Glycodeoxycholate transport in brush border membrane vesicles isolated from rat jejunum and ileum.

The transport of the bile salt, glycodeoxycholate, was studied in vesicles derived from rat jejunal and ileal brush border membranes using a rapid filtration technique. The uptake was osmotically sensitive, linearly related to membrane protein and resembled D-glucose transport. In ileal, but not jejunal, vesicles glycodeoxycholate uptake showed a transient vesicle/medium ratio greater than 1 in the presence of an initial sodium gradient. The differences between glycodeoxycholate uptake in the presence and absence of a Na+ gradient yielded a saturable transport component. Kinetic analysis revealed a Km value similar to that described previously in everted whole intestinal segments and epithelial cells isolated from the ileum. These findings support the existence of a transport system in the brush border membrane that: (1) reflects kinetics and characteristics of bile salt transport in intact intestinal preparations, and (2) catalyzes the co-transport of Na+ and bile salt across the ileal membrane in a manner analogous to D-glucose transport.     

Jejunal and ileal d-glucose transport in isolated brush border membranes

d-Glucose transport was investigated in isolated brush border membranes from small intestine. The transport properties of membranes from upper jejunum were compared with those from terminal ileum. The jejunal membranes accumulated d-glucose to a greater extent than the ileal membranes when supplied with energy in the form of a NASCN gradient. This difference is behavior is similar to that of the more intact epithelial preparations and suggests that the isolated membranes actually reflect the state present in intact cells. Ileal membranes transported d-glucose about two to three times slower than the jejunal ones, which can partially explain the lower sugar accumulation.     

Aboral changes in D-glucose transport by human intestinal brush-border membrane vesicles.

D-Glucose transport was investigated in isolated brush-border membrane vesicles from human small intestine. Characteristics of D-glucose transport from the jejunum were compared with that in the mid and terminal ileum. Jejunal and mid-ileal D-glucose transport was Na+-dependent and electrogenic. The transient overshoot of jejunal D-glucose transport was significantly greater than corresponding values in mid-ileum. The terminal ileum did not exhibit Na+-dependent D-glucose transport, but did exhibit Na+-dependent taurocholate transport. Na+-glucose co-transport activity as measured by tracer-exchange experiments was greatest in the jejunum, and diminished aborally. We conclude that D-glucose transport in man is Na+-dependent and electrogenic in the proximal intestine and directly related to the activity of D-glucose-Na+ transporters present in the brush-border membranes. D-Glucose transport in the terminal ileum resembles colonic transport of D-glucose.     

Reconstitution of a partially purified Na+-dependent D-glucose transport system from rat jejunal brush border membranes

The Na+-dependent D-glucose transport system of rat jejunal brush border membranes was partially purified and reconstituted into functional proteoliposomes. Brush border membrane vesciles isolated from villous cells were first extracted with 0.3% cholate to remove extrinsic proteins and the insoluble residual pellet was reextracted with 1.2% cholate. The 1.2% cholate-extracted soluble fraction was then further purified by hydroxylapatite and Concanavalin A affinity chromatography in tandem. When the HLP-unadsorbed-ConA-unadsorbed fraction was reconstituted into proteoliposomes, it showed a characteristic Na+-coupled, phlorizin inhibitable, D-glucose transport activity that was 3 fold higher than that of the reconstituted proteoliposomes of the 1.2% cholate-extracted fraction. This partially purified fraction also displayed the simplest polypeptide composition pattern among all the membrane fractions analysed in SDS-polyacrylamide gels.     

The Na+ gradient-dependent transport of D-glucose in renal brush border membranes.

The Na+-dependent transport of D-glucose was studied in brush border membrane vesicles isolated from the rabbit renal cortex. The presence of a Na+ gradient between the external incubation medium and the intravesicular medium induced a marked stimulation of D-glucose uptake. Accumulation of the sugar in the vesicles reached a maximum and then decreased, indicating efflux. The final level of uptake of the sugar in the presence of the Na+ gradient was identical with that attained in the absence of the gradient, suggesting that equilibrium was established. At the peak of the overshoot the uptake of D-glucose was more than 10-fold the equilibrium value. These results suggest that the imposition of a large extravesicular to intravesicular gradient of Na+ effects the transient movement of D-glucose into renal brush border membranes against its concentration gradient. The stimulation of D-glucose uptake into the membranes was specific for Na+. The rate of uptake was enhanced with increased concentration of Na+. Increasing Na+ in the external medium lowered the apparent Km for D-glucose. The Na+ gradient effect on D-glucose transport was dissected into a stimulatory effect when Na+ and sugar were on the same side of the membrane (cis stimulation) and an inhibitory effect when Na+ and sugar were on opposite sides of the membrane (trans inhibition). The uptake of D-glucose, at a given concentration of sugar, reflected the sum of the contributions from a Na+-dependent transport system and a Na+-independent system. The relative stimulation of D-glucose uptake by Na+ decreased as the sugar concentration increased. It is suggested, however, that at physiological concentrations of D-glucose the asymmetry of Na+ across the brush border membrane might fully account for uphill D-glucose transport. The physiological significance of the findings is enhanced additionally by observations that the Na+-dependent D-glucose transport system in the membranes in vitro possessed the sugar specificities and higg phlorizin sensitivity characteristic of more intact preparations. These results provide strong experimental evidence for the role of Na+ in transporting D-glucose across the renal proximal tubule luminal membrane.     

Resistance of the intact and reconstituted adipocyte hexose transport system to irreversible inhibition by sulfhydryl and amino reagents

Sensitivity of the adipocyte D-glucose transport system in intact plasma membranes or following solubilization and reconstitution into phospholipid vesicles to several protein-modifying reagents was investigated. When intact plasma membranes were incubated with N-ethylmaleimide (20 mM) or fluorodinitrobenzene (4 mM), D-glucose transport activity was virtually abolished. However, washing the membranes free of unreacted reagents restored transport activity, indicating that covalent interaction with the membranes did not mediate the transport inhibition. Reaction of [³H] N-ethylmaleimide with plasma membranes under similar conditions resulted in extensive labeling of all protein fractions resolved on dodecyl sulfate gels. Similarly, addition of N-ethyl-maleimide to cholate-solubilized membrane protein had no effect on transport activity in artifical phospholipid vesicles reconstituted under conditions where the membrane protein was free of unreacted N-ethylmaleimide. Transport activity in plasma membranes was also inhibited by both reduced and oxidized dithiothreitol or glutathione (15 mM) in a readily reversible manner, consistent with a noncovalent mode of inhibition. Thus, the insulin-responsive adipocyte D-glucose transport system differs from the red cell hexose transport system in its remarkable insensitivity to modulation by covalent blockade of sulfhydryal or amino groups by the reagents studied.     

Improved stability of rabbit and rat intestinal brush border membrane vesicles using phospholipase inhibitors

The initial rates of Na(+)-dependent D-aspartate and D-glucose uptakes were shown to decline from the time of resuspension of brush border membrane vesicles isolated from rabbit and rat jejunum by standard divalent cation precipitation procedures. The former were however more stable than the latter and followed quite closely the decrease in the intravesicular volume, thus suggesting that the loss of transport activity may involve both nonspecific opening of the vesicles and either direct or indirect specific inactivation of the transporters. Uptake rates for both substrates did tend to stabilize at 6-24 h from resuspension, however this final 'next day' uptake activity was too low to be of practical use in kinetic studies. Freezing aliquots of rabbit jejunal vesicles in liquid N2 until the time of assay resulted in complete stabilization of D-glucose uptake. A modified homogenate buffer designed to inhibit a broad spectrum of phospholipase activities resulted in a partial stabilization of glucose transport by rabbit jejunal vesicles with, on average, an over 6-fold enrichment in the 'next day' stable specific activity of uptake as compared to unfrozen vesicles. The modified homogenate buffer also improved the stability and the 'next day' specific activities of D-glucose uptake in rat jejunal brush border vesicles and D-aspartic acid uptake in rabbit jejunal vesicles. It also completely stabilized the intravesicular volume in the latter preparation. An evaluation of the kinetic parameters of Na(+)-dependent D-glucose transport in rabbit vesicles prepared from either the standard homogenate media and frozen in liquid N2 or the modified media and allowed to stabilize overnight, revealed a single transport system with a Km of 0.31-0.32 mM as the best model to fit the data. As such the modifications to the homogenate media do not appear to effect the functional properties of D-glucose transport in the membrane. While being less efficient in stabilizing the vesicles than the rapid freezing protocol, it is shown that the modified homogenate should however be preferred when dealing with slowly permeant ions like choline since it provides in this case the only alternative to reliable measurement of uptake rates across a stable and equilibrated vesicle preparation.     

Proximo-distal gradient of Na+-dependent D-glucose transport activity in the brush border membrane vesicles from the human fetal small intestine

Brush-border membrane vesicles were isolated from the jejunum and ileum of 17-20-week-old normal human fetuses and found to be highly enriched in sucrase activity with less than 5% contamination by basolateral membranes. Time course studies of D-glucose uptake clearly showed a transient, phlorizin-sensitive, and Na+-dependent accumulation of sugar into these vesicles. Higher maximum overshoot values and initial rates of D-glucose uptake were recorded in jejunal as compared to ileal vesicles while low substrate binding to the membranes, identical intravesicular volumes and equivalent dissipation of the Na+-gradient were found in the two preparations. It was concluded that a fully functional Na+-D-glucose cotransport system is present with a proximo-distal gradient of activity during the early gestation period.     

Retention of insulin-stimulated D-glucose transport activity by adipocyte plasma membranes following extraction of extrinsic proteins

Plasma membrane vesicles prepared from adipocytes incubated with insulin exhibited accelerated D-glucose transport activity characteristic of insulin action on intact fat cells. Both control and insulin-stimulated D-glucose transport activities were inhibited by cytochalasin B and thiol reagents. Extraction of plasma membranes with dimethylmaleic anhydride eluted 80% of the protein from plasma membrane vesicles. The two major glycoprotein bands (94,000 and 78,000 daltons) and small amounts of a 56,000-dalton band were retained in dodecyl sulfate gels of the extracted membranes. Both control and insulin-activated D-glucose transport activities were retained by plasma membrane vesicles extracted with dimethylmaleic anhydride. Cytochalasin B binding activity was also retained by extracted membrane vescles and D-glucose uptake into extracted vescles derived from untreated or insulin-treated fat cells was inhibited by cytochalasin B. These results suggest that the modification of the adipocyte hexose transport system elicited by insulin action is not altered by a major purification step which involves quantitative extraction of extrinsic membrane proteins.     

Insulin-stimulated glucose transport in rat adipose cells. Modulation of transporter intrinsic activity by isoproterenol and adenosine

The mechanism of modulation of insulin-stimulated glucose transport activity in isolated rat adipose cells by lipolytic and antilipolytic agents has been examined. We have measured glucose transport activity in intact cells with 3-O-methylglucose and in plasma membranes with D-glucose, and the concentration of glucose transporters in plasma membranes using a cytochalasin B binding assay. In intact cells, isoproterenol reduced insulin-stimulated transport activity by 60%. This effect was lost after cooling and washing the cells with homogenization buffer, and neither the concentration of glucose transporters nor transport activity in the plasma membranes differed from control. However, treatment of cells with KCN prior to homogenization preserved the isoproterenol effect through the fractionation procedure. Plasma membranes from these cells contained an unchanged number of transporters (31 +/- 7, mean +/- S.E., versus 31 +/- 4 pmol/mg of protein in controls) but transported glucose at a reduced rate (19 +/- 6 versus 48 +/- 9 pmol/mg of protein/s). Conversely, incubation of intact cells in the presence of adenosine stimulated plasma membrane glucose transport activity compared to that in the absence of adenosine (44 +/- 6 versus 36 +/- 6 pmol/mg of protein/s). Kinetic studies of isoproterenol-inhibited glucose transport in plasma membranes revealed a 60% decrease in Vmax (2900 +/- 350 versus 7200 +/- 1000 pmol/mg of protein/s) and a small increase in Km (15.1 +/- 1 versus 13.0 +/- 0.6 mM). These data indicate that modifications of glucose transport activity produced by lipolytic and antilipolytic agents in intact adipose cells can be fully retained in plasma membranes isolated under appropriate conditions. Furthermore, the effects of these agents occur through a modification of the glucose transporter intrinsic activity.     

Modulation of glucose uptake in animal cells. Studies using plasma membrane vesicles isolated from nontransformed and simian virus 40-transformed mouse fibroblast cultures.

Plasma membrane vesicles isolated from nontransformed and Simian virus 40-transformed mouse fibroblast cultures catalyzed carrier-mediated D-glucose transport without detectable metabolic conversion to glucose 6-phosphate. Glucose transport activity was stereospecific, temperature-dependent, sensitive to inactivation by p-chloromercuriphenylsulfonate, and accompanied plasma membrane material during subcellular fractionation. D-Glucose efflux from vesicles was inhibited by phloretin, an inhibitor of glucose uptake in intact cells. Cytochalasin B, a potent inhibitor of glucose uptake when tested with the intact cells used for vesicle isolation did not inhibit glucose transport in vesicles despite the presence of high affinity cytochalasin binding sites in isolated membranes. The enhanced glucose uptake observed in intact cells after viral transformation was not expressed in vesicles: no significant differences in glucose transport specific activity could be detected in vesicle preparations from nontransformed and transformed mouse fibroblast cultures. These findings indicate that cellular components distinct from glucose carriers can mediate changes in glucose uptake in mouse fibroblast cultures in at least two cases: sensitivity to inhibition by cytochalasin B and the enhanced cellular sugar uptake observed after viral transformation.     

Heterogeneity of brush-border-membrane vesicles from rat small intestine prepared by a precipitation method using Mg/EGTA

Brush border membrane vesicles from rat small intestine were isolated by a Mg/EGTA precipitation method. Further fractionation either by free flow electrophoresis or by sucrose density gradient centrifugation leads to subfractions which differ with respect to enzyme enrichment factors, transport properties for D-glucose and protein pattern analyzed by sodium dodecyl sulfate/polyacrylamide gel electrophoresis. A relative enrichment of (Na+ + K+)-ATPase is found in one fraction, whereas in another fraction maltase, aminopeptidase M and alkaline phosphatase are relatively enriched. The fractions show different properties of D-glucose transport under tracer exchange conditions and a different inhibition of D-glucose transport by phlorizin and phloretin. These results indicate that the vesicles obtained from rat small intestine by this cation precipitation method are not homogeneous. The inhomogeneity cannot be due to a crosscontamination by membranes other than from the cell envelopment, as none of the fractions show a significant enrichment of succinate--cytochrome c oxidoreductase, KCN-resistant NADH oxidoreductase or glucosaminidase. The inhomogeneity might be due either to a crosscontamination by basal-lateral membranes or to membranes derived from epithelial cells not yet fully differentiated.     

Differences in neutral amino acid and glucose transport between brush border and basolateral plasma membrane of intestinal epithelial cells.

A comparison of L-valine and D-glucose transport was carried out with vesicles of plasma membrane isolated either from the luminal (brush border) or from the contra-luminal (basolateral) region of small intestinal epithelial cells. The existence of transport systems for both non-electrolytes was demonstrated by stereospecificity and saturability of uptake, as well as tracer coupling. Transport of L-valine and D-glucose differs markedly in the two types of plasma membrane with respect to stimulation by Na+. The presence of Na+ stimulated initial L-valine and D-glucose uptake in brush border, but not in basolateral membrane. Moreover, an electro-chemical Na+ gradient, oriented with the lower potential on the inside, supported accumulation of the non-electrolytes above medium concentration only in the brush border membrane. L-Valine and D-glucose transport also were saturated at lower concentrations in brush border (10-20 mM) than in basolateral plasma membranes (30-50 mM). A third difference between the two membranes was found in the effectiveness of known inhibitors of D-glucose transport. In brush border membranes phlorizin was more potent than phloretin and 2', 3', 4'-trihydroxy-4-methoxy chalcone and cytochalasin B did not inhibit at all. In contrast, with the basolateral plasma membranes the order of potency was changed to phloretin = 2',3',4'-trihydroxy-4-methoxy chalcone greater than cytochalasin B greater than phlorizin. These results indicate the presence of different types of transport systems for monosaccharides and neutral amino acids in the luminal and contra-luminal region of the plasma membrane. Active transepithelial transport can be explained on the basis of the different properties of the non-electrolyte transport systems in the two cellular regions and an electro-chemical Na+ gradient that is dependent on cellular metabolism.     

Transport of sugars into microvessels isolated from rat brain: a model for the blood-brain barrier.

Abstract— Microvessels (primarily capillaries) were isolated from the brains of rats 25-35 days of age. This preparation was characterized by light, transmission, and scanning electron microscopy. Transmission electron microscopy revealed that the endothelial cell membranes were intact and were impermeable to horseradish peroxidase. However, scanning electron microscopy revealed that damage to the membrane occurred during isolation. The isolated microvessel preparations were metabolically competent as demonstrated by their ability to metabolize [¹⁴C]glucose. Aliquots of microvessel preparation were incubated with radioactive non-metabolizable analogs of D-glucose at various concentrations. The kinetics of accumulation of radioactivity in the capillaries were analyzed according to a model for carrier-mediated diffusion and affinity constants for 3-O-methyl- D-glucose and 2-deoxyglucose were calculated (about 18 mM at 20°C in each case). These affinity constants are somewhat greater than that expected from whole animal experiments reported by other laboratories. This discrepancy is probably accounted for by the presence of a passive diffusion component. However, despite this complication, the primary mechanism for entry of D-glucose analogues at physiological concentrations is compatible with carrier-mediated transport since: the uptake of sugar analogs was shown to be saturable, to exhibit competition for uptake between structurally similar molecules, and to be non-concentrative. In contrast, the uptake of glycerol, mannitol, and L-glucose by isolated microvessels obeyed the kinetics of simple passive diffusion and was not saturable. Our results are compatible with the concept that the capillary is the anatomic locus of the blood-brain barrier and that this structure contains the carrier-mediated transport system for monosaccharide penetration into brain.     

On the mechanism of sugar and amino acid interaction in intestinal transport.

The influence of amino acids on D-glucose transport was studied in isolated vesicles of brush border membrane from rat small intestine. It is demonstrated that: (a) Uptake of D-glucose by the membranes is inhibited by simultaneous flow of L- and D-alanine into the vesicles. (b) Addition of L-alanine to membranes pre-equilibrated with D-glucose causes efflux of this sugar. (c) The influence of amino acids on D-glucose is dependent on the presence of Na+. (d) The ionophorous agents monactin and valinomycin are able to prevent the transport interaction of D-glucose and amino acids. Monactin is effective in the presence of Na+ without further addition of other cations, while valinomycin is effective only with added K+, in accordance with the known specificity of these antibiotics. (e) The inhibitory effect increases with L-alanine concentration up to about 50 mM after which it levels off. The experiments provide evident that the Na+-dependent sugar and amino acid fluxes across the brush border membrane are coupled electrically.     

Variation in amino acid transport along the rabbit small intestine. Mutual jejunal carriers of leucine and lysine.

The jejuno-ileal variation of amino and imino acid transport across the brush-border membrane of intact rabbit small intestine was studied. For the amino acids tested--beta-alanine, leucine, lysine, MeAIB, proline--and for D-glucose, the rates of transport at constant concentrations increase from very low values in the proximal jejunum to maximum values in the most distal 30 cm of the ileum. The apparent affinity constant for jejunal taurine transport is identical to that of the distal ileum, while the jejunal transport capacity is less than half. In the jejunum, as in the distal ileum, leucine and lysine share both sodium-dependent and sodium-independent carriers. Approx. 50% of the quantitative difference in transport capacity is accounted for by the absence of the beta-alanine carrier in the jejunum. These data indicate that the gradients of transport along the small intestine reflect gradients of transport capacities rather than affinities. In comparison with hamster, man and rat, the rabbit seems unique with respect to the location of transport maximum and the steepness of the gradient along the intestine.     

Glycodeoxycholate transport in brush border membrane vesicles isolated from rat jejunum and ileum

The transport of the bile salt, glycodeoxycholate, was studied in vesicles derived from rat jejunal and ileal brush border membranes using a rapid filtration technique. The uptake was osmotically sensitive, linearly related to membrane protein and resembled d-glucose transport. In ileal, but not jejunal, vesicles glycodeoxycholate uptake showed a transient vesicle/medium ratio greater than 1 in the presence of an initial sodium gradient. The differences between glycodeoxycholate uptake in the presence and absence of a Na⁺ gradient yielded a saturable transport component. Kinetic analysis revealed a $\text{K}{}_{\mathrm{<mtext>m</mtext>}}$ value similar to that described previously in everted whole intestinal segments and epithelial cells isolated from the ileum. These findings support the existence of a transport system in the brush border membrane that: (1) reflects kinetics and characteristics of bile salt transport in intact intestinal preparations, and (2) catalyzes the co-transport of Na⁺ and bile salt across the ileal membrane in a manner analogous to d-glucose transport.     

Ion requirements for taurocholate transport by ileal brush border membrane vesicles.

The ion requirements for intestinal taurocholate transport were studied using vesicles prepared from the brush borders of guinea pig small intestines. For each experimental electrolyte, parallel uptake experiments were performed with vesicles from jejunal and ileal brush border membranes to differentiate between uptake by passive fluxes and non-specific binding and uptake by the ileal bile salt active transport system. Uptake of taurocholate prior to the addition of electrolyte was the same for vesicles prepared from jejunal and ileal tissue. During the presence of a sodium gradient (extravesicular concentration greater than intravesicular), only ileal vesicles displayed the enhanced uptake which is characteristic of the overshoot phenomenon. When NaCl was replaced by KCl or LiCl, the overshoot was not observed. Replacement of NaCl with NaCNS, Na₂SO₄, or NaSO₃C₂H₄OH, however, resulted in no significant difference in the initial uptake values observed in either the jejunal or ileal vesicles. This pattern of taurocholate transport independence of relative anion permeability differs from the pattern observed by others for the Na⁺ dependent transport of D-glucose by intestinal brush border membrane vesicles. This difference may be attributed in part to the fact that, unlike the situation with glucose, the binding of a taurocholate anion and a sodium cation by the hypothetical carrier would result in an electroneutral addition.     

Sodium-dependent D-glucose transport in brush-border membrane vesicles from isolated rat small intestinal villus and crypt epithelial cells

Differentiation and maturation of enterocytes occur with migration from the crypt to villus compartments. To investigate the effect of epithelial cell differentiation on sodium-dependent D-glucose transport, brush-border membrane vesicles were prepared from small intestinal epithelial cell suspensions selectively isolated from villus and crypt populations. Enterocytes were isolated with a morphologically monitored sequential cell dissociation method. Thymidine kinase, sucrase, and alkaline phosphatase activities were measured as differentiation markers of specific cell populations. Brush-border membrane vesicles were purified and their kinetic characteristics defined with a rapid filtration method under conditions of a zero-trans, 100 mM cis-NaSCN gradient. Typical "overshoot" phenomena characteristic of sodium D-glucose cotransport were observed for both villus (five- to eight-fold equilibrium values) and crypt brush-border membrane vesicles (two- to four-fold equilibrium values). Kinetics analyses of the initial D-glucose flux in brush-border membrane vesicles suggested the presence of at least two sodium-dependent D-glucose carriers in the villus and only a single carrier in the crypt compartments. These data indicate that sodium D-glucose cotransport occurs in brush-border membranes of both villus and crypt populations. Moreover, quantitative and qualitative differences between these two membrane populations suggest that epithelial D-glucose transport processes are differentiation dependent and reflect the degree of enterocyte development.     

Ultrastructural and functional changes in the jejunal epithelium of spontaneously hypertensive rats

Ultrastructural studies on the epithelium, sugar transport and immunocytochemistry of Na+-glucose cotransporter (SGLT1) were carried out in the jejunum of Spontaneously Hypertensive Rats (SHR) and their normotensive genetic control, Wistar-Kyoto (WKY) rats. Electron microscopy studies showed a regular brush-border membrane in the jejunal enterocytes of WKY rats, with colloidal gold particles, representing SGLTI, localized at the microvilli of the absorptive epithelial cells. However, a patchy loss of microvilli was detected in the jejunal sections from SHR, with no presence of colloidal gold particles, indicating the absence of the SGLT1 protein. Most adjacent microvilli were normal in size like those found in WKY rats, and SGLT1 labeling was observed. All these changes were accompanied by a reduction in Na+-dependent D-glucose and D-galactose uptakes in the jejunal BBMVs isolated from SHR, when compared to WKY rats. We conclude that ultrastructural changes were paralleled by modifications in the sugar transport and in the localization of SGLT1 in the jejunal epithelium of SHR.