Nutritional regulation of central fat mass and obesity-associated (FTO) expression, and its association with the central melanocortin signaling in the regulation of energy homeostasis

Poritsanos, Nicole Joanna

22 November 2010

The central nervous system (CNS) melanocortin signaling pathway plays a critical role in the regulation of metabolism. However, the regulatory effects of CNS melanocortin signaling on hepatic lipid metabolism and fatty liver disease have not been well established. Although the activity of the CNS melanocortin system is regulated by metabolic signals, the mechanism for this regulation is not fully understood. Variants of the FTO (fat mass and obesity-associated) gene are associated with obesity and FTO is expressed in the hypothalamic neurons including proopiomelanocortin (POMC) neurons. Therefore, it is hypothesized that hypothalamic FTO plays a role in the regulation of metabolism by mediating the effect of metabolic signals on hypothalamic melanocortinergic neurons, and that impairments in this regulation may cause metabolic impairments including obesity and fatty liver disease. Intracerebroventricular (i.c.v.) treatment with SHU9119, a melanocortin antagonist, increased hepatic lipid accumulation and the expression of genes encoding lipogenic enzymes in lean mice. Conversely, i.c.v. treatment with MTII, a melanocortin agonist, reduced the expression of hepatic lipogenic genes in association with reduction in body weight in ob/ob mice, a mouse model of fatty liver disease. Immunohistochemical analysis demonstrated that Fto is co-expressed in both POMC and agouti-related protein (AgRP) neurons in the mouse hypothalamus. Fto mRNA and protein expression was reduced by fasting and increased by glucose treatment in nutritionally important hypothalamic nuclei. Fasting-induced reduction in hypothalamic Fto expression was observed in both lean wild-type and obese ob/ob mice, while the stimulatory effect of glucose on hypothalamic Fto expression was absent in ob/ob mice. These findings support the hypothesis that central melanocortin signaling regulates hepatic lipid metabolism in part by regulating de novo lipogenesis. Impairments in the central melanocortin signaling lead to the development of hepatic steatosis, while enhanced melanocortin signaling may be beneficial in reversing abnormal hepatic lipid metabolism in fatty liver disease (Poritsanos et al., 2008). These findings also support the hypothesis that Fto is expressed in the hypothalamic melanocortinergic neurons and is regulated by metabolic signals involving changes in CNS glucose availability and/or glucose action. Impairments in this regulation may cause metabolic impairments including obesity and fatty liver disease.

Intracerebroventricular

SHU9119

MTII

ob/ob mice

Fto

glucose sensing

melanocortin signaling

AgRP

POMC

de novo lipogenesis

fatty liver

fasting

Hepatic steatosis

Energy homeostasis

Metabolism

Leptin

Insulin

intraperitoneal

Nutritional regulation of central fat mass and obesity-associated (FTO) expression, and its association with the central melanocortin signaling in the regulation of energy homeostasis

Poritsanos, Nicole Joanna

22 November 2010

The central nervous system (CNS) melanocortin signaling pathway plays a critical role in the regulation of metabolism. However, the regulatory effects of CNS melanocortin signaling on hepatic lipid metabolism and fatty liver disease have not been well established. Although the activity of the CNS melanocortin system is regulated by metabolic signals, the mechanism for this regulation is not fully understood. Variants of the FTO (fat mass and obesity-associated) gene are associated with obesity and FTO is expressed in the hypothalamic neurons including proopiomelanocortin (POMC) neurons. Therefore, it is hypothesized that hypothalamic FTO plays a role in the regulation of metabolism by mediating the effect of metabolic signals on hypothalamic melanocortinergic neurons, and that impairments in this regulation may cause metabolic impairments including obesity and fatty liver disease. Intracerebroventricular (i.c.v.) treatment with SHU9119, a melanocortin antagonist, increased hepatic lipid accumulation and the expression of genes encoding lipogenic enzymes in lean mice. Conversely, i.c.v. treatment with MTII, a melanocortin agonist, reduced the expression of hepatic lipogenic genes in association with reduction in body weight in ob/ob mice, a mouse model of fatty liver disease. Immunohistochemical analysis demonstrated that Fto is co-expressed in both POMC and agouti-related protein (AgRP) neurons in the mouse hypothalamus. Fto mRNA and protein expression was reduced by fasting and increased by glucose treatment in nutritionally important hypothalamic nuclei. Fasting-induced reduction in hypothalamic Fto expression was observed in both lean wild-type and obese ob/ob mice, while the stimulatory effect of glucose on hypothalamic Fto expression was absent in ob/ob mice. These findings support the hypothesis that central melanocortin signaling regulates hepatic lipid metabolism in part by regulating de novo lipogenesis. Impairments in the central melanocortin signaling lead to the development of hepatic steatosis, while enhanced melanocortin signaling may be beneficial in reversing abnormal hepatic lipid metabolism in fatty liver disease (Poritsanos et al., 2008). These findings also support the hypothesis that Fto is expressed in the hypothalamic melanocortinergic neurons and is regulated by metabolic signals involving changes in CNS glucose availability and/or glucose action. Impairments in this regulation may cause metabolic impairments including obesity and fatty liver disease.

Intracerebroventricular

SHU9119

MTII

ob/ob mice

Fto

glucose sensing

melanocortin signaling

AgRP

POMC

de novo lipogenesis

fatty liver

fasting

Hepatic steatosis

Energy homeostasis

Metabolism

Leptin

Insulin

intraperitoneal

Oscillatory Ca²⁺ signaling in glucose-stimulated murine pancreatic β-cells : Modulation by amino acids, glucagon, caffeine and ryanodine

Ahmed, Meftun

January 2001

<p>Oscillations in cytoplasmic Ca²⁺ concentration ([Ca²⁺]_i) is the key signal in glucose-stimulated β-cells governing pulsatile insulin release. The glucose response of mouse β-cells is often manifested as slow oscillations and rapid transients of [Ca²⁺]_i. In the present study, microfluorometric technique was used to evaluate the role of amino acids, glucagon, ryanodine and caffeine on the generation and maintenance of [Ca²⁺]_i oscillations and transients in individual murine β-cells and isolated mouse pancreatic islets. The amino acids glycine, alanine and arginine, at around their physiological concentrations, transformed the glucose-induced slow oscillations of [Ca²⁺]_i in isolated mouse β-cells into sustained elevation. Increased Ca²⁺ entry promoted the reappearance of the slow [Ca²⁺]_i oscillations. The [Ca²⁺]_i oscillations were more resistant to amino acid transformation in intact islets, supporting the idea that cellular interactions are important for maintaining the oscillatory activity. Individual rat β-cells responded to glucose stimulation with slow [Ca²⁺]_i oscillations due to periodic entry of Ca²⁺ as well as with transients evoked by mobilization of intracellular stores. The [Ca²⁺]_i oscillations in rat β-cells had a slightly lower frequency than those in mouse β-cells and were more easily transformed into sustained elevation in the presence of glucagon or caffeine. The transients of [Ca²⁺]_i were more common in rat than in mouse β-cells and often appeared in synchrony also in cells lacking physical contact. Depolarization enhanced the generation of [Ca²⁺]_i transients. In accordance with the idea that β-cells have functionally active ryanodine receptors, it was found that ryanodine sometimes restored oscillatory activity abolished by caffeine. However, the IP3 receptors are the major Ca²⁺ release channels both in β-cells from rats and mice. Single β-cells from ob/ob mice did not differ from those of lean controls with regard to frequency, amplitudes and half-widths of the slow [Ca²⁺]_i oscillations. Nevertheless, there was an excessive firing of [Ca²⁺]_i transients in the β-cells from the ob/ob mice, which was suppressed by leptin at close to physiological concentrations. The enhanced firing of [Ca²⁺]_i transients in ob/ob mouse β-cells may be due to the absence of leptin and mediated by activation of the phospholipase C signaling pathway.</p>

Cell biology

pancreatic β-cells

islets of Langerhans

glucose

Ca2+ oscillations

Ca2+ transients

potassium

ryanodine

caffeine

glucagon

cAMP

inositol 1

4

5-trisphosphate

fura-2

glycine

alanine

arginine

Ca2+ channels

rats

lean mice

ob/ob mice

leptin

Cellbiologi

Cell biology

Cellbiologi

Oscillatory Ca2+ signaling in glucose-stimulated murine pancreatic β-cells : Modulation by amino acids, glucagon, caffeine and ryanodine

Ahmed, Meftun

January 2001

Oscillations in cytoplasmic Ca2+ concentration ([Ca2+]i) is the key signal in glucose-stimulated β-cells governing pulsatile insulin release. The glucose response of mouse β-cells is often manifested as slow oscillations and rapid transients of [Ca2+] i. In the present study, microfluorometric technique was used to evaluate the role of amino acids, glucagon, ryanodine and caffeine on the generation and maintenance of [Ca2+] i oscillations and transients in individual murine β-cells and isolated mouse pancreatic islets. The amino acids glycine, alanine and arginine, at around their physiological concentrations, transformed the glucose-induced slow oscillations of [Ca2+] i in isolated mouse β-cells into sustained elevation. Increased Ca2+ entry promoted the reappearance of the slow [Ca2+] i oscillations. The [Ca2+] i oscillations were more resistant to amino acid transformation in intact islets, supporting the idea that cellular interactions are important for maintaining the oscillatory activity. Individual rat β-cells responded to glucose stimulation with slow [Ca2+] i oscillations due to periodic entry of Ca2+ as well as with transients evoked by mobilization of intracellular stores. The [Ca2+] i oscillations in rat β-cells had a slightly lower frequency than those in mouse β-cells and were more easily transformed into sustained elevation in the presence of glucagon or caffeine. The transients of [Ca2+] i were more common in rat than in mouse β-cells and often appeared in synchrony also in cells lacking physical contact. Depolarization enhanced the generation of [Ca2+] i transients. In accordance with the idea that β-cells have functionally active ryanodine receptors, it was found that ryanodine sometimes restored oscillatory activity abolished by caffeine. However, the IP3 receptors are the major Ca2+ release channels both in β-cells from rats and mice. Single β-cells from ob/ob mice did not differ from those of lean controls with regard to frequency, amplitudes and half-widths of the slow [Ca2+] i oscillations. Nevertheless, there was an excessive firing of [Ca2+] i transients in the β-cells from the ob/ob mice, which was suppressed by leptin at close to physiological concentrations. The enhanced firing of [Ca2+] i transients in ob/ob mouse β-cells may be due to the absence of leptin and mediated by activation of the phospholipase C signaling pathway.

Cell biology

pancreatic β-cells

islets of Langerhans

glucose

Ca2+ oscillations

Ca2+ transients

potassium

ryanodine

caffeine

glucagon

cAMP

inositol 1

4

5-trisphosphate

fura-2

glycine

alanine

arginine

Ca2+ channels

rats

lean mice

ob/ob mice

leptin

Cellbiologi

Cell biology

Cellbiologi

Encapsulation of Genetically Modified Preadipocytes for Potential Treatment of Metabolic Disorders

DiSilvestro, David Joel

January 2015

No description available.

Nutrition

Biochemistry

encapsulation

alginate poly-L-lysine

obesity

type 2 diabetes

leptin

obesity therapy

rptor

regulatory associated protein of mTOR

weight loss

nutrition

microcapsule

resistin

thermogenesis

ob ob mice

Aldh1a1

obese gene