A Nutrient Network Regulating Cellular Cholesterol and Glucose Metabolism

Pattar, Guruprasad R.

January 2014

Indiana University-Purdue University Indianapolis (IUPUI) / Insulin resistance, a hallmark of type 2 diabetes (T2D), is associated with accompanying derangements such as hyperinsulinemia that promote the progression of insulin resistance, yet a mechanism(s) is imperfectly understood. Data have demonstrated that hyperinsulinemia promotes insulin resistance as evidenced by diminished ability of insulin to mobilize glucose transporter GLUT4 to the plasma membrane (PM). We found that loss of PM phosphatidylinositol 4,5-bisphosphate (PIP2)-regulated filamentous actin (F-actin) structure contributes to hyperinsulinemia-induced insulin resistance. We tested if increased glucose flux through hexosamine biosynthesis pathway (HBP) causes dysregulation of PM components necessary for GLUT4 translocation. Increased HBP activity was detected in 3T3-L1 adipocytes cultured in hyperinsulinemia (5 nM Ins; 12 h) and also 2 mM glucosamine (GlcN), a distal HBP activator, inducing losses of PM PIP2 and F-actin. In accordance with HBP flux directly weakening PIP2/F-actin structure, inhibition of the rate-limiting HBP enzyme (glutamine:fructose-6-phosphate amidotransferase) restored F-actin and insulin responsiveness. Furthermore, less invasive challenges with glucose led to PIP2/F-actin dysregulation. New findings support a negative correlation between PM cholesterol accrual, PIP2/F-actin structure and GLUT4 regulation. These data stemmed from parallel study aimed at understanding the antidiabetic mechanism of the nutrient chromium (Cr3+). We found that chromium picolinate (CrPic) enhanced insulin-stimulated GLUT4 trafficking via reduction in PM cholesterol. In line with glucose/cholesterol toxicity findings, we demonstrated that therapeutic effects of CrPic occurred solely in adipocytes with increased HBP activity and a concomitant elevation in PM cholesterol. Mechanistically, data are consistent with a role of AMP-activated protein kinase (AMPK) in CrPic action. These data show that CrPic increases AMPK activity and perhaps suppresses cholesterol synthesis via distal phosphorylation and inactivation of 3-hydroxy-3-methylglutaryl CoA reductase (HMGR), a rate-limiting enzyme in cholesterol synthesis. Continued study of the consequence of increased HBP activity revealed alterations in cholesterogenic transcription factors – Sp1, SREBP-1, and NFY – with Sp1 showing a significant increase in O-linked glycosylation. Consistent with Sp1 modification eliciting maximal transcriptional activation of SREBP-1, Hmgr mRNA was significantly enhanced. In conclusion, these data are consistent with a central role of PM cholesterol in glucose transport and suggest perturbations in this lipid have a contributory role in developing insulin resistance.

chromium

membrane cholesterol

insulin

glucose

actin

Caveolae structure and importance in insulin action /

Thorn, Hans,

January 2004

Diss. (sammanfattning) Linköping : Linköpings universitet, 2004. / Härtill 4 uppsatser.

ELECTROCHEMICAL MEASUREMENT OF PLASMA MEMBRANE CHOLESTEROL IN LIVE CELLS AND MOUSE TISSUES

Fang, Danjun

January 2010

No description available.

Analytical Chemistry

cholesterol oxidase

platinum micro-cavity electrode

titration assay

plasma membrane cholesterol

CFTR

Cholesterol Oxidase Modified Microelectrodes for Detection of Cholesterol in the Plasma Membrane of Single Cells

Devadoss, Anando

January 2006

No description available.

Cholesterol

Cholesterol Oxidase

Plasma membrane cholesterol

Electrochemical detection of cholesterol

Xenopus oocyte

microelectrodes

enzyme modified microelectrodes

Lipid bilayer modified electrode

The effect of α-tocopherol on the membrane dipole potential

Le Nen Davey, Sterenn

January 2011

α-Tocopherol has a well known antioxidant action but is also considered likely to exert significant non-antioxidant effects in cell membranes. Due to its lipophilic nature α-tocopherol inserts into biological membranes where it influences the organisation of the component lipids and may therefore influence biophysical parameters including the membrane dipole potential. The dipole potential has been demonstrated to modulate the function of several membrane associated proteins and perturbation of this physical parameter by α-tocopherol may prove to be a significant non-antioxidant mechanism underlying several of its cellular effects. This study investigates the influence of α-tocopherol, and the non-antioxidant structural analogue α-tocopherol succinate, on the membrane dipole potential employing fluorescence spectroscopy techniques with the dipole potential sensitive probe Di-8-ANEPPS. Similar techniques are utilised with the surface potential sensitive probe FPE to investigate the interaction of the charged α-tocopherol succinate molecule with membranes. α-Tocopherol and α-tocopherol succinate are shown to decrease the dipole potential of egg-phosphatidylcholine vesicles and Jurkat T-lymphocyte cell membranes. This effect is placed in the context of the significant influence of membrane cholesterol oxidation on the dipole potential. 7-ketocholesterol, an oxidised form of cholesterol, significantly influences several cellular processes and is thought to mediate these effects, in part, through its physical effects on the cell membrane. These include altering the composition, and therefore biophysical properties, of rafts; structures which are considered to support the function of a host of membrane proteins. This study attempts to correlate the effect of 7-ketocholesterol on the dipole potential of microdomains with the influence of the oxysterol on the function of two microdomains associated receptors: P-glycoprotein and the insulin receptor, assessed by determining the extent of ligand binding using flow fluorocytometry. α-Tocopherol has been suggested to inhibit the raft-mediated effects of 7-ketocholesterol and the influence of this molecule on the effect of 7-ketocholesterol on the dipole potential are investigated as a potential mechanism for this inhibition. It is hypothesized that α-tocopherols may protect against the deleterious effects of cholesterol oxidation in cell membranes by excluding 7-ketocholesterol from specific microdomains, of which rafts are a subset, acting to preserve their dipole potential and maintain the function of the proteins they support. However, where significant cholesterol oxidation has previously occured the concurrent changes in the microdomain landscape of the membrane is suggested to prevent α-tocopherol succinate from eliciting this protective effect.

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