Effect of lipid packing on the conformational states of purified GLUT-1 hexose transporter
| Autor: | Suzanne Scarlata, Howard C. Haspel, Heather McBath |
|---|---|
| Rok vydání: | 1995 |
| Předmět: |
Conformational change
Monosaccharide Transport Proteins Cytochalasin B Proteolipids Hydrostatic pressure Population In Vitro Techniques Ligands Biochemistry Membrane Lipids Motion Hydrostatic Pressure Humans education Glucose Transporter Type 1 education.field_of_study Quenching (fluorescence) Chemistry Bilayer Erythrocyte Membrane Membrane Proteins Glucose analog Ligand (biochemistry) Glucose Spectrometry Fluorescence Membrane Biophysics |
| Zdroj: | Biochemistry. 34:7703-7711 |
| ISSN: | 1520-4995 0006-2960 |
| Popis: | The purpose of this study was to determine the effect of increased lipid packing on the conformational states of the GLUT-1 hexose transporter purified in endogenous lipids. The binding of glucose results in a conformational change that can be followed by a decrease in fluorescence intensity. Lipid packing was increased by subjecting the samples to hydrostatic pressure. We have found that in the absence of ligand, the fluorescence intensity decreased approximately 20% in the 600 bar range studied. In the presence of either saturating or half-saturating amounts of D-glucose, a substantial loss in intensity (approximately 80%) was observed. Similar decreases were also seen the presence of a glucose analog, maltose, or a noncompetitive inhibitor, cytochalasin B. Changes in the accessibility of aqueous soluble quenchers (I- and acrylamide) to GLUT-1 Trp and Tyr residues suggested that ligand binding causes interfacial fluorophores to move closer to ionic groups in the lipid head group region of the membrane. This idea was substantiated by (1) increased static quenching of the GLUT-1 fluorophores in the presence of ligand, (2) increased energy transfer efficiency between GLUT-1 fluorophores and a fluorescent membrane probe located close to the head group region, and (3) reduced change in rotational motion with temperature in the presence of ligand. Since the application of pressure results in an increase in bilayer thickness, and ligand binding causes a population of fluorophores to move closer to the membrane surface, then these interfacial interactions can be more stabilized under pressure. Studies monitoring the change in quenching of membrane probes by GLUT-1 tryptophans and energy transfer of GLUT-1 tryptophans to membrane probes support this idea. |
| Databáze: | OpenAIRE |
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