A Whole-Body Model for Glycogen Regulation Reveals a Critical Role for Substrate Cycling in Maintaining Blood Glucose Homeostasis

Xu, Ke; Morgan, Kevin T.; Abby, Todd Gehris,; Elston, Timothy C.; Gomez, Shawn M.

doi:10.1371/journal.pcbi.1002272

Cited by 35 publications

(45 citation statements)

References 59 publications

(76 reference statements)

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“…Taken together, metabolic regulation via phosphorylation/dephosphorylation of key enzymes in combination with futile cycles plays a key role in our model, in line with the results presented by Xu et al [34].…”

Section: Discussionsupporting

confidence: 92%

Quantifying the Contribution of the Liver to Glucose Homeostasis: A Detailed Kinetic Model of Human Hepatic Glucose Metabolism

2012

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Despite the crucial role of the liver in glucose homeostasis, a detailed mathematical model of human hepatic glucose metabolism is lacking so far. Here we present a detailed kinetic model of glycolysis, gluconeogenesis and glycogen metabolism in human hepatocytes integrated with the hormonal control of these pathways by insulin, glucagon and epinephrine. Model simulations are in good agreement with experimental data on (i) the quantitative contributions of glycolysis, gluconeogenesis, and glycogen metabolism to hepatic glucose production and hepatic glucose utilization under varying physiological states. (ii) the time courses of postprandial glycogen storage as well as glycogen depletion in overnight fasting and short term fasting (iii) the switch from net hepatic glucose production under hypoglycemia to net hepatic glucose utilization under hyperglycemia essential for glucose homeostasis (iv) hormone perturbations of hepatic glucose metabolism. Response analysis reveals an extra high capacity of the liver to counteract changes of plasma glucose level below 5 mM (hypoglycemia) and above 7.5 mM (hyperglycemia). Our model may serve as an important module of a whole-body model of human glucose metabolism and as a valuable tool for understanding the role of the liver in glucose homeostasis under normal conditions and in diseases like diabetes or glycogen storage diseases.

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Section: Discussionsupporting

confidence: 92%

Quantifying the Contribution of the Liver to Glucose Homeostasis: A Detailed Kinetic Model of Human Hepatic Glucose Metabolism

2012

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“…Hepatic dysfunction has been associated with enhanced futile metabolic cycles, as well as loss of energy in the form of heat 17 , 27 . Examples of futile cycles include the conversion of glucose to glycogen, which is then followed by glycogenolysis and glucose recycling, as well as the hydrolysis of triglycerides to free fatty acids, which are then reesterified to triglycerides.…”

Section: Nutrient Metabolism In Esldmentioning

confidence: 99%

“…Examples of futile cycles include the conversion of glucose to glycogen, which is then followed by glycogenolysis and glucose recycling, as well as the hydrolysis of triglycerides to free fatty acids, which are then reesterified to triglycerides. These cycles also occur at low levels in healthy people, primarily in the fasted state; they are thought to expedite the response time from the fed to the fasted state and vice versa 27 . Loss of energy as heat occurs during the futile metabolic cycles and also during the uncoupling of oxidative phosphorylation from respiration, mediated by the effects of free fatty acids 17 …”

Section: Nutrient Metabolism In Esldmentioning

confidence: 99%

Enteral Energy and Macronutrients in End‐Stage Liver Disease

Mouzaki

Kamath

et al. 2014

J Parenter Enteral Nutr

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Protein-energy malnutrition is the most common comorbidity affecting adults and children with end-stage liver disease. Despite clear evidence linking malnutrition to poor outcomes before and after liver transplantation, nutrition rehabilitation is often inadequately emphasized in the clinical management of these patients. The primary aim of this review is to synthesize the available evidence supporting the current clinical guidelines on enteral nutrition support and, more important, to highlight the lack of evidence behind much of what is considered "standard of care" for the nutrition management of patients with cirrhosis. In addition, the mechanisms of malnutrition are reviewed, the limitations of tools used to assess body composition in this setting are discussed, and the differences in macronutrient metabolism between healthy subjects and patients with end-stage liver disease are explained. A summary of recommendations is provided.

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“…The second is shear scission; however, for highly branched molecules of the size of glycogen, this effect can be minimised with an appropriate flow rate. [32] Technical Improvements in SEC Characterisation of Glycogen While past studies that have obtained size distributions of native glycogen using SEC have employed a dimethyl sulfoxide/ lithium bromide (DMSO/LiBr) eluent, it has recently been shown [33] that aqueous SEC results in significantly improved resolution, with the a-and b-particle peaks being better separated than in DMSO. There have however been several encouraging studies using aqueous SEC to characterise synthetic and commercial glycogen.…”

Section: Glycogen Size Characterisationmentioning

confidence: 99%

The Molecular Size Distribution of Glycogen and its Relevance to Diabetes

Gilbert

Sullivan

2014

Aust. J. Chem.

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Glycogen is a highly branched polymer of glucose, functioning as a blood-glucose buffer. It comprises relatively small b-particles, which may be joined as larger aggregate a-particles. The size distributions from size-exclusion chromatography (SEC, also known as GPC) of liver glycogen from non-diabetic and diabetic mice show that diabetic mice have impaired a-particle formation, shedding new light on diabetes. SEC data also suggest the type of bonding holding b-particles together in a-particles. SEC characterisation of liver glycogen at various time points in a day/night cycle indicates that liver glycogen is initially synthesised as b-particles, and then joined by an unknown process to form a-particles. These a-particles are more resistant to degradation, presumably because of their lower surface area-to-volume ratio. These findings have important implications for new drug targets for diabetes management.

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A Whole-Body Model for Glycogen Regulation Reveals a Critical Role for Substrate Cycling in Maintaining Blood Glucose Homeostasis

Cited by 35 publications

References 59 publications

Quantifying the Contribution of the Liver to Glucose Homeostasis: A Detailed Kinetic Model of Human Hepatic Glucose Metabolism

Quantifying the Contribution of the Liver to Glucose Homeostasis: A Detailed Kinetic Model of Human Hepatic Glucose Metabolism

Enteral Energy and Macronutrients in End‐Stage Liver Disease

The Molecular Size Distribution of Glycogen and its Relevance to Diabetes

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