myo-Inositol binding and transport in brush border membranes of rat kidney

Expression of the sodium-myo-inositol cotransporter SMIT2 at the apical membrane of Madin-Darby canine kidney cells

Myo-inositol is a compatible osmolyte used by cells which are challenged by variations in extracellular osmolarity, as in the renal medulla. In order to accumulate large quantities of this polyol, cells rely on Na(+)-dependent transporters such as SMIT1. We have recently identified a second Na(+)-myo-inositol cotransporter, SMIT2, which presents transport characteristics corresponding to those recently described for the apical membrane of renal proximal tubules. In order to further characterize this transport system, we transfected Madin-Darby canine kidney (MDCK) cells with rabbit SMIT2 cDNA and selected a stable clone with a high expression level. The accumulation of radiolabelled myo-inositol by this cell line is 20-fold larger than that seen in native MDCK cells. The affinity for myo-inositol of MDCK cells transfected with SMIT2 is slightly lower (K(m)= 334 microm) than that found in voltage-clamped Xenopus laevis oocytes expressing SMIT2 (K(m)= 120 microm). Transport studies performed using semipermeable filters showed complete apical targeting of the SMIT2 transporter. This apical localization of SMIT2 was confirmed by transport studies on purified rabbit renal brush border membrane vesicles (BBMVs). Using a purified antibody against SMIT2, we were also able to detect the SMIT2 protein (molecular mass = 66 kDa) in Western blots of BBMVs purified from SMIT2-transfected MDCK cells. SMIT2 activity was also shown to be stimulated 5-fold when submitted to 24 h hypertonic treatment (+200 mosmol l(-1)). The SMIT2-MDCK cell line thus appears to be a promising model for studying SMIT2 biochemistry and regulation.

Tubular reabsorption of myo-inositol vs. that of D-glucose in rat kidney in vivo et situ

Filtered myo-inositol, an important renal intracellular organic osmolyte, is almost completely reabsorbed. To examine tubule sites and specificity and, thus possible mechanism of this reabsorption, we microinfused myo-[(3)H]inositol or D-[(3)H]glucose into early proximal (EP), late proximal (LP), or early distal tubule sections of superficial nephrons and into long loops of Henle (LLH) of juxtamedullary nephrons and papillary vasa recta in rats in vivo et situ and determined urinary fractional recovery of the (3)H label compared with comicroinfused [(14)C]inulin. To determine the extent to which the proximal convoluted tubule (PCT) alone contributes to myo-inositol reabsorption, we also microperfused this tubule segment between EP and LP puncture sites. We examined specificity of reabsorptive carrier(s) by adding high concentrations of other polyols and monosaccharides to the infusate. The results show that >60% of the physiological glomerular load of myo-inositol can be reabsorbed in the PCT and >90% in the short loop of Henle (SLH) by a saturable, phloridzin-sensitive process. myo-Inositol can also be reabsorbed in the ascending limb of LLH and can move from papillary vasa recta blood into ipsilateral tubular structures. Essentially no reabsorption occurred in nephron segments beyond the SLH or in collecting ducts. Specificity studies indicate that reabsorption probably occurs via a luminal Na(+)-myo-inositol cotransporter.

Kinetic evidence for compartmentalization of myo-inositol in hepatocytes

myo-Inositol uptake and conversion to phosphatidylinositol (PI) was studied in isolated rat hepatocytes. Uptake of myo-[2-3H]-inositol into the trichloroacetic acid (TCA)-soluble fraction showed no evidence of saturation, while incorporation into lipid had an apparent Km of 0.28 mmol/L for external myo-inositol. With 50 mumol/L myo-[2-3H]-inositol, approximately half of the radiolabel was found in lipid at 30 minutes. Glucose and galactose were weak inhibitors, while phlorizin at 1 mmol/L reduced uptake by 50%. Metabolic inhibitors reduced incorporation of myo-[2-3H]-inositol into lipid, but had no effect on uptake. Hepatocytes maintained myo-inositol levels of 0.4 mmol/L for 60 minutes when incubated with 50 mumol/L myo-inositol, but levels increased when incubated with 1 mmol/L myo-inositol. Efflux of label was studied in hepatocytes prelabeled for 20 minutes with myo-[2-3H]-inositol. Loss of label was initially rapid, but had slowed by 20 minutes, with much of the label remaining in the cells. Phlorizin inhibited the loss of myo-[2-3H]-inositol, while increasing myo-inositol concentration in the medium enhanced efflux. The effects of these agents on the rate of efflux was found in lipid rather than in the TCA-soluble myo-inositol fraction. These findings suggest that myo-inositol is compartmentalized within hepatocytes, with a bulk metabolically inert pool and a smaller active pool that equilibrates with extracellular myo-inositol via an energy-independent carrier-mediated mechanism, and is preferentially available for efflux or for synthesis of phosphoinositides.

Inositol metabolism during neuroblastoma B50 cell differentiation: effects of differentiating agents on inositol uptake

Inositol uptake was studied in the rat CNS neuroblastoma B50 cell line. Eadie-Hofstee analysis of the uptake pattern reveals two defined modes of inositol entry into the cell. The high-affinity uptake component requires the presence of extracellular sodium and is inhibited by phloridzin. Analysis of the uptake velocities of the high-affinity uptake component provided the following apparent kinetic parameters: Km = 13.7 microM and Vmax = 14.7 pmol/mg of protein/min (without correcting for residual diffusion) and Km = 12.9 microM and Vmax = 12.3 pmol/mg of protein/min (with correction). At physiological concentrations, the high-affinity transport process contributes approximately 70% to total uptake; the remainder is due to a low-affinity diffusion-like process. Uptake inhibition studies reveal that the uptake process is sensitive to ouabain, amiloride, and dichlorobenzamil inhibition but relatively insensitive to cytochalasin B or phloretin. When neuroblastoma B50 cells are induced to differentiate morphologically with high extracellular calcium or with dibutyryl cyclic AMP, a significant decrease in inositol uptake is observed. The dibutyryl cyclic AMP-mediated inhibition of uptake affects only the high-affinity uptake component and is noncompetitive in nature. The high extracellular calcium-mediated inhibition is less specific; it involves "disappearance" of the high-affinity process, some inhibition of the low-affinity process, and an increase of inositol efflux. The significance of these observations is discussed in the context of neuroblastoma B50 cell differentiation.

Inositol uptake in rat aorta

The purpose of this study was to investigate the mechanism of inositol uptake into rat thoracic aorta. 3H-inositol uptake into deendothelialized aorta was linear for at least 2 h and was composed of both a saturable, Na(+)-dependent, and a nonsaturable, Na(+)-independent component. The Na(+)-dependent component of inositol uptake had a Km of 50 microM and a Vmax of 289 pmol/mg prot/h. Exposure to LiCl, ouabain, or Ca2(+)-free Krebs-Ringer bicarbonate solution inhibited uptake. Metabolic poisoning with dinitrophenol, as well as incubation with phloretin, an inhibitor of carrier-mediated hexose transport, also inhibited uptake. Exposure to norepinephrine decreased inositol uptake, while phorbol myristate acetate was without effect. Isobutylmethylxanthine significantly increased inositol uptake, while the increased uptake due to dibutyryl cyclic AMP and forskolin were not statistically significant. Sodium nitroprusside, an activator of guanylate cyclase, and 8-bromo cyclic GMP, were without effect on uptake, as was methylene blue, an inhibitor of guanylate cyclase. Inositol uptake into the aorta was increased when the endothelium was allowed to remain intact, although this effect was likely due to uptake into both the endothelial and smooth muscle cells. These results suggest that the uptake of inositol into vascular smooth muscle is: (1) dependent upon an inward Na(+)-gradient; (2) carrier mediated, and (3) inhibited by alpha 1 adrenoceptor agonists.

Retinoic acid treatment of fibroblasts causes a rapid decrease in [3H]inositol uptake

NIH 3T3 fibroblasts treated with all-trans-retinoic acid (RA) showed a dramatic decrease in the uptake of [3H]inositol compared to solvent-treated controls. The onset of RA-induced inhibition of [3H]inositol uptake was rapid with a 10-15% decrease occurring after 2-3 h of RA exposure and 60-70% reduction after 16 h of RA treatment. A progressive dose-dependent decrease in inositol uptake was found as the concentration of RA increased from 10(-8) to 10(-5) M and the effect was fully reversible within 48 h after RA removal. The Vmax and Kt for the controls were 10 nmol/2.5 x 10(6) cells/2 h and 51 microM; and for RA-treated cells the values were 4 nmol/2.5 x 10(6) cells/2 h and 52 microM. The decreased [3H]inositol uptake was not due to a change in the affinity (Kt) of the transporter for the inositol but to a decrease in the Vmax. The maximal effect on inositol uptake was dependent on RA treatment of the cells after they reached saturation density or if made quiescent by serum starvation. RA was the most active of the different retinoids examined in the order RA greater than 13-cis-RA = retinyl acetate greater than all-trans-retinol greater than 5,6-dihydroxyretinoic acid methyl ester greater than N-4-hydroxyphenyl retinamide. In contrast to this effect on inositol, the uptake of fucose, mannose, galactose, and glucose was either not affected or enhanced (for mannose and fucose) by RA treatment. RA inhibition of inositol uptake was also observed in 3T3-Swiss and Balb/3T3 cells but not in two virally transformed 3T3 cell lines. Phlorizin, amiloride, and monensin inhibited inositol uptake by 66, 74, and 58%, respectively, and this inhibition was additive when the cells were treated with RA as well as these inhibitors. A decreased incorporation of [3H]inositol into polyphosphoinositides was also observed in RA-treated cells but not to the same extent as for [3H]inositol uptake. In conclusion, RA treatment of 3T3 fibroblasts decreases the uptake of [3H]inositol by up to 70% within 8 to 10 h at near physiological concentrations in a reversible and specific manner.

Uptake and metabolism of myo-inositol by L1210 leukaemia cells

The initial rate of uptake of [3H]myo-inositol by L1210 murine leukaemia cells is directly proportional to the extracellular concentration and unaffected by several analogues of myo-inositol even at millimolar concentrations. Scyllitol, a geometric isomer of myo-inositol, partially inhibited the uptake of myo-inositol (40% at 0.1 mM). A portion of the uptake of myo-inositol was not inhibited even at 5 mM-scyllitol. At steady-state the intracellular concentration of [3H]myo-inositol is directly proportional to the extracellular concentration. Addition of myo-inositol to medium does not enhance the growth of L1210 cells; these cells can maintain an extracellular concentration of 20 microM-myo-inositol even when grown in myo-inositol-free medium. Synthesis of myo-inositol from glucose by L1210 cells was demonstrated by use of [13C]glucose and m.s. L1210 cells maintain myo-inositol pools by a combination of synthesis de novo and uptake of exogenous myo-inositol by either passive diffusion or a low affinity carrier.

[3H]-myo-inositol uptake in rat cortical slices. Identification of Na+-dependent and Na+-independent systems

[3H]-myo-Inositol (MI) uptake was measured in vitro using chopped rat cerebral cortical tissue. The uptake and accumulation of MI were linearly proportional to the amount of protein (0.1 to 4.0 mg) in the incubation medium. The uptake was also linear vs time for the first 20 min of incubation. When the uptake was observed at various substrate concentrations, it was found to be unsaturable up to a concentration of 0.78 M. Decreasing the concentration of NaCl or increasing the concentration of KCl in the incubation medium resulted in inhibition of the uptake and accumulation of MI. Inhibition of MI uptake was also produced by veratrine, ouabain and A23187 which alter the ionic gradients across the neuronal membranes. Inhibition of oxidative metabolism with dinitrophenol did not alter MI uptake. Sodium-independent uptake appeared to be the same as that which occurred at 0 degree. Sodium-independent uptake was still present in water-lysed homogenates and was inhibited by relatively high concentrations of ethanol. Thus, it appears that approximately one-half of the [3H]inositol uptake and accumulation in chopped rat cerebral cortex occurs by a sodium-dependent mechanism that can be altered by drugs which change the sodium gradient and the remaining occurs by a sodium-independent mechanism that can be altered by ethanol which is known to change membrane fluidity of neuronal membranes.

Myo-inositol transport in Saccharomyces cerevisiae

myo-Inositol uptake in Saccharomyces cerevisiae was dependent on temperature, time, and substrate concentration. The transport obeyed saturation kinetics with an apparent Km for myo-inositol of 0.1 mM, myo-Inositol analogs, such as scyllo-inositol, 2-inosose, mannitol, and 1,2-cyclohexanediol, had no effect on myo-inositol uptake, myo-Inositol uptake required metabolic energy. Removal of D-glucose resulted in a loss of activity, and azide and cyanide ions were inhibitory. In the presence of D-glucose, myo-inositol was accumulated in the cells against a concentration gradient. A myo-inositol transport mutant was isolated from UV-mutagenized S. cerevisiae cells using the replica-printing technique. The defect in myo-inositol uptake was due to a single nuclear gene mutation. The activities of L-serine and D-glucose transport were not affected by the mutation. Thus it was shown that S. cerevisiae grown under the present culture conditions possessed a single and specific myo-inositol transport system. myo-Inositol transport activity was reduced by the addition of myo-inositol to the culture medium. The activity was reversibly restored by the removal of myo-inositol from the medium. This restoration of activity was completely abolished by cycloheximide.

The nutritional significance, metabolism, and function of myo-inositol and phosphatidylinositol in health and disease

Recent advances in nutritional and biochemical research have substantiated the importance of inositol as a dietary and cellular constituent. The processes involved in the metabolism of inositol and its derivatives in mammalian tissues have been characterized both in vivo and at the enzyme level. Biochemical functions elucidated for phosphatidylinositol in biological membranes include the mediation of cellular responses to external stimuli, nerve transmission, and the regulation of enzyme activity through specific interactions with various proteins. Inositol deficiency in animals has been shown to produce an accumulation of triglyceride in liver, intestinal lipodystrophy, and other abnormalities. The metabolic mechanisms giving rise to these latter phenomena have been extensively studied as a function of dietary inositol. Altered metabolism of inositol has been documented in patients with diabetes mellitus, chronic renal failure, galactosemia, and multiple sclerosis. A moderate increase in plasma and nerve inositol levels by dietary supplementation has been suggested as a means of treating diabetic neuropathy, although excessively high levels, such as are found in uremic patients, may be neurotoxic. A thorough consideration of the biochemical functions of inositol and a further characterization of various diseases with the aid of appropriate animal models may suggest a possible role for inositol and other dietary components in their prevention and treatment

Participation of the ring oxygen in sugar interaction with transporters at renal tubular surfaces

The pulse-injection indicator-dilution technique in vivo has been used to study the interaction of 5-thio-D-glucose and methyl-beta-D-thiogalactopyranoside with renal tubular surfaces in dog kidney. (i) 5-Thio-D-glucose and methyl-beta-D-thiogalactopyranoside have nor antiluminal interaction. (ii) 37 +/- 5% of 5-thio-D-glucose is extracted at the luminal surface relative to simultaneously filtered creatinine. (iii) Luminal extraction of 5-thio-D-glucose is blocked by preloading with D-glucose and phlorizin. (iv) Methyl-beta-D-thiogalactopyranoside in contrast to D-galactose has not luminal interaction. It is concluded that 5-thio-D-glucose shares the glucose transporter at the luminal surface of the proximal tubule. The data also suggest that the ring oxygen participates in the interaction of pyranosides with luminal and antiluminal membrane carriers. At the luminal surface, its absence is quantitatively important while at the antiluminal surface it is apparently essential for the sugar-transporter interaction.

Concentration of myo-inositol in skeletal muscle of the rat occurs without active transport

The cellular uptake of nonphosphorylated myo-inositol (MI) and its incorporation into phosphoinositide in the rat epitrochlearis muscle was measured. Cellular uptake of [2-(3)H]MI was determined by the difference between total uptake and [2-(3)H]MI present in the extracellular fluid determined with [1-(14)C]mannitol. Cellular uptake was parabolic and directly proportional to medium MI concentrations between 25 and 3,200 muM. Saturation of a MI carrier was not evident. Moreover, uptake was not inhibited by 2 mM ouabain, 0.3 mM 2,4-dinitrophenol, or 22 mM glucose. Insulin, 100 mU/ml, was without effect on either cellular uptake of [2-(3)H]MI or its incorporation into phosphoinositides. In muscles that were preloaded with [2-(3)H]MI and then incubated in media that contained a constant amount of MI but no [2-(3)H]MI, 44.3% of the [2-(3)H]MI was released after 10 min increasing to 62.5% by 120 min. Cellular MI concentrations were 0.18 mumol/g wet tissue (four times plasma levels) in rapidly isolated and frozen epitrochlearis muscle. When muscle was incubated without MI, 48% of endogenous MI was lost rapidly. Restoration of cellular MI in 50 muM MI media occurred in two phases, a rapid uptake phase lasting 10 min and a subsequent slow phase of MI uptake. It is concluded that MI enters and leaves skeletal muscle cells freely by a process that does not involve active transport. Neither insulin nor hyperglycemia affected MI transport nor its incorporation into phosphoinositides. The intracellular to medium concentration gradient may be dependent on reversible binding to tubulin and possibly to other intracellular components.

Uptake of glycine from L-alanylglycine into renal brush border vesicles

Isolated renal brush border microvilli vesicles were employed to study the uptake of radiolabel from L-Ala. [3H]Gly and D-Ala.[3H]Gly as well as to determine the presence of dipeptidase activity. Microvilli vesicles were prepared from porcine kidney cortex by differential centrifugation through hypotonic Tris buffer containing Mg2+. The microvilli vesicles transiently accumulated radiolabel from L-Ala. [3H]Gly to higher levels than were initially present in the incubation medium (overshoot phenomenon). This accumulation was dependent on the presence of an inward-directed (extravesicular greater than intravesicular) Na+ gradient and was osmotically sensitive and linear with respect to microvilli protein concentration. Analysis of intravesicular contents revealed that all 3H uptake from L-Ala. [3H]Gly appeared as free glycine. Hydrolysis studies demonstrated the rate of L-Ala.[3H]Gly hydrolysis to free alanine and [3H[glycine by the microvilli to be greatly in excess of their rate of radiolabel uptake from this dipeptide. In addition, the uptake profiles and kinetic constants for vesicular uptake of radiolabel from L-Ala.[3H]Gly and free glycine were demonstrated to be identical when measured by double-labeling techniques in the same experiments. These results indicate that L-Ala.[3H]Gly is hydrolyzed at the external surface of the microvilli with the [3H]glycine released being transported into the vesicles by a Na+ gradient-dependent system identical to that employed for free glycine. Microvilli vesicle uptake of radiolabel from D-Ala.[3H]Gly exhibited no Na+ dependent "over-shoot" effect. D-Ala.[3H]Gly was completely resistant to microvilli-catalyzed hydrolysis. Analysis of the microvilli for renal dipeptidase, an enzyme with hydrolytic activity against a wide range of L-dipeptides, revealed this enzyme to be enriched in the microvilli vesicles to a degree equivalent to that observed for marker enzymes for renal microvilli. Renal dipeptidase catalyzed hydrolysis of L-Ala.Gly but not D-Ala.Gly, as was the case with microvilli-catalyzed hydrolysis of the dipeptides. With its location in the renal brush border microvilli and its hydrolytic action against L-dipeptides, renal dipeptidase my act at the luminal surface of the proximal tubule cell to hydrolyze L-dipeptides present in the glomerular filtrate, with the resultant free amino acids transported across the brush border microvilli by Na+ gradient-dependent processes.

A defect of the myo-inositol maintenance mechanism in the lens of hereditary cataract mice

The myo-inositol uptake system was studied in lenses of normal and hereditary cataract mouse. The normal mouse was able to accumulate myo-inositol continuously from medium and keep it in a high concentration. The specific myo-inositol uptake was dependent on temperature and it decreased in Ca(2+)-free medium. In contrast, specific uptake of myo-inositol reached a plateau after 15 min in the cataract mouse lens although initial incorporation was more rapid than that in normal mouse lens. This uptake system was not affected by temperature or Ca(2+) in the medium. The rate of myo-inositol efflux into the medium was more rapid in the cataract lens than that of the normal lens. It was shown that the low level of myo-inositol in the lens of hereditary cataract mouse was due to the defect of myo-inositol transport system and the enhanced efflux rate. These results suggest a dysfunction of the lens membrane.