D-Glucose-dependent sodium transport in renal brush border membrane vesicles

Glucose entry into rat mesangial cells is mediated by both Na(+)-coupled and facilitative transporters

Since previous studies from our laboratory have demonstrated that increased glucose consumption by cultured rat mesangial cells is accompanied by an accelerated production of type IV and type VI collagen, we have now examined the manner by which glucose is transported into these cells. A progressive stimulation of glucose uptake by the mesangial cells was observed with increasing concentrations of NaCl so that at 145 mmol/l about twice as much glucose entered the cells as in its absence (substituted by choline chloride). Moreover, since phlorizin inhibited the NaCl-promoted uptake of glucose and this salt was found to increase the accumulation of alpha-methylglucoside in a manner which could not be duplicated by KCl or mannitol, both Na(+)-coupled and facilitative glucose transporters appeared to be present in the cells. Km values of 1.93 mmol/l and 1.36 mmol/l were determined for the co-transport and facilitated transport pathways, respectively, with their Vmax being 29.5 and 18.0 nmol.mg protein-1.h-1. Both uptake activities were found to be down-regulated by exposure of the cells to high glucose and furthermore the Na(+)-dependent transport could no longer be detected after about 12 passages of the cells. Hybridization of mesangial cell mRNA with cDNA probes revealed transcripts for the Na+/glucose co-transporter as well as GLUT1 and to a lesser extent GLUT4.(ABSTRACT TRUNCATED AT 250 WORDS)

Oleic acid inhibition of Na+/D-glucose transport in isolated renal brush-border membranes: role of lipid physical parameters and trans Na(+)-inhibition

Inhibition of Na+/D-glucose transport by oleic acid was investigated in renal brush-border membrane vesicles (BBMV). Lipid physical parameters were determined by spectrofluorometry. cis-Unsaturated C16-C22 long-chain fatty acids (LCFA) as oleic acid reduced nonzero limiting anisotropy r infinity with DPH and 12-AS as probes and decreased rotational correlation time phi of 12-AS. At 8 s and 15 s Na+/D-glucose transport was competitively inhibited. A positive correlation existed between decrease in r infinity (acyl chain order) or decrease in rotational correlation time phi (= increase in 'fluidity') and inhibition of Na+/D-glucose transport. Except elaidic acid trans unsaturated and saturated LCFA had no effect on fluorescence anisotropy and Na+/D-glucose transport. Per cent transport inhibition was unaffected by 0 voltage clamping and by FCCP. Ki for trans Na(+)-inhibition of D-glucose transport was 29 mmol/l. Na(+)-transport was stimulated by oleic acid, exceeding the Ki value for trans Na+ inhibition.

CONCLUSION

oleic acid inhibits Na+/D-glucose transport by a decrease in lipid acyl chain order and an increase in 'fluidity', by trans Na(+)-inhibition and presumably by a third unknown mechanism.

Changes in membrane-bound hydrolases by metronidazole in rat renal brush border

The antiprotozoal drug metronidazole, when administered orally at a dose level of 100 mg/kg body wt. daily for 7 days to rats, brought about significant elevation of renal brush-border-membrane-bound hydrolytic enzymes, such as alkaline phosphatase, maltase, sucrase, and leucine aminopeptidase (LAP). Kinetic analysis of the enzymes (substrate saturation) indicated that the drug produced an increase in the maximum of apparent initial enzyme velocity (Vmax), while the substrate affinity constant (Km) remained unaltered. These changes were not recovered to the normal level even after the drug regimen was stopped and the animals were allowed to recover for a period of 7 days. Lipid analysis of brush border membrane (BBM) revealed a significant elevation in the cholesterol, phospholipid, and ganglioside levels, while no marked change was recorded in triglyceride, free fatty acid and plasmalogen. Study of the temperature-dependent parameters of the enzymes showed that metronidazole induced a shift in the transition temperature (To) in LAP with nearly total reversibility in the recovery group. No such change was seen in the other enzymes. However, there also was a lowering in the energy of activation (Ea) below To, which returned to normal after the treatment was withdrawn.

H+/Ca2+ exchange in rabbit renal cortical endosomes

We have examined the effect of second messengers on ATP-driven H+ transport in an H+ ATPase-bearing endosomal fraction isolated from rabbit renal cortex. cAMP (0.1 mM) had no effect on H+ transport. Acridine orange fluorescence in the presence of 0.5 mM Ca2+ (+1 mM EGTA) was 19 +/- 6% of control. Inhibition of ATP-driven H+ transport by Ca2+ was concentration dependent; 0.25 and 0.5 mM Ca2+ (+1 mM EGTA) inhibited acridine orange fluorescence by approximately 50 and approximately 80%, respectively. Ca2+ also produced a concentration-dependent increase in the rate of pH-gradient dissipation. Ca2+ did not affect ATP hydrolysis. ATP-dependent Br- uptake was virtually unchanged in the presence of 0.5 mM Ca2+ (+1 mM EGTA). These vesicles were also shown to transport Ca2+ in an ATP-dependent mode. Inositol 1,4,5-trisphosphate had no effect on ATP-dependent Ca2+ uptake. These results are consistent with the co-existence of an H+ ATPase and an H+/Ca2+ exchanger on these endosomes, the latter transport system using the H+ gradient to energize Ca2+ uptake. Attempts to demonstrate an H+/Ca2+ antiporter in the absence of ATP have been unsuccessful. Yet, when a pH gradient was established by preincubation with ATP and residual ATP was subsequently removed by hexokinase + glucose, stimulation of Ca2+ uptake could be demonstrated. A Ca2(+)-dependent increase in H+ permeability and an ATP-dependent Ca2+ uptake might have important implications for the regulation of vacuolar H+ ATPase activity as well as the homeostasis of cytosolic Ca2+ concentration.

Techniques for isolation of brush-border and basolateral membrane vesicles from dog kidney cortex

Two methods are reported for renal membrane preparation from the dog kidney cortex. One method is a simultaneous preparation of brush-border (BBMV) and basolateral (BLMV) membranes. Using readily available laboratory equipment, differential centrifugation produced a supernatant which was treated with Mg2+. The Mg2+ treatment produced a pellet (crude BLMV) which was added to Percoll and centrifuged to produce purified BLMV. The supernatant after Mg2+ treatment eventually yielded pure BBMV after additional Mg2+ precipitations. The second method used an acidic medium in conjunction with divalent-cation precipitation to prepare BBMV. Whichever method was used, BBMV and BLMV showed appropriate enzyme and transport activities.

The effects of iron-mediated oxidative stress in isolated renal cortical brush border membrane vesicles at normothermic and hypothermic temperatures

Experiments on renal cortical brush border membrane vesicles have been undertaken in order to assess the involvement of iron in oxidative stress at physiological temperatures and under conditions of hypothermia. A decrease in temperature stimulated iron-induced lipid peroxidation. The results are discussed in relation to the role of the oxidation state of the iron and iron(II)/iron(III) ratios in the initiation of peroxidative events.

Evidence from 23Na NMR studies for the existence of sodium-channels in the brush border membrane of the renal proximal tubule

A fast Na+-exchange is shown to be present in isolated renal brush border membranes. The lower limit of the rate constant for this process, calculated from the 23Na-NMR spectrum is 580 sec-1. The actual exchange rate may be higher. A fast 7Li exchange is also shown to be present in the isolated membrane vesicles. The characteristic overshoot of the Na+ dependent D-glucose cotransport and Na+/H+ antiport can be demonstrated. The fact that neither treatment with papain, nor lowering of the temperature to 5 degrees C affected the 23Na-NMR spectra obtained in the renal brush border membrane vesicles is consistent with the possibility that the fast Na+-exchange occurs through a channel mechanism.

Na+ transport by brush border membrane from rat kidney

Na+ uptake was measured in brush border membrane isolated from rat kidney cortex. In the presence of 100 mM NaCl gradient, Na+ equilibrated across the membranes within 30 minutes, but uptake was linear only for the first 10 seconds. Total uptake could be analysed in terms of a diffusion component and a saturable component (Kt = 5 mM, Jmax = 0.62 pmol/microgram prot/s). Uptake at 1 mM NaCl was found to be inhibited at 60% by amiloride; stimulation of uptake by pH gradient (inside greater than outside) supports the functioning of a Na+-H+ antiport. Uptake at 100 mM NaCl was insensitive to amiloride in the absence of pH gradient. The influence of anions on Na+ uptake was in agreement with known permeabilities for generation of electrical potentials (Thiocyanate greater than chloride greater than gluconate) and was observed at 100 mM Na+ but not at 40 microM. These results suggest that rat renal brush border membrane vesicles are leaky towards Na+ and present a permeability coefficient for Na+ much higher than what is expected from the in vivo conditions.

Glucose-dependent respiration in suspensions of rabbit cortical tubules

The effects of glucose on cellular respiration were examined in suspensions of rabbit cortical tubules. When glucose was removed from the bathing fluid, oxygen consumption (QO2) decreased from 18.6 +/- 0.8 to 15.7 +/- 0.5 nmol O2/mg protein X min (P less than 0.01). The transported but nonmetabolized analogue of glucose, alpha-methyl-D-glucoside (alpha MG), was found to support QO2 to the same extent as glucose. These observations were also evident in the presence of butyrate, a readily oxidized substrate of the renal cortex. Additional studies with nystatin and ouabain indicated that glucose-related changes in QO2 were the result of changes in Na, K-ATPase associated respiration. The effect of glucose was localized to the luminal membrane since phlorizin (10(-5) M), a specific inhibitor of luminal glucose-sodium cotransport, also significantly reduced QO2 by 10 +/- 1%. Phlorizin inhibition of QO2 was also evident in the presence of alpha MG but was abolished when glucose was removed from the bathing medium. Finally, measurement of NADH fluorescence showed that addition of glucose (5 mM) to a tubule suspension causes an oxidation of NAD. These data are all consistent with glucose acting to increase respiration by stimulating sodium entry at the luminal membrane (via glucose-sodium cotransport) followed by increased sodium pump activity and its associated increase in mitochondrial respiration.

Solubilization and reconstitution of an amiloride-inhibited sodium transporter from rabbit kidney medulla

An octyl glucoside extract has been formed from rabbit kidney medulla microsomes from which reconstituted proteoliposomes can be formed by lipid addition and dialysis to remove detergent. These proteoliposomes are capable of amiloride-inhibited 22Na+ transport. The amiloride-inhibited Na+ transport process is complete within 10 min and directly proportional to the vesicle protein concentration. Sodium accumulation by the proteoliposomes has been proven to represent transport by the demonstration that all Na+ taken up by the vesicles can be removed by the ionophore nigericin. The process has been shown to be specific for amiloride by the demonstration that the effect of amiloride on Na+ transport could not be reproduced by the similar compound sulfaguanidine nor by pyrazine, 2-pyrazinecarboxamide, 2-pyrazinecarboxylate, or 3-amino-2-pyrazinecarboxylate. The relationship between Na+ uptake into proteoliposomes and Na+ concentration was similar to the relationship between Na+ uptake and concentration observed with medulla microsomes. The concentration of amiloride required for half-maximal inhibition of Na+ uptake into either proteoliposomes or medulla microsomes was also the same. The evidence seems clear that the protein responsible for amiloride-inhibited Na+ transport into rabbit kidney medulla microsomes has been extracted from the membranes and incorporated into purified lipid vesicles.

Inhibition by amiloride of sodium transport into rabbit kidney medulla microsomes

Sodium transport into rabbit kidney medullar microsomes was 50% inhibited by amiloride. This Na+ uptake was shown to represent transport when the uptake process was reserved by the ionophore nigericin. The transport was complete within 60 min and proportional to the microsomal protein concentration. The effect of amiloride on transport was specific since the similar compound sulfaguanidine failed to affect microsomal Na+ transport. Amiloride-sensitive Na+ transport into microsomes was inhibited 70% by decreasing the pH (from 7.0 to 5.9), but was unaffected by the presence of a pH gradient. The kinetics of Na+ transport could be explained by a simple model, assuming that amiloride lowered the rate of Na+ entrance into the vesicles but had not effect on the rate of efflux. The failure of amiloride to effect efflux from the vesicles was also demonstrated directly.

Partial purification of the Na+-dependent D-glucose transport system from renal brush border membranes

A membrane extract enriched with the Na+ -dependent D-glucose transport system was obtained by differential cholate solubilization of rat renal brush border membranes in the presence of 120 mM Na+ ions. Sodium ions were essential in stabilizing the transport system during cholate treatment. This membrane extract was further purified with respect to its Na+-coupled D-glucose transport activity and protein content by the use of asolectin-equilibrated hydroxylapatite. The reconstituted proteoliposomes prepared from this purified fraction showed a transient accumulation of D-glucose in response to a Na+ gradient. The observed rate of Na+-coupled D-glucose uptake by the proteoliposomes represented about a sevenfold increase as compared to that of the reconstituted system derived from an initial 1.2% cholate extract of the membranes. Other Na+-coupled transport systems such as L-alanine, alpha -ketoglutarate and phosphate were not detected in these reconstituted proteoliposomes.

Amino acid-dependent sodium transport in plasma membrane vesicles from rat liver

The L-alanine-dependent transport of sodium ions across the plasma membrane of rat-liver parenchymal cells was studied using isolated plasma membrane vesicles. Sodium uptake is stimulated specifically by the L-isomer of alanine and other amino acids, whose transport is sodium-dependent in rat-liver plasma membrane vesicles. The L-alanine-dependent sodium flux across the membrane is inhibited by an excess of Li+ ions, but not by K+ or choline ions. Sodium transport is sensitive to -SH reagents and ionophores, and is an electrogenic process: a membrane potential (negative inside) can enhance L-alanine-dependent sodium accumulation. The data presented provide further evidence for a sodium-alanine cotransport mechanism.

Regulation of canine renal vesicle Pi transport by growth hormone and parathyroid hormone

Renal phosphate (Pi) reabsorption is increased by growth hormone (GH) and decreased by parathyroid hormone (PTH). Na+-stimulated Pi transport across the brush border membrane of the proximal tubule is the initial step in the process of Pi reabsorption. To determine whether changes in Pi reabsorption induced by GH or PTH are accompanied by changes in brush border membrane Na+-gradient-stimulated Pi transport, we examined the effect of in vivo GH and PTH administration and thyroparathyroidectomy on Pi transport by isolated brush border membrane vesicles prepared from canine kidney. In experiments in which the effect of PTH administration was examined, the same animal provided the control kidney (before PTH administration) and the experimental kidney (after PTH administration). The Na+-gradient Pi overshoot in vesicles isolated from normal, GH-treated and thyroparathyroidectomized dogs was increased after in vivo PTH administration. GH administration and thyroparathyroidectomy increased the height of the overshoot compared to normal. PTH administration decreased the apparent V value by 44% in vesicles from normal animals. The apparent V value was increased, compared to normal, by GH (34%) and thyroparathyroidectomy (57%). PTH administration decreased the apparent V in both the latter groups. GH administration to thyroparathyroidectomized dogs further increased the apparent V. Changes in the apparent V paralleled changes in Pi reabsorption in vivo induced by experimental manipulations. We conclude that changes in renal Pi reabsorption induced by GH were like those induced by PTH, accompanied by changes in the Na+-stimulated Pi transport system in the renal brush border membrane, and that the effect of PTH on vesicular Pi transport in GH-treated dogs did not differ from the effect on vesicles from normal animals.

Specificity of the transport system for tricarboxylic acid cycle intermediates in renal brush borders

Uptake studies employing renal brush border membranes were used to examine the structural specificity of the TCA cycle intermediate transport system. The kinetics of reciprocal inhibition between succinate and citrate revealed these compounds to be transported by a common mechanism. The Michaelis constant for succinate (0.11 mM) was significantly lower than that of citrate (0.28 mM), indicating that the system has a higher affinity for succinate than for citrate. The specificity of the transport system was determined from the relative inhibitory constants of 40 organic acids on the transport of succinate. The results established that the system is highly specific for 4-carbon, terminal dicarboxylic acids in the trans-configuration, including the major intermediates of the TCA cycle. The system is comparatively insensitive to monocarboxylates. Substitution of one of several polar, non-charged residues on the alpha-carbon of succinate permitted interaction of the substrate with the transport system, but substitutions on both the alpha and beta-carbons did not. The structural specificity of the system is fundamentally different from that of the dicarboxylate and tricarboxylate exchange systems of mitochondria. The role of this transport system in the reabsorption of TCA cycle intermediates from the proximal tubule is discussed.