Your search keyword '"Scherer, Thomas"' showing total 9 results

1. Binge drinking induces whole-body insulin resistance by impairing hypothalamic insulin action.

Author

Lindtner C, Scherer T, Zielinski E, Filatova N, Fasshauer M, Tonks NK, Puchowicz M, and Buettner C

Subjects

Adipose Tissue drug effects, Adipose Tissue metabolism, Animals, Body Weight drug effects, Female, Glucose metabolism, Glucose Tolerance Test, Homeostasis drug effects, Humans, Hypothalamus metabolism, Inflammation pathology, Liver drug effects, Liver metabolism, Protein Tyrosine Phosphatase, Non-Receptor Type 1 metabolism, Rats, Signal Transduction drug effects, Binge Drinking pathology, Hypothalamus drug effects, Hypothalamus pathology, Insulin pharmacology, Insulin Resistance

Abstract

Individuals with a history of binge drinking have an increased risk of developing the metabolic syndrome and type 2 diabetes. Whether binge drinking impairs glucose homeostasis and insulin action is unknown. To test this, we treated Sprague-Dawley rats daily with alcohol (3 g/kg) for three consecutive days to simulate human binge drinking and found that these rats developed and exhibited insulin resistance even after blood alcohol concentrations had become undetectable. The animals were resistant to insulin for up to 54 hours after the last dose of ethanol, chiefly a result of impaired hepatic and adipose tissue insulin action. Because insulin regulates hepatic glucose production and white adipose tissue lipolysis, in part through signaling in the central nervous system, we tested whether binge drinking impaired brain control of nutrient partitioning. Rats that had consumed alcohol exhibited impaired hypothalamic insulin action, defined as the ability of insulin infused into the mediobasal hypothalamus to suppress hepatic glucose production and white adipose tissue lipolysis. Insulin signaling in the hypothalamus, as assessed by insulin receptor and AKT phosphorylation, decreased after binge drinking. Quantitative polymerase chain reaction showed increased hypothalamic inflammation and expression of protein tyrosine phosphatase 1B (PTP1B), a negative regulator of insulin signaling. Intracerebroventricular infusion of CPT-157633, a small-molecule inhibitor of PTP1B, prevented binge drinking-induced glucose intolerance. These results show that, in rats, binge drinking induces systemic insulin resistance by impairing hypothalamic insulin action and that this effect can be prevented by inhibition of brain PTP1B.

Published

2013

2. Short term voluntary overfeeding disrupts brain insulin control of adipose tissue lipolysis.

Author

Scherer T, Lindtner C, Zielinski E, O'Hare J, Filatova N, and Buettner C

Subjects

Animals, Diabetes Mellitus, Type 2 metabolism, Dietary Fats pharmacology, Glucose metabolism, Glycerol metabolism, Humans, Male, Obesity metabolism, Rats, Rats, Sprague-Dawley, Time Factors, Adipose Tissue, White metabolism, Dietary Fats adverse effects, Energy Intake, Hypothalamus metabolism, Insulin metabolism, Insulin Resistance, Lipolysis drug effects

Abstract

Insulin controls fatty acid (FA) release from white adipose tissue (WAT) through direct effects on adipocytes and indirectly through hypothalamic signaling by reducing sympathetic nervous system outflow to WAT. Uncontrolled FA release from WAT promotes lipotoxicity, which is characterized by inflammation and insulin resistance that leads to and worsens type 2 diabetes. Here we tested whether early diet-induced insulin resistance impairs the ability of hypothalamic insulin to regulate WAT lipolysis and thus contributes to adipose tissue dysfunction. To this end we fed male Sprague-Dawley rats a 10% lard diet (high fat diet (HFD)) for 3 consecutive days, which is known to induce systemic insulin resistance. Rats were studied by euglycemic pancreatic clamps and concomitant infusion of either insulin or vehicle into the mediobasal hypothalamus. Short term HFD feeding led to a 37% increase in caloric intake and elevated base-line free FAs and insulin levels compared with rats fed regular chow. Overfeeding did not impair insulin signaling in WAT, but it abolished the ability of mediobasal hypothalamus insulin to suppress WAT lipolysis and hepatic glucose production as assessed by glycerol and glucose flux. HFD feeding also increased hypothalamic levels of the endocannabinoid 2-arachidonoylglycerol after only 3 days. In summary, overfeeding impairs hypothalamic insulin action, which may contribute to unrestrained lipolysis seen in human obesity and type 2 diabetes.

Published

2012

3. Yin and Yang of hypothalamic insulin and leptin signaling in regulating white adipose tissue metabolism.

Author

Scherer T and Buettner C

Subjects

Homeostasis physiology, Humans, Insulin Resistance physiology, Obesity metabolism, Signal Transduction physiology, Adipose Tissue, White metabolism, Hypothalamus metabolism, Insulin metabolism, Leptin metabolism

Abstract

Fatty acids released from white adipose tissue (WAT) provide important energy substrates during fasting. However, uncontrolled fatty acid release from WAT during non-fasting states causes lipotoxicity and promotes inflammation and insulin resistance, which can lead to and worsen type 2 diabetes (DM2). WAT is also a source for insulin sensitizing fatty acids such as palmitoleate produced during de novo lipogenesis. Insulin and leptin are two major hormonal adiposity signals that control energy homeostasis through signaling in the central nervous system. Both hormones have been implicated to regulate both WAT lipolysis and de novo lipogenesis through the mediobasal hypothalamus (MBH) in an opposing fashion independent of their respective peripheral receptors. Here, we review the current literature on brain leptin and insulin action in regulating WAT metabolism and discuss potential mechanisms and neuro-anatomical substrates that could explain the opposing effects of central leptin and insulin. Finally, we discuss the role of impaired hypothalamic control of WAT metabolism in the pathogenesis of insulin resistance, metabolic inflexibility and type 2 diabetes.

Published

2011

4. Discovery of melanin-concentrating hormone receptor 1 in brown adipose tissue.

Author

Philippe, Cécile, Klebermass, Eva-Maria, Balber, Theresa, Kulterer, Oana C., Zeilinger, Markus, Egger, Gerda, Dumanic, Monika, Herz, Carsten T., Kiefer, Florian W., Scheuba, Christian, Scherer, Thomas, Fürnsinn, Clemens, Vraka, Chrysoula, Pallitsch, Katharina, Spreitzer, Helmut, Wadsak, Wolfgang, Viernstein, Helmut, Hacker, Marcus, and Mitterhauser, Markus

Subjects

BROWN adipose tissue, WESTERN immunoblotting, FAT cells, HYPOTHALAMUS, HOMEOSTASIS

Abstract

Although extensive research on brown adipose tissue (BAT) has stimulated optimism in the battle against obesity and diabetes, BAT physiology and organ crosstalk are not fully understood. Besides BAT, melanin-concentrating hormone (MCH) and its receptor (MCHR1) play an important role in energy homeostasis. Because of the link between hypothalamic MCH neurons and sympathetic BAT activation via ß-adrenoceptors, we investigated the expression and physiological role of the MCHR1 in BAT. MCHR1 was detected in rodent and human BAT with RT-qPCR and western blot analyses. In vivo imaging in rats used the glucose analog [18F]FDG and the MCHR1- tracer [11C]SNAP-7941. We found that the ß3-adrenoceptor (ADRB3) agonist CL316,243 increased [11C]SNAP- 7941 uptake in BAT. Additionally, a pharmacological concentration of SNAP-7941--a low-affinity ADRB3 ligand--stimulated [18F]FDGuptake, reflecting BAT activation. In cultured human adipocytes, CL316,243 inducedMCHR1 expression, further supporting a direct interaction between MCHR1 and ADRB3. These findings characterized MCHR1 expression in rodent and human BAT for the first time, including in vitro and in vivo data demonstrating a link betweenMCHR1 and the ß3-adrenergic system. The presence of MCHR1 in BAT emphasizes the role of BAT in energy homeostasis and may help uncover treatment approaches for obesity. [ABSTRACT FROM AUTHOR]

Published

2021

5. Brain insulin signaling suppresses lipolysis in the absence of peripheral insulin receptors and requires the MAPK pathway.

Author

Metz, Matthäus, O'Hare, James, Cheng, Bob, Puchowicz, Michelle, Buettner, Christoph, and Scherer, Thomas

Abstract

Insulin's ability to counterbalance catecholamine-induced lipolysis defines insulin action in adipose tissue. Insulin suppresses lipolysis directly at the level of the adipocyte and indirectly through signaling in the brain. Here, we further characterized the role of brain insulin signaling in regulating lipolysis and defined the intracellular insulin signaling pathway required for brain insulin to suppress lipolysis. We used hyperinsulinemic clamp studies coupled with tracer dilution techniques to assess insulin's ability to suppress lipolysis in two different mouse models with inducible insulin receptor depletion in all tissues (IRΔWB) or restricted to peripheral tissues excluding the brain (IRΔPER). To identify the underlying signaling pathway required for brain insulin to inhibit lipolysis, we continuously infused insulin +/− a PI3K or MAPK inhibitor into the mediobasal hypothalamus of male Sprague Dawley rats and assessed lipolysis during clamps. Genetic insulin receptor deletion induced marked hyperglycemia and insulin resistance in both IRΔPER and IRΔWB mice. However, the ability of insulin to suppress lipolysis was largely preserved in IRΔPER, but completely obliterated in IRΔWB mice indicating that insulin is still able to suppress lipolysis as long as brain insulin receptors are present. Blocking the MAPK, but not the PI3K pathway impaired the inhibition of lipolysis by brain insulin signaling. Brain insulin is required for insulin to suppress adipose tissue lipolysis and depends on intact hypothalamic MAPK signaling. [Display omitted] • Insulin signaling in the brain is sufficient for suppression of lipolysis. • Hypothalamic MAPK is required for insulin's anti-lipolytic actions. • MAPK inhibition impairs suppression of lipolysis and glucose production. [ABSTRACT FROM AUTHOR]

Published

2023

6. [F]FE@SNAP-a specific PET tracer for melanin-concentrating hormone receptor 1 imaging?

Author

Philippe, Cécile, Haeusler, Daniela, Scherer, Thomas, Fürnsinn, Clemens, Zeilinger, Markus, Wadsak, Wolfgang, Shanab, Karem, Spreitzer, Helmut, Hacker, Marcus, and Mitterhauser, Markus

Subjects

MELANINS, HORMONE receptors, HYPOTHALAMUS, ENDOCRINE diseases, HOMEOSTASIS, AUTORADIOGRAPHY

Abstract

Background: The melanin-concentrating hormone receptor 1 (MCHR1), which is highly expressed in the lateral hypothalamus, plays a key role in energy homeostasis, obesity and other endocrine diseases. Hence, there is a major interest in in vivo imaging of this receptor. A PET tracer would allow non-invasive in vivo visualization and quantification of the MCHR1. The aim of the study was the ex vivo evaluation of the MCHR1 ligand [F]FE@SNAP as a potential PET tracer for the MCHR1. Methods: [F]FE@SNAP was injected directly into the jugular vein of awake naïve rats for ex vivo brain autoradiography, biodistribution and additional blood metabolite analysis. Blocking experiments were conducted using the unlabeled MCHR1 ligand SNAP-7941. Results: A high uptake of [F]FE@SNAP was observed in the lateral hypothalamus and the ventricular system. Both regions were significantly blocked by SNAP-7941. Biodistribution evinced the highest uptake in the kidneys, adrenals, lung and duodenum. Specific blocking with SNAP-7941 led to a significant tracer reduction in the heart and adrenals. In plasma samples, 47.73 ± 6.1 % of a hydrophilic radioactive metabolite was found 45 min after tracer injection. Conclusions: Since [F]FE@SNAP uptake was significantly blocked in the lateral hypothalamus, there is strong evidence that [F]FE@SNAP is a highly suitable agent for specific MCHR1 imaging in the central nervous system. Additionally, this finding is supported by the specific blocking in the ventricular system, where the MCHR1 is expressed in the ependymal cells. These findings suggest that [F]FE@SNAP could serve as a useful imaging and therapy monitoring tool for MCHR1-related pathologies. [ABSTRACT FROM AUTHOR]

Published

2016

7. Brain Insulin Controls Adipose Tissue Lipolysis and Lipogenesis.

Author

Scherer, Thomas, O'Hare, James, Diggs-Andrews, Kelly, Schweiger, Martina, Cheng, Bob, Lindtner, Claudia, Zielinski, Elizabeth, Vempati, Prashant, Su, Kai, Dighe, Shveta, Milsom, Thomas, Puchowicz, Michelle, Scheja, Ludger, Zechner, Rudolf, Fisher, Simon J., Previs, Stephen F., and Buettner, Christoph

Subjects

INSULIN, ADIPOSE tissues, LIPOLYSIS, TYPE 2 diabetes, FATTY acids, INSULIN resistance, HYPOTHALAMUS, LABORATORY mice

Abstract

Summary: White adipose tissue (WAT) dysfunction plays a key role in the pathogenesis of type 2 diabetes (DM2). Unrestrained WAT lipolysis results in increased fatty acid release, leading to insulin resistance and lipotoxicity, while impaired de novo lipogenesis in WAT decreases the synthesis of insulin-sensitizing fatty acid species like palmitoleate. Here, we show that insulin infused into the mediobasal hypothalamus (MBH) of Sprague-Dawley rats increases WAT lipogenic protein expression, inactivates hormone-sensitive lipase (Hsl), and suppresses lipolysis. Conversely, mice that lack the neuronal insulin receptor exhibit unrestrained lipolysis and decreased de novo lipogenesis in WAT. Thus, brain and, in particular, hypothalamic insulin action play a pivotal role in WAT functionality. [ABSTRACT FROM AUTHOR]

Published

2011

8. The dysregulation of the endocannabinoid system in diabesity—a tricky problem.

Author

Scherer, Thomas and Buettner, Christoph

Subjects

*LEPTIN, *ADIPOSE tissues, *HYPOTHALAMUS, *LIPOPROTEIN lipase, *WEIGHT loss, *ENERGY metabolism, *OBESITY

Abstract

Endocannabinoids (ECs) are small lipid mediators that play a critical role in energy metabolism. Human studies have shown that the EC tone in peripheral tissues positively correlates with increased adiposity. Furthermore, pharmacological inhibition of EC signaling results in weight loss in humans. However, the mechanisms that cause the dysregulation of the EC system in obesity are not well-understood. Since the clinical utility of currently available EC blockers is severely limited due to their side effects like depression and suicidal ideation that are caused by central effects, it is important to delineate the role of central and peripheral effects of EC signaling in regulating glucose and lipid metabolism. [ABSTRACT FROM AUTHOR]

Published

2009

9. Cajal revisited: does the VMH make us fat?

Author

Yi, Chun-Xia, Scherer, Thomas, and Tschöp, Matthias H

Subjects

*HYPOTHALAMUS, *OBESITY, *METABOLISM, *INSULIN, *BODY weight

Abstract

The article presents information on a study, according to which the ventromedial nucleus of the hypothalamus (VMH) plays a role in promoting obesity. It is stated that some of the key circuits responsible for nutrient sensing and the control of body metabolism are located in the VMH. Insulin receptor signaling in VMH neuronal subpopulations controls systemic metabolism and represents a key requirement for high-fat diet-induced obesity.

Published

2011