG, before and after glucagon stimulation. Increased pPKA and phosphorylated hormone‐sensitive lipase content were also observed in white fat of MSG. MSG islets hypersecreted glucagon in response to 11.1 and 0.5 mmol/L glucose, a phenomenon that persisted in the presence of insulin. Additionally, MSG α cells were hypertrophic displaying increased α‐cell mass and immunoreactivity to phosphorylated mammalian target of rapamycin (pmTOR) protein. Therefore, severe glucose intolerance in MSG‐obese mice was associated with increased hepatic glucose output, in association with hyperglucagonemia, caused by the refractory actions of glucose and insulin in α cells and via an effect that may be due to enhanced mTOR activation. Neonatal treatment with monosodium glutamate (MSG) induces obesity and impaired body glucose control at adulthood in mice. We demonstrated that pancreatic α cells of MSG mice did not suppress glucagon release in response to increased glucose and insulin levels, leading to hyperglucagonemia and the loss of capacity to enhance insulin/glucagon ratio in the fed state. Hyperglucagonemia in turn exacerbates hepatic glucose production, impairing glucose clearance, and homeostasis in MSG mice. Since increased phosphorylated mammalian target of rapamycin (pmTOR) immunoreactivity was detected in MSG α cells, this protein may account for the α‐cell dysfunction, hypertrophy and enlarged mass. Therefore, these data indicate that both β and α cells must be considered for understanding the pathophysiological mechanisms that lead to glucose control disruption in obesity. [ABSTRACT FROM AUTHOR]

Published
2019
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25. Acute Exercise Improves Insulin Clearance and Increases the Expression of Insulin-Degrading Enzyme in the Liver and Skeletal Muscle of Swiss Mice

Author

Kurauti, Mirian A., primary, Freitas-Dias, Ricardo, additional, Ferreira, Sandra M., additional, Vettorazzi, Jean F., additional, Nardelli, Tarlliza R., additional, Araujo, Hygor N., additional, Santos, Gustavo J., additional, Carneiro, Everardo M., additional, Boschero, Antonio C., additional, Rezende, Luiz F., additional, and Costa-Júnior, José M., additional

Published
2016
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26. Benefits of l-alanine or l-arginine supplementation against adiposity and glucose intolerance in monosodium glutamate-induced obesity

Author

Araujo, Thiago R., primary, Freitas, Israelle N., additional, Vettorazzi, Jean F., additional, Batista, Thiago M., additional, Santos-Silva, Junia C., additional, Bonfleur, Maria L., additional, Balbo, Sandra L., additional, Boschero, Antonio C., additional, Carneiro, Everardo M., additional, and Ribeiro, Rosane A., additional

Published
2016
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27. Augmentedβ-Cell Function and Mass in Glucocorticoid-Treated Rodents Are Associated with Increased Islet Ir-β/AKT/mTOR and Decreased AMPK/ACC and AS160 Signaling

Author

Protzek, André O. P., primary, Costa-Júnior, José M., additional, Rezende, Luiz F., additional, Santos, Gustavo J., additional, Araújo, Tiago Gomes, additional, Vettorazzi, Jean F., additional, Ortis, Fernanda, additional, Carneiro, Everardo M., additional, Rafacho, Alex, additional, and Boschero, Antonio C., additional

Published
2014
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28. Augmented β-Cell Function and Mass in Glucocorticoid-Treated Rodents Are Associated with Increased Islet Ir-β/AKT/mTOR and Decreased AMPK/ACC and AS160 Signaling.

Author

Protzek, André O. P., Costa-Júnior, José M., Rezende, Luiz F., Santos, Gustavo J., Araújo, Tiago Gomes, Vettorazzi, Jean F., Ortis, Fernanda, Carneiro, Everardo M., Rafacho, Alex, and Boschero, Antonio C.

Subjects
PROTEIN kinases, GLUCOCORTICOIDS, PHOSPHORYLATION, CELL physiology, MAMMALS
Abstract

Glucocorticoid (GC) therapies may adversely cause insulin resistance (IR) that lead to a compensatory hyperinsulinemia due to insulin hypersecretion. The increased ß-cell function is associated with increased insulin signaling that has the protein kinase B (AKT) substrate with 160 kDa (AS160) as an important downstream AKT effector. In muscle, both insulin and AMP-activated protein kinase (AMPK) signalingphosphorylate and inactivate AS160, which favors the glucose transporter (GLUT)-4 translocation to plasma membrane. Whether AS160 phosphorylation is modulated in islets from GC-treated subjects is unknown. For this, two animal models, Swiss mice and Wistar rats, were treated with dexamethasone (DEX) (1 mg/kg body weight) for 5 consecutive days. DEX treatment induced IR, hyperinsulinemia, and dyslipidemia in both species, but glucose intolerance and hyperglycemia only in rats. DEX treatment caused increased insulin secretion in response to glucose and augmented ß-cell mass in both species that were associated with increased islet content and increased phosphorylation of the AS160 protein. Protein AKT phosphorylation, but not AMPK phosphorylation, was found significantly enhanced in islets from DEX-treated animals. We conclude that the augmented ß-cell function developed in response to the GC-induced IR involves inhibition of the islet AS160 protein activity. [ABSTRACT FROM AUTHOR]

Published
2014
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29. Coenzyme Q 10 protects against β-cell toxicity induced by pravastatin treatment of hypercholesterolemia.

Author

Lorza-Gil E, de Souza JC, García-Arévalo M, Vettorazzi JF, Marques AC, Salerno AG, Trigo JR, and Oliveira HCF

Subjects
Animals, Cell Line, Cell Survival, Diabetes Mellitus chemically induced, Dietary Supplements, Female, Glucose Tolerance Test, Hydrogen Peroxide, Insulin, Liver metabolism, Mice, Mice, Knockout, Pravastatin therapeutic use, Receptors, LDL genetics, Ubiquinone pharmacology, Hypercholesterolemia drug therapy, Insulin-Secreting Cells drug effects, Pravastatin adverse effects, Receptors, LDL metabolism, Ubiquinone analogs & derivatives
Abstract

New onset of diabetes is associated with the use of statins. We have recently demonstrated that pravastatin-treated hypercholesterolemic LDL receptor knockout (LDLr -/- ) mice exhibit reductions in insulin secretion and increased islet cell death and oxidative stress. Here, we hypothesized that these diabetogenic effects of pravastatin could be counteracted by treatment with the antioxidant coenzyme Q 10 (CoQ 10 ), an intermediate generated in the cholesterol synthesis pathway. LDLr -/- mice were treated with pravastatin and/or CoQ 10 for 2 months. Pravastatin treatment resulted in a 75% decrease of liver CoQ 10 content. Dietary CoQ 10 supplementation of pravastatin-treated mice reversed fasting hyperglycemia, improved glucose tolerance (20%) and insulin sensitivity (>2-fold), and fully restored islet glucose-stimulated insulin secretion impaired by pravastatin (40%). Pravastatin had no effect on insulin secretion of wild-type mice. In vitro, insulin-secreting INS1E cells cotreated with CoQ 10 were protected from cell death and oxidative stress induced by pravastatin. Simvastatin and atorvastatin were more potent in inducing dose-dependent INS1E cell death (10-15-fold), which were also attenuated by CoQ 10 cotreatment. Together, these results demonstrate that statins impair β-cell redox balance, function and viability. However, CoQ 10 supplementation can protect the statins detrimental effects on the endocrine pancreas., (© 2018 Wiley Periodicals, Inc.)

Published
2019
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30. Augmented β-Cell Function and Mass in Glucocorticoid-Treated Rodents Are Associated with Increased Islet Ir-β /AKT/mTOR and Decreased AMPK/ACC and AS160 Signaling.

Author

Protzek AO, Costa-Júnior JM, Rezende LF, Santos GJ, Araújo TG, Vettorazzi JF, Ortis F, Carneiro EM, Rafacho A, and Boschero AC

Abstract

Glucocorticoid (GC) therapies may adversely cause insulin resistance (IR) that lead to a compensatory hyperinsulinemia due to insulin hypersecretion. The increased β-cell function is associated with increased insulin signaling that has the protein kinase B (AKT) substrate with 160 kDa (AS160) as an important downstream AKT effector. In muscle, both insulin and AMP-activated protein kinase (AMPK) signaling phosphorylate and inactivate AS160, which favors the glucose transporter (GLUT)-4 translocation to plasma membrane. Whether AS160 phosphorylation is modulated in islets from GC-treated subjects is unknown. For this, two animal models, Swiss mice and Wistar rats, were treated with dexamethasone (DEX) (1 mg/kg body weight) for 5 consecutive days. DEX treatment induced IR, hyperinsulinemia, and dyslipidemia in both species, but glucose intolerance and hyperglycemia only in rats. DEX treatment caused increased insulin secretion in response to glucose and augmented β-cell mass in both species that were associated with increased islet content and increased phosphorylation of the AS160 protein. Protein AKT phosphorylation, but not AMPK phosphorylation, was found significantly enhanced in islets from DEX-treated animals. We conclude that the augmented β-cell function developed in response to the GC-induced IR involves inhibition of the islet AS160 protein activity.

Published
2014
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