Biological and phytochemical studies on some traditional anti-diabetic plants

Srijayanta, Sairavee

January 2000

No description available.

615.1

Medicinal; Glucose uptake

The apparent chloride conductance of the proximal tubule brush border membrane

King, Nicola

January 1995

No description available.

612

Kidney; Glucose uptake

Shift reagents for '2'3Na NMR

Anson, Susan Melanie

January 1988

No description available.

572

Intestinal glucose uptake

Multi-level multi-scaled metabolites simulation

Li, Hao

January 2016

Diabetes is a world-wide health problem with 415 millions of people suffering from the disease. Most diabetics are suffering from Type 2 Diabetes, which is preceded by insulin resistance in glucose utilizing tissues, such as adipose, liver, and muscle tissues. Diabetes is diagnosed when the insulin control of the glucose levels fails, which leads to high glucose levels in the blood. To better understand the insulin control of blood glucose, mathematical modeling has been used for many years to simulate the dynamics of glucose and insulin levels in the blood. Models have also been used to understand the intracellular insulin-signaling network in the insulin responding tissues. There have also been attempts to connect models from these different layers of control into a multi-level and multi-scale simulation model. However, to do such connections, several assumptions must be made about the comparability of the data from the different levels. Here, I aim for a deeper understanding of these assumptions and to use more advanced data for glucose uptake dynamics than in earlier work. I used data from the literature for the dynamics of glucose uptake in adipose and muscle tissues and improve the model in several steps to have a better agreement with these data. In particular, I refined the sub-division of the glucose uptake between the organs, to also account for liver uptake, a correction that implied a reduction by 50% for the muscle and adipose tissue glucose uptake. Unlike previous models, the updated model also describes blood flow. Finally, because of the connection to the intracellular level, the model can be used to simulate the response to anti-diabetic drugs.

multi-level

model

simulation

glucose uptake

diabetes

Effect of vitamin A deficiency on glucose uptake in the rat.

Oenzil, Fadil, mikewood@deakin.edu.au

January 1988

This thesis describes an investigation of the effects of vitamin A deficiency on gut function, The central hypothesis to be tested was that acute vitamin A deficiency affects glucose uptake from the small intestine- The hypothesis was tested using a system involving perfusion of isolated segments of the small intestine in the anaesthetized rat. The system was used to study effects on glucose uptake under steady-state conditions. In the initial part of the study, experiments were diverted towards setting up the system for measuring steady-state uptake, and determining the relative contributions of active uptake and diffusion. Phenol red was found to be a reliable non-absorbable marker for determining net water movement. Phlorizin, generally at 1 mmol/L, was used as a competitive (reversible) inhibitor of active uptake. It is difficult however to confirm complete inhibition of active uptake by phlorizin because of the limited solubility of the inhibitor. The kinetics of glucose uptake f ram intra-luminal maltose were found to be, in general, not significantly different from those applying to the uptake of glucose from an equivalent glucose solution. Maltase activity in the perfused gut segment was found to be sufficient to hydrolyse most of the maltose (80 per cent or more) in the solution being perfused, a much greater proportion than was absorbed. Glucose absorptive capacity, measured on an intestinal dry weight basis, was greatest in the duodenum and progressively less in the jejunum and ileum. The rate of water uptake f ran the gut was increased by the presence of glucose in the lumen, and was linked to glucose uptake as shown by the inhibition of water uptake by phlorizin. Uptake of glucose by solvent drag was demonstrated by showing an increased rate of glucose uptake when the rate of water uptake was increased by perfusing a solution of reduced osmotic pressure. In the experiment a low intra-luminal glucose concentration was used to preclude net uptake by diffusion and active uptake was blocked with phlorizin. This process was further investigated using streptozotocin-diabetic rats in which the diabetes establishes a hyperosomotic blood with hyperglycaemia. Uptake by solvent drag was more obvious in diabetic animals. A back-diffusion (exsorption) of glucose from the tissues to the lumen was also shown; the rate being proportional to plasma glucose concentration. Vitamin A deficiency was established in weanling rats after 6-7 weeks feeding on a diet based on wheat starch, coconut oil, and casein washed with hot ethanol, together with vitamins and minerals. The vitamin A deficiency led to classic eye signs and was reversed by the addition to the diet of retinoic acid (5 g/g diet). Vitamin A deficiency decreased intestinal mucus production (dry weight) but had no detectable effect on the histology of the villous epithelium as shown under the light microscope. Using perfusion experiments it was shown that vitamin A deficiency had no significant effect on the rate of active uptake of glucose, but that deficiency increased the rate of passive uptake.

vitamin A deficiency

glucose uptake

mtabolism

diabetes

Phlorizin

Design and Synthesis of Improved Glucose Uptake Inhibitors

Wang, Liyi

January 2021

No description available.

Chemistry

Glucose uptake

glucose transporters (GLUTs)

cancer

Uniaxial Cyclic Stretch-Stimulated Glucose Transport Is Mediated by a Ca2+-Dependent Mechanism in Cultured Skeletal Muscle Cells

Iwata, Masahiro, 岩田, 全広, Hayakawa, Kimihide, Murakami, Taro, Naruse, Keiji, Kawakami, Keisuke, Inoue-Miyazu, Masumi, Yuge, Louis, Suzuki, Shigeyuki

07 1900

"Uniaxial Cyclic Stretch-Stimulated Glucose Transport Is Mediated by a Ca2+-Dependent Mechanism in Cultured Skeletal Muscle Cells" Pathobiology, v.74, n.3, pp.159-168を、博士論文として提出したもの。 / 名古屋大学博士学位論文 学位の種類:博士（リハビリテーション療法学）（課程）学位授与年月日:平成19年3月23日

Mechanical stretch

Myotube

Glucose uptake

Intracellular Ca 2+ concentration

An amino acid mixture enhances insulin-stimulated glucose uptake in isolated epitrochlearis muscle

Kleinert, Maximilian

22 December 2010

Amino acids are important modulators of skeletal muscle metabolism, but their impact on glucose uptake by skeletal muscle remains unclear. To address the effect of an amino acid (AA) mixture consisting predominately of isoleucine on glucose uptake we first conducted a dose-response experiment, investigating how different concentrations of the AA mixture affect glucose uptake by isolated rat epitrochlearis muscle. In a subsequent experiment we examined how the AA mixture affects insulin-stimulated glucose uptake by isolated rat epitrochlearis muscle. It was found that the AA mixture with as little as 0.5 mM Ile increases [H3]2-deoxy-D-glucose (2-DG) uptake by 76% compared to basal glucose uptake. The AA mixtures with 1, 2 or 4 mM Ile provided no significant additional effect. Next we combined the AA mixture consisting of 2 mM Ile, 0.012 mM Cys, 0.006 mM Val and 0.014 mM Leu with physiological levels (75 μU/ml, sINS) and maximally-stimulating levels (2 mU/ml, mINS) of insulin. The AA mixture only, sINS and mINS significantly increased 2-DG uptake compared to basal by 63, 79 and 298%, respectively. When the AA mixture was combined with sINS and mINS 2-DG uptake was further increased significantly by 26 and 14%, respectively. Western blotting analysis revealed that compared to basal the AA mixture increased AS160 phosphorylation, while phosphorylation of Akt and mTOR did not change. Combining the AA mixture with sINS resulted in no additional phosphorylation compared to sINS alone. Interestingly, addition of the AA mixture to mINS resulted in increased phosphorylation of mTOR, Akt and AS160 compared to mINS alone. Our results suggest that certain AAs (1) increase glucose uptake in the absence of insulin and (2) augment insulin-stimulated glucose uptake in an additive manner. These effects on glucose uptake appear to be mediated via a molecular pathway that is partially independent from the canonical insulin signaling cascade. / text

Glucose uptake

AS160

Epitrochlearis

Amino acids

Skeletal muscle

Insulin

Brain Glucose Transporter (Glut3) Haploinsufficiency Does Not Impair Mouse Brain Glucose Uptake

Stuart, Charles A., Ross, Ian R., Howell, Mary E.A., McCurry, Melanie P., Wood, Thomas G., Ceci, Jeffrey D., Kennel, Stephen J., Wall, Jonathan

12 April 2011

Mouse brain expresses three principal glucose transporters. Glut1 is an endothelial marker and is the principal glucose transporter of the blood-brain barrier. Glut3 and Glut6 are expressed in glial cells and neural cells. A mouse line with a null allele for Glut3 has been developed. The Glut3-/- genotype is intrauterine lethal by 7 days post-coitis, but the heterozygous (Glut3+/-) littermate survives, exhibiting rapid post-natal weight gain, but no seizures or other behavioral aberrations. At 12 weeks of age, brain uptake of tail vein-injected 3 H-2-deoxy glucose in Glut3 +/- mice was not different from Glut3+/+ littermates, despite 50% less Glut3 protein expression in the brain. The brain uptake of injected 18F-2-fluoro-2-deoxy glucose was similarly not different from Glut3+/- littermates in the total amount, time course, or brain imaging in the Glut3+/- mice. Glut1 and Glut6 protein expressions evaluated by immunoblots were not affected by the diminished Glut3 expression in the Glut3+/- mice. We conclude that a 50% decrease in Glut3 is not limiting for the uptake of glucose into the mouse brain, since Glut3 haploinsufficiency does not impair brain glucose uptake or utilization.

brain

glucose uptake

Glut1

Glut3

Glut6

Internal Medicine

Regulation of skeletal muscle insulin sensitivity by PAK1

Tunduguru, Ragadeepthi

06 September 2016

Indiana University-Purdue University Indianapolis (IUPUI) / Insulin-stimulated glucose uptake into skeletal muscle cells requires translocation of the glucose transporter-4 (GLUT4) from the cell interior to the plasma membrane. Insulin-stimulated GLUT4 vesicle translocation is dysregulated in Type 2 diabetes (T2D). The Group I p21–activated kinase (PAK1) is a required element in insulin-stimulated GLUT4 vesicle translocation in mouse skeletal muscle in vivo, although its placement and function(s) in the canonical insulin signaling cascade in skeletal muscle cells, remain undetermined. Therefore, the objective of my project is to determine the molecular mechanism(s) underlying the requirement for PAK1 in the process of insulin-stimulated GLUT4 vesicle translocation and subsequent glucose uptake by skeletal muscle cells. Toward this, my studies demonstrate that the pharmacological inhibition of PAK1 activation blunts insulin-stimulated GLUT4 translocation and subsequent glucose uptake into L6-GLUT4myc skeletal myotubes. Inhibition of PAK1 activation also ablates insulin-stimulated F-actin cytoskeletal remodeling, a process known to be required for mobilizing GLUT4 vesicles to the plasma membrane. Consistent with this mechanism, PAK1 activation was also required for the activation of cofilin, another protein implicated in F-actin remodeling. Interestingly, my studies reveal a novel molecular mechanism involving PAK1 signaling to p41-ARC, a regulatory subunit of the cytoskeletal Arp2/3 complex, and its interactions with another cytoskeletal factor, N-WASP, to elicit the insulin-stimulated F-actin remodeling in skeletal muscle cells. Pharmacological inactivation of N-WASP fully abrogated insulin-stimulated GLUT4 vesicle translocation to the cell surface, coordinate with blunted F-actin remodeling. Furthermore, my studies revealed new insulin-induced interactions amongst N WASP, actin, p41-ARC and PAK1; inactivation of PAK1 signaling blocked these dynamic interactions. Taken together, the above studies demonstrate the significance of PAK1 and its downstream signaling to F-actin remodeling in insulin-stimulated GLUT4 vesicle translocation and glucose uptake, revealing new signaling elements that may prove to be promising targets for future therapeutic design.

Actin remodeling

GLUT4

Insulin sensitivity

PAK1

Skeletal muscle

Glucose uptake