Your search keyword '"Wasserman, David H"' showing total 33 results

1. Epoxygenase Cyp2c44 Regulates Hepatic Lipid Metabolism and Insulin Signaling by Controlling FATP2 Localization and Activation of the DAG/PKCδ Axis.

Author

Ghoshal K, Luther JM, Pakala SB, Chetyrkin S, Falck JR, Zent R, Wasserman DH, and Pozzi A

Subjects

Animals, Male, Mice, Cytochrome P-450 Enzyme System metabolism, Cytochrome P-450 Enzyme System genetics, Diet, High-Fat, Epoxide Hydrolases, Insulin Resistance physiology, Mice, Inbred C57BL, Cytochrome P450 Family 2 metabolism, Cytochrome P450 Family 2 genetics, Diglycerides metabolism, Insulin metabolism, Lipid Metabolism physiology, Liver metabolism, Mice, Knockout, Protein Kinase C-delta metabolism, Protein Kinase C-delta genetics, Signal Transduction physiology

Abstract

Cytochrome P450 epoxygenase Cyp2c44, a murine epoxyeicosatrienoic acid (EET)-producing enzyme, promotes insulin sensitivity, and Cyp2c44-/- mice show hepatic insulin resistance. Because insulin resistance leads to hepatic lipid accumulation and hyperlipidemia, we hypothesized that Cyp2c44 regulates hepatic lipid metabolism. Standard chow diet (SCD)-fed male Cyp2c44-/- mice had significantly decreased EET levels and increased hepatic and plasma lipid levels compared with wild-type mice. We showed increased hepatic plasma membrane localization of the FA transporter 2 (FATP2) and total unsaturated fatty acids and diacylglycerol (DAG) levels. Cyp2c44-/- mice had impaired glucose tolerance and increased hepatic plasma membrane-associated PKCδ and phosphorylated IRS-1, two negative regulators of insulin signaling. Surprisingly, SCD and high-fat diet (HFD)-fed Cyp2c44-/- mice had similar glucose tolerance and hepatic plasma membrane PKCδ levels, suggesting that SCD-fed Cyp2c44-/- mice have reached their maximal glucose intolerance. Inhibition of PKCδ resulted in decreased IRS-1 serine phosphorylation and improved insulin-mediated signaling in Cyp2c44-/- hepatocytes. Finally, Cyp2c44-/- HFD-fed mice treated with the analog EET-A showed decreased hepatic plasma membrane FATP2 and PCKδ levels with improved glucose tolerance and insulin signaling. In conclusion, loss of Cyp2c44 with concomitant decreased EET levels leads to increased hepatic FATP2 plasma membrane localization, DAG accumulation, and PKCδ-mediated attenuation of insulin signaling. Thus, Cyp2c44 acts as a regulator of lipid metabolism by linking it to insulin signaling., (© 2024 by the American Diabetes Association.)

Published

2024

2. Pharmacological SERCA activation limits diet-induced steatohepatitis and restores liver metabolic function in mice.

Author

Bednarski TK, Rahim M, Hasenour CM, Banerjee DR, Trenary IA, Wasserman DH, and Young JD

Subjects

Animals, Mice, Male, Fatty Liver metabolism, Fatty Liver pathology, Endoplasmic Reticulum Stress, Mice, Inbred C57BL, Oxidative Stress drug effects, Diet, Western adverse effects, Mice, Knockout, Sarcoplasmic Reticulum Calcium-Transporting ATPases metabolism, Liver metabolism, Liver pathology

Abstract

Metabolic dysfunction-associated steatotic liver disease is the most common form of liver disease and poses significant health risks to patients who progress to metabolic dysfunction-associated steatohepatitis. Fatty acid overload alters endoplasmic reticulum (ER) calcium stores and induces mitochondrial oxidative stress in hepatocytes, leading to hepatocellular inflammation and apoptosis. Obese mice have impaired liver sarco/ER Ca 2+ -ATPase (SERCA) function, which normally maintains intracellular calcium homeostasis by transporting Ca 2+ ions from the cytoplasm to the ER. We hypothesized that restoration of SERCA activity would improve diet-induced steatohepatitis in mice by limiting ER stress and mitochondrial dysfunction. WT and melanocortin-4 receptor KO (Mc4r -/- ) mice were placed on either chow or Western diet (WD) for 8 weeks. Half of the WD-fed mice were administered CDN1163 to activate SERCA, which reduced liver fibrosis and inflammation. SERCA activation also restored glucose tolerance and insulin sensitivity, improved histological markers of metabolic dysfunction-associated steatohepatitis, increased expression of antioxidant enzymes, and decreased expression of oxidative stress and ER stress genes. CDN1163 decreased hepatic citric acid cycle flux and liver pyruvate cycling, enhanced expression of mitochondrial respiratory genes, and shifted hepatocellular [NADH]/[NAD + ] and [NADPH]/[NADP + ] ratios to a less oxidized state, which was associated with elevated PUFA content of liver lipids. In sum, the data demonstrate that pharmacological SERCA activation limits metabolic dysfunction-associated steatotic liver disease progression and prevents metabolic dysfunction induced by WD feeding in mice., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

3. Energy metabolism couples hepatocyte integrin-linked kinase to liver glucoregulation and postabsorptive responses of mice in an age-dependent manner.

Author

Trefts E, Hughey CC, Lantier L, Lark DS, Boyd KL, Pozzi A, Zent R, and Wasserman DH

Subjects

Age Factors, Animals, Cell Differentiation, Cell Respiration, Energy Metabolism, Gene Knockout Techniques, Glucose metabolism, Glucose Tolerance Test, Homeostasis, Inflammation, Liver embryology, Liver pathology, Liver Cirrhosis, Mice, Protein Serine-Threonine Kinases metabolism, Blood Glucose metabolism, Hepatocytes metabolism, Insulin metabolism, Insulin Resistance, Liver metabolism, Obesity metabolism, Protein Serine-Threonine Kinases genetics

Abstract

Integrin-linked kinase (ILK) is a critical intracellular signaling node for integrin receptors. Its role in liver development is complex, as ILK deletion at E10.5 (before hepatocyte differentiation) results in biochemical and morphological differences that resolve as mice age. Nevertheless, mice with ILK depleted specifically in hepatocytes are protected from the hepatic insulin resistance during obesity. Despite the potential importance of hepatocyte ILK to metabolic health, it is unknown how ILK controls hepatic metabolism or glucoregulation. The present study tested the role of ILK in hepatic metabolism and glucoregulation by deleting it specifically in hepatocytes, using a cre-lox system that begins expression at E15.5 (after initiation of hepatocyte differentiation). These mice develop the most severe morphological and glucoregulatory abnormalities at 6 wk, but these gradually resolve with age. After identifying when the deletion of ILK caused a severe metabolic phenotype, in depth studies were performed at this time point to define the metabolic programs that coordinate control of glucoregulation that are regulated by ILK. We show that 6-wk-old ILK-deficient mice have higher glucose tolerance and decreased net glycogen synthesis. Additionally, ILK was shown to be necessary for transcription of mitochondrial-related genes, oxidative metabolism, and maintenance of cellular energy status. Thus, ILK is required for maintaining hepatic transcriptional and metabolic programs that sustain oxidative metabolism, which are required for hepatic maintenance of glucose homeostasis.

Published

2019

4. Metformin reduces liver glucose production by inhibition of fructose-1-6-bisphosphatase.

Author

Hunter RW, Hughey CC, Lantier L, Sundelin EI, Peggie M, Zeqiraj E, Sicheri F, Jessen N, Wasserman DH, and Sakamoto K

Subjects

Adenosine Monophosphate pharmacology, Aminoimidazole Carboxamide analogs & derivatives, Aminoimidazole Carboxamide pharmacology, Animals, Base Sequence, Chickens, Disease Models, Animal, Fructose-Bisphosphatase chemistry, Fructose-Bisphosphatase genetics, Glucose Intolerance pathology, Homeostasis drug effects, Humans, Hypoglycemia pathology, Liver drug effects, Mice, Inbred C57BL, Mutation genetics, Obesity pathology, Prodrugs chemistry, Ribonucleotides pharmacology, Fructose-Bisphosphatase metabolism, Glucose biosynthesis, Liver enzymology, Metformin pharmacology

Abstract

Metformin is a first-line drug for the treatment of individuals with type 2 diabetes, yet its precise mechanism of action remains unclear. Metformin exerts its antihyperglycemic action primarily through lowering hepatic glucose production (HGP). This suppression is thought to be mediated through inhibition of mitochondrial respiratory complex I, and thus elevation of 5'-adenosine monophosphate (AMP) levels and the activation of AMP-activated protein kinase (AMPK), though this proposition has been challenged given results in mice lacking hepatic AMPK. Here we report that the AMP-inhibited enzyme fructose-1,6-bisphosphatase-1 (FBP1), a rate-controlling enzyme in gluconeogenesis, functions as a major contributor to the therapeutic action of metformin. We identified a point mutation in FBP1 that renders it insensitive to AMP while sparing regulation by fructose-2,6-bisphosphate (F-2,6-P 2 ), and knock-in (KI) of this mutant in mice significantly reduces their response to metformin treatment. We observe this during a metformin tolerance test and in a metformin-euglycemic clamp that we have developed. The antihyperglycemic effect of metformin in high-fat diet-fed diabetic FBP1-KI mice was also significantly blunted compared to wild-type controls. Collectively, we show a new mechanism of action for metformin and provide further evidence that molecular targeting of FBP1 can have antihyperglycemic effects.

Published

2018

5. Loss of hepatic AMP-activated protein kinase impedes the rate of glycogenolysis but not gluconeogenic fluxes in exercising mice.

Author

Hughey CC, James FD, Bracy DP, Donahue EP, Young JD, Viollet B, Foretz M, and Wasserman DH

Subjects

AMP-Activated Protein Kinases deficiency, Animals, Energy Metabolism, Gluconeogenesis, Glucose metabolism, Homeostasis, Isotope Labeling, Mice, Mice, Knockout, AMP-Activated Protein Kinases metabolism, Glycogenolysis, Liver enzymology, Physical Conditioning, Animal

Abstract

Pathologies including diabetes and conditions such as exercise place an unusual demand on liver energy metabolism, and this demand induces a state of energy discharge. Hepatic AMP-activated protein kinase (AMPK) has been proposed to inhibit anabolic processes such as gluconeogenesis in response to cellular energy stress. However, both AMPK activation and glucose release from the liver are increased during exercise. Here, we sought to test the role of hepatic AMPK in the regulation of in vivo glucose-producing and citric acid cycle-related fluxes during an acute bout of muscular work. We used 2 H/ 13 C metabolic flux analysis to quantify intermediary metabolism fluxes in both sedentary and treadmill-running mice. Additionally, liver-specific AMPK α1 and α2 subunit KO and WT mice were utilized. Exercise caused an increase in endogenous glucose production, glycogenolysis, and gluconeogenesis from phosphoenolpyruvate. Citric acid cycle fluxes, pyruvate cycling, anaplerosis, and cataplerosis were also elevated during this exercise. Sedentary nutrient fluxes in the postabsorptive state were comparable for the WT and KO mice. However, the increment in the endogenous rate of glucose appearance during exercise was blunted in the KO mice because of a diminished glycogenolytic flux. This lower rate of glycogenolysis was associated with lower hepatic glycogen content before the onset of exercise and prompted a reduction in arterial glucose during exercise. These results indicate that liver AMPKα1α2 is required for maintaining glucose homeostasis during an acute bout of exercise., (© 2017 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2017

6. The liver.

Author

Trefts E, Gannon M, and Wasserman DH

Subjects

Amino Acids metabolism, Animals, Biological Transport, Glucose metabolism, Glycogen metabolism, Hepatic Stellate Cells metabolism, Humans, Kupffer Cells metabolism, Obesity metabolism, Proteins metabolism, Energy Metabolism physiology, Lipid Metabolism physiology, Liver anatomy & histology, Liver metabolism, Liver physiology

Abstract

The liver is a critical hub for numerous physiological processes. These include macronutrient metabolism, blood volume regulation, immune system support, endocrine control of growth signaling pathways, lipid and cholesterol homeostasis, and the breakdown of xenobiotic compounds, including many current drugs. Processing, partitioning, and metabolism of macronutrients provide the energy needed to drive the aforementioned processes and are therefore among the liver's most critical functions. Moreover, the liver's capacities to store glucose in the form of glycogen, with feeding, and assemble glucose via the gluconeogenic pathway, in response to fasting, are critical. The liver oxidizes lipids, but can also package excess lipid for secretion to and storage in other tissues, such as adipose. Finally, the liver is a major handler of protein and amino acid metabolism as it is responsible for the majority of proteins secreted in the blood (whether based on mass or range of unique proteins), the processing of amino acids for energy, and disposal of nitrogenous waste from protein degradation in the form of urea metabolism. Over the course of evolution this array of hepatic functions has been consolidated in a single organ, the liver, which is conserved in all vertebrates. Developmentally, this organ arises as a result of a complex differentiation program that is initiated by exogenous signal gradients, cellular localization cues, and an intricate hierarchy of transcription factors. These processes that are fully developed in the mature liver are imperative for life. Liver failure from any number of sources (e.g. viral infection, overnutrition, or oncologic burden) is a global health problem. The goal of this primer is to concisely summarize hepatic functions with respect to macronutrient metabolism. Introducing concepts critical to liver development, organization, and physiology sets the stage for these functions and serves to orient the reader. It is important to emphasize that insight into hepatic pathologies and potential therapeutic avenues to treat these conditions requires an understanding of the development and physiology of specialized hepatic functions., (Copyright © 2017 Elsevier Ltd. All rights reserved.)

Published

2017

7. Integrin-Linked Kinase Is Necessary for the Development of Diet-Induced Hepatic Insulin Resistance.

Author

Williams AS, Trefts E, Lantier L, Grueter CA, Bracy DP, James FD, Pozzi A, Zent R, and Wasserman DH

Subjects

Animals, Gene Deletion, Glucose Clamp Technique, Mice, Mice, Transgenic, Real-Time Polymerase Chain Reaction, Triglycerides metabolism, Diet, High-Fat, Extracellular Matrix metabolism, Insulin Resistance genetics, Liver metabolism, Protein Serine-Threonine Kinases genetics

Abstract

The liver extracellular matrix (ECM) expands with high-fat (HF) feeding. This finding led us to address whether receptors for the ECM, integrins, are key to the development of diet-induced hepatic insulin resistance. Integrin-linked kinase (ILK) is a downstream integrin signaling molecule involved in multiple hepatic processes, including those related to differentiation, wound healing, and metabolism. We tested the hypothesis that deletion of ILK in mice on an HF diet would disrupt the ECM-integrin signaling axis, thereby preventing the transformation into the insulin-resistant liver. To determine the role of ILK in hepatic insulin action in vivo, male C57BL/6J ILK lox/lox mice were crossed with Albcre mice to produce a hepatocyte-specific ILK deletion (ILK lox/lox Albcre). Results from this study show that hepatic ILK deletion has no effect on insulin action in lean mice but sensitizes the liver to insulin during the challenge of HF feeding. This effect corresponds to changes in the expression and activation of key insulin signaling pathways as well as a greater capacity for hepatic mitochondrial glucose oxidation. This demonstrates that ILK contributes to hepatic insulin resistance and highlights the previously undefined role of integrin signaling in the pathogenesis of diet-induced hepatic insulin resistance., (© 2017 by the American Diabetes Association.)

Published

2017

8. Liver AMP-Activated Protein Kinase Is Unnecessary for Gluconeogenesis but Protects Energy State during Nutrient Deprivation.

Author

Hasenour CM, Ridley DE, James FD, Hughey CC, Donahue EP, Viollet B, Foretz M, Young JD, and Wasserman DH

Subjects

Adenosine Triphosphate metabolism, Animals, Male, Mice, Mice, Inbred C57BL, Mice, Knockout, AMP-Activated Protein Kinases metabolism, Energy Metabolism, Gluconeogenesis, Liver enzymology

Abstract

AMPK is an energy sensor that protects cellular energy state by attenuating anabolic and promoting catabolic processes. AMPK signaling is purported to regulate hepatic gluconeogenesis and substrate oxidation; coordination of these processes is vital during nutrient deprivation or pathogenic during overnutrition. Here we directly test hepatic AMPK function in regulating metabolic fluxes that converge to produce glucose and energy in vivo. Flux analysis was applied in mice with a liver-specific deletion of AMPK (L-KO) or floxed control littermates to assess rates of hepatic glucose producing and citric acid cycle (CAC) fluxes. Fluxes were assessed in short and long term fasted mice; the latter condition is a nutrient stressor that increases liver AMP/ATP. The flux circuit connecting anaplerosis with gluconeogenesis from the CAC was unaffected by hepatic AMPK deletion in short and long term fasting. Nevertheless, depletion of hepatic ATP was exacerbated in L-KO mice, corresponding to a relative elevation in citrate synthase flux and accumulation of branched-chain amino acid-related metabolites. L-KO mice also had a physiological reduction in flux from glycogen to G6P. These results demonstrate AMPK is unnecessary for maintaining gluconeogenic flux from the CAC yet is critical for stabilizing liver energy state during nutrient deprivation., Competing Interests: The authors have declared that no competing interests exist.

Published

2017

9. Mass spectrometry-based microassay of (2)H and (13)C plasma glucose labeling to quantify liver metabolic fluxes in vivo.

Author

Hasenour CM, Wall ML, Ridley DE, Hughey CC, James FD, Wasserman DH, and Young JD

Subjects

Animals, Biological Transport, Blood Glucose chemistry, Carbon Isotopes analysis, Carbon Isotopes pharmacokinetics, Citric Acid Cycle physiology, Deuterium analysis, Glucose metabolism, Liver Glycogen metabolism, Male, Mice, Mice, Inbred C57BL, Blood Glucose metabolism, Deuterium pharmacokinetics, Gas Chromatography-Mass Spectrometry methods, Isotope Labeling methods, Liver metabolism

Abstract

Mouse models designed to examine hepatic metabolism are critical to diabetes and obesity research. Thus, a microscale method to quantitatively assess hepatic glucose and intermediary metabolism in conscious, unrestrained mice was developed. [(13)C3]propionate, [(2)H2]water, and [6,6-(2)H2]glucose isotopes were delivered intravenously in short- (9 h) and long-term-fasted (19 h) C57BL/6J mice. GC-MS and mass isotopomer distribution (MID) analysis were performed on three 40-μl arterial plasma glucose samples obtained during the euglycemic isotopic steady state. Model-based regression of hepatic glucose and citric acid cycle (CAC)-related fluxes was performed using a comprehensive isotopomer model to track carbon and hydrogen atom transitions through the network and thereby simulate the MIDs of measured fragment ions. Glucose-6-phosphate production from glycogen diminished, and endogenous glucose production was exclusively gluconeogenic with prolonged fasting. Gluconeogenic flux from phosphoenolpyruvate (PEP) remained stable, whereas that from glycerol modestly increased from short- to long-term fasting. CAC flux [i.e., citrate synthase (VCS)] was reduced with long-term fasting. Interestingly, anaplerosis and cataplerosis increased with fast duration; accordingly, pyruvate carboxylation and the conversion of oxaloacetate to PEP were severalfold higher than VCS in long-term fasted mice. This method utilizes state-of-the-art in vivo methodology and comprehensive isotopomer modeling to quantify hepatic glucose and intermediary fluxes during physiological stress in mice. The small plasma requirements permit serial sampling without stress and the affirmation of steady-state glucose kinetics. Furthermore, the approach can accommodate a broad range of modeling assumptions, isotope tracers, and measurement inputs without the need to introduce ad hoc mathematical approximations., (Copyright © 2015 the American Physiological Society.)

Published

2015

10. FoxO1 integrates direct and indirect effects of insulin on hepatic glucose production and glucose utilization.

Author

O-Sullivan I, Zhang W, Wasserman DH, Liew CW, Liu J, Paik J, DePinho RA, Stolz DB, Kahn CR, Schwartz MW, and Unterman TG

Subjects

Animals, Forkhead Box Protein O1, Forkhead Transcription Factors genetics, Gene Expression Regulation physiology, Glucose Clamp Technique, Male, Mice, Forkhead Transcription Factors metabolism, Gluconeogenesis physiology, Glucose metabolism, Insulin metabolism, Liver metabolism

Abstract

FoxO proteins are major targets of insulin action. To better define the role of FoxO1 in mediating insulin effects in the liver, we generated liver-specific insulin receptor knockout (LIRKO) and IR/FoxO1 double knockout (LIRFKO) mice. Here we show that LIRKO mice are severely insulin resistant based on glucose, insulin and C-peptide levels, and glucose and insulin tolerance tests, and genetic deletion of hepatic FoxO1 reverses these effects. (13)C-glucose and insulin clamp studies indicate that regulation of both hepatic glucose production (HGP) and glucose utilization is impaired in LIRKO mice, and these defects are also restored in LIRFKO mice corresponding to changes in gene expression. We conclude that (1) inhibition of FoxO1 is critical for both direct (hepatic) and indirect effects of insulin on HGP and utilization, and (2) extrahepatic effects of insulin are sufficient to maintain normal whole-body and hepatic glucose metabolism when liver FoxO1 activity is disrupted.

Published

2015

11. Exercise and the Regulation of Hepatic Metabolism.

Author

Trefts E, Williams AS, and Wasserman DH

Subjects

Animals, Carbon metabolism, Humans, Inactivation, Metabolic, Metabolome, Motor Activity, Exercise physiology, Liver metabolism

Abstract

The accelerated metabolic demands of the working muscle cannot be met without a robust response from the liver. If not for the hepatic response, sustained exercise would be impossible. The liver stores, releases, and recycles potential energy. Exercise would result in hypoglycemia if it were not for the accelerated release of energy as glucose. The energetic demands on the liver are largely met by increased oxidation of fatty acids mobilized from adipose tissue. Adaptations immediately following exercise facilitate the replenishment of glycogen stores. Pancreatic glucagon and insulin responses orchestrate the hepatic response during and immediately following exercise. Like skeletal muscle and other physiological systems, liver adapts to repeated demands of exercise by increasing its capacity to produce energy by oxidizing fat. The ability of regular physical activity to increase fat oxidation is protective and can reverse fatty liver disease. Engaging in regular physical exercise has broad ranging positive health implications including those that improve the metabolic health of the liver., (© 2015 Elsevier Inc. All rights reserved.)

Published

2015

12. 5-Aminoimidazole-4-carboxamide-1-β-D-ribofuranoside (AICAR) effect on glucose production, but not energy metabolism, is independent of hepatic AMPK in vivo.

Author

Hasenour CM, Ridley DE, Hughey CC, James FD, Donahue EP, Shearer J, Viollet B, Foretz M, and Wasserman DH

Subjects

AMP-Activated Protein Kinases genetics, Aminoimidazole Carboxamide pharmacology, Animals, Fatty Acids blood, Glucose genetics, Liver cytology, Mice, Mice, Knockout, Mitochondria, Liver genetics, Mitochondria, Liver metabolism, Oxidative Phosphorylation drug effects, Triglycerides blood, AMP-Activated Protein Kinases metabolism, Aminoimidazole Carboxamide analogs & derivatives, Energy Metabolism, Glucose biosynthesis, Hypoglycemic Agents pharmacology, Liver metabolism, Ribonucleotides pharmacology

Abstract

Metabolic stress, as well as several antidiabetic agents, increases hepatic nucleotide monophosphate (NMP) levels, activates AMP-activated protein kinase (AMPK), and suppresses glucose production. We tested the necessity of hepatic AMPK for the in vivo effects of an acute elevation in NMP on metabolism. 5-Aminoimidazole-4-carboxamide 1-β-D-ribofuranoside (AICAR; 8 mg·kg(-1)·min(-1))-euglycemic clamps were performed to elicit an increase in NMP in wild type (α1α2(lox/lox)) and liver-specific AMPK knock-out mice (α1α2(lox/lox) + Albcre) in the presence of fixed glucose. Glucose kinetics were equivalent in 5-h fasted α1α2(lox/lox) and α1α2(lox/lox) + Albcre mice. AMPK was not required for AICAR-mediated suppression of glucose production and increased glucose disappearance. These results demonstrate that AMPK is unnecessary for normal 5-h fasting glucose kinetics and AICAR-mediated inhibition of glucose production. Moreover, plasma fatty acids and triglycerides also decreased independently of hepatic AMPK during AICAR administration. Although the glucoregulatory effects of AICAR were shown to be independent of AMPK, these studies provide in vivo support for the AMPK energy sensor paradigm. AICAR reduced hepatic energy charge by ∼20% in α1α2(lox/lox), which was exacerbated by ∼2-fold in α1α2(lox/lox) + Albcre. This corresponded to a ∼6-fold rise in AMP/ATP in α1α2(lox/lox) + Albcre. Consistent with the effects on adenine nucleotides, maximal mitochondrial respiration was ∼30% lower in α1α2(lox/lox) + Albcre than α1α2(lox/lox) livers. Mitochondrial oxidative phosphorylation efficiency was reduced by 25%. In summary, these results demonstrate that the NMP capacity to inhibit glucose production in vivo is independent of liver AMPK. In contrast, AMPK promotes mitochondrial function and protects against a more precipitous fall in ATP during AICAR administration.

Published

2014

13. Glucose-6-phosphate-mediated activation of liver glycogen synthase plays a key role in hepatic glycogen synthesis.

Author

von Wilamowitz-Moellendorff A, Hunter RW, García-Rocha M, Kang L, López-Soldado I, Lantier L, Patel K, Peggie MW, Martínez-Pons C, Voss M, Calbó J, Cohen PT, Wasserman DH, Guinovart JJ, and Sakamoto K

Subjects

Animals, Blood Glucose metabolism, Glucose pharmacology, Glycogen Synthase genetics, Hepatocytes drug effects, Homeostasis drug effects, Homeostasis physiology, Insulin pharmacology, Liver drug effects, Mice, Mice, Transgenic, Muscle, Skeletal metabolism, Phosphorylation, Glucose-6-Phosphate metabolism, Glycogen Synthase metabolism, Hepatocytes metabolism, Liver metabolism, Liver Glycogen biosynthesis

Abstract

The liver responds to an increase in blood glucose levels in the postprandial state by uptake of glucose and conversion to glycogen. Liver glycogen synthase (GYS2), a key enzyme in glycogen synthesis, is controlled by a complex interplay between the allosteric activator glucose-6-phosphate (G6P) and reversible phosphorylation through glycogen synthase kinase-3 and the glycogen-associated form of protein phosphatase 1. Here, we initially performed mutagenesis analysis and identified a key residue (Arg(582)) required for activation of GYS2 by G6P. We then used GYS2 Arg(582)Ala knockin (+/R582A) mice in which G6P-mediated GYS2 activation had been profoundly impaired (60-70%), while sparing regulation through reversible phosphorylation. R582A mutant-expressing hepatocytes showed significantly reduced glycogen synthesis with glucose and insulin or glucokinase activator, which resulted in channeling glucose/G6P toward glycolysis and lipid synthesis. GYS2(+/R582A) mice were modestly glucose intolerant and displayed significantly reduced glycogen accumulation with feeding or glucose load in vivo. These data show that G6P-mediated activation of GYS2 plays a key role in controlling glycogen synthesis and hepatic glucose-G6P flux control and thus whole-body glucose homeostasis.

Published

2013

14. Emerging role of AMP-activated protein kinase in endocrine control of metabolism in the liver.

Author

Hasenour CM, Berglund ED, and Wasserman DH

Subjects

AMP-Activated Protein Kinases genetics, Adiponectin genetics, Adiponectin metabolism, Animals, Gene Expression Regulation, Ghrelin genetics, Ghrelin metabolism, Glucagon genetics, Glucagon metabolism, Glucose metabolism, Humans, Insulin genetics, Insulin metabolism, Leptin genetics, Leptin metabolism, Mice, Resistin genetics, Resistin metabolism, Signal Transduction, AMP-Activated Protein Kinases metabolism, Endocrine System physiology, Energy Metabolism physiology, Liver metabolism

Abstract

This review summarizes the emerging role of AMP-activated protein kinase (AMPK) in mediating endocrine regulation of metabolic fluxes in the liver. There are a number of hormones which, when acting on the liver, alter AMPK activation. Here we describe those hormones associated with activation and de-activation of AMPK and the potential mechanisms for changes in AMPK activation state. The actions of these hormones, in many cases, are consistent with downstream effects of AMPK signaling thus strengthening the circumstantial case for AMPK-mediated hormone action. In recent years, genetic mouse models have also been used in an attempt to establish the role of AMPK in hormone-stimulated metabolism in the liver. Few experiments have, however, firmly established a causal relationship between hormone action at the liver and AMPK signaling., (Copyright © 2012 Elsevier Ireland Ltd. All rights reserved.)

Published

2013

15. Hepatic glucagon action is essential for exercise-induced reversal of mouse fatty liver.

Author

Berglund ED, Lustig DG, Baheza RA, Hasenour CM, Lee-Young RS, Donahue EP, Lynes SE, Swift LL, Charron MJ, Damon BM, and Wasserman DH

Subjects

Animals, Body Weight, Dietary Fats adverse effects, Disease Progression, Fatty Liver pathology, Lipid Metabolism, Liver pathology, Magnetic Resonance Imaging, Male, Mice, Mice, Inbred C57BL, Mice, Knockout, Receptors, Glucagon genetics, Signal Transduction, Fatty Liver metabolism, Fatty Liver therapy, Glucagon metabolism, Liver metabolism, Motor Activity, Receptors, Glucagon metabolism

Abstract

Objective: Exercise is an effective intervention to treat fatty liver. However, the mechanism(s) that underlie exercise-induced reductions in fatty liver are unclear. Here we tested the hypothesis that exercise requires hepatic glucagon action to reduce fatty liver., Research Design and Methods: C57BL/6 mice were fed high-fat diet (HFD) and assessed using magnetic resonance, biochemical, and histological techniques to establish a timeline for fatty liver development over 20 weeks. Glucagon receptor null (gcgr(-/-)) and wild-type (gcgr(+/+)) littermate mice were subsequently fed HFD to provoke moderate fatty liver and then performed either 10 or 6 weeks of running wheel or treadmill exercise, respectively., Results: Exercise reverses progression of HFD-induced fatty liver in gcgr(+/+) mice. Remarkably, such changes are absent in gcgr(-/-) mice, thus confirming the hypothesis that exercise-stimulated hepatic glucagon receptor activation is critical to reduce HFD-induced fatty liver., Conclusions: These findings suggest that therapies that use antagonism of hepatic glucagon action to reduce blood glucose may interfere with the ability of exercise and perhaps other interventions to positively affect fatty liver.

Published

2011

16. Glucagon and lipid interactions in the regulation of hepatic AMPK signaling and expression of PPARalpha and FGF21 transcripts in vivo.

Author

Berglund ED, Kang L, Lee-Young RS, Hasenour CM, Lustig DG, Lynes SE, Donahue EP, Swift LL, Charron MJ, and Wasserman DH

Subjects

Adenylate Kinase genetics, Animals, Area Under Curve, Blood Glucose metabolism, Catecholamines blood, Fatty Acids, Nonesterified blood, Female, Fibroblast Growth Factors genetics, Fibroblast Growth Factors metabolism, Glucose Clamp Technique, Insulin blood, Liver enzymology, Male, Mice, Mice, Inbred C57BL, Mice, Knockout, PPAR alpha genetics, PPAR alpha metabolism, Physical Conditioning, Animal physiology, RNA, Messenger biosynthesis, RNA, Messenger genetics, Receptors, Glucagon metabolism, Reverse Transcriptase Polymerase Chain Reaction, Signal Transduction, Adenylate Kinase metabolism, Fat Emulsions, Intravenous metabolism, Fibroblast Growth Factors biosynthesis, Glucagon metabolism, Liver metabolism, PPAR alpha biosynthesis

Abstract

Hepatic glucagon action increases in response to accelerated metabolic demands and is associated with increased whole body substrate availability, including circulating lipids. The hypothesis that increases in hepatic glucagon action stimulate AMP-activated protein kinase (AMPK) signaling and peroxisome proliferator-activated receptor-α (PPARα) and fibroblast growth factor 21 (FGF21) expression in a manner modulated by fatty acids was tested in vivo. Wild-type (gcgr(+/+)) and glucagon receptor-null (gcgr(-/-)) littermate mice were studied using an 18-h fast, exercise, and hyperglucagonemic-euglycemic clamps plus or minus increased circulating lipids. Fasting and exercise in gcgr(+/+), but not gcgr(-/-) mice, increased hepatic phosphorylated AMPKα at threonine 172 (p-AMPK(Thr(172))) and PPARα and FGF21 mRNA. Clamp results in gcgr(+/+) mice demonstrate that hyperlipidemia does not independently impact or modify glucagon-stimulated increases in hepatic AMP/ATP, p-AMPK(Thr(172)), or PPARα and FGF21 mRNA. It blunted glucagon-stimulated acetyl-CoA carboxylase phosphorylation, a downstream target of AMPK, and accentuated PPARα and FGF21 expression. All effects were absent in gcgr(-/-) mice. These findings demonstrate that glucagon exerts a critical regulatory role in liver to stimulate pathways linked to lipid metabolism in vivo and shows for the first time that effects of glucagon on PPARα and FGF21 expression are amplified by a physiological increase in circulating lipids.

Published

2010

17. Fibroblast growth factor 21 controls glycemia via regulation of hepatic glucose flux and insulin sensitivity.

Author

Berglund ED, Li CY, Bina HA, Lynes SE, Michael MD, Shanafelt AB, Kharitonenkov A, and Wasserman DH

Subjects

Animals, Fasting, Glucagon metabolism, Liver drug effects, Liver Glycogen metabolism, Male, Mice, Mice, Obese, Blood Glucose metabolism, Fibroblast Growth Factors physiology, Insulin Resistance physiology, Liver metabolism

Abstract

Fibroblast growth factor 21 (FGF21) is a novel metabolic regulator shown to improve glycemic control. However, the molecular and functional mechanisms underlying FGF21-mediated improvements in glycemic control are not completely understood. We examined FGF21 effects on insulin sensitivity and glucose fluxes upon chronic (daily injection for 8 d) and acute (6 h infusion) administration in ob/+ and ob/ob mice. Results show that chronic FGF21 ameliorated fasting hyperglycemia in ob/ob mice via increased glucose disposal and improved hepatic insulin sensitivity. Acute FGF21 suppressed hepatic glucose production, increased liver glycogen, lowered glucagon, and improved glucose clearance in ob/+ mice. These effects were blunted in ob/ob mice. Neither chronic nor acute FGF21 altered skeletal muscle or adipose tissue glucose uptake in either genotype. In conclusion, FGF21 has potent glycemic effects caused by hepatic changes in glucose flux and improved insulin sensitivity. Thus, these studies define mechanisms underlying anti-hyperglycemic actions of FGF21 and support its therapeutic potential.

Published

2009

18. Hepatic energy state is regulated by glucagon receptor signaling in mice.

Author

Berglund ED, Lee-Young RS, Lustig DG, Lynes SE, Donahue EP, Camacho RC, Meredith ME, Magnuson MA, Charron MJ, and Wasserman DH

Subjects

Adenosine Diphosphate analysis, Adenosine Monophosphate analysis, Adenosine Triphosphate analysis, Animals, Glucagon physiology, Male, Mice, Mice, Inbred C57BL, Phosphoenolpyruvate Carboxykinase (GTP) metabolism, Energy Metabolism, Liver metabolism, Receptors, Glucagon physiology, Signal Transduction physiology

Abstract

The hepatic energy state, defined by adenine nucleotide levels, couples metabolic pathways with energy requirements. This coupling is fundamental in the adaptive response to many conditions and is impaired in metabolic disease. We have found that the hepatic energy state is substantially reduced following exercise, fasting, and exposure to other metabolic stressors in C57BL/6 mice. Glucagon receptor signaling was hypothesized to mediate this reduction because increased plasma levels of glucagon are characteristic of metabolic stress and because this hormone stimulates energy consumption linked to increased gluconeogenic flux through cytosolic phosphoenolpyruvate carboxykinase (PEPCK-C) and associated pathways. We developed what we believe to be a novel hyperglucagonemic-euglycemic clamp to isolate an increment in glucagon levels while maintaining fasting glucose and insulin. Metabolic stress and a physiological rise in glucagon lowered the hepatic energy state and amplified AMP-activated protein kinase signaling in control mice, but these changes were abolished in glucagon receptor- null mice and mice with liver-specific PEPCK-C deletion. 129X1/Sv mice, which do not mount a glucagon response to hypoglycemia, displayed an increased hepatic energy state compared with C57BL/6 mice in which glucagon was elevated. Taken together, these data demonstrate in vivo that the hepatic energy state is sensitive to glucagon receptor activation and requires PEPCK-C, thus providing new insights into liver metabolism.

Published

2009

19. Energy state of the liver during short-term and exhaustive exercise in C57BL/6J mice.

Author

Camacho RC, Donahue EP, James FD, Berglund ED, and Wasserman DH

Subjects

AMP-Activated Protein Kinase Kinases, Adenosine Diphosphate metabolism, Adenosine Triphosphate metabolism, Animals, Energy Metabolism, Glucagon metabolism, Liver enzymology, Male, Mice, Mice, Inbred C57BL, Muscle, Skeletal metabolism, Phosphorylation, Protein Kinases metabolism, Adenosine Monophosphate metabolism, Liver metabolism, Physical Exertion physiology

Abstract

A portal venous 5-aminoimidazole-4-carboxamide-1-beta-D-ribofuranoside infusion that results in hepatic 5-aminoimidazole-4-carboxamide-1-beta-D-ribosyl-5-monophosphate (ZMP) concentrations of approximately 4 micromol/g liver increases hepatic glycogenolysis and glucose output. ZMP is an AMP analog that mimics the regulatory actions of this nucleotide. The aim of this study was to measure hepatic AMP concentrations in response to increasing energy requirements to test the hypothesis that AMP achieves concentrations during exercise, consistent with a role in stimulation of hepatic glucose metabolism. Male C57BL/6J mice (27.4+/- 0.4 g) were subjected to 35 min of rest [sedentary (SED), n=8], underwent short-term (ST, 35 min) moderate (20 m/min, 5% grade) exercise (n=8), or underwent treadmill exercise under similar conditions but until exhaustion (EXH, n=8). Hepatic AMP concentrations were 0.82+/- 0.05, 1.17+/- 0.11, and 2.52+/- 0.16 micromol/g liver in SED, ST, and EXH mice, respectively (P< 0.05). Hepatic energy charge was 0.66+/- 0.01, 0.58+/- 0.02, and 0.33+/- 0.22 in SED, ST, and EXH mice, respectively (P< 0.05). Hepatic glycogen was 11.6+/- 1.0, 8.8+/- 2.2, and 0.0+/- 0.1 mg/g liver in SED, ST, and EXH mice, respectively (P< 0.05). Hepatic AMPK (Thr(172)) phosphorylation was 1.00+/- 0.14, 1.96+/- 0.16, and 7.44+/- 0.63 arbitrary units in SED, ST, and EXH mice, respectively (P< 0.05). Thus exercise increases hepatic AMP concentrations. These data suggest that the liver is highly sensitive to metabolic demands, as evidenced by dramatic changes in cellular energy indicators (AMP) and sensors thereof (AMP-activated protein kinase). In conclusion, AMP is sensitively regulated, consistent with it having an important role in hepatic metabolism.

Published

2006

20. 5-Aminoimidazole-4-carboxamide-1-beta-D-ribofuranoside renders glucose output by the liver of the dog insensitive to a pharmacological increment in insulin.

Author

Camacho RC, Lacy DB, James FD, Donahue EP, and Wasserman DH

Subjects

AMP-Activated Protein Kinases, Aminoimidazole Carboxamide pharmacology, Animals, Arteries, Blood Glucose analysis, Dogs, Female, Glucose Clamp Technique, Glycogen analysis, Infusions, Intravenous, Insulin administration & dosage, Insulin blood, Kinetics, Liver chemistry, Male, Multienzyme Complexes metabolism, Phosphorylation, Protein Serine-Threonine Kinases metabolism, Aminoimidazole Carboxamide analogs & derivatives, Glucose metabolism, Hypoglycemic Agents pharmacology, Insulin pharmacology, Liver drug effects, Liver metabolism, Ribonucleotides pharmacology

Abstract

This study aimed to test whether stimulation of net hepatic glucose output (NHGO) by increased concentrations of the AMP analog, 5-aminoimidazole-4-carboxamide-1-beta-d-ribosyl-5-monophosphate, can be suppressed by pharmacological insulin levels. Dogs had sampling (artery, portal vein, hepatic vein) and infusion (vena cava, portal vein) catheters and flow probes (hepatic artery, portal vein) implanted >16 days before study. Protocols consisted of equilibration (-130 to -30 min), basal (-30 to 0 min), and hyperinsulinemic-euglycemic (0-150 min) periods. At time (t) = 0 min, somatostatin was infused, and basal glucagon was replaced via the portal vein. Insulin was infused in the portal vein at either 2 (INS2) or 5 (INS5) mU.kg(-1).min(-1). At t = 60 min, 1 mg.kg(-1).min(-1) portal venous 5-aminoimidazole-4-carboxamide-1-beta-d-ribofuranoside (AICAR) infusion was initiated. Arterial insulin rose approximately 9- and approximately 27-fold in INS2 and INS5, respectively. Glucagon, catecholamines, and cortisol did not change throughout the study. NHGO was completely suppressed before t = 60 min. Intraportal AICAR stimulated NHGO by 1.9 +/- 0.5 and 2.0 +/- 0.5 mg.kg(-1).min(-1) in INS2 and INS5, respectively. AICAR stimulated tracer-determined endogenous glucose production similarly in both groups. Intraportal AICAR infusion significantly increased hepatic acetyl-CoA carboxylase (ACC, Ser(79)) phosphorylation in INS2. Hepatic ACC (Ser(79)) phosphorylation, however, was not increased in INS5. Thus intraportal AICAR infusion renders hepatic glucose output insensitive to pharmacological insulin. The effectiveness of AICAR in countering the suppressive effect of pharmacological insulin on NHGO occurs even though AICAR-stimulated ACC phosphorylation is completely blocked.

Published

2005

21. Mobilization of glucose from the liver during exercise and replenishment afterward.

Author

Pencek RR, Fueger PT, Camacho RC, and Wasserman DH

Subjects

Animals, Dogs, Glucagon metabolism, Insulin metabolism, Glucose metabolism, Liver metabolism, Physical Conditioning, Animal

Abstract

The liver is anatomically well situated to regulate blood glucose. It is positioned downstream from the pancreas, which releases the key regulatory hormones glucagon and insulin. It is also just downstream from the gut, permitting efficient extraction of ingested glucose and preventing large excursions in systemic glucose after a glucose-rich meal. The position of the liver is not as well situated from the standpoint of experimentation and clinical assessment, as its primary blood supply is impossible to access in conscious human subjects. Over the last 20 years, to study hepatic glucose metabolism during and after exercise, we have utilized a conscious dog model which permits sampling of the blood that perfuses (portal vein, artery) and drains (hepatic vein) the liver. Our work has demonstrated the key role of exercise-induced changes in glucagon and insulin in stimulating hepatic glycogenolysis and gluconeogenesis during exercise. Recently we showed that portal venous infusion of the pharmacological agent 5'-aminoimidazole-4-carboxamide-1-beta-D-ribofuranoside leads to a marked increase in hepatic glucose production. Based on this, we propose that the concentration of AMP may be a component of a physiological pathway for stimulating hepatic glucose production during exercise. Insulin-stimulated hepatic glucose uptake is increased following exercise by an undefined mechanism that is independent of liver glycogen content. The fate of glucose taken up by the liver is critically dependent on hepatic glycogen stores, however, as glycogen deposition is greatly facilitated by prior glycogen depletion.

Published

2005

22. 5-Aminoimidazole-4-carboxamide-1-beta-D-ribofuranoside causes acute hepatic insulin resistance in vivo.

Author

Pencek RR, Shearer J, Camacho RC, James FD, Lacy DB, Fueger PT, Donahue EP, Snead W, and Wasserman DH

Subjects

Aminoimidazole Carboxamide administration & dosage, Animals, Blood Glucose drug effects, Blood Glucose metabolism, Cyclic AMP metabolism, Dogs, Female, Glucose Clamp Technique, Glycolysis drug effects, Hyperinsulinism blood, Infusions, Intravenous, Liver drug effects, Male, Patch-Clamp Techniques, Portal Vein physiology, Ribonucleotides administration & dosage, Aminoimidazole Carboxamide analogs & derivatives, Aminoimidazole Carboxamide pharmacology, Insulin Resistance physiology, Liver physiology, Ribonucleotides pharmacology

Abstract

The infusion of 5-aminoimidazole-4-carboxamide-1-beta-D-ribofuranoside (AICAR) causes a rise in tissue concentrations of the AMP analog 5-aminoimidazole-4-carboxamide-1-beta-D-ribofuranotide (ZMP), which mimics an elevation of cellular AMP levels. The purpose of this work was to determine the effect of raising hepatic ZMP levels on hepatic insulin action in vivo. Dogs had sampling and infusion catheters as well as flow probes implanted 16 days before an experiment. After an 18-h fast, blood glucose was 82 +/- 1 mg/dl and basal net hepatic glucose output 1.5 +/- 0.2 mg . kg(-1) . min(-1). Dogs received portal venous glucose (3.2 mg . kg(-1) . min(-1)), peripheral venous somatostatin, and basal portal venous glucagon infusions from -90 to 60 min. Physiological hyperinsulinemia was established with a portal insulin infusion (1.2 mU . kg(-1) . min(-1)). Peripheral venous glucose infusion was used to clamp arterial blood glucose at 150 mg/dl. Starting at t = 0 min, dogs received portal venous AICAR infusions of 0, 1, or 2 mg . kg(-1) . min(-1). Net hepatic glucose uptake was 2.4 +/- 0.5 mg . kg(-1) . min(-1) (mean of all groups) before t = 0 min. In the absence of AICAR, net hepatic glucose uptake was 1.9 +/- 0.4 mg . kg(-1) . min(-1) at t = 60 min. The lower-dose AICAR infusion caused a complete suppression of net hepatic glucose uptake (-1.0 +/- 1.7 mg . kg(-1) . min(-1) at t = 60 min). The higher AICAR dose resulted in a profound shift in hepatic glucose balance from net uptake to a marked net output (-6.1 +/- 1.9 mg . kg(-1) . min(-1) at t = 60 min), even in the face of hyperglycemia and hyperinsulinemia. These data show that elevations in hepatic ZMP concentrations, induced by portal venous AICAR infusion, cause acute hepatic insulin resistance. These findings have important implications for the targeting of AMP kinase for the treatment of insulin resistance, using AMP analogs.

Published

2005

23. Exercise-induced changes in insulin and glucagon are not required for enhanced hepatic glucose uptake after exercise but influence the fate of glucose within the liver.

Author

Pencek RR, James FD, Lacy DB, Jabbour K, Williams PE, Fueger PT, and Wasserman DH

Subjects

Alanine blood, Animals, Biological Transport, Blood Glucose drug effects, Blood Glucose metabolism, Dogs, Fatty Acids, Nonesterified blood, Glucagon administration & dosage, Glucose Clamp Technique, Glycerol blood, Infusions, Intravenous, Insulin administration & dosage, Insulin blood, Kinetics, Lactates blood, Liver drug effects, Somatostatin administration & dosage, Somatostatin pharmacology, Exercise Test, Glucagon pharmacology, Glucose metabolism, Insulin pharmacology, Liver metabolism, Physical Conditioning, Animal physiology

Abstract

To test whether pancreatic hormonal changes that occur during exercise are necessary for the postexercise enhancement of insulin-stimulated net hepatic glucose uptake, chronically catheterized dogs were exercised on a treadmill or rested for 150 min. At the onset of exercise, somatostatin was infused into a peripheral vein, and insulin and glucagon were infused in the portal vein to maintain basal levels (EX-Basal) or simulate the response to exercise (EX-Sim). Glucose was infused as needed to maintain euglycemia during exercise. After exercise or rest, somatostatin infusion was continued in exercised dogs and initiated in dogs that had remained sedentary. In addition, basal glucagon, glucose, and insulin were infused in the portal vein for 150 min to create a hyperinsulinemic-hyperglycemic clamp in EX-Basal, EX-Sim, and sedentary dogs. Steady-state measurements were made during the final 50 min of the clamp. During exercise, net hepatic glucose output (mg x kg(-1) x min(-1)) rose in EX-Sim (7.6 +/- 2.8) but not EX-Basal (1.9 +/- 0.3) dogs. During the hyperinsulinemic-hyperglycemic clamp that followed either exercise or rest, net hepatic glucose uptake (mg x kg(-1) x min(-1)) was elevated in both EX-Basal (4.0 +/- 0.7) and EX-Sim (4.6 +/- 0.5) dogs compared with sedentary dogs (2.0 +/- 0.3). Despite this elevation in net hepatic glucose uptake after exercise, glucose incorporation into hepatic glycogen, determined using [3-3H]glucose, was not different in EX-Basal and sedentary dogs, but was 50 +/- 30% greater in EX-Sim dogs. Exercise-induced changes in insulin and glucagon, and consequent glycogen depletion, are not required for the increase in net hepatic glucose uptake after exercise but result in a greater fraction of the glucose consumed by the liver being directed to glycogen.

Published

2004

24. Portal vein caffeine infusion enhances net hepatic glucose uptake during a glucose load in conscious dogs.

Author

Pencek RR, Battram D, Shearer J, James FD, Lacy DB, Jabbour K, Williams PE, Graham TE, and Wasserman DH

Subjects

Alanine blood, Animals, Arteries, Blood Glucose analysis, Dogs, Epinephrine blood, Fatty Acids, Nonesterified blood, Female, Fructosephosphates analysis, Glucagon blood, Glucose Clamp Technique, Glucose-6-Phosphate analysis, Glycerol blood, Glycogen analysis, Glycogen Phosphorylase metabolism, Glycogen Synthase metabolism, Infusions, Intravenous, Insulin blood, Lactic Acid blood, Lactic Acid metabolism, Liver chemistry, Male, Norepinephrine blood, Caffeine administration & dosage, Glucose administration & dosage, Glucose metabolism, Liver drug effects, Liver metabolism, Portal Vein

Abstract

We determined whether intraportal caffeine infusion, at rates designed to create concentrations similar to that seen with normal dietary intake, would enhance net hepatic glucose uptake (NHGU) during a glucose load. Dogs (n = 15) were implanted with sampling and infusion catheters as well as flow probes >16 d before the studies. After a basal sampling period, dogs were administered a somatostatin infusion (0-150 min) as well as intraportal infusions of glucose [18 micromol/(kg . min)], basal glucagon [0.5 ng/(kg . min)], and insulin [8.3 pmol/(kg . min)] to establish mild hyperinsulinemia. Arterial glucose was clamped at 10 mmol/L with a peripheral glucose infusion. At 80 min, either saline (Control; n = 7) or caffeine [1.5 micromol/(kg . min); n = 8] was infused into the portal vein. Arterial insulin, glucagon, norepinephrine, and glucose did not differ between groups. In dogs infused with caffeine, NHGU was significantly higher than in controls [21.2 +/- 4.3 vs. 11.2 +/- 1.6 micromol/(kg . min)]. Caffeine increased net hepatic lactate output compared with controls [12.5 +/- 3.8 vs. 5.5 +/- 1.5 micromol/(kg . min)]. These findings indicate that physiologic circulating levels of caffeine can enhance NHGU during a glucose load, and the added glucose consumed by the liver is in part converted to lactate.

Published

2004

25. Zonation of labeling of lipogenic acetyl-CoA across the liver: implications for studies of lipogenesis by mass isotopomer analysis.

Author

Bederman IR, Reszko AE, Kasumov T, David F, Wasserman DH, Kelleher JK, and Brunengraber H

Subjects

Acetates metabolism, Animals, Bile metabolism, Catheterization, Cholesterol metabolism, Dogs, Fatty Acids metabolism, Female, Gas Chromatography-Mass Spectrometry, Glucose metabolism, Hepatocytes metabolism, Lipoproteins, VLDL chemistry, Liver Extracts, Male, Models, Chemical, Models, Theoretical, Perfusion, Portal Vein metabolism, Rats, Rats, Sprague-Dawley, Sterols metabolism, Time Factors, Ultrasonics, Acetyl Coenzyme A chemistry, Lipids chemistry, Liver metabolism

Abstract

Measurement of fractional lipogenesis by condensation polymerization methods assumes constant enrichment of lipogenic acetyl-CoA in all hepatocytes. mass isotopomer distribution analysis (MIDA) and isotopomer spectral analysis (ISA) represent such methods and are based on the combinatorial analyses of mass isotopomer distributions (MIDs) of fatty acids and sterols. We previously showed that the concentration and enrichment of [13C]acetate decrease markedly across the dog liver because of the simultaneous uptake and production of acetate. To test for zonation of the enrichment of lipogenic acetyl-CoA, conscious dogs, prefitted with transhepatic catheters, were infused with glucose and [1,2-13C2]acetate in a branch of the portal vein. Analyses of MIDs of fatty acids and sterols isolated from liver, bile, and plasma very low density lipoprotein by a variant of ISA designed to detect gradients in precursor enrichment revealed marked zonation of enrichment of lipogenic acetyl-CoA. As control experiments where no zonation of acetyl-CoA enrichment would be expected, isolated rat livers were perfused with 10 mm [1,2-13C2]acetate. The ISA analyses of MIDs of fatty acids and sterols from liver and bile still revealed a zonation of acetyl-CoA enrichment. We conclude that zonation of hepatic acetyl-CoA enrichment occurs under a variety of animal models and physiological conditions. Failure to consider gradients of precursor enrichment can lead to underestimations of fractional lipogenesis calculated from the mass isotopomer distributions. The degree of such underestimation was modeled in vitro, and the data are reported in the companion paper (Bederman, I. R., Kasumov, T., Reszko, A. E., David, F., Brunengraber, H., and Kelleher, J. K. (2004) J. Biol. Chem. 279, 43217-43226).

Published

2004

26. Hepatic glucose autoregulation: responses to small, non-insulin-induced changes in arterial glucose.

Author

Camacho RC, Lacy DB, James FD, Coker RH, and Wasserman DH

Subjects

Animals, Arteries, Blood Glucose drug effects, Dogs, Female, Glucagon blood, Glucose Clamp Technique, Insulin blood, Kidney Tubules drug effects, Male, Somatostatin metabolism, Blood Glucose metabolism, Homeostasis physiology, Liver metabolism, Monosaccharide Transport Proteins drug effects, Phlorhizin pharmacology

Abstract

The purpose of this study was to determine whether the sedentary dog is able to autoregulate glucose production (R(a)) in response to non-insulin-induced changes (<20 mg/dl) in arterial glucose. Dogs had catheters implanted >16 days before study. Protocols consisted of basal (-30 to 0 min) and bilateral renal arterial phloridzin infusion (0-180 min) periods. Somatostatin was infused, and glucagon and insulin were replaced to basal levels. In one protocol (Phl +/- Glc), glucose was allowed to fall from t = 0-90 min. This was followed by a period when glucose was infused to restore euglycemia (90-150 min) and a period when glucose was allowed to fall again (150-180 min). In a second protocol (EC), glucose was infused to compensate for the renal glucose loss due to phloridzin and maintain euglycemia from t = 0-180 min. Arterial insulin, glucagon, cortisol, and catecholamines remained at basal in both protocols. In Phl +/- Glc, glucose fell by approximately 20 mg/dl by t = 90 min with phloridzin infusion. R(a) did not change from basal in Phl +/- Glc despite the fall in glucose for the first 90 min. R(a) was significantly suppressed with restoration of euglycemia from t = 90-150 min (P < 0.05) and returned to basal when glucose was allowed to fall from t = 150-180 min. R(a) did not change from basal in EC. In conclusion, the liver autoregulates R(a) in response to small changes in glucose independently of changes in pancreatic hormones at rest. However, the liver of the resting dog is more sensitive to a small increment, rather than decrement, in arterial glucose.

Published

2004

27. Regulation of hepatic and peripheral glucose disposal.

Author

Moore MC, Cherrington AD, and Wasserman DH

Subjects

Animals, Humans, Insulin metabolism, Blood Glucose metabolism, Homeostasis physiology, Liver metabolism

Abstract

Precise regulation of hepatic and peripheral glucose uptake is essential to preserve glucose homeostasis. The liver extracts approximately 1/3 of an oral glucose load, skeletal muscle extracts approximately 1/3, and other tissues, particularly the central nervous system and the formed elements of the blood, take up the balance. The load of glucose reaching the liver, the insulin concentration, and the route of glucose delivery (the hepatic portal or a peripheral vein) are key determinants of the rate of net hepatic glucose uptake. Glucose uptake by muscle requires three steps: delivery of glucose from the blood to the muscle, transport of glucose across the muscle membrane, and phosphorylation of glucose, processes affected by glycaemia and insulinaemia. Exercise stimulates insulin-dependent and -independent muscle glucose uptake, as well as the liver's ability to take up glucose.

Published

2003

28. Interaction of insulin and prior exercise in control of hepatic metabolism of a glucose load.

Author

Pencek RR, James F, Lacy DB, Jabbour K, Williams PE, Fueger PT, and Wasserman DH

Subjects

Alanine blood, Animals, Dogs, Fatty Acids, Nonesterified blood, Female, Fructosephosphates metabolism, Glucose pharmacokinetics, Glucose-6-Phosphate metabolism, Glycerol blood, Glycogen metabolism, Glycogen Phosphorylase metabolism, Glycogen Synthase metabolism, Hypoglycemic Agents pharmacology, Insulin pharmacology, Lactic Acid blood, Male, Blood Glucose metabolism, Hypoglycemic Agents blood, Insulin blood, Insulin Resistance physiology, Liver metabolism, Physical Exertion physiology

Abstract

To determine if prior exercise enhances insulin-stimulated extraction of glucose by the liver, chronically catheterized dogs were submitted to 150 min of treadmill exercise or rest. After exercise or rest, dogs received portal glucose (18 micro mol x kg(-1) x min(-1)), peripheral somatostatin, and basal portal glucagon infusions from t = 0 to 150 min. A peripheral glucose infusion was used to clamp arterial blood glucose at 8.3 mmol/l. Insulin was infused into the portal vein to create either basal levels or mild hyperinsulinemia. Prior exercise did not increase whole-body glucose disposal in the presence of basal insulin (25.5 +/- 1.5 vs. 20.3 +/- 1.7 micro mol x kg(-1) x min(-1)), but resulted in a marked enhancement in the presence of elevated insulin (97.2 +/- 15.1 vs. 64.4 +/- 7.4 micro mol x kg(-1) x min(-1)). Prior exercise also increased net hepatic glucose uptake in the presence of both basal insulin (7.5 +/- 1.2 vs. 2.9 +/- 2.4 micro mol x kg(-1) x min(-1)) and elevated insulin (22.0 +/- 3.5 vs. 11.5 +/- 1.8 micro mol x kg(-1) x min(-1)). Likewise, net hepatic glucose fractional extraction was increased by prior exercise with both basal insulin (0.04 +/- 0.01 vs. 0.01 +/- 0.01 micro mol x kg(-1) x min(-1)) and elevated insulin (0.10 +/- 0.01 vs. 0.05 +/- 0.01). Hepatic glycogen synthesis was increased by elevated insulin, but was not enhanced by prior exercise. Although the increase in glucose extraction after exercise could be ascribed to increased insulin action, the increase in hepatic glycogen synthesis was independent of it.

Published

2003

29. Role and Regulation of Hepatic Metabolism During Exercise

Author

Trefts, Elijah, Wasserman, David H., and McConell, Glenn, editor

Published

2022

30. AS160 deficiency causes whole-body insulin resistance via composite effects in multiple tissues.

Author

WANG, Hong Yu, DUCOMMUN, Serge, Chao QUAN, XIE, Bingxian, LI, Min, WASSERMAN, David H., SAKAMOTO, Kei, MACKINTOSH, Carol, and CHEN, Shuai

Subjects

PROTEIN kinase B, INSULIN resistance, GUANOSINE triphosphatase, GLUCOSE transporters, GENETIC mutation, HYPERINSULINISM, GTPASE-activating protein, KNOCKOUT mice

Abstract

AS160 (Akt substrate of 160 kDa) is a Rab GTPase-activating protein implicated in insulin control of GLUT4 (glucose transporter 4) trafficking. In humans, a truncation mutation (R363X) in one allele of AS160 decreased the expression of the protein and caused severe postprandial hyperinsulinaemia during puberty. To complement the limited studies possible in humans, we generated an AS160-knockout mouse. In wild-type mice, AS160 expression is relatively high in adipose tissue and soleus muscle, low in EDL (extensor digitorum longus) muscle and detectable in liver only after enrichment. Despite having lower blood glucose levels under both fasted and randomfed conditions, the AS160-knockout mice exhibited insulin resistance in both muscle and liver in a euglycaemic clamp study. Consistent with this paradoxical phenotype, basal glucose uptake was higher in AS160-knockout primary adipocytes and normal in isolated soleus muscle, but their insulin-stimulated glucose uptake and overall GLUT4 levels were markedly decreased. In contrast, insulin-stimulated glucose uptake and GLUT4 levels were normal in EDL muscle. The liver also contributes to the AS160-knockout phenotype via hepatic insulin resistance, elevated hepatic expression of phosphoenolpyruvate carboxykinase isoforms and pyruvate intolerance, which are indicative of increased gluconeogenesis. Overall, as well as its catalytic function, AS160 influences expression of other proteins, and its loss deregulates basal and insulin-regulated glucose homoeostasis, not only in tissues that normally express AS160, but also by influencing liver function. [ABSTRACT FROM AUTHOR]

Published

2013

31. Regulation of Endogenous Glucose Production in Glut4 Overexpressing Mice.

Author

Li, Candice Y., Ayala, Julio E., Bracy, Deanna P., Santomango, Tammy S., Mcguinness, Owen P., and Wasserman, David H.

Subjects

GLUCOSE, BLOOD sugar, LIVER, GLUCOKINASE, INSULIN, GLUCAGON, LABORATORY mice

Abstract

Peripheral Glut4 overexpression is a model of increased extrahepatic (e.g. heart, muscle, fat) glucose tolerance. Secondary hepatic adaptations in response to Glut4 overexpression, independent of the blood glucose and associated hormonal differences, have not been well defined. In order to determine the effect of increased non-hepatic Glut4 expression on the liver, endogenous glucose production (R[sub a], mg/kg/min) was assessed before and during phloridzin glucose clamps in Glut4 overexpressing mice (G4Tg) and wild type C57BL/6J littermates (WT). The phloridzin glucose clamp is a novel approach for control of blood glucose without hyperinsulinemia. Arterial and venous catheters were implanted in 4 mo old mice. After 5 d, mice were studied after a 4.5 h fast, beginning with a basal pre-clamp period, followed by a 90 min infusion of 80 µg/kg/min phloridzin with blood glucose (mg/dl) clamped at ∼115. [3-³H]glucose was used to determine R[sub 1]. In the pre-clamp state, blood glucose of G4Tg was lower than WT (G4Tg: 97±3, WT: 145±9) while R[sub a] (G4Tg: 19±1, WT: 16±2) was higher. The greater pre-clamp R[sub a] corresponded to 100% greater liver glucose-6-phosphatase (G-6-Pase) activity and 50% lower glucokinase (GK) activity. Insulin (ng/ml) was lower in G4Tg than in WT (G4Tg: 0.4±0.1, WT: 0.8±0.2), while glucagun (pg/ml) was similar (G4Tg: 40±7, WT: 35±4). Phloridzin glucose clamps resulted in equal blood glucose (G4Tg: 114±2, WT: 116±2), glucagon (G4Tg: 28±7, WT: 36±5), and insulin (G4Tg: 0.7±0.1, WT: 0.5±0.2) levels. Normalizing glucose, insulin, and glucagon of G4Tg to WT levels revealed a R[sub a] that was 50% lower in G4Tg than WT (G4Tg: 6±1, WT: 12±2). In summary, the elevated fasting R[sub a] of G4Tg is associated with increased G6-Pase and decreased GK activity and is secondary to a reduction in eirculating glucose. Acute correction for differences in blood glucose by using the phloridzin glucose clamp shows that the liver of G4Tg produces 50% less glucose. In conclusion, a primary increase of glucose tolerance due to increasing Glut4 in extrahepatic tissue results in important adaptations at the liver as well. [ABSTRACT FROM AUTHOR]

Published

2007

32. The extracellular matrix and insulin resistance.

Author

Williams, Ashley S., Kang, Li, and Wasserman, David H.

Subjects

*TYPE 2 diabetes treatment, *INSULIN resistance, *INSULIN regulation, *EXTRACELLULAR matrix, *ADIPOSE tissues, *INTEGRINS, *HOMEOSTASIS

Abstract

The extracellular matrix (ECM) is a highly-dynamic compartment that undergoes remodeling as a result of injury and repair. Over the past decade, mounting evidence in humans and rodents suggests that ECM remodeling is associated with diet-induced insulin resistance in several metabolic tissues. In addition, integrin receptors for the ECM have also been implicated in the regulation of insulin action. This review addresses what is currently known about the ECM, integrins, and insulin action in the muscle, liver, and adipose tissue. Understanding how ECM remodeling and integrin signaling regulate insulin action may aid in the development of new therapeutic targets for the treatment of insulin resistance and type 2 diabetes (T2D). [ABSTRACT FROM AUTHOR]

Published

2015

33. Effect of physical activity and fasting on gut and liver proteolysis in the dog.

Author

Halseth, Amy E., Flakoll, Paul J., Reed, Erica K., Messina, Allison B., Krishna, Mahesh G., Lacy, D. Brooks, Williams, Phillip E., and Wasserman, David H.

Subjects

*LIVER, *EXERCISE

Abstract

Presents a study which examined how acute exercise in the dog affected physical activity and fasting on gut and liver proteolysis. Details on sampling, infusion catheters and Doppler flow probes being implanted in the dogs under general anesthesia; Importance of gut and hepatic proteolysis to the body proteolysis; Findings of the study.

Published

1997