A novel family of transporters mediating the transport of glutathione derivatives in plants

Uptake and compartmentation of reduced glutathione (GSH), oxidized glutathione (GSSG), and glutathione conjugates are important for many functions including sulfur transport, resistance against biotic and abiotic stresses, and developmental processes. Complementation of a yeast (Saccharomyces cerevisiae) mutant (hgt1) deficient in glutathione transport was used to characterize a glutathione transporter cDNA (OsGT1) from rice (Oryza sativa). The 2.58-kb full-length cDNA (AF393848, gi 27497095), which was obtained by screening of a cDNA library and 5'-rapid amplification of cDNA ends-polymerase chain reaction, contains an open reading frame encoding a 766-amino acid protein. Complementation of the hgt1 yeast mutant strain with the OsGT1 cDNA restored growth on a medium containing GSH as the sole sulfur source. The strain expressing OsGT1 mediated [3H]GSH uptake, and this uptake was significantly competed not only by unlabeled GSSG and GS conjugates but also by some amino acids and peptides, suggesting a wide substrate specificity. OsGT1 may be involved in the retrieval of GSSG, GS conjugates, and nitrogen-containing peptides from the cell wall.     

Preferential transport of glutathione versus glutathione disulfide in rat liver microsomal vesicles

A bi-directional, saturable transport of glutathione (GSH) was found in rat liver microsomal vesicles. GSH transport could be inhibited by the anion transport blockers flufenamic acid and 4, 4'-diisothiocyanostilbene-2,2'-disulfonic acid. A part of GSH taken up by the vesicles was metabolized to glutathione disulfide (GSSG) in the lumen. Microsomal membrane was virtually nonpermeable toward GSSG; accordingly, GSSG generated in the microsomal lumen could hardly exit. Therefore, GSH transport, contrary to previous assumptions, is preferred in the endoplasmic reticulum, and GSSG entrapped and accumulated in the lumen creates the oxidized state of its redox buffer.     

Low- and high-Km transport of dinitrophenyl glutathione in inside out vesicles from human erythrocytes.

Kinetic studies on the low- and high-Km transport systems for S-2,4-dinitrophenyl glutathione (DNP-SG) present in erythrocyte membranes were performed using inside-out plasma membrane vesicles. The high-affinity system showed a Km of 3.9 microM a Vmax of 6.3 nmol/mg protein per h, and the low-affinity system a Km of 1.6 mM and a Vmax of 131 nmol/mg protein per h. Both uptake components were inhibited by fluoride, vanadate, p-chloromercuribenzoate (pCMB) and bis(4-nitrophenyl)dithio-3,3'-dicarboxylate (DTNB). The low-Km uptake process was less sensitive to the inhibitory action of DTNB as compared to the high-Km process. N-Ethylmaleimide (1 mM) inhibited the high-Km process only. The high-affinity uptake of DNP-SG was competitively inhibited by GSSG (Ki = 88 microM). Vice versa, DNP-SG inhibited competitively the low-Km component of GSSG uptake (Ki = 3.3 microM). The high-Km DNP-SG uptake system was not inhibited by GSSG. The existence of a common high-affinity transporter for DNP-SG and GSSG in erythrocytes is suggested.     

Excretion of glutathione conjugates by primary cultured rat hepatocytes

Conjugation of xenobiotics with glutathione occurs commonly within the liver, and these glutathione conjugates are then preferentially excreted into bile. We have characterized this excretory process using primary cultured hepatocytes (24 h). 1-Chloro-2,4-dinitrobenzene rapidly entered the cells and formed a glutathione conjugate, S-(dinitrophenyl)glutathione, irrespective of the temperature of incubation. In contrast, the efflux of the glutathione conjugate was essentially absent in the cold but recovered rapidly upon rewarming of the cells. Therefore, initial rates of efflux of the conjugate at 37 degrees C were measured from cells preloaded biosynthetically at 10 degrees C. Efflux was a saturable process with respect to intracellular S-(dinitrophenyl)glutathione with an apparent Km of 0.58 +/- 0.12 mM and Vmax of 0.15 +/- 0.05 nmol/min/mg of protein. The excretion of S-(dinitrophenyl)glutathione had an energy of activation of 15.3 kcal/mol. The glutathione conjugate of p-nitrobenzylchloride when formed within the hepatocytes acted as a competitive inhibitor of S-(dinitrophenyl)glutathione efflux. Cultured hepatocytes, therefore, appeared to have a specific transport process for the excretion of glutathione conjugates. The addition of S-(dinitrophenyl)glutathione, but not GSH, GSSG, or methionine, to the medium caused a decrease in the rate of efflux of radiolabeled S-(dinitrophenyl)glutathione. The hepatocytes were able, however, to excrete the glutathione conjugate against an excess of extracellular S-(dinitrophenyl)glutathione. This observation suggested that extracellular S-(dinitrophenyl)glutathione, although capable of binding to the carrier, entered the hepatocytes quite slowly relative to rates of efflux. This carrier may function in a manner that would minimize the reuptake by hepatocytes of conjugates that have been excreted into the bile.     

The mechanism of biliary secretion of reduced glutathione. Analysis of transport process in isolated rat-liver canalicular membrane vesicles

Transport of reduced glutathione (GSH) was studied in isolated rat liver canalicular membrane vesicles by a rapid filtration technique. The membrane vesicles exhibit uptake of [2-3H]glycine--labeled GSH into an osmotically reactive intravesicular space. Although the canalicular membrane vesicles possess gamma-glutamyltransferase and aminopeptidase M, enzymes that hydrolyze glutathione into component amino acids, inactivation of the vesicle-associated transferase by affinity labeling with L-(alpha S,5S)-alpha-amino-3-chloro-4,5-dihydro-5-isoxazoleacetic acid (AT-125) had no effect on the initial rate of GSH transport. Chemical analysis revealed that intact GSH accounted for most of vesicle-associated radioactivity. The initial rate of transport followed saturation kinetics with respect to GSH concentration; an apparent Km of 0.33 mM and V of 1.47 nmol/mg protein in 20 s were calculated. These results indicate that transport of GSH across the canalicular membranes is a carrier-mediated process. Replacement of NaCl in the transport medium by KCl, LiCl or choline chloride had no effect on the transport activity of the vesicles. The rate of GSH uptake by the vesicles was enhanced by valinomycin-induced K+-diffusion potential (vesicle inside-positive) and was inhibited by probenecid, indicating that GSH transport across the canalicular membranes is electrogenic and involves the transfer of negative charge. The transport of GSH was inhibited by oxidized glutathione or S-benzyl-glutathione. This transport system in canalicular plasma membranes may function in biliary secretion of GSH and its derivatives which are synthesized in hepatocytes by oxidative processes or glutathione S-transferase.     

Light-dependent reduction of dehydroascorbate and uptake of exogenous ascorbate by spinach chloroplasts

A reconstituted spinach chloroplast system containing thylakoids, stroma and 0.1 mM NADPH supported O₂ evolution in the presence of oxidised glutathione (GSSG). The properties of the reaction were consistent with light-coupled GSSG-reductase activity involving H₂O as eventual electron donor. The reconstituted system also supported dehydroascorbate-dependent O₂ evolution in the presence of 0.6 mM reduced glutathione (GSH) and 0.1 mM NADPH with the concomitant production of ascorbate. The GSSG could replace GSH in which case the production of GSH preceded the accumulation of ascorbate. The data are consistent with the light-dependent reduction of dehydroascorbate using H₂O as eventual electron donor via the sequence H₂O→NADP→GSSG→dehydroascorbate. Approximately 30% of the GSH-dehydrogenase activity of spinach leaf protoplasts is localised in chloroplasts: this could not be attributed to contamination of chloroplasts by activity from the extrachloroplast compartment. Washed intact chloroplasts supported the uptake of ascorbate but the uptake mechanism had a very low affinity for ascorbate (K_m approximately 20 mM). The rate of uptake of ascorbate was less than the rate of light-dependent reduction of dehydroascorbate and too slow to account for the rate of H₂O₂ reduction by washed intact chloroplasts.     

ATP-dependent S-(2,4-dinitrophenyl)glutathione transport in canalicular plasma membrane vesicles from rat liver

Uptake of the thioether S-(2,4-dinitrophenyl)glutathione (DNPSG) in canalicular plasma membrane vesicles from rat liver is enhanced in the presence of ATP and exhibits an overshoot with a transient 5.5-fold accumulation of DNPSG. Stimulation by ATP is not caused by the generation of a membrane potential, based on responses of the indicator dye oxonol V. ATP-dependent uptake has an apparent Km of 71 microM for DNPSG and a Vmax of 0.34 nmol.min-1.mg of vesicle protein-1. Protein thiol groups are essential for transport activity as indicated by the sensitivity of DNPSG transport to sulfhydryl reagents. There is competitive inhibition with other thioethers, S-hexylglutathione (Ki = 66 microM), the photoaffinity label S-(4-azidophenacyl)glutathione (Ki = 56 microM), as well as with glutathione disulfide (Ki = 0.44 mM) and with the bile acid taurocholate (Ki = 0.61 mM). GSH (2 mM) or cholate (0.4 mM) does not inhibit. Both glutathione disulfide and taurocholate show ATP-dependent transport in the canalicular membrane vesicles which is inhibited by DNPSG. No ATP-dependent transport is found for GSH. Transport of DNPSG is also inhibited competitively by alpha-naphthyl-beta-D-glucuronide (Ki = 0.42 mM) but not by alpha-naphthylsulfate (2 mM), and there is substantial inhibition with the glucuronides from ebselen and p-nitrophenol. The results indicate that the canalicular transport system for DNPSG is directly driven by ATP and that the biliary transport of other classes of compounds may also proceed via this system.     

Molecular and structural basis of glutathione import in Gram‐positive bacteria via GshT and the cystine ABC importer TcyBC of Streptococcus mutans

Glutathione (GSH) protects cells against oxidative injury and maintains a range of vital functions across all branches of life. Despite recent advances in our understanding of the transport mechanisms responsible for maintaining the spatiotemporal homeostasis of GSH and its conjugates in eukaryotes and Gram‐negative bacteria, the molecular and structural basis of GSH import into Gram‐positive bacteria has remained largely uncharacterized. Here, we employ genetic, biochemical and structural studies to investigate a possible glutathione import axis in Streptococcus mutans, an organism that has hitherto served as a model system. We show that GshT, a type 3 solute binding protein, displays physiologically relevant affinity for GSH and glutathione disulfide (GSSG). The crystal structure of GshT in complex with GSSG reveals a collapsed structure whereby the GS‐I‐leg of GSSG is accommodated tightly via extensive interactions contributed by the N‐ and C‐terminal lobes of GshT, while the GS‐II leg extends to the solvent. This can explain the ligand promiscuity of GshT in terms of binding glutathione analogues with substitutions at the cysteine‐sulfur or the glycine‐carboxylate. Finally, we show that GshT primes glutathione import via the l ‐cystine ABC transporter TcyBC, a membrane permease, which had previously exclusively been associated with the transport of l ‐cystine.     

Bidirectional mechanism of plasma membrane transport of reduced glutathione in intact rat hepatocytes and membrane vesicles.

We determined the trans effects of extracellular reduced glutathione (GSH) on the rate of efflux of endogenous labeled GSH from freshly isolated rat hepatocytes. The presence of GSH (10 mM) in the medium significantly stimulated the fractional rate of efflux of [35S]GSH from 5.2 to 12.6%/15 min (p < 0.01). This effect was concentration-dependent, had sigmoid type of kinetics (D50 of 0.32 mM), and was reversible upon removal of external GSH. trans-Stimulation (counter-transport) was also observed with 5 mM oxidized glutathione (GSSG) and ophthalmic acid (fractional [35S] GSH efflux: 13.4% +/- 4.1 and 8.8% +/- 2.3 in 15 min, respectively, compared with control: 4.7 +/- 2.5/15 min). Bromosulphthalein-glutathione (BSP-GSH, 5 mM) in Krebs buffer inhibited the fractional [35S]GSH efflux (1.1%/15 min), whereas in Cl(-)-free buffer, GSH efflux was stimulated (14.2%/15 min) compared with control. trans-Stimulation was independent of chloride. BSP-GSH cis-inhibited and trans-stimulated the initial rate of GSH transport in basolateral-enriched membrane vesicles (bLPM) but not in canalicular-enriched membrane vesicles (cLPM). gamma-Glutamyl compounds also cis-inhibited and trans-stimulated GSH transport in bLPM vesicles. GSH-depleted hepatocytes incubated with 10 mM [35S]GSH accumulated more GSH than repleted cells, but the initial rate of uptake of radioactivity was faster in repleted cells. In contrast, repleted hepatocytes incubated with tracer or 50 microM [35S]GSH did not take up GSH. Thus, the sinusoidal membrane GSH transporter exhibits low affinity kinetics with sigmoid features for both GSH uptake and trans-stimulation of efflux, explaining the lack of uptake of GSH at low physiologic extracellular concentrations. Therefore, our findings support and explain the widely held view that GSH transport is unidirectional under physiologic conditions. However, the efflux of GSH may also occur in exchange for the uptake of organic anions and gamma-glutamyl compounds.     

Studies on glutathione transport utilizing inside-out vesicles prepared from human erythrocytes

Adenosine triphosphate-dependent glutathione transport was characterized using inside-out vesicles made from human erythrocytes. Kinetic analysis of the glutathione disulfide (GSSG) transport showed a biphasic Lineweaver-Burk plot as a function of GSSG concentration suggesting the operation of two different processes. One phase had a high affinity for GSSG and a low transport velocity. Most active at acidic pH and at 25 degrees C, this transport activity was easily lost during the storage of vesicles at 4 degrees C. The Km for Mg-ATP was 0.63 mM; guanosine triphosphate (GTP) substituted for ATP gave a 340% stimulation fo transport activity. Neither dithiothreitol nor thiol reagents affected this transport process. The other phase had a low affinity for GSSG and a high transport velocity. Most active at pH 7.2 and 37 degrees C, this transport activity was stable during storage of vesicles at 4 degrees C for several days. The Km for Mg-ATP was 1.25 mM; GTP substituted with no change in activity. Dithiothreitol increased the V but did not alter the Km, and thiol reagents inhibited the transport. These findings suggest that there are two independent transfer processes for GSSG in human erythrocytes.     

Uptake of L-[14C]Proline by Isolated Rat Brain Capillaries

Rat brain capillaries exhibit concentrative uptake of L-proline. The uptake is mediated by two saturable systems, one with a Km of 0.11 mM and another with a Km of 5.9 mM. Entry also occurred by diffusion, especially at high substrate concentrations. The saturable high-affinity system is sodium-dependent, with a Km for sodium of 36 mM. Proline uptake is not inhibited by lysine, but is inhibited by phenylalanine, glycine, and leucine. alpha-Methylaminoisobutyric acid (MeAIB), a model for sodium-requiring transport systems, is a competitive inhibitor of the low-Km system. b-2-Aminobicyclo-[2,2,1]-heptane-2-carboxylic acid (BCH), a model for nonsodium-dependent transport, however, also inhibited proline uptake.     

Sugar Transport and Sulfite Action in Etioprotoplasts,Semi-Etioprotoplasts and Green Protoplasts of Avena sativa L.

The mechanism of glucose and sucrose transport and the influence of various concentrations of sulfite on its activity was studied in mesophyll protoplasts (etioprotoplasts, semi-etioprotoplasts and green protoplasts) isolated from oat (Avena sativa L.) seedlings. Kinetic analysis of [¹⁴C] glucose loading (in darkness) revealed in each kind of protoplasts the presence of two transport components. At low exogenous glucose concentrations a saturable system was the main mode of transport. At concentrations higher than 20 mM the loading of glucose in all types of protoplasts was dominated by a non-saturable, linear diffusion-like component. The rate of glucose uptake was greatest in etioprotoplasts and lowest in green protoplasts. In contrast to the above we have not found saturable components of sucrose transport in any kind of protoplasts. The rate of its uptake was greatest in semi-etioprotoplasts. Sulfite, at a concentration of < 1.0 mM stimulated and at ≥ 1.0 mM inhibited the uptake of glucose to etioprotoplasts and semi-etioprotoplasts and inhibited that to green protoplasts at any concentration. The transport of sucrose underwent a significant inhibition in the various types of protoplasts only under the influence of 10.0 mM of sulfite ions. Inhibition of glucose uptake by sulfite was of the non-competitive type. Sulfite also affected the level of adenylic nucleotides and lowered the energy charge and ATP/ADP ratio. Intensity of sulfite uptake was significantly higher in green protoplasts than in etioprotoplasts.     

Characterization of Paraquat Transport in Protoplasts from Maize (Zea mays L.) Suspension Cells

Protoplasts isolated from maize (Zea mays L.) suspension cells were used to study transport of paraquat. [14C]Paraquat uptake was measured in 400-[mu]L centrifuge tubes using silicon oil centrifugation techniques. Approximately 50% of accumulation from a 100 [mu]M paraquat solution occurred in the first 10 s, and net accumulation reached a maximum after about 10 min. Membrane binding accounted for about 30% of apparent accumulation. Concentration-dependent uptake kinetics were characterized by a non-saturating curve, which was resolved into a linear and a saturable component. The Km of the saturable component was 132 [mu]M, and the Vmax was 0.512 nmol [mu]L of protoplasts-1 min-1. In the absence of sucrose, the Vmax of the saturable component was reduced by 52%, suggesting that paraquat uptake across the plasmalemma is energy dependent. Measurement of concentration-dependent binding of paraquat to burst protoplasts showed a linear response. This suggests that the linear component from intact protoplast concentration kinetics represented paraquat binding to the plasmalemma surface. Calcium inhibited the saturable component, and this inhibition was shown by Lineweaver-Burk analysis to be noncompetitive. Putrescine, a divalent cationic polyamine with a charge distribution similar to that of paraquat, competitively inhibited paraquat uptake. These results show that paraquat transport characteristics at the plasmalemma of maize protoplasts are similar to those reported earlier for paraquat transport in roots of intact maize seedlings.     

Glutathione-Mediated Regulation of ATP Sulfurylase Activity,SO42- Uptake,and Oxidative Stress Response in Intact Canola Roots

The dual role of glutathione as a transducer of S status (A.G. Lappartient and B. Touraine [1996] Plant Physiol 111: 147-157) and as an antioxidant was examined by comparing the effects of S deprivation, glutathione feeding, and H2O2 (oxidative stress) on SO42- uptake and ATP sulfurylase activity in roots of intact canola (Brassica napus L.). ATP sulfurylase activity increased and SO42- uptake rate severely decreased in roots exposed to 10 mM H2O2, whereas both increased in S-starved plants. In split-root experiments, an oxidative stress response was induced in roots remote from H2O2 exposure, as revealed by changes in the reduced glutathione (GSH) level and the GSH/oxidized glutathione (GSSG) ratio, but there was only a small decrease in SO42- uptake rate and no effect on ATP sulfurylase activity. Feeding plants with GSH increased GSH, but did not affect the GSH/GSSG ratio, and both ATP sulfurylase activity and SO42- uptake were inhibited. The responses of the H2O2-scavenging enzymes ascorbate peroxidase and glutathione reductase to S starvation, GSH treatment, and H2O2 treatment were not to glutathione-mediated S demand regulatory process. We conclude that the regulation of ATP sulfurylase activity and SO42- uptake by S demand is related to GSH rather than to the GSH/GSSG ratio, and is distinct from the oxidative stress response.     

Glutathione disulfide reduction in tumor mitochondria after t-butyl hydroperoxide treatment.

Treatment of isolated mitochondria from rat hepatoma tumor cells (AS-30D) with the oxidant, t-butyl hydroperoxide (tBuOOH, 1 or 5 mumol/ml) resulted in the oxidation of glutathione (GSH to GSSG) and the formation of protein-glutathione mixed disulfides (ProSSG). The GSSG was retained inside of the hepatoma mitochondria. In the presence of ADP+succinate (5 or 10 mM), or ketoglutarate (10 mM) or malate (5 mM), the GSSG was reduced to GSH, but the amount of ProSSG stayed constant. With saline or ADP+glutamate (10 mM)/malate (0.1 mm) no reduction of GSSG to GSH occurred. The presence of antimycin (5 micrograms/ml) with ADP+succinate inhibited reduction. At a concentration of 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU, 0.5 mM) which inhibited a major portion of the glutathione reductase activity, the reduction of GSSG to replenish GSH was also inhibited. NADPH may play a critical role as well, for the addition of 2.4 mM NADPH to permeabilized hepatoma mitochondria fostered the reduction of GSSG after tBuOOH treatment. Therefore, hepatoma mitochondria possess a glutathione reductase-dependent system to reduce GSSG to GSH. The reaction only occurs with actively respiring mitochondria.     

Multidrug resistance-associated proteins: Export pumps for conjugates with glutathione,glucuronate or sulfate

Many endogenous or xenobiotic lipophilic substances are eliminated from the cells by the sequence of oxidation, conjugation to an anionic group (glutathione, glucuronate or sulfate) and transport across the plasma membrane into the extracellular space. The latter step is mediated by integral membrane glycoproteins belonging to the superfamily of ATP-Binding Cassette (ABC) transporters. A subfamily, referred as ABCC, includes the famous/infamous cystic fibrosis transmembrane regulator (CFTR), the sulfonylurea receptors (SUR 1 and 2), and the multidrug resistance-associated proteins (MRPs). The name of the MRPs refers to their potential role in clinical multidrug resistance, a phenomenon that hinders the effective chemotherapy of tumors. The MRPs that have been functionally characterized so far share the property of ATP-dependent export pumps for conjugates with glutathione (GSH), glucuronate or sulfate. MRP1 and MRP2 are also mediating the cotransport of unconjugated amphiphilic compounds together with free GSH. MRP3 preferentially transports glucuronides but not glutathione S-conjugates or free GSH. MRP1 and MRP2 also contribute to the control of the intracellular glutathione disulfide (GSSG) level. Although these proteins are low affinity GSSG transporters, they can play essential role in response to oxidative stress when the activity of GSSG reductase becomes rate limiting. The human MRP4, MRP5 and MRP6 have only partially been characterized. However, it has been revealed that MRP4 can function as an efflux pump for cyclic nucleotides and nucleoside analogues, used as anti-HIV drugs. MRP5 also transports GSH conjugates, nucleoside analogues, and possibly heavy metal complexes. Transport of glutathione S-conjugates mediated by MRP6, the mutation of which causes pseudoxantoma elasticum, has recently been shown. In summary, numerous members of the multidrug resistance-associated protein family serve as export pumps that prevent the accumulation of anionic conjugates and GSSG in the cytoplasm, and play, therefore, an essential role in detoxification and defense against oxidative stress.     

Catalysis of the oxidative folding of ribonuclease A by protein disulfide isomerase: dependence of the rate on the composition of the redox buffer

The velocity of the oxidative renaturation of reduced ribonuclease A catalyzed by protein disulfide isomerase (PDI) is strongly dependent on the composition of a glutathione/glutathione disulfide redox buffer. As with the uncatalyzed, glutathione-mediated oxidative folding of ribonuclease, the steady-state velocity of the PDI-catalyzed reaction displays a distinct optimum with respect to both the glutathione (GSH) and glutathione disulfide (GSSG) concentrations. Optimum activity is observed at [GSH] = 1.0 mM and [GSSG] = 0.2 mM. The apparent kcat at saturating RNase concentration is 0.46 +/- 0.05 mumol of RNase renatured min-1 (mumol of PDI)-1 compared to the apparent first-order rate constant for the uncatalyzed reaction of 0.02 +/- 0.01 min-1. Changes in GSH and GSSG concentration have a similar effect on the rate of both the PDI-catalyzed and uncatalyzed reactions except under the more oxidizing conditions employed, where the catalytic effectiveness of PDI is diminished. The ratio of the velocity of the catalyzed reaction to that of the uncatalyzed reaction increases as the quantity [GSH]2/[GSSG] increases and approaches a constant, limiting value at [GSH]2/[GSSG] greater than 1 mM, suggesting that a reduced, dithiol form of PDI is required for optimum activity. As long as the glutathione redox buffer is sufficiently reducing to maintain PDI in an active form [( GSH]2/[GSSG] greater than 1 mM), the rate acceleration provided by PDI is reasonably constant, although the actual rate may vary by more than an order of magnitude. PDI exhibits half of the maximum rate acceleration at a [GSH]2/[GSSG] of 0.06 +/- 0.01 mM.     

Kidney epithelial cells of monkey origin (BSC-1) express a sodium bicarbonate cotransport. Characterization by 22Na+ flux measurements

Na movement across the plasma membranes of confluent monolayers of monkey kidney epithelial cells (BSC-1) was studied using 22Na+ uptake and efflux techniques in the presence of 10(-4) M ouabain. In the presence of 28 mM bicarbonate, uptake was inhibited by both 10(-3) M amiloride and 10(-3) M 4,4'diisothiocyanostilbene-2,2'-disulfonic acid (DIDS). In DIDS-pretreated cells, 10(-3) M amiloride led to a further reduction of 22Na+ uptake, while 10(-5) furosemide was ineffective. DIDS also inhibited sodium efflux, indicating that the DIDS-sensitive pathway mediates both influx and efflux of 22Na+. DIDS-sensitive 22Na+ uptake, as studied in the presence of both 10(-4) M ouabain and 10(-3) M amiloride, was abolished by the absence of bicarbonate, which could not be substituted by other plasma membrane-permeable buffers. In 28 mM HCO3-, DIDS-sensitive uptake of 28 mM Na+ was cis-inhibited by 124 mM Na+, but no significant inhibition by K+ or Li+ was found. DIDS-sensitive 22Na+ uptake was a saturable function of both Na+ concentration (apparent Km between 20 and 40 mM at 28 mM HCO3-) and HCO3- concentration (apparent Km between 7 and 14 mM at 151 mM Na+). Intracellular microelectrode measurements showed that net Na+ transport in the presence of HCO3- is electrogenic, i.e. that there is anion cotransport with Na+. This effect is abolished by 1 mM DIDS. It is concluded that monkey kidney epithelial cells possess a stilbene-sensitive, electrogenic sodium bicarbonate symport, which may play an important role in bicarbonate reabsorption in the mammalian kidney.     

Temperature sensitivity and substrate specificity of two distinct Na+-activated D-glucose transport systems in guinea pig jejunal brush border membrane vesicles

D-Glucose transport was studied with isolated brush border membrane vesicles from guinea pig jejunum. Saturation curves were carried out at either 25 or 35 degrees C in buffers containing Na+, Li+, K+ (100 mM chloride salt), or sorbitol (200 mM). Uncorrected uptake rates were fitted by nonlinear regression analysis to an equation involving one diffusional and two saturable terms. In the presence of Na+ at 35 degrees C, two saturable systems (Km = 0.4 and 24 mM, respectively) were evident, as well as a diffusion component quantitatively identical with that measured with L-glucose in separate experiments. In contrast, at 25 degrees C only one saturable system was apparent (Km = 1.2 mM): the second exhibited diffusion-like kinetics. In the presence of Na+ at 35 degrees C, D-glucose uptake was fully inhibited by both D-glucose and D-galactose, whereas alpha-methylglucoside gave kinetics of partial inhibition. We conclude that in the presence of Na+ there are at least two distinct D-glucose transport systems: 1) System I, a low temperature-sensitive system, fully inhibited by D-glucose, D-galactose, and alpha-methylglucoside; we identify it as the "classical" D-glucose/Na+ cotransport system, insensitive to inhibition by cytochalasin B and obligatorily dependent on Na+; and 2) System II, a high temperature-sensitive system where D-glucose and D-galactose inhibit but alpha-methylglucoside is inert. Its cation specificity is unclear but it appears to be sensitive to cytochalasin B inhibition. When Li+ or K+ substituted for Na+, only one transport system was apparent. The Li+-activated transport was: independent of the incubation temperature; inhibited by D-glucose and D-galactose but not by alpha-methylglucoside, 2-deoxy-D-glucose, D-mannose, and D-xylose; and sensitive to cytochalasin B inhibition. The exact nature of the system (or systems) involved in D-glucose transport in the absence of sodium remains to be established.     

Changes in the glutathione level induced by transplasma membrane electron transport in maize (Zea mays L.)

Summary We investigated changes of thiols (GSH, GSSG, and cysteine) induced by transplasma membrane electron transport after addition of artificial electron acceptors and the influence of the thiol level on redox activity. GSH, GSSG, and cysteine content of maize (Zea mays L. cv. Golden Bantam) roots and coleoptile segments was determined by high performance liquid chromatography with a fluorescence detector. GSSG increased after treatment with 0.8 mM diamide, an SH-group oxidizer. GSH level of roots increased after treatment with diamide, while GSH levels of coleoptiles decreased. Incubation of roots with the GSH biosynthesis inhibitor buthionine-D,L-sulfoximine for 6 days lowered the glutathione level up to 80%. However, the GSH/GSSG ratio of maize roots remained constant after treatment with both effectors. The GSH/GSSG ratio and the glutathione level were changed by addition of artificial electron acceptors like hexacyanoferrate (III) or hexabromoiridate (IV), which do not permeate the plasma membrane. Hexacyanoferrate (III) reduction was inhibited up to 25% after the cellular glutathione level was lowered by treatment with diamide or buthionine-D,L-sulfoximine. Proton secretion induced by reduction of the electron acceptors was not affected by both modulators. The change in glutathione level is different for roots and coleoptiles. Our data are discussed with regard to the role of GSH in electron donation for a plasma membrane bound electron transport system.Abbreviations Buthionine-D,L-sulfoximine s-n-butyl-homocysteine sulfoximine - cys cysteine - diamide 1,1-azobis (N,N-dimethyl-formamide) - DTE dithioerythritol - EDTA ethylenediaminetetraacetic acid - GSH reduced glutathione - GSSG oxidizied glutathione, glutathione disulfide - HBI IV hexabromoiridate (IV) (K₂[IrBr₆]) - HCF III hexacyanoferrate (III) (K₃[Fe(CN)₆] - NEM N-ethylmaleimide - PM plasma membrane - Tris Tris(hydroxymethyl)aminomethane