Mapping the urea channel through the rabbit Na(+)-glucose cotransporter SGLT1.

1. The rabbit Na(+)-glucose cotransporter rbSGLT1 and its carboxy-terminal part, C5, which contains transmembrane helices 10-14 of SGLT1 and functions as a low affinity glucose uniporter, were expressed as individual proteins in Xenopus oocytes. Transport of 55 microM urea, ethylene glycol, mannitol and alpha-methyl-D-glucopyranoside (alphaMDG) by control oocytes and by oocytes expressing SGLT1 and C5 was studied by uptake measurements of the 14C-labelled substrates. 2. There was a 5- to 6-fold increase in urea transport mediated by C5, compared with control oocytes. Similar to SGLT1, the C5-urea uptake was cation independent, linear in time and with increasing urea concentration, and blocked with the same sensitivity by the inhibitor phloretin (K(i) approximately 1 mM). Like SGLT1 in choline buffer, the C5-mediated uptake was insensitive to phlorizin. 3. Mannitol was transported by C5 but not by SGLT1 or control oocytes. 4. The activation energy (E(a)) for urea transport through C5 was low (5 +/- 3 kcal mol(-1)) compared with that of non-injected oocytes (16 +/- 0.5 kcal mol(-1)) and comparable with the E(a) of passive urea or water transport through intact SGLT1. 5. The urea influx through C5 increased in the presence of alphaMDG, but not in the presence of the same concentration of mannitol. 6. We conclude that the five carboxy-terminal transmembrane helices of SGLT1 form a channel for the permeation of small molecules such as urea and water.

Purification and functional reconstitution of a truncated human Na(+)/glucose cotransporter (SGLT1) expressed in E. coli.

A truncated human Na(+)/glucose cotransporter (C(5), residues 407-664) was expressed and purified from Escherichia coli using a GST fusion vector and glutathione affinity chromatography. The truncated transporter (C(5)) was cleaved from GST-C(5) by Factor Xa proteolysis and purified by gel filtration chromatography. Up to 1 mg of purified GST-C(5) was obtained from 1 l bacterial culture. Reconstitution of both GST-C(5) and C(5) proteins into lipid vesicles resulted in 2.5-fold higher initial uptake rates of [(3)H]D-glucose into C(5)-proteoliposomes than into liposomes. Transport was stereospecific, saturable, and inhibited by phloretin. These properties are similar to those obtained for C(5) in Xenopus laevis oocytes, and provide additional evidence that the five C-terminal transmembrane helices in SGLT1 form the sugar translocation pathway.

Structure and function of the Na+/glucose cotransporter.

Cotransporters are a major class of membrane transport proteins that are responsible for the accumulation of nutrients, neurotransmitters, osmolytes and ions in cells from bacteria to man. The energy for solute accumulation comes from the proton and/or sodium electrochemical gradients that exist across cell membranes. A major problem in biology is how transport is coupled to these electrochemical potential gradients. The primary example of this class of membrane proteins is the intestinal brush border Na+/glucose cotransporter (SGLT1), first described by Bob Crane in 1960. Over 35 members of the SGLT1 gene family have been identified in animal cells, yeast and bacteria, and all share a common core structure of 13 transmembrane (TM) helices. Electrophysiological techniques have been used to examine the function of several family members, chimeras and mutants expressed in heterologous systems such as Xenopus laevis oocytes. These have revealed that cotransporters are multi-functional proteins: they are responsible for 1). uncoupled passive Na+ transport (Na+ uniport); 2). down-hill water transport in the absence of substrate; 3). Na+/substrate cotransport; and 4). Na+/substrate/water cotransport. The sugar binding and translocation pathway is formed by 4 TM helices near the C-terminal of the protein, helices 10-13. We propose that the N-terminal domains of SGLT1 are responsible for Na+ binding and/or translocation, and that Na+/glucose cotransport results from interactions between the N- and C-terminal domains of the protein.

Neutralization of conservative charged transmembrane residues in the Na+/glucose cotransporter SGLT1.

Our goal was to identify pairs of charged residues in the membrane domains of the Na+/glucose cotransporter (SGLT1) that form salt bridges, to obtain information about packing of the transmembrane helices. The strategy was to neutralize Glu225, Asp273, Asp294, and Lys321 in helices 6-8, express the mutants in oocytes, measure [14C]-alphaMDG uptake, and then attempt to find second-site mutations of opposite charge that restored function. alphaMDG uptake by E225A was identical to that by SGLT1, whereas transport was reduced by over 90% for D273A, D294A, and K321A and was not restored in the double mutants D273A/K321A or D294A/K321A. This suggested that K321 did not form salt bridges with D273 or D294 and that E225 was not involved in salt-bridging. Neutralization of K321 dramatically changed the Na+ uniport and Na+/glucose cotransport kinetics. The maximum rate of uniport in K321A increased 3-5-fold with a decrease in the apparent affinity for Na+ (70 vs 3 mM) and no change in apparent H+ affinity (0.5 microM). The change in Na+ affinity caused a +50 mV shift in the charge/voltage (Q/V) and relaxation time constant (tau)/voltage curves in the presteady-state kinetics. The presteady-state kinetics in H+ remained unchanged. The lower Na+ affinity resulted also in a 200-fold increase in the apparent K0.5 for alphaMDG and phlorizin. Replacements of K321 with alanine, valine, glutamine, arginine, or glutamic acid residues changed the steady-state kinetics in a similar way. Therefore, we suggest that K321 determines, directly or indirectly, (i) the rate and selectivity of SGLT1 uniport activity and (ii) the apparent affinities of SGLT1 for Na+, and indirectly sugar in the cotransport mode.

Five transmembrane helices form the sugar pathway through the Na+/glucose cotransporter.

To test the hypothesis that the C-terminal half of the Na+/glucose cotransporter (SGLT1) contains the sugar permeation pathway, a cDNA construct (C5) coding for rabbit SGLT1 amino acids 407-662, helices 10-14, was expressed in Xenopus oocytes. Expression and function of C5 was followed by Western blotting, electron microscopy, radioactive tracer, and electrophysiological methods. The C5 protein was synthesized in 20-fold higher levels than SGLT1. The particle density in the protoplasmic face of the oocyte plasma membrane increased 2-fold after C5-cRNA injection compared with noninjected oocytes. The diameters of the C5 particles were heterogeneous (4.8 +/- 0.3, 7.1 +/- 1.2, and 10.3 +/- 0.8 nm) in contrast to the endogenous particles (7.6 +/- 1.2 nm). C5 increased the alpha-methyl-D-glucopyranoside (alphaMDG) uptake up to 20-fold above that of noninjected oocytes and showed an apparent K0.5alphaMDG of 50 mM and a turnover of approximately 660 s-1. Influx was independent of Na+ with transport characteristics similar to those of SGLT1 in the absence of Na+: 1) selective (alphaMDG > D-glucose > D-galactose >> L-glucose approximately D-mannose), 2) inhibited by phloretin, KiPT = approximately 500 microM, and 3) insensitive to phlorizin. These results indicate that C5 behaves as a specific low affinity glucose uniporter. Preliminary studies with three additional constructs, hC5 (the human equivalent of C5), hC4 (human SGLT1 amino acids 407-648, helices 10-13), and hN13 (amino acids 1-648, helices 1-13), further suggest that helices 10-13 form the sugar permeation pathway for SGLT1.

Biophysical characteristics of the pig kidney Na+/glucose cotransporter SGLT2 reveal a common mechanism for SGLT1 and SGLT2.

The Na+-dependent, low affinity glucose transporter SGLT2 cloned from pig kidney is 76% identical (at the amino acid level) to its high affinity homologue SGLT1. Using two-microelectrode voltage clamp, we have characterized the presteady-state and steady-state kinetics of SGLT2 expressed in Xenopus oocytes. The kinetic properties of the steady-state sugar-evoked currents as a function of external Na+ and alpha-methyl-D-glucopyranoside (alphaMG) concentrations were consistent with an ordered, simultaneous transport model in which Na+ binds first. Na+ binding was voltage-dependent and saturated with hyperpolarizing voltages. Phlorizin was a potent inhibitor of the sugar-evoked currents (KiPz approximately 10 microM) and blocked an inward Na+ current in the absence of sugar. SGLT2 exhibited Na+-dependent presteady-state currents with time constants 3-7 ms. Charge movements were described by Boltzmann relations with apparent valence approximately 1 and maximal charge transfer approximately 11 nC, and were reduced by the addition of sugar or phlorizin. The differences between SGLT1 and SGLT2 were that (i) the apparent affinity constant (K0.5) for alphaMG (approximately 3 mM) was an order of magnitude higher for SGLT2; (ii) SGLT2 excluded galactose, suggesting discrete sugar binding; (iii) K0.5 for Na+ was lower in SGLT2; and (iv) the Hill coefficient for Na+ was 1 for SGLT2 but 2 for SGLT1. Simulations of the six-state kinetic model previously proposed for SGLT1 indicated that many of the kinetic properties observed in SGLT2 are expected by simply reducing the Na+/glucose coupling from 2 to 1.

Kinetic and specificity differences between rat, human, and rabbit Na+-glucose cotransporters (SGLT-1).

The Na+ activation and substrate specificity of human, rabbit, and rat Na+-glucose cotransporter (SGLT-1) isoforms were characterized using the Xenopus oocyte expression system and the two-electrode voltageclamp method. We find that there are differences, major and minor, in both the kinetics and substrate specificities between these isoforms; the substrate concentration at half-maximal current (K0.5) for hexoses varies from 0.2 to > 40 mM, depending on the species and sugar; the affinity constant (Ki) for phlorizin, the classic competitive inhibitor of SGLT-1, varies lover two orders of magnitude (rat Ki = 0.03 microM vs. rabbit Ki = 1.4 microM); and some glucoside inhibitors of the rabbit isoform, p-nitrophenyl glucose and beta-naphthyl glucose, are transported by the human and rat transporters. Na+ activation is more sensitive to membrane potential in the human and rat isoforms compared with rabbit. The rabbit isoform has a higher apparent affinity for alpha-methylglucose and 3-O-methylglucose by a factor of two than either human or rat. These results can be quantitatively fitted by our six-state kinetic model of SGLT-1, providing insight into the processes involved in these changes. For example, the model predicts that Na+ binding (rate constant, k12) in human and rat SGLT-1 is similar but is fourfold larger than in rabbit, whereas sugar binding (k23) in rabbit and rat is similar but double the value in human SGLT-1. The differences in the primary amino acid sequences between these three homologous proteins must account for the kinetic and substrate specificity differences, and comparisons of the functional properties and amino acid sequences of SGLT-1 isoforms provide useful information about structure/function relationships.

Sugar binding to Na+/glucose cotransporters is determined by the carboxyl-terminal half of the protein.

d-Glucose is absorbed across the proximal tubule of the kidney by two Na+/glucose cotransporters (SGLT1 and SGLT2). The low affinity SGLT2 is expressed in the S1 and S2 segments, has a Na+:glucose coupling ratio of 1, a K0.5 for sugar of approximately 2 mM, and a K0.5 for Na+ of approximately 1 mM. The high affinity SGLT1, found in the S3 segment, has a coupling ratio of 2, and K0.5 for sugar and Na+ of approximately 0.2 and 5 mM, respectively. We have constructed a chimeric protein consisting of amino acids 1-380 of porcine SGLT2 and amino acids 381-662 of porcine SGLT1. The chimera was expressed in Xenopus oocytes, and steady-state kinetics were characterized by a two-electrode voltage-clamp. The K0.5 for alpha-methyl-d-glucopyranoside (0.2 mM) was similar to that for SGLT1, and like SGLT1 the chimera transported D-galactose and 3-O-methylglucose. In contrast, SGLT2 transports poorly D-galactose and excludes 3-O-methylglucose. The apparent K0.5Na was 3.5 mM (at -150 mV), and the Hill coefficient ranged between 0.8 and 1.5. We conclude that recognition/transport of organic substrate is mediated by interactions distal to amino acid 380, while cation binding is determined by interactions arising from the amino- and carboxyl-terminal halves of the transporters. Surprisingly, the chimera transported alpha-phenyl derivatives of D-glucose as well as the inhibitors of sugar transport: phlorizin, deoxyphlorizin, and beta-D-glucopyranosylphenyl isothiocyanate are transported with high affinity (K0.5 for phlorizin was 5 microM). Thus, the pocket for organic substrate binding is increased from 10 x 5 x 5 (A) for SGLT1 to 11 x 18 x 5 (A) for the chimera.

Arginine-427 in the Na+/glucose cotransporter (SGLT1) is involved in trafficking to the plasma membrane.

To investigate the role of charged intramembrane residues in the function of the rabbit Na+/glucose cotransporter (rbSGLT1) we substituted arginine-427 (R427) by alanine in the putative domain M9 SGLT1. This residue is conserved in all the members of the SGLT1 family. The mutant protein (R427A) was expressed in Xenopus oocytes and, although Western blot analysis revealed that it was produced in amounts comparable to wild-type, no function was measured. Freeze-fracture analysis showed that R427A SGLT1 was not in the plasma membrane while immunocytochemical experiments localized the transporter to just beneath it. These results indicate that arginine-427 plays a critical role in SGLT1 trafficking to the plasma membrane.

Kinetics of steady-state currents and charge movements associated with the rat Na+/glucose cotransporter.

The rat Na+/glucose cotransporter (SGLT1) was expressed in Xenopus oocytes and steady-state and transient currents were measured using a two-electrode voltage clamp. The maximal glucose induced Na(+)-dependent inward current was approximately 300-500 nA. The apparent affinity constants for sugar (alpha-methyl-D-glucopyranoside; alpha MDG) (K alpha MDG 0.5) and sodium (KNa0.5) at a membrane potential of -150 mV were 0.2 mM and 4 mM. The KNa0.5 increased continuously with depolarizing potentials reaching 40 mM at -30 mV, K alpha MDG 0.5 was steeply voltage dependent, 0.46 mM at -30 mV and 1 mM at -10 mV. From all tested monovalent cations only Li+ could substitute for Na+, but with lower affinity. The relative substrate specificity was D-glucose > alpha MDG approximately D-galactose > 3-O-Me-Glc >> beta-naphthyl-D-glucoside >> uridine. Phlorizin (Pz), the specific blocker of sugar transport, showed an extremely high affinity for the rat cotransporter with an inhibitor constant (KPzi) of 12 nM. SGLT1 charge movements in the absence of sugar were fitted by the Boltzmann equation with an apparent valence of the movable charge of approximately 1, a potential for 50% maximal charge transfer (V0.5) of -43 mV, and a maximal charge (Qmax) of 9 nanocoulombs. The apparent turnover number for the rat SGLT1 was 30 s-1. Model simulations showed that the kinetics of the rat SGLT1 are described by a six-state ordered nonrapid equilibrium model, and comparison of the kinetics of the rat, rabbit and human cotransporters indicate that they differ mainly in their presteady-state kinetic parameters.

'Active' sugar transport in eukaryotes.

Sugar transporters in prokaryotes and eukaryotes belong to a large family of membrane proteins containing 12 transmembrane alpha-helices. They are divided into two classes: one facilitative (uniporters) and the other concentrative (cotransporters or symporters). The concentrative transporters are energised by either H+ or Na+ gradients, which are generated and maintained by ion pumps. The facilitative and H(+)-driven sugar transporters belong to a gene family with a distinctive secondary structure profile. The Na(+)-driven transporters belong to a separate, small gene family with no homology at either the primary or secondary structural levels. It is likely that the Na(+)- and H(+)-driven sugar cotransporters share common transport mechanisms. To explore these mechanisms, we have expressed cloned eukaryote Na+/sugar cotransporters (SGLT) in Xenopus laevis oocytes and measured the kinetics of sugar transport using two-electrode voltage-clamp techniques. For SGLT1, we have developed a six-state ordered model that accounts for the experimental data. To test the model we have carried out the following experiments. (i) We measured pre-steady-state kinetics of SGLT1 using voltage-jump techniques. In the absence of sugar, SGLT1 exhibits transient carrier currents that reflect voltage-dependent conformational changes of the protein. Time constants for the carrier currents give estimates of rate constants for the conformational changes, and the charge movements, integrals of the transient currents, give estimates of the number and valence of SGLT1 proteins in the plasma membrane. Ultrastructural studies have confirmed these estimates of SGLT1 density. (ii) We have perturbed the kinetics of the cotransporter by site-directed mutagenesis of selected residues.(ABSTRACT TRUNCATED AT 250 WORDS)

SAAT1 is a low affinity Na+/glucose cotransporter and not an amino acid transporter. A reinterpretation.

Recently a member of the Na+/glucose (SGLT1) gene family of cotransporters was isolated from a pig renal cell line and was thought to be the neutral amino acid transporter System A. This cDNA (Kong, C. T., Yet, S. F., and Lever, J. E. (1993) J. Biol. Chem. 268, 1509-1512) encodes a 660-amino acid protein with 76% identity to SGLT1. To confirm and extend the kinetic characterization of SAAT1, we have expressed this clone in Xenopus oocytes and measured transport using both radiotracer and electrophysiological techniques. SAAT1 did not stimulate either 50 microM 2-(methylamino)isobutyrate uptake or 2-(methylamino)isobutyrate-evoked inward Na+ currents, but instead stimulated 50 microM alpha MG (alpha-methyl-D-glucopyranoside) uptake 27-fold from 2 +/- 1 pmol.h-1/oocyte (n = 9) to 55 +/- 6 pmol.h-1/oocyte (n = 9) and alpha MG-evoked inward Na+ currents (I) by up to 1000 nA/oocyte. The apparent affinity constant for alpha MG (K alpha MG 0.5) was approximately 2 mM and was independent of membrane potential from -30 to -150 mV but was voltage-sensitive between -30 and +30 mV. The relative sugar specificity for the transporter was alpha MG > or = D-glucose >> D-galactose >>> 3-O-methyl-D-glucopyranose, L-glucose. The sugar-evoked currents were Na(+)-dependent (KNa 0.5 approximately 10 mM at -50 mV) and the Hill coefficient was 1. KNa 0.5 decreased with hyperpolarization of the membrane from -50 to -150 mV. Phlorizin inhibited the alpha MG-evoked current with apparent Ki of 18 microM at -50 mV. We conclude that the SAAT1 cDNA encodes a renal low affinity Na+(1)/glucose(1) cotransporter and propose that pig SAAT1 be renamed pSGLT2.

Sodium/D-glucose cotransporter charge movements involve polar residues.

Na(+)-dependent glucose transporters (SGLT1) exhibit transient carrier currents with a time constant (tau) of 2-20 ms, and the charge transfer (Q) fits the Boltzmann equation. There is a 60-mV negative displacement in the tau/V and Q/V curves between the human and rabbit SGLT1 proteins, and the initial goal was to identify the charges responsible for these differences in kinetics. We have focused on residue 176 in putative transmembrane helix (M4) because this is an aspartic acid in rabbit and asparagine in human. Asp-176 in rabbit SGLT1 was replaced with asparagine and alanine residues, and the wild-type and mutant proteins were expressed in Xenopus laevis oocytes. A two-electrode voltage clamp was used to measure the kinetics of charge transfer. There was no difference between the wild-type and D176N, but there was a 60-mV negative shift in the tau/V and Q/V curves with D176A. This suggests that polar residues at position 176 play an important role in determining charge transfer, probably by electrostatic bonding to a neighboring polar residue in the membrane domain of the protein. The similarity between rabbit SGLT1 and the D176N mutant further indicates that other membrane residues account for the difference between rabbit and human SGLT1. There were only modest changes in the steady-state Na+/glucose cotransport kinetics between wild-type and D176A mutant transporters in the voltage range +50 to -50 mV. Model simulations show that the mutation alters the rate constants for conformational changes of the unloaded transporter. Phlorizin, a specific competitive inhibitor of sugar transport, has a lower affinity for the D176A mutant than for SGLT1. This indicates that polar residues at position 176 hydrogen bond with the -OH group on the B-phenyl ring of the inhibitor.

Sequence comparison of the sodium-D-glucose cotransport systems in rabbit renal and intestinal epithelia.

Using an isolated 1.2 kbp PCR product as specific probe, the rabbit renal cortex sodium-D-glucose cotransport system has been found and cloned from a renal cortex cDNA library. Two overlapping cDNA clones were found, one with a length of 2.1 kbp and one of 1.1 kbp resulting in a total sequence of 2.2 kbp without the poly(A) tail. Northern blot hybridization indicated a transcript of approx. 2.4 kb in size. Tissue distribution in the rabbit kidney and intestine indicates that this sequence is present in renal cortex, renal medulla and small intestine in different proportions. It is proposed that this clone codes for a member of the sodium-D-glucose cotransporter systems.

Characterization of an estradiol-stimulated mRNA in the brain of adult male rats.

Differential hybridization of a cDNA library from rat C6 glioma cells with cDNA probes from naive C6 glioma cells and from cells exposed to 17 beta-estradiol identified cDNAs of an mRNA stimulated by 17 beta-estradiol. This mRNA designated ESP1 mRNA, reached maximal levels after 8 h of treatment with 17 beta-estradiol. The stimulation was not suppressed by cycloheximide. Dexamethasone treatment of C6 glioma cells did not induce ESP1 mRNA. It codes for a 164 amino acids long peptide. The sequence is similar in part to that of CRIP protein, a probably member of the ferredoxin superfamily. The conservation of primary structure suggests a role of ESP1 peptide in oxygen consumption. ESP1 mRNA expression is sexually dimorphic in body tissue, whereas it is expressed to comparative levels in the brain of adult males and females. This suggests that 17 beta-estradiol stimulates the expression of the ESP1 gene in the brain of both gender.