Transepithelial transport in cell culture: stoichiometry of Na/phlorizin binding and Na/D-glucose cotransport. A two-step, two sodium model of binding and translocation

Heat shock-induced protection and enhancement of Na+-glucose cotransport by LLC-PK1 monolayers

Monolayers of the porcine-derived renal epithelial cell line, LLC-PK1, were used to characterize the effects of heat stress on Na+-glucose cotransport. Transepithelial current dependent on 5 mM glucose (I(Glc)), phloridzin-sensitive current (I(phz)), and total transepithelial current (I(total)) were measured as indicators of Na+-glucose cotransport. Severe heat shock (SHS; 45 degrees C for 1 h, then 37 degrees C for measurements) decreased transepithelial electrical resistance (TER), I(Glc), I(phz), and I(total) 50-70%. Mild heat shock (MHS; 42 degrees C for 3 h, then 37 degrees C for 12 h) induced accumulation of 72-kDa heat shock protein (HSP-72), decreased damage to TER from SHS, and prevented damage to I(Glc), I(phz), and I(total). Kinetic analysis showed that SHS damaged and MHS protected total Na+-glucose transport capacity (Vmax of I(Glc)). MHS alone increased TER (50%), I(Glc) (20%), I(total) (20%), and Vmax of I(Glc) (25%). On enhancement of the Na+ gradient by depletion of intracellular Na+, MHS increased I(Glc) 50% and had no effect on transepithelial Na+-dependent sulfate reabsorptive flux measured concurrently or in Na+-replete tissues. These effects of MHS were not reflected in effects on cell survival or luminal membrane surface area as indicated by lactate dehydrogenase or alkaline phosphatase release. In conclusion, HSP-72-inducing heat treatment both protected and enhanced Na+-glucose cotransport independently of the luminal membrane Na+ gradient and selectively with respect to effects on TER, reabsorptive sulfate transport, cell survival, and luminal membrane surface area.

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

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

Vanadate reduces sodium-dependent glucose transport and increases glycolytic activity in LLC-PK1 epithelia

The effect of vanadate pentoxide on apical sodium-dependent glucose transport in LLC-PK1 epithelia was examined. Epithelia grown in the presence or absence of 1 microM vanadate formed confluent monolayers and exhibited no differences in DNA, protein, or ultrastructure. Vanadate-supplemented epithelia demonstrated a lower steady-state alpha-methyl-D-glucopyranoside (AMG) concentrating capacity and a twofold reduction in apical AMG uptake Jmax. This decreased AMG transport occurred as a consequence of a reduction in the number of transport carriers and was not associated with a change in the sodium electrochemical gradient. The vanadate-induced reduction in apical glucose carrier functional activity and expression was accompanied by a stimulation of intracellular glycolytic flux activity, as evidenced by increased glucose consumption, lactate production, PFK-1 activity, and intracellular ATP. There was no difference in intracellular cAMP levels between vanadate-supplemented and non-supplemented epithelia. These results demonstrate an association between stimulation of glycolytic pathway activity and an adaptive response in the form of a reduction in the function and expression of the sodium-dependent apical glucose transporter in LLC-PK1 epithelia.

Decreased cellular toxicity of neomycin in a clonal cell line isolated from LLC-PK1

We have previously shown in LLC-PK1 cells, that apical membrane enzyme activity was inhibited by aminoglycoside antibiotics (Am. J. Physiol. 254, C251-C257, 1988). In the present study, the relationship between the lethal cytotoxic effect of aminoglycoside and its effect on apical membrane enzyme was examined by establishing aminoglycoside resistant cells. A clonal cell line, LLC-PK1/NRa3, was isolated from parent LLC-PK1 cells in the presence of neomycin. Neomycin inhibited colony formation and increased the number of floating dead cells in parent LLC-PK1 cultures. In contrast, these cytotoxic effects of neomycin were negligible or less pronounced in NRa3 cells, indicating that NRa3 cells were more resistant to neomycin compared with the parent cells. The inhibitory effect of neomycin on apical enzyme activity was significantly weaker in NRa3 cells than in the parent cells. These results suggest that a common mechanism is involved in the aminoglycoside-induced reductions in the apical enzyme activity and in cell viability of LLC-PK1 cells.

Regulation of glucose transporters in LLC-PK1 cells: effects of D-glucose and monosaccharides

Regulation of D-glucose transport in the porcine kidney epithelial cell line LLC-PK1 was examined. To identify the sodium-coupled glucose transporter (SGLT), we cloned and sequenced several partial cDNAs homologous to SGLT1 from rabbit small intestine (M. A. Hediger, M. J. Coady, T. S. Ikeda, and E. M. Wright, Nature (London) 330:379-381, 1987). The extensive homology of the two sequences leads us to suggest that the high-affinity SGLT expressed by LLC-PK1 cells is SGLT1. SGLT1 mRNA levels were highest when the D-glucose concentration in the culture medium was 5 to 10 mM. Addition of D-mannose or D-fructose, but not D-galactose, in the presence of 5 mM D-glucose suppressed SGLT1 mRNA levels. SGLT1 activity, measured by methyl alpha-D-glucopyranoside uptake, paralleled message levels except in cultures containing D-galactose. Therefore, SGLT1 gene expression may respond either to the cellular energy status or to the concentration of a hexose metabolite(s). By isolating several cDNAs homologous to rat GLUT-1, we identified the facilitated glucose transporter in LLC-PK1 cells as the erythroid/brain type GLUT-1. High-stringency hybridization of a single mRNA transcript to the rat GLUT-1 cDNA probe and failure to observe additional transcripts hybridizing either to GLUT-1 or to GLUT-2 probes at low stringency provide evidence that GLUT-1 is the major facilitated glucose transporter in this cell line. LLC-PK1 GLUT-1 mRNAs were highest at medium D-glucose concentrations of less than or equal to 2 mM. D-Fructose, D-mannose, and to a lesser extent D-galactose all suppressed GLUT-1 mRNA levels. Since the pattern of SGLT1 and GLUT-1 expression differed, particularly in low D-glucose or in the presence of D-galactose, we suggest that the two transporters are regulated independently.

Regulation of glucose transporters in LLC-PK1 cells: effects of D-glucose and monosaccharides

Regulation of D-glucose transport in the porcine kidney epithelial cell line LLC-PK1 was examined. To identify the sodium-coupled glucose transporter (SGLT), we cloned and sequenced several partial cDNAs homologous to SGLT1 from rabbit small intestine (M. A. Hediger, M. J. Coady, T. S. Ikeda, and E. M. Wright, Nature (London) 330:379-381, 1987). The extensive homology of the two sequences leads us to suggest that the high-affinity SGLT expressed by LLC-PK1 cells is SGLT1. SGLT1 mRNA levels were highest when the D-glucose concentration in the culture medium was 5 to 10 mM. Addition of D-mannose or D-fructose, but not D-galactose, in the presence of 5 mM D-glucose suppressed SGLT1 mRNA levels. SGLT1 activity, measured by methyl alpha-D-glucopyranoside uptake, paralleled message levels except in cultures containing D-galactose. Therefore, SGLT1 gene expression may respond either to the cellular energy status or to the concentration of a hexose metabolite(s). By isolating several cDNAs homologous to rat GLUT-1, we identified the facilitated glucose transporter in LLC-PK1 cells as the erythroid/brain type GLUT-1. High-stringency hybridization of a single mRNA transcript to the rat GLUT-1 cDNA probe and failure to observe additional transcripts hybridizing either to GLUT-1 or to GLUT-2 probes at low stringency provide evidence that GLUT-1 is the major facilitated glucose transporter in this cell line. LLC-PK1 GLUT-1 mRNAs were highest at medium D-glucose concentrations of less than or equal to 2 mM. D-Fructose, D-mannose, and to a lesser extent D-galactose all suppressed GLUT-1 mRNA levels. Since the pattern of SGLT1 and GLUT-1 expression differed, particularly in low D-glucose or in the presence of D-galactose, we suggest that the two transporters are regulated independently.

Whole cell recording of sugar-induced currents in LLC-PK1 cells

Gigaohm-seal whole cell recording techniques were used to monitor function of the Na(+)-coupled sugar transport system in LLC-PK1 cells. The currents coupled to sugar transport were identified as those that are induced by the presence of 10 mM alpha-methylglucoside (AMG) in either the extracellular or intracellular compartment and were inhibited by addition of 320-800 microM phlorizin to the extracellular bathing medium. The sugar-induced currents are small, 15-20 pA, but of the expected magnitude as determined from the known kinetic parameters for Na(+)-coupled sugar transport in LLC-PK1 cells. The phlorizin-sensitive currents are Na+ dependent and can be studied under conditions in which the net Na+ and sugar flux (and consequently the Na+ electrical current) is in either the inward or outward direction. The reversal potential of the sugar-induced currents measured under conditions with high Na+ and AMG concentrations inside the cell is close to values predicted from thermodynamic principles, assuming a coupling stoichiometry of 2 Na+: 1 sugar for the transport system. The reversal potential of the sugar-induced currents with high extracellular Na+ and AMG is not equal to the predicted value, but it is of the polarity expected for inward-imposed solute gradients. Reasons for the observed discrepancy between observed and calculated values are discussed.

Computer analysis reveals changes in renal Na+-glucose cotransporter in diabetic rats

A novel, computer-assisted program was developed to analyze the time course of Na+-glucose cotransport by rat renal cortical brush-border membrane vesicles (BBMV). Transporter characteristics can be measured, which routine kinetic analyses fail to distinguish: cotransporter membrane density is derived from the picomoles of D-glucose bound per milligram of protein. Binding is stereospecific, blocked by phlorizin, and supported equally well by Na+ or K+ (but not Cs+). Quasi-first-order influx and efflux rate constants for the composite Na+-driven influx and the (presumed) Na+-independent efflux processes were highly dependent on glucose concentration. Either two Na+-glucose transporters exist in proximal tubules or a single mechanism abruptly changes rate when glucose falls to low levels. The major operation mode is slow, has a high capacity but low affinity, and may have a 2 Na+:2 glucose stoichiometry (Hill coefficient is unity). The minor system is a fast, smaller-capacity, higher-affinity operation with a 2 Na+:1 glucose stoichiometry that was not distinguishable when the same data were analyzed in conventional kinetic plots. Results with streptozocin-induced diabetic rats illustrate the method's utility. Low-glucose-affinity cotransporters were upregulated in hyperglycemic, but not in cachectic, ketoacidotic animals. Rate constants, especially for efflux, were decreased in diabetes.

Characteristics of Na+-dependent hexose transport in OK, an established renal epithelial cell line

The characteristics of Na+-dependent hexose uptake were determined for monolayers of OK, an established renal epithelial cell line derived from an opossum kidney. A comparison is made with other cultured cells, particularly LLC-PK1. The capacity to accumulate alpha-methyl D-glucoside (AMG) in OK cells develops with time, reaching a maximum level of 18 nmol/mg protein per h, 3 days after confluency. In contrast to LLC-PK1, this level is not influenced by the medium D-glucose concentration. AMG uptake in OK cells was characterized by an apparent Km of 2.9 mM and a Vmax of 17.1 nmol/mg protein per min. For Na+-dependent phlorisin binding, a KD of 0.025 microM and a Bmax of 1.5 pmol/mg protein were found. A turnover frequency of 158/s was derived from our data. The hexose carrier of OK shares with the carrier of LLC-PK1 a high level of expression, its substrate specificity and turnover frequency. It differs however with respect to the substrate binding site. The affinity for AMG and D-glucose is 3- and 10-fold lower, whereas the affinity for phlorizin is 3-times higher in OK than in LLC-PK1. The Na+ dependence of AMG uptake was also different for both cell lines and suggested for OK cells a 1:1, Na+:substrate stoichiometry. In OK cells, the phlorizin-sensitive uptake rate of D-glucose is much lower than the one for AMG. Nevertheless, D-glucose interacts with the AMG binding site in a competitive way and with an affinity similar to AMG. This could indicate a malfunction of the carrier with D-glucose as a substrate at the level of the translocation step.

Porous-bottom dishes for culture of polarized cells

Porous-bottom dishes offer several advantages for growing and studying epithelia in culture. Many epithelia differentiate more on porous surfaces than on plastic tissue culture dishes. In addition, separate solutions can be maintained on each side of the epithelium and can be sampled easily for studies of transport and other polarized functions. We describe the fabrication of dishes with a cellulose ester filter, a collagen-coated polycarbonate filter, or a collagen membrane forming the surface for cell attachment at the bottom of the dish.

Separation of hexose-transporting from nontransporting LLC-PK1 cells on density gradients

Over a period of 2-3 wk after plating, cultured LLC-PK1 (pig kidney) cells develop a high capacity for Na+-dependent accumulation of alpha-methyl-D-glucoside. To further the analysis of this developmental process, we have developed a method for separating transporting from nontransporting cells on the basis of density changes accompanying hexose accumulation and the corresponding uptake of water. Volume regulation was prevented by suspending the cells in a K+-free, Cl(-)-free Na-gluconate medium. Na+-dependent transport was maintained at nearly control levels by addition of low concentrations of (NH4)2SO4, since NH+4 stimulates Na+-K+-ATPase at the K+ site and allows for the extrusion of accumulated Na+; NH+4-stimulated hexose uptake is ouabain sensitive. With volume regulation blocked but with transport near normal, transporting cells exhibited a phlorizin-sensitive density shift in methylglucoside-containing medium and could be separated from nontransporting cells on Percoll gradients.

Vasoactive intestinal polypeptide-induced chloride secretion by a colonic epithelial cell line. Direct participation of a basolaterally localized Na+,K+,Cl- cotransport system

We have used a well-differentiated human colonic cell line, the T84 cell line, as a model system to study the pathways of cellular ion transport involved in vasoactive intestinal polypeptide (VIP)-induced chloride secretion. A modified Ussing chamber was used to study transepithelial Na+ and Cl- fluxes across confluent monolayer cultures of the T84 cells grown on permeable supports. In a manner analogous to isolated intestine, the addition of VIP caused an increase of net Cl- secretion which accounted for the increase in short circuit current (Isc). The effect of VIP on Isc was dose dependent with a threshold stimulation at 10(-10) M VIP, and a maximal effect at 10(-8) M. Bumetanide prevented or reversed the response to VIP. Inhibition by bumetanide occurred promptly when it was added to the serosal, but not to the mucosal bathing media. Ion replacement studies demonstrated that the response to VIP required the simultaneous presence of Na+, K+, and Cl- in the serosal media. Utilizing cellular ion uptake techniques, we describe an interdependence of bumetanide-sensitive 22Na+, 86Rb+, and 36Cl- uptake, which is indicative of a Na+,K+,Cl- cotransport system in this cell line. This transport pathway was localized to the basolateral membrane. Extrapolated initial velocities of uptake for each of the three ions was consistent with the electroneutral cotransport of 1 Na+:1 K+ (Rb+):2 Cl-. Our findings indicate that VIP-induced Cl- secretion intimately involves a bumetanide-sensitive Na+,K+,Cl- cotransport system which is functionally localized to the basolateral membrane.

Regulation of expression of the sodium-coupled hexose transporter in cultured LLC-PK1 epithelia

A variety of techniques have been used to study the sodium-coupled hexose transporter in epithelia formed by LLC-PK1 cells. The expression of the transporter is affected by the density and age of the culture and by the concentration of glucose in the growth medium. Sodium-coupled hexose transport appears as the epithelium becomes confluent and increases further as the epithelium matures. The increased transport is associated with increased transport in apical plasma membrane vesicles. Epithelia grown in medium containing 5 mM glucose express more transporters than epithelia grown in medium containing 25 mM glucose. The increase in transport is not the result of an extracellular signal that is generated as a consequence of the concentration of glucose. The response to different hexoses that are or are not transported on the carrier indicates that it is the metabolism of glucose that acts as the signal for expression of more or fewer transporters. The results are compared to similar studies of the effects of substrate concentration on expression of transporters in cultured fibroblasts and the intestines in situ.

Fluid composition of basolateral space of kidney cells in culture and its modification by intracellular cAMP

LLC-PK1 kidney cells, like other epithelial cells, form domes due to Na+ and water movements from the apical to the basolateral side of the epithelium when cultured on a nonpermeable support. The composition of the fluid trapped under these domes can therefore be considered to reflect the nature of the fluid reabsorbed through the epithelium. Collecting the basolateral fluid by micropuncture and analyzing it by electron microprobe revealed that it was isosmotic with the external medium and that the concentrations of Na+, Cl-, Ca2+, Mg2+, and phosphate were nearly the same in both. In contrast, the K+ concentration was found to be 40% lower under the domes than in the bath. Changing the osmolality of the apical medium showed that the epithelium was leaky for water, although it maintained an ionic gradient for at least 20 min. Fifteen minutes after addition of dibutyryl adenosine 3',5'-cyclic monophosphate or 3-isobutyl-1-methylxanthine (5 X 10(-4) M) to the external medium, the phosphate concentration in the basolateral fluid was increased. This rise peaked at 1 h and diminished thereafter. The significance of these observations is discussed in regard to transepithelial permeability and to the transport properties of LLC-PK1 cells.

The static head method for determining the charge stoichiometry of coupled transport systems. Applications to the sodium-coupled D-glucose transporters of the renal proximal tubule

The static head method for determining the charge stoichiometry (the number of moles of charge translocated per mole of substrate) of a coupled transport system is presented. The method involves establishing experimental conditions under which a membrane potential exactly balances the thermodynamic driving force of a known substrate gradient. The charge stoichiometry can then be calculated from thermodynamic principles. In contrast to the usual steady-state method for determining charge stoichiometry in cell suspensions and vesicle preparations, the static head method is applicable to systems which are not capable of maintaining a constant membrane potential over time. The charge stoichiometries of two renal sodium coupled D-glucose transporters previously identified in brush-border membrane vesicle preparations from the outer cortex (early proximal tubule) and outer medulla (late proximal tubule) are determined. The charge stoichiometries of these transporters are in good agreement with their sodium/glucose coupling ratios arguing against the possibility that glucose transport is coupled to ions other than sodium in these membranes.

Hexose regulation of sodium-hexose transport in LLC-PK1 epithelia: The nature of the signal

We have shown previously that the concentration of glucose in the growth medium regulates sodium-coupled hexose transport in epithelia formed by the porcine renal cell line LLC-PK1. Assayed in physiological salt solution, the ratio of the concentration of alpha-methyl glucoside (AMG) accumulated inside the cell at steady state to its concentration outside, and the number of glucose transporters, as measured by phlorizin binding, was inversely related to the glucose concentration in the growth medium. In this study, using a cloned line of LLC-PK1 cells, we provide evidence that the difference in AMG concentrating capacity is the result of a regulatory signal and not simply due to a selection process where the growth of cells with enhanced glucose transport is favored by low glucose medium or vice-versa. By adding glucose to conditioned medium (collected after 48 hr incubation with cells and therefore containing less than 0.1 mM glucose), we demonstrate that the signal in the growth medium is indeed the concentration of glucose rather than another factor secreted into or depleted from the medium. Fructose and mannose, two sugars not transported by the sodium-dependent glucose transporter, can substitute for glucose as a carbohydrate source in the growth medium and have a modest glucose-like effect on the transporter. Growth in medium containing AMG does not affect the transporter, indicating that the regulatory signal is not a direct effect of the hexose on its carrier but involves hexose metabolism.