Carrier-mediated transfer of d-glucose in brush border vesicles derived rom rabbit renal tubules. Na+-dependent versus Na+-independent transfer

A brush border preparation from rabbit renal tubules containing a high yield of vesicles has been used to study the transfer of d-glucose through the brush border membrane. In the presence of an Na⁺ gradient across the vesicular membrane, the vesicles could concentrate d-glucose to a factor of 1.5, whereas in the absence of an Na⁺ gradient, only equilibrium with the medium was achieved. Two types of transfer could be distinguished by their requirement of Na⁺, their sensitivity to phlorizin and their pH optimum. The Na⁺-independent transfer was about 100 times less sensitive to phlorizin than the Na⁺-dependent path and exhibited a pH optimum between 7 and 8, whereas the Na⁺-dependent transfer was highest at a pH between 8 and 9.The brush border preparation could be freed of most of the contaminating material derived from the basal and lateral tubular cell membrane by a discontinuous density gradient centrifugation. It still showed both forms of transfer to a similar extent, indicating that both are located in the brush border membrane.A study of the sensitivity of d-glucose transfer to phlorizin, in the presence and absence of Na⁺ at different temperature, suggests a single carrier species functioning in two interchangeable conformational states with different affinities for phlorizin rather than two transfer systems working independently.     

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.     

Hormone action at the membrane level. IV. Epinephrine binding to rat liver plasma membranes and rat epididymal fat cells

[³H]Epinephrine binding to isolated purified rat liver plasma membrane is a reversible process. An initial peak in binding occurs at about 15 min and a plateau occurs by 50 min. Optimal binding occurred at a membrane protein concentration of 125μg. Rat liver plasma membranes stored at ?70 °C up to 4 weeks showed no difference in epinephrine binding capacity as compared to control fresh membranes.Epinephrine binding to liver plasma membranes was decreased by 79% by phospholipase A₂ (phosphatide acylhydrolase EC 3. 1. 1. 4), 81% by phospholipase C (phosphatidylcholine choline phosphohydrolase EC 3.1.4.3) and 59% by phopholipase D (phosphatidylcholine phosphatidohydrolase EC 3.1.4.4). Trypsin and pronase digestion of the membrane decreased epinephrine binding by 97 and 47% respectively.In the presence of 10^?3M Mg²⁺ ions, increasing concentrations of GTP decreased epinephrine binding to liver plasma membranes. A maximal effect was demonstrated with 10^?5M GTP, representing an inhibition of 52% of the control. In a Mg²⁺-free system, epinephrine binding was unaffected by GTP. However, in a Mg²⁺-free system, increasing concentrations of ATP cause increasing inhibition of hormone binding. ATP at 10^-3 M reduced epinephrine binding to 28% of the control. GTP (10^?5M) was shown to inhibit epinephrine uptake rather than epinephrine release from the membrane.[³H]Epinephrine binding to isolated rat epididymal fat cells shows an initial peak within 5 min followed by a gradual rise which plateaus after 60 min. Epinephrine binding increased nearly linearly with increasing fat cell protein concentration (40–200 μg protein).GTP (10^?5M) and ATP (10^?4M) decreased epinephrine binding to rat epididymal fat cells by 41%. Nearly complete inhibition of binding was demonstrated with 10^?2?10^?3M ATP. Epinephrine analogs that contain two hydroxyl groups in the 3 and 4 position on the benzene ring act as inhibitors of [³H]epinephrine binding to rat adipocytes. Alteration of the epinephrine side chain has relatively little influence on binding. Analogs in which one of the ring hydroxyl groups is missing or methylated are poor inhibitors of [³H]epinephrine binding.Alpha-(phentolamine and phenoxybenzamine) and beta-(propranolol and dichorisoproterenol) adrenergic blocking agents were tested with respect to their ability to influence [³H]epinephrine binding and their influence on epinephrine-stimulated lipolysis. Only dichloroisoproterenol significantly inhibited epinephrine binding (by 25%). The two beta-adrenergic blocking agents caused an inhibition of epinephrine-stimulated glycerol release, with propranolol being most effective. Phentolamine and phenoxybenzamine had no significant effect on the epinephrine stimulation of glycerol release by fat cells.     

Two-Step Mechanism of Phlorizin Binding to the SGLT1 Protein in the Kidney

The relationships between phlorizin binding and Na⁺-glucose cotransport were addressed in rabbit renal brush-border membrane vesicles. At pH 6.0 and 8.6, high affinity phlorizin binding followed single exponential kinetics. With regard to phlorizin concentrations, the binding data conformed to simple Scatchard kinetics with lower apparent affinities of onset binding (K _di = 12–30 μm) compared to steady-state binding (K _de = 2–5 μm), and the first-order rate constants demonstrated a Michaelis-Menten type of dependence with K _m values identical to K _di . Phlorizin dissociation from its receptor sites also followed single exponential kinetics with time constants insensitive to saturating concentrations of unlabeled phlorizin or d-glucose, but directly proportional to Na⁺ concentrations. These results prove compatible with homogeneous binding to SGLT1 whereby fast Na⁺ and phlorizin addition on the protein is followed by a slow conformation change preceding further Na⁺ attachment, thus occluding part of the phlorizin-bound receptor complexes. This two-step mechanism of inhibitor binding invalidates the recruitment concept as a possible explanation of the fast-acting slow-binding paradigm of phlorizin, which can otherwise be resolved as follows: the rapid formation of an initial collision complex explains the fast-acting behavior of phlorizin with regard to its inhibition of glucose transport; however, because this complex also rapidly dissociates in a rapid filtration assay, the slow kinetics of phlorizin binding are only apparent and reflect its slow isomerization into more stable forms. Received: 22 June 2000/Revised: 1 November 2000     

High-resolution radioautography of phlorizin-3H in rings of hamster intestine

Quantitative light microscope radioautographs of galactose-³H and phlorizin-³H were prepared from freeze-dried plastic-embedded hamster small intestine incubated in vitro. The usual uphill epithelial cell accumulation of galactose accompanied by a somewhat smaller lamina propria accumulation was observed in control tissue incubated 3 min in 1 mM galactose-³H. The addition of 5 x 10^-4 M phlorizin to the medium blocked uphill accumulation, but did not prevent galactose equilibration with the epithelial cells. The galactose content of the lamina propria was considerably less than the galactose content of the epithelial cell. Varying the phlorizin-³H content of the medium from 0.6 to 60 µM revealed a brush border binding of phlorizin which followed a Langmuir adsorption isotherm with a half-saturation constant of 13 µM and a maximum binding of 84 µmoles of phlorizin/liter of microvilli or 2.6 x 10⁶ sites/epithelial cell. The phlorizin content of the epithelial cell compartment, excluding microvilli, never exceeded 10% that of the medium after 20 min of incubation. These findings directly support the view that phlorizin is a nontransported inhibitor which binds glucose-galactose carriers at the surface of epithelial cell microvilli.     

Photo-activated inhibition of sulfate equilibrium exchange in human erythrocyte ghosts by a 4-azido-2-nitrobenzoate derivative of phlorizin

Like phlorizin, two glycosidic esters of phlorizin, the 4-azido-2-nitrobenzoate (ANB-phlorizin) and the 2-nitrobenzoate (NB-phlorizin) were found to be effective inhibitors of SO₄^2? equilibrium exchange at the outer but not at the inner membrane surface of the human erythrocyte ghost. After photolysis of ghost suspensions in the presence of extracellular ANB-phlorizin an irreversible inhibition of SO₄^2? exchange was observed, while photolysis of intracellular ANB-phlorizin was without effect. After photolysis in the presence of extracellular or intracellular tritiated ANB-phlorizin gel electrophoresis of the labelled membranes revealed similar locations of binding. These findings suggest that the sidedness of action of ANB-phlorizin could not be related to inaccessibility of the inner membrane surface for the agent but that inhibition occurs via binding to fixed sites at the outer membrane surface that are not associated with a mobile carrier which crosses the membrane.     

Effect of physical training on glucose transporters in fat cell fractions

Physical training increases maximally insulin-stimulated glucose assimilation and 3-O-methylglucose transport in epididymal fat cells. In the present report, glucose-inhibitable cytochalasin B binding in subcellular fractions of epididymal adipocytes was measured to assess changes in number of glucose transporters induced by training. Groups of rats trained by swimming were compared to control groups of the same age, matched with respect to body weight by restricted feeding. It was found that in trained rats the number of glucose transporters in the low density microsome fractions from non-insulin-stimulated fat cells was larger than in untrained rats. In both groups of rats, insulin stimulation of adipocytes decreased the number of glucose transporters in low-density microsomes by about 60% and increased the number of glucose transporters in the plasma membrane fractions. The number of glucose transporters in the plasma membrane fractions from maximally insulin-stimulated fat cells was larger in trained rats than in control rats. [U-¹⁴C]Glucose incorporation into lipids varied in proportion to plasma membrane cytochalasin B binding per cell under all conditions tested. The results explain the enhancing effect of training on insulin responsiveness transport of hexose in fat cells.     

Phlorizin as a probe of the small-intestinal Na+,d-glucose cotransporter. A model

(1)‘Uptake’ of phlorizin by intestinal brush border membrane vesicles is stimulated, much as that of d-glucose, by the simultaneous presence of Na_out⁺ and $\text{Δψ?0}$. However, phlorizin contrary to d-glucose, fulfills all criteria of a non-translocated ligand (i.e., of a fully competitive inhibitor) of the Na⁺,d-glucose cotransporter. (2) The stoicheiometry of Na⁺/phlorizin binding is 1, as shown by a Hill coefficient of approx. 1 in the Na_out⁺-dependence of phlorizin binding. (3) The preferred order of binding at $\text{Δψ?0}$ is Na⁺ first, phlorizin second (4) The velocity of association of phlorizin to the cotransporter, but not the velocity of its dissociation therefrom, responds to Δψ. These observations while agreeing with the effect of $\text{Δψ?0}$ on the $\text{K}{}_{\mathrm{<mtext>d</mtext>}}$ of phlorizin binding in the steady-state time range, also confirm that the mobile part of the cotransporter bears a negative charge of 1. (5) A model is proposed describing the Na⁺,Δψ-dependent interaction of phlorizin with the cotransporter and agreeing with a more general model of Na⁺,d-glucose cotransport. (6) The $\text{k}{}_{\mathrm{<mtext>on</mtext>}}$, $\text{k}{}_{\mathrm{<mtext>off</mtext>}}$ and $\text{K}{}_{\mathrm{<mtext>d</mtext>}}$ constants of phlorizin interaction with the Na⁺,d-glucose cotransporter are smaller in the kidney than in the small-intestinal brush border membrane, which results in a number of quantitative differences in the overall behaviour of the two systems.     

A method for measuring apical glucose transporter site density in intact intestinal mucosa by means of phlorizin binding

Summary Phlorizin binding has been widely used to estimate the site density of glucose transporters on intestinal and renal brush-border vesicles. Glucose transport measurements in the intact intestinal mucosa show that changes in transport rate postulated to arise from changes in site density occur under many physiological and pathological conditions. Exploring the basis of these regulatory phenomena would be facilitated by comparing changes in transport rate and site density measured in the same preparation. Hence we developed methods for measuring phlorizin binding in everted sleeves of intact mouse intestine. Specific binding of phlorizin to glucose carriers reached an asymptotic value within 120 sec, while nonspecific binding continued to rise thereafter. Hence we used 120-sec incubations. The rate of dissociation of specifically bound phlorizin was accelerated by Na⁺-free solutions and even more by 50mm glucose, while the rate of dissociation of nonspecifically bound phlorizin was independent of these solution changes. Hence we chose a 20-sec rinse in Ringer+50mm mannitol, because it washes out 30–40% of the nonspecifically bound phlorizin but virtually none of the specifically bound phlorizin. Ligand-binding analysis of specific binding against phlorizin concentration suggested two classes of binding sites, of which the one with stronger affinity for phlorizin probably has the higher capacity for glucose transport in mouse jejunum. The calculated affinity and capacity of this component are independent of whether one estimates the specific component of total binding by adding glucose or by removing Na⁺.     

Localization of the Na+-sugar cotransport system in a kidney epithelial cell line (LLC PK1)

Studies of the localization of the Na⁺-dependent sugar transport in monolayers of LLC PK₁ cells show that the uptake of a methyl α-d-glucoside, a nonmetabolizable sugar which shares the glucose-galactose transport system, occurs mainly from the apical side of the monolayer. Kinetics of [³H]phlorizin binding to monolayers of LLC PK₁ cells were also measured. These studies demonstrate the presence of two distinct classes of receptor sites. The class comprising high affinity binding sites had a dissociation constant ($\text{K}{}_{\mathrm{<mtext>d</mtext>}}$) of 1.2 μM and a concentration of high affinity receptors of 0.30 μmol binding sites per g DNA. The other class involving low affinity sites had a $\text{K}{}_{\mathrm{<mtext>d</mtext>}}$ of 240 μM with the number of binding sites equal to 12 μmol/g DNA. Phlorizin binding at high affinity binding sites is a Na⁺-dependent process. Binding at the low affinity sites on the contrary is Na⁺-independent. The mode of action of Na⁺ on the high affinity binding sites was to increase the dissociation constant without modifying the number of binding sites. The Na⁺ dependence and the matching of $\text{K}{}_{\mathrm{<mtext>d</mtext>}}$ for high affinity binding sites with the $\text{K}{}_{\mathrm{<mtext>i</mtext>}}$ of phlorizin for the inhibition of methyl α-d-glucoside strongly suggest that the high affinity phlorizin binding site is, or is part of the methyl α-d-glucoside transport system. Binding studies from either side of the monolayer also show that the binding of phlorizin at the Na⁺ dependent high affinity binding sites occurs mainly from the apical rather than the basolateral side. The specific location of the Na⁺-dependent sugar transport system in the apical membrane of LLC PK₁ cells is, therefore, another expression of the functional polarization of epithelial cells that is retained under tissue culture condition. In addition, since this sugar transport almost disappears after the cells are brought into suspension, it can be used as a marker to study the development of the apical membrane in this cell line.     

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).     

Glucose transport in isolated brush-border and lateral-basal plasma-membrane vesicles from intestinal epithelila cells

Free-flow electrophoresis was used to separate microvilli from the lateral basal plasma membrane of the epithelial cells from rat small intestine. The activities of the marker enzyme for the microvillus membrane, i.e. alkaline phosphatase (EC 3.1.31), was clearly separated from the marker for the lateral-basal plasma membrane, i.e. the (Na⁺, K⁺)-ATPase (EC 3.6.1.3). A microvillus membrane fraction was obtained with a high specific activity of alkaline phosphatase (an 8-fold enrichement over the starting homogenate). The lateral-basal plasma membrane fraction contained (Na⁺, K⁺)-ATPase (5-fold over homogenate) with some alkaline phosphatase (2-fold over homogenate).Glucose transport was studied in both membrane fractions. The uptake of d-glucose was much faster than that of l-glucose in either plasma membrane, d-Glucose uptake could be accounted for completely by its transport into an osmotically active space. Interestingly, the characteristics of the glucose transport of the microvillus membrane were different from those of the lateral-basal plasma membrane. In particular: Na⁺ stimulated the d-glucose transport by the microvillus membrane, but not by the lateral-basal plasma membrane. In addition, the glucose transport of the microvillus membrane was much more sensitive to phlorizin inhibition than that of the lateral-basal plasma membrane.These experiments thus provide evidence not only for an asymmetrical distribution of the enzymes, but also for differences in the transport properties with respect to glucose between the two types of plasma membrane of the intestinal epithelial cell.     

A two sodium ion/D-glucose symport mechanism: membrane potential effects on phlorizin binding

Apical membrane vesicles isolated from a continuous renal cell line, LLC-PK1, catalyze electrogenic Na+-stimulated hexose transport and Na+-dependent binding of 3H-labeled 1-[2-(beta-D-glucopyranosyloxy)-4, 6-dihydroxyphenyl]-3-(4-hydroxyphenyl)-1-propanone [( 3H]phlorizin), a competitive ligand of this transport system. Phlorizin was not itself transported across the membrane and thus can serve as a probe of the binding step. The stoichiometry of Na+-dependent phlorizin binding in vesicles was 1:1, whereas Na+/hexose cotransport in vesicles exhibited a 2:1 stoichiometry. Na+ increased the affinity of phlorizin binding without affecting the total number of binding sites. An increased number of Na+-dependent phlorizin binding sites was observed under conditions of interior-negative membrane potential. These results are consistent with a model of the Na+/glucose cotransport cycle in which the unloaded transporter is negatively charged and its orientation influenced by membrane potential. Glucose and one sodium ion interact with the transporter, resulting in an uncharged complex. Binding of a second sodium ion triggers translocation of glucose and both sodium ions via formation of a loaded carrier complex bearing a single positive charge.     

Small-intestinal Na+/d-glucose cotransport. Inactivation of sugar transport and phlorizin binding by thiol-group and amino-group reagents

It has previously been shown that mercurials acting from the cytoplasmic side or from within the hydrophobic part of the membrane inactivate the small intestinal Na⁺/d-glucose cotransporter by blocking essential SH-groups (Klip, A., Grinstein, S. and Semenza, G. (1979) Biochim. Biophys. Acta 558, 233–245). Another (set of) sulfhydryl(s) which are critical for phlorizin binding and sugar transport function and which may lie on the luminal side of the brush border membrane, can be blocked by DTNB and 4,4′-dithiopyridine but not by $\text{N-}\text{ethylmaleimide}$. In addition, modification of amino groups by fluorescamine, reductive methylation and (under certain conditions) DIDS also lead to inactivation of the carrier's binding and transport functions. No evidence was obtained that any of the above groups is directly involved in the binding of either Na⁺/d-glucose or phlorizin, since none of these compounds prevented inactivation of the cotransporter.     

Partial purification of the sugar carrier of intestinal brush border membranes. Enrichment of the phlorizin-binding component by selective extractions

Summary The [³H] phlorizin-binding component of brush border vesicles was enrichedin situ by negative purification. Several procedures, known to effect selective solubilization of membrane components, were used separately or in combination to remove proteins unrelated to the binding. Deoxycholate ruptured the vesicles and released 67% of their protein, thereby increasing the specific [³H] phlorizin-binding activity of the pellet three-to fourfold. Extracting the deoxycholate-pellets with either NaI or alkaline solutions released up to 38% of the deoxycholate-insoluble protein without significantly affecting phlorizin binding. The polypeptide composition of the membranes at the different stages was analyzed by NaDodSO₄-polyacrylamide gel electrophoresis. A number of polypeptides present in the original vesicles could be ruled out as essential components of the [³H] phlorizin binding entity.Intact and deoxycholate-treated vesicles were subjected to proteolytic attack. Papain liberated sucrase and isomaltase from intact vesicles, but affected neither other Coomassiestained bands nor phlorizin binding. Neither the protein composition nor the binding properties of sealed vesicles were influenced by trypsin or chymotrypsin. However, all the proteolytic enzymes tested on deoxycholate-treated membranes substantially reduced [³H] phlorizin binding and produced concomitantly the disappearance of several bands from the electrophoretic profile.Pretreatment of vesicles with papain, followed by deoxycholate extraction and incubation in alkaline media, increased the specific binding activity of the membranes up to ninefold by removing close to 90% of the protein. A limited number of polypeptides are suggested as possible candidates for the glycoside-binding site of intestinal brush borders.     

Structural state of the Na+ /d-glucose cotransporter in calf kidney brush-border membranes Target size analysis of Na+-dependent phlorizin binding and Na+-dependent d-glucose transport

Target sizes of the renal sodium-d-glucose cotransport system in brush-border membranes of calf kidney cortex were estimated by radiation inactivation. In brush-border vesicles irradiated at ?50°C with 1.5 MeV electron beams, sodium-dependent phlorizin binding, and Na⁺-dependent d-glucose tracer exchange decreased exponentially with increasing doses of radiation (0.4–4.4 Mrad). Inactivation of phlorizin binding was due to a reduction in the number of high-affinity phlorizin binding sites but not in their affinity. The molecular weight of the Na⁺-dependent phlorizin binding unit was estimated to be 230 000 ± 38 000. From the tracer exchange experiments a molecular weight of 345 000 ± 24 500 was calculated for the d-glucose transport unit. The validity of these target size measurements was established by concomitant measurements of two brush-border enzymes, alkaline phosphatase and γ-glutamyltransferase, whose target sizes were found to be 68 570 ± 2670 and 73 500 ± 2270, respectively. These findings provide further evidence for the assumption that the sodium-d-glucose cotransport system is a multimeric structure, in which distinct complexes are responsible for phlorizin binding and d-glucose translocation.     

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).     

High affinity phlorizin binding to the LLC-PK1 cells exhibits a sodium:phlorizin stoichiometry of 2:1

The phlorizin binding properties of luminal membrane vesicles isolated from the LLC-PK1 cells, a continuous epithelial cell line derived from pig kidney, are studied. Scatchard analysis of this binding indicates the existence of a single high affinity sodium-dependent site with KD = 0.4 microM at 266 mM sodium. The specificity properties of this site indicate that it represents the binding of phlorizin to the hexose binding site of the sodium-dependent D-glucose transporter previously identified in this cell line. Both phlorizin equilibrium binding and the rate of phlorizin binding were found to be sigmoidal functions of sodium concentration. A Hill analysis of these data was consistent with a sodium:phlorizin stoichiometry of 2:1 in good agreement with the sodium:glucose stoichiometry already established in these cells. Phlorizin dissociation was also found to be sodium-dependent. On the basis of the phlorizin binding data presented here, a number of models of the binding of phlorizin and sodium to the transporter can be excluded. An analysis of a random binding model consistent with the data is presented. The significance of the LLC-PK1 sodium-dependent D-glucose transporter as a model system for related renal and intestinal transporters is discussed.     

Assembly and secretion of lipophorin by the larval fat body of the southwestern corn borer,Diatraea grandiosella: An in vitro study

The synthesis, processing, and secretion of lipophorin by the larval fat body of the southwestern corn borer, Diatraea grandiosella, was examined using in vitro techniques. Pulse-labeling of lipophorin with [³⁵S]methionine showed that apolipophorin-I and -II were each synthesized and secreted from the fat body into Grace's medium with an intracellular transit time of about 45 min. Secretion of the apolipoproteins from the fat body became insensitive to the presence of monensin, which disrupts protein processing in the Golgi complex, at 30 min, indicating that most of the pulse-labeled apolipoprotein has transited the Golgi complex by this time. Three inhibitors of protein processing, carbonylcyanide m-chlorophenyl hydrazone, monensin, and brefeldin A, inhibited secretion of lipophorin into medium. Puromycin treatment did not appear to result in the secretion into the medium of lipophorin particles containing incomplete translation products of apolipophorin-I or -II. Incubation of fat bodies with [³H]oleate resulted in the secretion of lipophorin containing [³H]glycerides, a process that was inhibited by cycloheximide, puromycin, and monensin, indicating that apolipoprotein synthesis is required for secretion of [³H]glyceride on nascent lipophorin particles. In contrast, suramin, which has been shown to block the binding of lipophorin to plasma membrane receptors, inhibited the synthesis and secretion of lipophorin, but it did not appear to inhibit the transfer of [³H]lipid from the fat body to lipophorin. Inhibitors of protein synthesis and processing, therefore, can be used to distinguish between secretion of lipophorin-associated lipids and secretion of lipids mediated by the lipid-transfer particle outside the plasma membrane of the fat body.     

Common characteristics for Na+-dependent sugar transport in Caco-2 cells and human fetal colon

Summary The recent demonstration that the human colon adenocarcinoma cell line Caco-2 was susceptible to spontaneous enterocytic differentiation led us to consider the question as to whether Caco-2 cells would exhibit sodium-coupled transport of sugars. This problem was investigated using isotopic tracer flux measurements of the nonmetabolizable sugar analog -methylglucoside (AMG). AMG accumulation in confluent monolayers was inhibited to the same extent by sodium replacement, 200 m phlorizin, 1mm phloretin, and 25mm d-glucose, but was not inhibited further in the presence of both phlorizin and phloretin. Kinetic studies were compatible with the presence of both a simple diffusive process and a single, Na⁺-dependent, phlorizin-and phloretin-sensitive AMG transport system. These results also ruled out any interaction between AMG and a Na⁺-independent, phloretin-sensitive, facilitated diffusion pathway. The brush-border membrane localization of the Na⁺-dependent system was inferred from the observations that its functional differentiation was synchronous with the development of brush-border membrane enzyme activities and that phlorizin and phloretin addition 1 hr after initiating sugar transport produced immediate inhibition of AMG uptake as compared to ouabain. Finally, it was shown that brush-border membrane vesicles isolated from the human fetal colonic mucosa do possess a Na⁺-dependent transport pathway(s) ford-glucose which was inhibited by AMG and both phlorizin and phloretin. Caco-2 cells thus appear as a valuable cell culture model to study the mechanisms involved in the differentiation and regulation of intestinal transport functions.