Evidence for High-Capacity Bidirectional Glucose Transport across the Endoplasmic Reticulum Membrane by Genetically Encoded Fluorescence Resonance Energy Transfer Nanosensors

Abstract: Glucose release from hepatocytes is important for maintenance of blood glucose levels. Glucose-6-phosphate phosphatase, catalyzing the final metabolic step of gluconeogenesis, faces the endoplasmic reticulum (ER) lumen. Thus, glucose produced in the ER has to be either exported from the ER into the cytosol before release into circulation or exported directly by a vesicular pathway. To measure ER transport of glucose, fluorescence resonance energy transfer-based nanosensors were targeted to the cytosol or the E… Show more

“…However, it is probable that GLUT10 is not a single DAA/ glucose transporter in the endomembranes. Functional studies indicated the heterogeneity of glucose transport in the ER [19,20]. Moreover, it was also demonstrated that various GLUT transporters can sufficiently mediate glucose transport en route from the ER to the plasma membrane [21].…”

“…The presence of GLUT10 in the endomembranes as a DAA and glucose transporter can be the molecular background of the functionally already observed transport activities [19,20,32]. However, it is probable that GLUT10 is not a single DAA/ glucose transporter in the endomembranes.…”

Glucose transporter type 10—lacking in arterial tortuosity syndrome—facilitates dehydroascorbic acid transport

“…However, it is probable that GLUT10 is not a single DAA/ glucose transporter in the endomembranes. Functional studies indicated the heterogeneity of glucose transport in the ER [19,20]. Moreover, it was also demonstrated that various GLUT transporters can sufficiently mediate glucose transport en route from the ER to the plasma membrane [21].…”

“…The presence of GLUT10 in the endomembranes as a DAA and glucose transporter can be the molecular background of the functionally already observed transport activities [19,20,32]. However, it is probable that GLUT10 is not a single DAA/ glucose transporter in the endomembranes.…”

Glucose transporter type 10—lacking in arterial tortuosity syndrome—facilitates dehydroascorbic acid transport

“…Fluorescent nanosensors have also been developed for concentration-dependent sensing of maltose in yeast (Fehr et al, 2002), as well as for detecting glucose uptake and subcellular compartmentalization Fehr et al, 2005) or ribose uptake in mammalian cells. Furthermore, bimolecular fluorescence complementation (BiFC) can detect interaction between protein partners in living cells.…”

Imaging Cellular Metabolism

“…In special cases, a priori knowledge can be used. For example, glucose concentrations in liver cells are known to be equilibrated by reversible GLUT-mediated plasma membrane transport (Fehr et al, 2005). Accordingly, intracellular glucose levels equal those in the extracellular space.…”

Molecular tools for cell and systems biology