Onal role in modulating chromatin histone acetylation. The increase of FFA and, specifically, palmitic acid was also included in the model, but was limited to its inhibitory effect on HNF1A and FOXA2 translocation to the nucleus. Thus, the model would capture a beneficial effect of FFA reduction on glucose uptake. However, down-modulation of FFA receptor binding and signaling was not incorporated into our model. It has been reported that FFA receptors are essential to normal b-cell function [25]. An efficacious inhibitor of FFA receptor signaling may disrupt the normal Calciferol functions of multiple cell types. In contrast, chronic elevations of FFAs may become pathogenic [26], perhaps by membrane fusion in receptor independent processes among cell organelles including mitochondria, leading to increased oxidative stress with changes to intracellular transcriptional networks. From computational modeling of the initial steps in pancreatic b-cell glycolysis, beginning with glucose transport and G6P formation, we have achieved an integration of experimental and computational data that encompasses a recently discovered pathogenic pathway to T2D that proceeds through attenuation of pancreatic b-cell GNT-4A activity and glucose transport [7]. This model closely simulates outcomes of rigorous experimentation in rodents and human b-cells, and further indicates the presence of a metabolic threshold wherein the pacemaker of b-cell glycolysis switches from GK activity to glucose transport. Beyond this tipping point, b-cells are defective in glucose sensing and are unable to produce G6P by mechanisms that support normal functions including GSIS. Our model is further consistent with studies of human b-cells from T2D donors, in which this metabolicthreshold is crossed and GSIS is defective. With inherent metabolic flexibility, 18325633 b-cells can subsequently respond by increasing their oxidation of fatty acids as a substitute source of cellular energy. However, this flexibility cannot restore normal insulin secretion processes linked to glucose sensing, thereby inducing a pathogenic pathway leading to diabetes.Methods Model DescriptionThe mathematical model was developed as a system of ordinary differential equations. Most of the biochemical kinetic rates were expressed by mass action laws. Exceptions are the GLUT-1 and GLUT-2 transport described by Michaelis-Menten kinetics, and the GK rate and glucose transporters interaction with lectins described by Hill kinetics. Further details and MATLAB programs are provided in (Text S1, S2 and S3).Sensitivity AnalysisRelative sensitivity coefficients, Si , were calculated approximating by finite differences the expression Si L ln y=L ln xi , where y represents GK rate at steady-state for a given extra-cellular glucose concentration, and xi the concentration of RNA perturbed, for i corresponding to HNF1A, FOXA2, MGAT4A, GLUT1, and GLUT2.Supporting InformationText S1 Detailed description of the reduced mathematical model. (PDF) Text S2 Detailed description of the full model.(PDF)Text S3 MATLAB programs of the full model.(PDF)Author ContributionsConceived and designed the 69-25-0 web experiments: CL JDM. Performed the experiments: CL. Analyzed the data: CL JDM FJD. Wrote the paper: CL JDM FJD.
The henipaviruses are recently emerged highly pathogenic paramyxovirus zoonoses and include Hendra virus (HeV) and several distinct isolates of Nipah virus (NiV) [1]. HeV was first isolated in 1994 from specimens obtained during an outbreak of respir.Onal role in modulating chromatin histone acetylation. The increase of FFA and, specifically, palmitic acid was also included in the model, but was limited to its inhibitory effect on HNF1A and FOXA2 translocation to the nucleus. Thus, the model would capture a beneficial effect of FFA reduction on glucose uptake. However, down-modulation of FFA receptor binding and signaling was not incorporated into our model. It has been reported that FFA receptors are essential to normal b-cell function [25]. An efficacious inhibitor of FFA receptor signaling may disrupt the normal functions of multiple cell types. In contrast, chronic elevations of FFAs may become pathogenic [26], perhaps by membrane fusion in receptor independent processes among cell organelles including mitochondria, leading to increased oxidative stress with changes to intracellular transcriptional networks. From computational modeling of the initial steps in pancreatic b-cell glycolysis, beginning with glucose transport and G6P formation, we have achieved an integration of experimental and computational data that encompasses a recently discovered pathogenic pathway to T2D that proceeds through attenuation of pancreatic b-cell GNT-4A activity and glucose transport [7]. This model closely simulates outcomes of rigorous experimentation in rodents and human b-cells, and further indicates the presence of a metabolic threshold wherein the pacemaker of b-cell glycolysis switches from GK activity to glucose transport. Beyond this tipping point, b-cells are defective in glucose sensing and are unable to produce G6P by mechanisms that support normal functions including GSIS. Our model is further consistent with studies of human b-cells from T2D donors, in which this metabolicthreshold is crossed and GSIS is defective. With inherent metabolic flexibility, 18325633 b-cells can subsequently respond by increasing their oxidation of fatty acids as a substitute source of cellular energy. However, this flexibility cannot restore normal insulin secretion processes linked to glucose sensing, thereby inducing a pathogenic pathway leading to diabetes.Methods Model DescriptionThe mathematical model was developed as a system of ordinary differential equations. Most of the biochemical kinetic rates were expressed by mass action laws. Exceptions are the GLUT-1 and GLUT-2 transport described by Michaelis-Menten kinetics, and the GK rate and glucose transporters interaction with lectins described by Hill kinetics. Further details and MATLAB programs are provided in (Text S1, S2 and S3).Sensitivity AnalysisRelative sensitivity coefficients, Si , were calculated approximating by finite differences the expression Si L ln y=L ln xi , where y represents GK rate at steady-state for a given extra-cellular glucose concentration, and xi the concentration of RNA perturbed, for i corresponding to HNF1A, FOXA2, MGAT4A, GLUT1, and GLUT2.Supporting InformationText S1 Detailed description of the reduced mathematical model. (PDF) Text S2 Detailed description of the full model.(PDF)Text S3 MATLAB programs of the full model.(PDF)Author ContributionsConceived and designed the experiments: CL JDM. Performed the experiments: CL. Analyzed the data: CL JDM FJD. Wrote the paper: CL JDM FJD.
The henipaviruses are recently emerged highly pathogenic paramyxovirus zoonoses and include Hendra virus (HeV) and several distinct isolates of Nipah virus (NiV) [1]. HeV was first isolated in 1994 from specimens obtained during an outbreak of respir.