Na-dependent <Emphasis Type="SmallCaps">D</Emphasis>-Glucose Transport by Intestinal Brush Border Membrane Vesicles from Gilthead Sea Bream (<Emphasis Type="Italic">Sparus aurata</Emphasis>)

Brush border membrane vesicles (BBMV) enriched in sucrase, maltase and alkaline phosphatase, and impoverished in Na⁺-K⁺-ATPase, were isolated from proximal and distal intestine of the gilthead sea bream (Sparus aurata) by a MgCl₂ precipitation method. Vesicles were suitable for the study of the characteristics of D-glucose apical transport. Only one D-glucose carrier was found in vesicles from each intestinal segment. In both cases, the D-glucose transport system was sodium-dependent, phlorizin-sensitive, significantly inhibited by D-glucose, D-galactose, α-methyl-D-glucose, 3-O-methyl-D-glucose and 2-deoxy-D-glucose, and showed stereospecificity. Apparent affinity constants of D-glucose transport (K_t) were 0.24 ± 0.03 mM in proximal and 0.18 ± 0.03 mM in distal intestine. Maximal rate of influx (Jmax) was 47.3 ± 2.2 pmols. mg⁻¹ protein for proximal and 27.3 ± 3.6 pmols. mg⁻¹ protein for distal intestine. Specific phlorizin binding and relative abundance of an anti-SGLT1 reactive protein were significantly higher in proximal than in distal BBMV. These results suggest the presence of the same D-glucose transporter along the intestine, with a higher density in the proximal portion. This transporter is compatible with the sodium-dependent D-glucose carrier described for other fish and with the SGLT1 of higher vertebrates.This revised version was published online in June 2005 with a corrected cover date.     

Location of amino acid and carbohydrate transport sites in the surface membrane of normal and transformed mammalian cells

Summary Amino acid and carbohydrate transport in normal and malignant transformed hamster cells was studied after binding of the protein Concanavalin A (Con. A) to the surface membrane. Experimental conditions were used so that a similar number of Con. A molecules were bound to both types of cells. The transport of amino acids was inhibited after Con. A binding in the transformed cells but not in normal cells. This was found with the metabolizable amino acidsl-leucine,l-arginine,l-glutamic acid, andl-glutamine, and with the non-metabolizable amino acids cycloleucine and -aminoisobutyric acid. Transport ofd-glucose andd-galactose was more inhibited by Con. A in transformed than in normal cells, and in both types of cellsd-glucose was inhibited more thand-galactose. The inhibition by Con. A on transport was specific, since there was no effect on the transport ofl-fucose in either normal or transformed cells. Con. A also did not effect the entry of 3-0-methyl-d-glucose.These observations can be used to locate amino acid and carbohydrate transport sites in the surface membrane in relation to the binding sites for Con. A. The results indicate that Con. A sites are associated in normal cells with transport sites ford-glucose and to a lesser extentd-galactose, and in transformed cells with transport sites for amino acids and to a greater extent than in normal cells withd-glucose andd-galactose. Malignant transformation of normal cells therefore results in a change in the location of amino acid and carbohydrate transport sites in the surface membrane in relation to the binding sites for Con. A.     

Hexose-transport-deficient mutants of Chlorella vulgaris

Autotrophically grown cells of Chlorella vulgaris show a strong increase in the uptake rates for hexoses and for seven amino acids when incubated in the presence of hexoses. This increase is due to de-novo synthesis of three transport proteins: one forhexoses and two for amino acids. Mutants deficient in hexose transport were obtained after treatment of wild-type cells with acridine orange, followed by a selection procedure using the toxic hexose analogue, 2-deoxy-D-glucose. Moreover, the two amino-acid-transport systems could not be induced in these mutants by hexoses. The capacity to phosphorylate hexoses was identical in mutants and in the wild-type strain. The loss of transport activities can be correlated with the loss of certain radiolabeled protein bands on fluorograms of sodium dodecylsulfate-polyacrylamide gels. These proteins are assumed to be responsible for the different transport systems in the wild-type strain. With the help of additional mutants defective in one or two of the different aminoacid-transport systems, it has been attempted to assign the different transport activities to individual protein bands on the gel.Abbreviations AUP arginine-uptake-defective mutant - 2-DG 2-deoxy-D-glucose - 6-DG 6-deoxy-D-glucose - HUP hexose-uptake-defective mutant - PUP^- proline-uptake-defective mutant - SDS sodium dodecyl sulfate - WT wild type     

Active Sugar Transport by the Small Intestine : The effects of sugars,amino acids,hexosamines, sulfhydryl-reacting compounds,and cations on the preferential binding of D-glucose to Tris-disrupted brush borders

Tris-disrupted and intact brush border membrane preparations from mucosa of hamster jejunum were capable of preferentially binding actively transported D-glucose in a similar manner. Density gradient centrifugation of the Tris-disrupted brush borders indicated that D-glucose was bound to a fraction containing the cores or inner material of the microvilli. The properties of this binding were examined with the Tris-disrupted brush border preparation. Actively transported sugars competitively inhibited preferential D-glucose binding, whereas no effect was observed with nonactively transported sugars. Neither actively nor nonactively transported amino acids affected D-glucose binding. D-Glucosamine, which is not actively transported, was inhibitory to preferential D-glucose binding as well as to the active transport of D-glucose by everted sacs of hamster jejunum. No inhibitory effect was observed with the same concentration of D-galactosamine. Preferential D-glucose binding was also inhibited by sulfhydryl-reacting compounds, Ca²⁺, and Li⁺ ions. On the other hand, Mg²⁺ was shown to be stimulatory and Na⁺, NH₄ ⁺, and K⁺ had no effect on this phenomenon. The results of these experiments suggest that preferential D-glucose binding to brush borders is related to the initial step in active sugar transport by the small intestine.     

Two substrate sites in the renal Na+-d-glucose cotransporter studied by model analysis of phlorizin binding and-d-glucose transport measurements

Summary Time courses of phlorizin binding to the outside of membrane vesicles from porcine renal outer cortex and outer medulla were measured and the obtained families of binding curves were fitted to different binding models. To fit the experimental data a model with two binding sites was required. Optimal fits were obtained if a ratio of low and high affinity phlorizin binding sites of 1:1 was assumed. Na⁺ increased the affinity of both binding sites. By an inside-negative membrane potential the affinity of the high affinity binding site (measured in the presence of 3 mM Na⁺) and of the low affinity binding site (measured in the presence of 3 or 90 mM Na⁺) was increased. Optimal fits were obtained when the rate constants of dissociation were not changed by the membrane potential. In the presence of 90 mM Na⁺ on both membrane sides and with a clamped membrane potential,K _D values of 0.4 and 7.9 M were calculated for the low and high affinity phlorizin binding sites which were observed in outer cortex and in outer medulla. Apparent low and high affinity transport sites were detected by measuring the substrate dependence ofd-glucose uptake in membrane vesicles from outer cortex and outer medulla which is stimulated by an initial gradient of 90 mM Na⁺(out>in). Low and high affinity transport could be fitted with identicalK _m values in outer cortex and outer medulla. An inside-negative membrane potential decreased the apparentK _m ofhigh affinity transport whereas the apparentK _m of low affinity transport was not changed. The data show that in outer cortex and outer medulla of pighigh and low affinity Na⁺-d-glucose cotransporters are present which containlow and high affinity phlorizin binding sites, respectively. It has to be elucidated from future experiments whether equal amounts of low and high affinity transporters are expressed in both kidney regions or whether the low and high affinity transporter are parts of the same glucose transport moleculc.     

Kinetics of the Reverse Mode of the Na<Superscript>+</Superscript>/Glucose Cotransporter

This study investigates the reverse mode of the Na⁺/glucose cotransporter (SGLT1). In giant excised inside-out membrane patches from Xenopus laevis oocytes expressing rabbit SGLT1, application of α-methyl-D-glucopyranoside (αMDG) to the cytoplasmic solution induced an outward current from cytosolic to external membrane surface. The outward current was Na⁺- and sugar-dependent, and was blocked by phlorizin, a specific inhibitor of SGLT1. The current-voltage relationship saturated at positive membrane voltages (30–50 mV), and approached zero at −150 mV. The half-maximal concentration for αMDG-evoked outward current (K_0.5^αMDG) was 35 mM (at 0 mV). In comparison, K_0.5^αMDG for forward sugar transport was 0.15 mM (at 0 mV). K_0.5^Na was similar for forward and reverse transport (≈35 mM at 0 mV). Specificity of SGLT1 for reverse transport was: αMDG (1.0) > D-galactose (0.84) > 3-O-methyl-glucose (0.55) > D-glucose (0.38), whereas for forward transport, specificity was: αMDG ≈ D-glucose ≈ D-galactose > 3-O-methyl-glucose. Thus there is an asymmetry in sugar kinetics and specificity between forward and reverse modes. Computer simulations showed that a 6-state kinetic model for SGLT1 can account for Na⁺/sugar cotransport and its voltage dependence in both the forward and reverse modes at saturating sodium concentrations. Our data indicate that under physiological conditions, the transporter is poised to accumulate sugar efficiently in the enterocyte.     

Identification and purification of a stress associated nuclear carbohydrate binding protein (Mr 33000) from rat liver by application of a new photoreactive carbohydrate probe

A photoreactive -D-glucose probe has been designed for the specific detection of carbohydrate binding proteins (CBPs). The probe consists of four parts: (i) an -D-glucose moiety; (ii) the digoxigenin tag; (iii) the photoreactive cross-linker; and (iv) the lysyl-lysine backbone. After incubation with lectins in the dark, the probe is activated and cross-linked to the CBPs after being treated by several flashes.Using this method we have identified a new -D-glucose CBP ofM _r=33000, termed CBP33, in the nuclei of rats exposed to transient immobilization stress. Monoclonal antibodies were raised against the partially purified protein and subsequently used to enrich CBP33. It was purified (>2400-fold) to apparent homogeneity from a 0.6M nuclear salt extract by two subsequent affinity chromatography steps (antibody-affinity as well as -D-glucose affinity column).Abbreviations BSA bovine serum albumin - CBP carbohydrate binding protein - DIG digoxigenin - Gal galactose - Glc glucose - Lys lysine - PAGE polyacrylamide gel electrophoresis - SDS sodium dodecyl sulphate.     

The Na+-independentd-glucose transporter in the enterocyte basolateral membrane: Orientation and cytochalasin B binding characteristics

Summary Phloridzin-insensitive, Na⁺-independentd-glucose uptake into isolated small intestinal epithelial cells was shown to be only partially inhibited by trypsin treatment (maximum 20%). In contrast, chymotrypsin almost completely abolished hexose transport. Basolateral membrane vesicles prepared from rat small intestine by a Percoll^® gradient procedure showed almost identical susceptibility to treatment by these proteolytic enzymes, indicating that the vesicles are predominantly oriented outside-out. These vesicles with a known orientation were employed to investigate the kinetics of transport in both directions across the membrane. Uptake data (i.e. movement into the cell) showed aK _t of 48mm and aV _max of 1.14 nmol glucose/mg membrane protein/sec. Efflux data (exit from the cell) showed a lowerK _t of 23mm and aV _max of 0.20 nmol glucose/mg protein/sec.d-glucose uptake into these vesicles was found to be sodium independent and could be inhibited by cytochalasin B. TheK _t for cytochalasin B as an inhibitor of glucose transport was 0.11 m and theK _D for binding to the carrier was 0.08 m.d-glucose-sensitive binding of cytochalasin B to the membrane preparation was maximized withl- andd-glucose concentrations of 1.25m. Scatchard plots of the binding data indicated that these membranes have a binding site density of 8.3 pmol/mg membrane protein. These results indicate that the Na⁺-independent glucose transporter in the intestinal basolateral membrane is functionally and chemically asymmetric. There is an outward-facing chymotrypsin-sensitive site, and theK _t for efflux from the cell is smaller than that for entry. These characteristics would tend to favor movement of glucose from the cell towards the bloodstream.     

Initial steps of αand β-d-glucose binding to intact red cell membrane

Summary The kinetics of the initial phases of d-glucose binding to the glucose transport protein (GLUT1) of the human red cell can be followed by stopped-flow measurements of the time course of tryptophan (trp) fluorescence enhancement. A number of control experiments have shown that the trp fluorescence kinetics are the result of conformational changes in GLUT1. One shows that nontransportable l-glucose has no kinetic response, in contrast to d-glucose kinetics. Other controls show that d-glucose binding is inhibited by cytochalasin B and by extracellular d-maltose. A typical time course for a transportable sugar, such as d-glucose, consists of a zero-time displacement, too fast for us to measure, followed by three rapid reactions whose exponential time courses have rate constants of0.5–100 sec^+–1 at 20°C. It is suggested that the zero-time displacement represents the initial bimolecular ligand/GLUT1 association. Exponential 1 appears to be located at, or near, the external membrane face where it is involved in discriminating among the sugars. Exponential 3 is apparently controlled by events at the cytosolic face. Trp kinetics distinguish the K _d of the epimer, d-galactose, from the K _dfor d-glucose, with results in agreement with determinations by other methods. Trp kinetics distinguish between the binding of the - and -d-glucose anomers. The exponential 1 activation energy of the -anomer, 13.6 ± 1.4 kcal mol^+–1, is less than that of -d-glucose, 18.4 ± 0.8 kcal mol^+–1, and the two Arrhenius lines cross at 23.5°C. The temperature dependence of the kinetic response following -d-glucose binding illustrates the interplay among the exponentials and the increasing dominance of exponential 2 as the temperature increases from 22.3 to 36.6°C. The existence of these interrelations means that previously acceptable approximations in simplified reaction schemes for sugar transport will now have to be justified on a point-to-point basis.We should like to express our thanks to Michael R. Toon for his important contributions. This work was supported in part by a grant-in-aid from the American Heart Association, by the Squibb Institute for Medical Research and by The Council for Tobacco Research.     

Catabolite Repression of induction of aldose reductase activity and utilization of mixed hemicellulosic surgars in Candida guilliermondii

NADPH-dependent aldose reductase activity induced by d-xylose or l-arabinose was detected in cell-free extracts of Candida guilliermondii, but only negligible activities were observed if d-glucose served as carbon source. The induction of aldose reductase activity on mixed sugars was investigated under resting cell conditions. d-Glucose repressed enzyme induction by d-xylose or l-arabinose to varying degrees, and l-arabinose inhibited enzyme induction by d-xylose. During incubation in a mixture of d-xylose-d-glucose, glucose consumption by cells was fast and simultaneous with d-xylose utilization. l-arabinose consumption was poor when it was present as the only sugar and in a mixture with d-glucose; this pentose depletion occurred only when all hexose was consumed. When d-xylose and l-arabinose were present in a mixture, the consumption of both pentoses was reduced by the presence of the second sugar, although both sugars were consumed simultaneously by cells. The results show that induction of aldose reductase activity and d-xylose utilization by cells of Candida guilliermondii are under control of glucose repression.     

Reevaluation of use of retardation chromatography to demonstrate selective monosaccharide “binding” by erythrocyte membranes

Summary Retardation chromatography has been reported to show stereoselective binding of the preferred sugar-transport substrate,d-glucose, by human red cell ghosts or by certain protein extracts of such membranes. However, no detectable differential elution of glucose (as compared with the poorly transported analogue,l-sorbose) was observed with columns of diethylaminoethanol-cellulose impregnated with ghost proteins prepared by either of the recommended procedures (using Triton X-100, or NaI followed by extensive dialysis). Celite columns bearing intact ghosts did show marked initial relative delay in glucose emergence, but this persisted only partially through the elution peak, to be followed by a nearly equivalent and much more protracted retardation of the sorbose. Moreover, this differentiation required that the columns be handled sufficiently gently as to leave intact whole-cell membranes or fairly gross vesicles; freeze-thaw treatment or abrasive stirring abolished both the early glucose retardation and the subsequent sorbose retention. Although conflicting seriously with the simple selective-binding interpretation, these phenomena accord with the suggestion that the sugarcomplexing entities on the columns continue to operate as carriers mediating sugar access into membrane-enclosed compartments. Effects of experimental manipulation of elution rates and of applied sugar levels lend further support to this interpretation. The capacity of the vesicular spaces so vastly exceeds that of the binding itself that resolution of the latter cannot be achieved through this approach.Initial studies were carried out at Department of Pharmacology, University of Louisville School of Medicine, Louisville, Ky.     

Single Step Purification,Characterization and N-Terminal Sequences of a Mannose Specific Lectin from Mulberry Seeds

A mannose/glucose specific lectin have been isolated and purified from mulberry seeds by affinity chromatography on ConA Sepharose. The lectin is monomer in nature as judged by SDS-PAGE and its MW was estimated to be 22,000. The lectin is glycoprotein with neutral sugar content of 28.57%, and mannose and glucose were identified as carbohydrate. The lectin agglutinated rat red blood cells and in a hapten inhibition test, D-mannose and D-glucose was found to be inhibitor. The lectin also exhibited cytotoxic effect in brine shrimp lethality bioassay. The N-terminal sequences of the lectin upto 45-residues except the positions of 21, 39, 42 and 44 were identified. Sequence homology of the lectin is also discussed.     

Control of erythritol dehydrogenase in Schizophyllum commune

Summary An NAD-dependent erythritol dehydrogenase was detected in cell-extracts of basidiospore germinants of Schizophyllum commune following culture on either meso-erythritol or glycerol as sole carbon sources. Induction of erythritol dehydrogenase was also observed in purely vegetative mycelium (str. 845 or str. 699). Erythritol dehydrogenase was not observed in ungerminated basidiospores or germinants which arose on d-glucose, d-mannitol, sorbitol, ribitol, xylitol, d-arabitol or l-arabitol. NAD-coupled polyol dehydrogenases for all the latter sugar alcohols were observed in ungerminated basidiospores, germinants, and vegetative mycelium of S. commune cultured on d-glucose. Basidiospore germination on d-glucose plus meso-erythritol led to a 90% decrease in erythritol dehydrogenase and the specific activity of ribitol dehydrogenase was directly comparable to that seen in d-glucose germinants. Storage experiments of crude extracts of meso-erythritol germinants indicated differential enzyme decay of dehydrogenases for d-mannitol, sorbitol and erythritol while the respective enzymes could be further distinguished by heat-stability as well as preferential utilization of analogues of NAD. DEAE-cellulose column chromatography led to separation of sorbitol dehydrogenase which was also active with xylitol, erythritol dehydrogenase, and mannitol dehydrogenase which was also active with d-arabitol.     

Glucose uptake into plasma membrane vesicles from the maternal surface of human placenta

Summary Glucose uptake into plasma membrane vesicles from the maternal surface of the human placenta was measured with the Millipore filtration technique. Uptake ofd-glucose was dependent on the osmolarity of the incubation medium surrounding the vesicles. Uptake ofd-glucose exceeded that ofl-glucose. The uptake ofd-glucose was not enhanced by placing 100mm NaCl or NaSCN in the medium outside the vesicles (none inside) at the onset of uptake determinations.d-glucose transport was inhibited by cytochalasin B; phloretin, phlorizin, and 1-fluoro-2,4-dinitrobenzene.d-glucose uptake was inhibited by 2-deoxy-d-glucose, 3-O-methyl-d-glucose and to a lesser extent byd-galactose. It was not inhibited by -methyl-d-glucoside. Cytochalasin B binding to the vesicles was 30% inhibited in the presence of 80mm d-glucose. The results indicate that the system for facilitated transport ofd-glucose at the maternal face of the placenta is distinctly different from that on the brush-border membrane of intestine or renal tubule and more closely resembles that of human erythrocyte.     

Functional Asymmetry of the Sodium-d-Glucose Cotransporter Expressed in Yeast Secretory Vesicles

The sodium-d-glucose cotransporter (SGLT1) was expressed in a yeast mutant strain NY 17 (sec6-4) that accumulates secretory vesicles at a nonpermissive temperature because of a block in the delivery of these vesicles to the plasma membrane. By differential centrifugation a microsomal fraction enriched in secretory vesicles was prepared with a high specific activity of the vanadate-sensitive H⁺-ATPase and invertase. In this membrane fraction one protein band of an apparent molecular weight of 55 kDa representing the nonglycosylated SGLT1 protein could be detected by immunochemical analysis. In addition, higher molecular weight protein bands probably representing dimers and aggregates were found. In transport studies with the microsomes d-glucose fluxes showed asymmetric properties: efflux experiments revealed the typical properties of the SGLT1 such as sodium dependence, inhibition by phlorizin and potential dependence. Influx of d-glucose showed no dependence on sodium and was not inhibited by phlorizin. Furthermore, the transporter exhibited a striking asymmetry with regard to the d-glucose affinity and the sugar specificity. These results suggest that the orientation of the SGLT1 expressed in yeast secretory vesicles is, indeed, inverted with regard to its configuration in the plasma membrane of epithelial cells. Moreover, there are striking functional differences between the periplasmic and cytoplasmic face of the transporter. Received: 16 August 2000/Revised: 24 October 2000     

Sodium-cotransport systems in intestine and kidney of the winter flounder

Summary Brush-border membrane vesicles were isolated from the intestine and kidney of the winter flounder,Pseudopleuronectes americanus, and the transport ofd-glucose,l-alanine and sodium was examined by a rapid filtration technique.d-glucose,l-alanine, and sodium entered the same osmotically reactive space suggesting that uptake into vesicles represents transport across rather than binding to the membrane. d-glucose andl-alanine uptake by intestinal and renal brush-border membrane vesicles was stimulated by sodium as compared to potassium or choline. In the presence of a sodium chloride gradient, overshooting uptake was observed indicating a transient intravesicular accumulation ofd-glucose andl-alanine. The sodium-dependentd-glucose uptake was inhibited by phlorizin andd-galactose while the transport ofl-alanine was inhibited byl-phenylalanine. The sodium-dependent transport ofd-glucose andl-alanine was affected by the electrical potential difference across the vesicle membrane; the addition of valinomycin in the presence of an inwardly directed potassium chloride gradient inhibited sodium-dependent solute uptake, whereas replacing chloride or gluconate with more permeant anions, such as SCN^–, stimulated uptake. Similar results were obtained with intestinal and renal membranes; they document the presence of sodium/d-glucose and sodium/l-alanine cotransport systems in the brush-border membrane of intestine and kidney.Sodium uptake into brush border membrane vesicles from the flounder intestine and kidney was saturable (tracer replacement) and trans-stimulated (tracer coupling), indicating transport via facilitated diffusion systems. Additionally, sodium uptake was only slightly affected by superimposing diffusion potentials demonstrating that the majority of sodium transport was by electroneutral coupled processes. In both the intestinal and kidney brush-border membrane vesicles sodium uptake was inhibited by an inwardly directed proton gradient suggesting the presence of a sodium/proton exchange mechanism. In intestinal, but not in renal membrane preparations, sodium uptake was stimulated by chloride. Chloride stimulation was abolished after preincubation with furosemide indicating the presence of an additional coupled sodium-chloride transport in the intestinal brush-border membranes.The experiments were carried out at the Mount Desert Island Biological Laboratory, Salsbury Cove, Maine 04672, USAAddress effective February 1, 1980: Albert Einstein College of Medicine, Department of Physiology, 1300 Morris Park Avenue, Bronx, New York 10461, USA     

Ethanol fermentation of mixed-sugars using a two-phase, fed-batch process: method to minimize D-glucose repression of Candida shehatae D-xylose fermentations

Candida shehatae cells pre-grown on D-xylose simultaneously consumed mixtures of D-xylose and D-glucose, under both non-growing (anoxic) and actively growing conditions (aerobic), to produce ethanol. The rate of D-glucose consumption was independent of the D-xylose concentration for cells induced on D-xylose. However, the D-xylose consumption rate was approximately three times lower than the D-glucose consumption rate at a 50% D-glucose: 50% D-xylose mixture. Repression was not observed (substrate utilization rates were approximately equal) when the percentage of D-glucose and D-xylose was changed to 22% and 78%, respectively. In fermentations with actively growing cells (50% glucose and D-xylose), ethanol yields from D-xylose increased, the % D-xylose utilized increased, and the xylitol yield was significantly reduced in the presence of D-glucose, compared to anoxic fermentations (Y_ETOH,xylose = 0.2–0.40 g g⁻¹, 75–100%, and Y_xylitol = 0–0.2 g g⁻¹ compared to Y_ETOH,xylose = 0.15 g g⁻¹, 56%, Y_xylitol = 0.51 g g⁻¹, respectively). To increase ethanol levels and reduce process time, fed-batch fermentations were performed in a single stage reactor employing two phases: (1) rapid aerobic growth on D-xylose (μ = 0.32 h⁻¹) to high cell densities; (2) D-glucose addition and anaerobic conditions to produce ethanol (Y_ETOH,xylose = 0.23 g g⁻¹). The process generated high cell densities, 2 × 10⁹ cells ml⁻¹, and produced 45–50 g L⁻¹ ethanol within 50 h from a mixture of D-glucose and D-xylose (compared to 30 g L⁻¹ in 80 h in the best batch process). The two-phase process minimized loss of cell viability, increased D-xylose utilization, reduced process time, and increased final ethanol levels compared to the batch process. Received 23 February 1998/ Accepted in revised form 15 July 1998     

Modulation of water and urea transport in human red cells: Effects of pH and phloretin

Summary It has previously been shown by Macey and Farmer (Biochim. Biophys. Acta 211:104–106, 1970) that phloretin inhibits urea transport across the human red cell membrane yet has no effect on water transport. Jennings and Solomon (J. Gen. Physiol. 67:381–397, 1976) have shown that there are separate lipid and protein binding sites for phloretin on the red cell membrane. We have now found that urea transport is inhibited by phloretin binding to the lipids with aK ₁ of 25±8 m in reason-able agreement with theK _D of 54±5 m for lipid binding. These experiments show that lipid/protein interactions can alter the conformational state of the urea transport protein. Phloretin binding to the protein site also modulates red cell urea transport, but the modulation is opposed by the specific stilbene anion transport inhibitor, DIDS (4,4-diisothiocyano-2,2-stilbene disulfonate), suggesting a linkage between the urea transport protein and band 3. Neither the lipid nor the protein phloretin binding site has any significant effect on water transport. Water transport is, however, inhibited by up to 30% in a pH-dependent manner by DIDS binding, which suggests that the DIDS/band 3 complex can modulate water transport.     

Biosynthesis of gallotannins. Enzymatic conversion of 1,6-digalloylglucose to 1,2,6-trigalloylglucose

Cell-free extracts from Rhus typhina L. (staghorn sumach) leaves were found to catalyze the transfer of the galloyl moiety of -glucogallin (1-O-galloyl--D-glucose) to 1,6-di-O-galloyl--D-glucose, resulting in the specific formation of 1,2,6-tri-O-galloyl--D-glucose, an intermediate of gallotannin biosynthesis. The reaction product was unequivocally identified by co-chromatography with authentic references using reversed-phase high-performance liquid chromatography and by ¹H-nuclear-magnetic-resonance spectroscopy.Abbreviations HPLC high-performance liquid chromatography - NMR nuclear magnetic resonance     

Function and presumed molecular structure of Na+-D-glucose cotransport systems

Functional characterization of Na⁺-d-glucose cotransport in intestine and kidney indicates the existence of heterogeneous Na⁺-d-glucose cotransport systems. Target size analysis of the transporting unit and model analysis of substrate binding have been performed and proteins have been cloned which mediate (SGLT1) and modulate (RS1) the expression of Na⁺-d-glucose cotransport. The experiments support the hypothesis that functional Na⁺-d-glucose cotransport systems in mammals are composed of two SGLT1-type subunits and may contain one or two RS1-type proteins. SGLT1 contains up to twelve membrane-spanning -helices, whereas RS1 is a hydrophilic extracellular protein which is anchored in the brush-border membrane by a hydrophobic -helix at the C-terminus. SGLT1 alone is able to translocate glucose together with sodium; however, RS1 increases the V _max of transport expressed by SGLT1. In addition, the biphasic glucose dependence of transport, which is typical for kidney and has been often observed in intestine, was only obtained after coexpression of SGLT1 and RS1.