Specific d-glucose transport in sarcolemma vesicles

The sarcolemmal fraction prepared from rat skeletal muscle consists of osmotically active vesicles that accumulate d-glucose in preference to l-glucose, apparently by facilitated diffusion into intravesicular space. Stereospecific d-glucose uptake by these vesicles is a saturable process, inhibited by phloridzin, by cytochalasin B, and by certain sugars, and enhanced by counterflow. An additional leak pathway permits entry of both d- and l-glucose into the vesicles.Stereospecific d-glucose transport by sarcolemmal vesicles is enhanced to a small extent by insulin, provided the hormone is administered prior to cell disruption. In membranes prepared from insulin-pretreated muscle, Ca²⁺ produces a small further enhancement. Local anesthetics preferentially inhibit stereospecific d-glucose transport. Apparent uptake of both d- and l-glucose is greater when vesicles are suspended in salt solutions rather than sucrose, an effect attributed to increased functional vesicular volume.     

Transport of d-glucose by brush border membranes isolated from the renal cortex

The transport of d-glucose by brush border membranes isolated from the rabbit renal cortex was studied. At concentrations less than 2 mM, the rate of d-glucose uptake increased linearly with the concentration of the sugar. No evidence was found for a “high-affinity” (μM) saturable site. Saturation was indicated at concentrations of d-glucose greater than 5 mM. The uptake of d-glucose was stereospecific and selectively inhibited by d-galactose and other sugars. Phlorizin inhibited the uptake of d-glucose in the presence and absence of Na⁺. The glycoside was a potent inhibitor of the efflux of d-glucose. Preloading the brush border membrane vesicles with d-glucose, but not with l-glucose, accelerated exchange diffusion of d-glucose. These results demonstrate that the uptake of d-glucose by renal brush borders represents transport into an intravesicular space rather than solely binding. The rate of d-glucose uptake was increased when the Na⁺ in the extravesicular medium was high and the membranes were preloaded with a Na⁺-free medium. The rate of d-glucose uptake was inhibited by preloading the brush border membranes with Na⁺. These results are consistent with the Na⁺ gradient hypothesis for d-glucose transport in the kidney. Thus, the presence of a Na⁺-dependent facilitated transport of d-glucose in isolated renal brush border membranes is indicated. This finding is consistent with what is known of the transport of the sugar in more physiologically intact preparations and suggests that the membranes serve as an effective model system in examining the mechanism of d-glucose transport in the kidney.     

Effects of ethanol in vitro on rat intestinal brush-border membranes

Ethanol, at concentrations found in the intestinal lumen after moderate drinking, has been shown to inhibit carrier-mediated intestinal transport processes. This inhibition could occur by direct interaction with membrane transporters, dissipation of the energy producing Na⁺ electrochemical gradient and/or nonspecific alteration of membrane integrity. The latter alteration may be reflected by changes in membrane fluidity, chemical composition or vesicular size. These possibilities were examined with studies in purified brush border membrane vesicles of rat intestine. Ethanol inhibited concentrative Na⁺-dependent d-glucose uptake in a dose-dependent manner. In contrast, ethanol did not inhibit concentrative d-glucose uptake under conditions of d-glucose trans-stimulation in the absence of a Na⁺ electrochemical gradient. Ethanol also inhibited initial, concentrative Na⁺-dependent taurocholic acid uptake, as well as equilibrium uptake. That ethanol exerted a dual effect on transport by increasing membrane conductance for Na⁺ while decreasing intravesicular space was supported by direct studies of Na⁺ uptake. Morphometric analysis confirmed that ethanol-treated membranes had a decreased intravesicular size when compared to untreated membranes. Finally, membrane fluidity measured by EPR showed that ethanol had a significant fluidizing effect without producing qualitative changes in membrane proteins, as determined by SDS gel electrophoresis. These results suggest that ethanol inhibits carrier-mediated transport by dissipation of the Na⁺ electrochemical gradient and alteration of membrane integrity rather than by direct interaction with membrane transporters.     

Synthesis of phlorizin derivatives and their inhibitory effect on the renal sodium/d-glucose cotransport system

To characterize further the Na⁺/d-glucose cotransport system in renal brush border membranes, phlorizin - a potent inhibitor of d-glucose transport - has been chemically modified without affecting the d-glucose moiety or changing the side groups that are essential for the binding of phlorizin to the Na⁺/d-glucose cotransport system. One series of chemical modifications involved the preparation of 3-nitrophlorizin and the subsequent catalytic reduction of the nitro compound to 3-aminophlorizin. From 3-aminophlorizin, 3-bromoacetamido-, 3-dansyl- and 3-azidophlorizin have been synthesized. In another approach, 3′-mercuryphlorizin was obtained by reaction of phlorizin with Hg(II) acetate. The phlorizin derivatives inhibit sodium-dependent but not sodium-independent d-glucose uptake by hog renal brush border membrane vesicles in the following order of potency: 3′-mercuryphlorizin = phlorizin > 3-aminophlorizin > 3-bromoacetamidophlorizin > 3-azidophlorizin > 3-nitrophlorizin > 3-dansylphlorizin. 3-Bromoacetamidophlorizin - a potential affinity label - also inhibits sodium-dependent but not sodium-independent phlorizin binding to brush border membranes. In addition, sodium-dependent phosphate and sodium-dependent alanine uptake are not affected by 3-bromoacetamidophlorizin. The results described above indicate that specific modifications of the phlorizin molecule at the A-ring or B-ring are possible that yield phlorizin derivatives with a high affinity and high specificity for the renal Na⁺/d-glucose cotransport system. Such compounds should be useful in future studies using affinity labeling (3-bromoacetamido- and 3-azidophlorizin) or fluorescent probes (3-dansylphlorizin).     

Synthesis of phlorizin derivatives and their inhibitory effect on the renal sodium/d-glucose cotransport system

To characterize further the Na⁺/d-glucose cotransport system in renal brush border membranes, phlorizin - a potent inhibitor of d-glucose transport - has been chemically modified without affecting the d-glucose moiety or changing the side groups that are essential for the binding of phlorizin to the Na⁺/d-glucose cotransport system. One series of chemical modifications involved the preparation of 3-nitrophlorizin and the subsequent catalytic reduction of the nitro compound to 3-aminophlorizin. From 3-aminophlorizin, 3-bromoacetamido-, 3-dansyl- and 3-azidophlorizin have been synthesized. In another approach, 3′-mercuryphlorizin was obtained by reaction of phlorizin with Hg(II) acetate. The phlorizin derivatives inhibit sodium-dependent but not sodium-independent d-glucose uptake by hog renal brush border membrane vesicles in the following order of potency: 3′-mercuryphlorizin = phlorizin > 3-aminophlorizin > 3-bromoacetamidophlorizin > 3-azidophlorizin > 3-nitrophlorizin > 3-dansylphlorizin. 3-Bromoacetamidophlorizin - a potential affinity label - also inhibits sodium-dependent but not sodium-independent phlorizin binding to brush border membranes. In addition, sodium-dependent phosphate and sodium-dependent alanine uptake are not affected by 3-bromoacetamidophlorizin. The results described above indicate that specific modifications of the phlorizin molecule at the A-ring or B-ring are possible that yield phlorizin derivatives with a high affinity and high specificity for the renal Na⁺/d-glucose cotransport system. Such compounds should be useful in future studies using affinity labeling (3-bromoacetamido- and 3-azidophlorizin) or fluorescent probes (3-dansylphlorizin).     

Sensitivity of Na-coupled d-glucose uptake, Mg-ATPase and sucrase to perturbations of the fluidity of brush-border membrane vesicles induced by n-aliphatic alcohols

The aim of our work is to show the importance of the role of hydrophobic bonds in maintaining Mg²⁺-ATPase or sucrase activity and Na⁺-coupled d-glucose uptake normal for the brush border of rat enterocytes. The activity of the two enzymes and the d-glucose uptake were therefore measured under the action of n-aliphatic alcohols and related to the fluidity determined by ESR. Three concentrations were used for the first eight alcohols, those of octanol being about 1500-times lower than those of methanol. For each alcohol the d-glucose uptake and the fluidity were linear functions of the logarithm of the concentration, the linear regressions being practically parallel and equidistant. The concentrations (C) of the eight alcohols inhibiting the d-glucose uptake by 80% were similar to those increasing the membrane fluidity by 3%. The linear relationship which existed in both cases between log 1 / C and log P, P being octanol / water partition coefficients of the alcohols, was evidence of great sensitivity to the hydrophobic effect of the alcohols. Only the first alcohols, however, produced any notable inhibition of Mg²⁺-ATPase and sucrase. Hydrophobic bonds are thus shown to have little influence in maintaining the activity of Mg²⁺-ATPase and sucrase, but they modulate the Na⁺-coupled d-glucose uptake.     

Sensitivity of Na+-coupled d-glucose uptake,Mg2+-ATPase and sucrase to perturbations of the fluidity of brush-border membrane vesicles induced by n-aliphatic alcohols

The aim of our work is to show the importance of the role of hydrophobic bonds in maintaining Mg²⁺-ATPase or sucrase activity and Na⁺-coupled d-glucose uptake normal for the brush border of rat enterocytes. The activity of the two enzymes and the d-glucose uptake were therefore measured under the action of $\text{n-}\text{aliphatic alcohols}$ and related to the fluidity determined by ESR. Three concentrations were used for the first eight alcohols, those of octanol being about 1500-times lower than those of methanol. For each alcohol the d-glucose uptake and the fluidity were linear functions of the logarithm of the concentration, the linear regressions being practically parallel and equidistant. The concentrations ($\text{C}$) of the eight alcohols inhibiting the d-glucose uptake by 80% were similar to those increasing the membrane fluidity by 3%. The linear relationship which existed in both cases between log 1 / $\text{C}$ and log $\text{P, P}$ being octanol / water partition coefficients of the alcohols, was evidence of great sensitivity to the hydrophobic effect of the alcohols. Only the first alcohols, however, produced any notable inhibition of Mg²⁺-ATPase and sucrase. Hydrophobic bonds are thus shown to have little influence in maintaining the activity of Mg²⁺-ATPase and sucrase, but they modulate the Na⁺-coupled d-glucose uptake.     

Glucose transport into spinach chloroplasts

The uptake of radioactively labeled hexoses and pentoses into the sorbitol-impermeable (3)H(2)O space (the space surrounded by the inner envelope membrane) of spinach (Spinacia oleracea L.) chloroplasts has been studied using silicone layer filtering centrifugation. Of the compounds tested, d-xylose, d-mannose, l-arabinose, and d-glucose are transported most rapidly, followed by d-fructose and l-arabinose. The rate of l-glucose uptake is only about 5% of that of d-glucose.The transport of d-glucose and d-fructose shows saturation characteristics, the K(m) for d-glucose was found to be about 20 mm. All sugars transport and phloretin inhibit d-glucose transport. The temperature dependency of d-glucose transport appears to have an activation energy of 17 kcal/mol.With low external concentrations of d-glucose the transport into the chloroplasts proceeds until nearly the external concentration is reached inside the chloroplasts.d-glucose transport is inhibited by high d-glucose concentrations in the medium. It is concluded that d-glucose and other hexoses are transported by carrier-mediated diffusion across the inner envelope membrane. This transport is similar to the transport of d-glucose into erythrocytes.     

Interactions between Na+-dependent uptake of d-glucose,phosphate and l-alanine in rat renal brush border membrane vesicles

d-Glucose decreases phosphate reabsorption in rat proximal tubule. It is also postulated that some amino acids interact with phosphate reabsorption. To investigate the mechanism of these interactions, phosphate, d-glucose and l-alanine transport kinetics were measured in brush border membrane vesicles isolated from superficial rat kidney cortex by the calcium precipitation technique. At pH 7.4, Na⁺-dependent phosphate transport was inhibited in the presence of either d-glucose (39 mM) or l-alanine (2.4 mM). In this model, with d-glucose or with l-alanine the $\text{V}$ value of the phosphate uptake was decreased, whereas the apparent $\text{K}{}_{\mathrm{<mtext>m</mtext>}}$ for the phosphate uptake was not affected. However, some inhibition of phosphate transport was observed in the presence of l-glucose, d-alanine or d-glucose after phlorizin preincubation. A 30% Na⁺-dependent l-alanine (0.1 mM) transport inhibition was observed in the presence of 5 mM phosphate. d-Glucose (1 mM) was also inhibited by 20% when 5 mM phosphate was added to incubation medium. According to several authors, in our model, d-glucose decreased the l-alanine transport and vice versa. Moreover, when the membrane potential was abolished, a clear inhibition of d-glucose by l-alanine persisted. These multiple interactions could be explained by the accelerated dissipation of the Na⁺ gradient insofar as the rate of the Na⁺ uptake was increased with d-glucose, l-alanine or phosphate and since the absence of variations in membrane potential did not suppress these inhibitions.     

Reconstitution into liposomes of glucose active transport from the rabbit renal proximal tubule. Characteristics of the system

This paper describes the characteristics of Na⁺-dependent d-glucose transport into liposomes made from soybean phospholipids into which have been reconstituted detergent-solubilized components from the rabbit renal proximal tubular brush border membrane. Conditions for optimal and quantitative reconstitution of glucose carriers are defined. Na⁺-dependent d-glucose uptake occurs via a saturable system with a $\text{K}{}_{\mathrm{<mtext>m</mtext>}}$ of 0.125–0.135 mM, is responsive to the volume of the internal liposomal space, and shows ‘overshoot’ as seen in natural membranes. The rate of Na⁺-dependent d-glucose uptake and the magnitude of the ‘overshoot’ are proportional to the concentration of protein used in reconstitution.     

Asymmetric transport of a fluorescent glucose analogue by human erythrocytes

A fluorescent glucose analogue, 6-deoxy-N-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)-aminoglucose (NBDG), was synthesized and its interactions with the hexose transport system of the human red blood cell were investigated. NBDG entry is inhibited by increasing concentrations of d-glucose (K_i = 2 mM). However, NBDG exit is unaffected by d-glucose in red blood cells. Cytochalasin B was found to inhibit both NBDG entry and exit. NBDG accumulates in the red blood cell above the theoretical equilibrium concentration. Accumulation of NBDG is temperature-sensitive and is due to the binding of NBDG to some intracellular substance. The binding of NBDG to purified hemoglobin suggests that accumulation of NBDG by erythrocytes is due to the intracellular binding of NBDG to hemoglobin. NBDG does not accumulate in pink erythrocyte ghosts, while its rate of uptake is still inhibited by d-glucose and cytochalasin B. Although there was no apparent d-glucose inhibition of NBDG exit by intact red blood cells, d-glucose was able to inhibit NBDG exit by pink erythrocyte ghosts. The differing properties of NBDG influx and efflux support the interpretation that the hexose transport system of the human red blood cell appears asymmetric although it may be intrinsically symmetric.     

Triphenylmethylphosphonium uptake by pancreatic islet cells

Uptake of triphenylmethylphosphonium cation (TPMP⁺) was studied in pancreatic islet cells. Islets rich in β-cells were prepared from non-inbred ob/ob-mice and incubated with [³H]TPMP⁺ and l-[1-¹⁴C]glucose. Conjoined with the Nernst equation, the values for TPMP⁺ uptake in excess of the extracellular (l-glucose) space predicted membrane electric potentials far from those previously recorded with intracellular electrodes. Improved agreement with the electrode data was achieved by correcting for assumed voltage-independent binding of TPMP⁺; plausible correction terms were derived from the kinetics of TPMP⁺ efflux and from the uptake of [³H]TPMP⁺ in islets treated with non-radioactive TPMP⁺ at such a high concentration (50 μM) as to abolish the glucose oxidation. In whole islets the magnitude of the TPMP⁺-derived potentials decreased with increasing extracellular K⁺ in the range 5.9–130 mM, and was diminished by 20 mM d-glucose or 0.5 mM 2,4-dinitrophenol, but not by 20 mM 3-O-methyl-d-glucose, 20 mM d-mannoheptulose alone, or 10 μM chlorotetracycline. The effect of d-glucose was not observed in the presence of d-mannoheptulose and was diminished when 130 mM NaCl in the medium was replaced by sodium isethionate. The magnitude of TPMP⁺ uptake and the effects of K⁺ and dinitrophenol were reproduced with dispersed islet cells from ob/ob-mice and with whole islets of normal inbred NMRI-mice; the d-glucose effect was reproduced with NMRI-mouse islets. The results support our previous hypotheses that the depolarizing and insulin-releasing actions of d-glucose are in part mediated by electrodiffusion mechanisms involving K⁺ and Cl^?.     

Contrasting modes of action of d-glucose and 3-O-methyl-d-glucose as protectors of the rat pancreatic B-cell against alloxan

Both d-glucose and its nonmetabolized analog $\text{3-O-}\text{methyl-}\text{d}\text{-glucose}$ are known to protect the pancreatic B-cell against the toxic action of alloxan, as if the protective action of hexoses were to involve a membrane-associated glucoreceptor site. In the present study, the protective actions of the two hexoses were found to differ from one another in several respects. Using the process of glucose-stimulated insulin release by rat pancreatic islets as an index of alloxan cytotoxicity, we observed that the protective action of d-glucose was suppressed by d-mannoheptulose and menadione, impaired by NH₄Cl, and little affected by aminooxyacetate. These findings and the fact that d-glucose failed to decrease [2-¹⁴C]alloxan uptake by the islets suggest that the protective action of d-glucose depends on an increase in the generation rate of reducing equivalents (NADH and NADPH). The latter view is supported by the observation that the protective action of a noncarbohydrate nutrient, 2-ketoisocaproate, was also abolished by menadione. Incidentally, the protective action of 2-ketoisocaproate was apparently a mitochondrial phenomenon, it not being suppressed by aminooxyacetate. In contrast to that of glucose, the protective action of $\text{3-O-}\text{methyl-}\text{d}\text{-glucose}$ was unaffected by d-mannoheptulose, failed to be totally suppressed by menadione, and coincided with a decreased uptake of [2-¹⁴C]-alloxan by the islets. It is concluded that the protective action of d-glucose in linked to the metabolism of the sugar in islet cells, whereas that of $\text{3-O-}\text{methyl-}\text{d}\text{-glucose}$ results from inhibition of alloxan uptake. This conclusion reinforces our opinion that the presence in the B-cell of an alleged stereospecific membrane glucoreceptor represents a mythical concept.     

Regional distribution study of brain perfusion and metabolic agents in normal and tumour bearing rat brains using autoradiographic technique

Regional distribution of brain perfusion imaging agents, [¹³¹I]N,N,N′-trimethyl-N′-[2-hydroxy-3-methyl-5-iodobenzyl]1,3 propanediamine (HIPDM) and [¹³¹I]N-isopropyl-p-iodoamphetamine (IMP), was compared with the distribution of patterns of [¹⁴C]l-methionine and [¹⁴C]d-glucose in normal and tumour bearing rat brains using autoradiographic technique. There was higher concentration of the radiopharmaceutical in grey than white matter in normal rat brain. Autoradiographs of brain tumour sections showed very low uptake of [¹³¹I]HIPDM and [¹³¹I]IMP as compared to normal brain tissue. There was moderate concentration of [¹⁴C]d-glucose and avid uptake of [¹⁴C]l-methionine in tumours. Autoradiographic study is useful for evaluating distribution patterns of radiopharmaceuticals.     

Specificity of d-glucose transport by the apical membrane of Nereis diversicolor epidermis

(1) The specificity of d-[6-³H]glucose influx by a Na⁺-dependent and phlorizin-sensitive transport system in the apical epidermal membrane of the polychaete worm, Nereis diversicolor, was investigated in vivo. (2) The inhibitory effect of eleven d-glucose analogues on d-[6-³H]glucose influx from a 5 μM external concentration was recorded. The inhibitors (each tested at 5, 50, 500 and 5000 μM) were selected to illuminate the configurational requirements for interaction with the d-glucose transport system. (3) The following compounds were found to be significant inhibitors: methyl α-d-glucoside, methyl β-d-glucoside, d-galactose, $\text{3-O-}\text{methyl-}\text{d}\text{-glucose}$, 2-deoxy-d-glucose, d-xylose, myo-inositol, β-d-fructose; the effect was graded according to inhibitor concentration. l-Glucose also inhibited d-glucose influx but to the same extent at all four concentrations tested, suggesting transport site heterogeneity. d-Mannose and l-arabinose did not inhibit influx. (4) The most potent inhibitor, methyl-α-d-glucoside, was itself a substrate, and its transport was inhibited by phlorizin and d-glucose, as well as by substitution of Na⁺ in the incubation medium with Li⁺ or choline⁺. (5) We conclude that the specificity of the Na⁺-dependent d-glucose transporter in the apical epidermal membrane of Nereis is similar to that in the apical membrane of vertebrate small intestinal and proximal tubular epithelium, and in the tapeworm integument.     

Decreased Na+-gradient-dependent d-glucose transport in brush-border membrane vesicles from rabbits with experimental fanconi syndrome

The effect of anhydro-4-epitetracycline on sodium gradient-dependent d-glucose transport of rabbit renal brush-border membrane vesicles was studied. The purity of isolated brush-border membrane vesicles as judged by enzyme activities was not different between normal control and anhydro-4-epitetracycline-administered rabbits. There was no difference in estimate of intravesicular volume, either. When NaCl was used for sodium gradient, the overshoot of d-glucose uptake into brush-border membrane vesicles isolated from anhydro-4-epitetracycline-treated rabbits was significantly smaller than that of normal control rabbits. In the cases of NaSCN or Na₂SO₄, the former was also smaller than the latter, but not significantly so. To avoid the possible effect of membrane potential on d-glucose uptake, the voltage-clamp method was applied. Even in the voltage-clamped condition, the overshoot of d-glucose uptake into vesicles from anhydro-4-epitetracycline-treated rabbits was decreased compared to that of normal rabbits. In vitro incubation of brush-border membrane vesicles with 20 mM anhydro-4-epitetracycline caused no alteration in sodium gradient-dependent d-glucose uptake. Our results demonstrate that there exists a disorder in sodium gradient-dependent d-glucose uptake of renal brush-border membrane in anhydro-4-epitetracycline-treated rabbits, and suggest that this disorder is one of the underlying mechanisms of experimental Fanconi syndrome.     

A simple method for the isolation of basolateral plasma membrane vesicles from rat kidney cortex Enzyme activities and some properties of glucose transport

A procedure for preparing basolateral membrane vesicles from rat renal cortex was developed by differential centrifugation and Percoll density gradient centrifugation, and the uptake of d-[³H]glucose into these vesicles was studied by a rapid filtration technique. (Na⁺ + K⁺)-ATPase, the marker enzyme for basolateral membranes, was enriched 22-fold compared with that found in the homogenate. The rate of d-glucose uptake was almost unaffected by Na⁺ gradient (no overshoot).     

Characterization and solubilization of the cytochalasin B binding component from human placental microsomes

Human placental microsomes exhibit uptake of d-[³H]glucose which is sensitive to inhibition by cytochalasin B (apparent K_i = 0.78 /gm M). Characterization of [³H]cytochalasin B binding to these membranes reveals a glucose-sensitive site, inhibited by d-glucose with an ED₅₀ = 40 mM. The glucose-sensitive cytochalasin B binding site is found to have a K_d = 0.15μM by analysis according to Scatchard. Solubilization with octylglucoside extracts 60–70% of the glucose-sensitive binding component. Equilibrium dialysis binding of [³H]cytochalasin B to the soluble protein displays a pattern of inhibition by d-glucose similar to that observed for intact membranes, and the measurement of an ED₅₀ = 37.5 mM d-glucose confirms the presence of the cytochalasin B binding component, putatively assigned as the glucose transporter. Further evidence is attained by photoaffinity labelling; ultraviolet-sensitive [³H]cytochalasin B incorporation into soluble protein (M_r range 42 000-68 000) is prevented by the presence of d-glucose. An identical photolabelling pattern is observed for incorporation of [³H]cytochalasin B into intact membrane protein, confirming the usefulness of this approach as a means of identifying the presence of the glucose transport protein under several conditions.     

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.