Intracellular Hypertonicity Is Responsible for Water Flux Associated with Na+/Glucose Cotransport

Equilibrative sugar uptake in human erythrocytes is characterized by a rapid phase, which equilibrates 66% of the cell water, and by a slow phase, which equilibrates 33% of the cell water. This behavior has been attributed to the preferential transport of beta-sugars by erythrocytes (Leitch JM, Carruthers A. Am J Physiol Cell Physiol 292: C974-C986, 2007). The present study tests this hypothesis. The anomer theory requires that the relative compartment sizes of rapid and slow transport phases are determined by the proportions of beta- and alpha-sugar in aqueous solution. This is observed with D-glucose and 3-O-methylglucose but not with 2-deoxy-D-glucose and D-mannose. The anomer hypothesis predicts that the slow transport phase, which represents alpha-sugar transport, is eliminated when anomerization is accelerated to generate the more rapidly transported beta-sugar. Exogenous, intracellular mutarotase accelerates anomerization but has no effect on transport. The anomer hypothesis requires that transport inhibitors inhibit rapid and slow transport phases equally. This is observed with the endofacial site inhibitor cytochalasin B but not with the exofacial site inhibitors maltose or phloretin, which inhibit only the rapid phase. Direct measurement of alpha- and beta-sugar uptake demonstrates that erythrocytes transport alpha- and beta-sugars with equal avidity. These findings refute the hypothesis that erythrocytes preferentially transport beta-sugars. We demonstrate that biphasic 3-O-methylglucose equilibrium exchange kinetics refute the simple carrier hypothesis for protein-mediated sugar transport but are compatible with a fixed-site transport mechanism regulated by intracellular ATP and cell shape.

Section: ) Glucose Transport Inhibitors Must Inhibit Both Fast Transmentioning

confidence: 99%

α- and β-Monosaccharide transport in human erythrocytes

Leitch¹,

Carruthers²

2009

“…The variations in volume were used to determine water permeability values (P f) which are given in micrometers per second. For a more detailed description of this setup and procedure, see Duquette et al (9) and Charron et al (4).…”

Section: Volume Measurementsmentioning

confidence: 99%

Elaboration of a novel technique for purification of plasma membranes from Xenopus laevis oocytes

Leduc‐Nadeau¹,

Lahjouji²,

Bissonnette³

et al. 2007

Self Cite

Over the past two decades, Xenopus laevis oocytes have been widely used as an expression system to investigate both physiological and pathological properties of membrane proteins such as channels and transporters. Past studies have clearly shown the key implications of mistargeting in relation to the pathogenesis of these proteins. To unambiguously determine the plasma membrane targeting of a protein, a thorough purification technique becomes essential. Unfortunately, available techniques are either too cumbersome, technically demanding, or require large amounts of material, all of which are not adequate when using oocytes individually injected with cRNA or DNA. In this article, we present a new technique that permits excellent purification of plasma membranes from X. laevis oocytes. This technique is fast, does not require particular skills such as peeling of vitelline membrane, and permits purification of multiple samples from as few as 10 and up to >100 oocytes. The procedure combines partial digestion of the vitelline membrane, polymerization of the plasma membrane, and low-speed centrifugations. We have validated this technique essentially with Western blot assays on three plasma membrane proteins [aquaporin (AQP)2, Na(+)-glucose cotransporter (SGLT)1, and transient receptor potential vanilloid (TRPV)5], using both wild-type and mistargeted forms of the proteins. Purified plasma membrane fractions were easily collected, and samples were found to be adequate for Western blot identification.

“…The diffusion coefficients of ions and small organic molecules in the oocyte cytoplasm are reported to be in the order of D ϭ 0.2-0.6 ϫ 10 -5 cm 2 /s (35). The expected equilibration time constant in the oocyte cytoplasm is then in the order of a few hundred seconds, and this is confirmed by experimental observations as well (8,18).…”

Section: Methodsmentioning

confidence: 57%

GABA reverse transport by the neuronal cotransporter GAT1: influence of internal chloride depletion

Bertram

Cherubino

Bossi

et al. 2011

role of intracellular ions on the reverse GABA transport by the neuronal transporter GAT1 was studied using voltage-clamp and [ 3 H]GABA efflux determinations in Xenopus oocytes transfected with heterologous mRNA. Reverse transport was induced by intracellular GABA injections and measured in terms of the net outward current generated by the transporter. Changes in various intracellular ionic conditions affected the reverse current: higher concentrations of Na ϩ enhanced the ratio of outward over inward transport current, while a considerable decrease of the outward current and a parallel reduction of the transporter-mediated GABA efflux were observed after treatments causing a diminution of the intracellular Cl Ϫ concentration. Particularly interesting was the impairment of the reverse transport observed after depletion of internal Cl Ϫ generated by the activity of a coexpressed K ϩ -Cl Ϫ exporter KCC2. This finding suggests that reverse GABA transport may be physiologically regulated during early neuronal development, similarly to the functional alterations seen in GABA receptors caused by KCC2 activity. ␥-aminobutyric acid; KCC2; Xenopus oocytes NEUROTRANSMITTER TRANSPORTERS (NTTs), located on presynaptic terminals and surrounding glia cells in the central nervous system (CNS), are necessary for the reuptake of neurotransmitter molecules from the synaptic space. Their involvement in the termination of synaptic transmission, the prevention of neurotransmitter spread to neighboring synapses, and the maintenance of the neurotransmitter concentration below neurotoxic levels make them essential for an efficient signal transduction in the brain. Beside the uptake mode, NTTs can also work in reverse and they can release neurotransmitter in a nonvesicular, calcium-independent manner, as demonstrated, for example, for the ␥-aminobutyric acid (GABA) transporter GAT1 (7, 22, 23). GAT1 is thought to play an important role in physiologically regulating the level of tonic inhibition in the CNS, thereby contributing to the control of brain excitability. Failure of this function may result in pathological conditions such as epileptic seizures, possibly caused by GABA spillover through GABA transporters (31, 32).Under normal conditions, GAT1, a member of the SLC6 family, couples GABA uptake to that of two Na ϩ ions and one Cl Ϫ ion. Recently, on the basis of the atomic structure of the bacterial homologue LeuT (43), the putative external Cl Ϫ -binding site of GAT1 was identified (4, 12, 47): mutations of an uncharged serine residue in position 331 to a negatively charged amino acid converted GABA transport into a Cl Ϫ -independent process. Furthermore, it has been shown that a higher external Cl Ϫ concentration facilitates the binding of external Na ϩ ions necessary for the GAT1 transport cycle (13, 20, 24). These observations suggest that a negative charge is required for GABA translocation and that, in GAT1, which lacks an intrinsic negative charge, this is provided by Cl Ϫ binding. Indeed, Cl Ϫ -independent transporters of t...