Effect of fatty acid chain length on initial reaction rates and regioselectivity of lipase-catalysed esterification of disaccharides

In a reaction medium mixture of 9:11 t-BuOH and pyridine (v/v) the effect of fatty acid chain length (C-4-C-12) on C. antarctica lipase B (Novozym 435, EC 3.1.1.3) catalysed esterification was studied. alpha and beta maltose 6'-O-acyl esters in an anomeric molar ratio of 1.0:1.1 were synthesised independently of the chain length, but the initial specific reaction rate increased with decreasing chain length of the acyl donor. The product yield followed the same trend with a lauryl ester yield of 1.1% (mol/mol) and a butyl ester yield of 27.6% (mol/mol) after 24 h of reaction. With sucrose as the acyl acceptor the 6'-O-acyl and 6-O-acyl monoesters were formed with fatty acids of chain length C-4 and C-10 while the 6',6-O-acyl diester was formed only with butanoic acid (C-4:0) as acyl donor. The 6'-O-acyl and 6-O-acyl monoesters and the 6',6-O-acyl diester of butanoic acid were produced in a molar ratio of 1.0:0.5:0.2 and with decanoic acid (C-10:0) the 6'-O-acyl and 6-O-acyl monoesters were formed in the ratio of 1.0:0.3. The highest initial reaction rate and yield were obtained with the shortest chain length of the acyl donor. Initial reaction rates and ester yields were affected by the solubility of the disaccharide, with higher reaction rates and yields with maltose than with sucrose, while no formation of esters were observed with either cellobiose or lactose as acyl acceptors.     

Preparation of N-tBoc L-glutathione dimethyl and di-tert-butyl esters: versatile synthetic building blocks

The title l-glutathione derivatives, containing acid- and base-labile esters, respectively, were obtained in good overall yields. N-(t)Boc l-glutathione dimethyl ester was prepared via Fischer esterification of l-glutathione disulfide (GSSG) using HCl in dry methanol, protection of the amine with (t)Boc(2)O, and tributylphosphine cleavage of the disulfide in wet isopropanol. Alternatively, Fischer esterification and (t)Boc-protection of l-glutathione (GSH) also furnished N-(t)Boc glutathione dimethyl ester accompanied by a small amount of S-(t)Boc that was removed chromatographically. The di-tert-butyl ester was obtained by S-palmitoylation of GSH in TFA as solvent, N-(t)Boc-protection, esterification using (t)BuOH mediated by diisopropylcarbodiimide/copper(I) chloride, and saponification of the thioester. These l-glutathione derivatives are versatile synthetic building blocks for the preparation of S-glutathione adducts.     

Glutathione monoethyl ester: preparation, uptake by tissues, and conversion to glutathione

Glutathione monoethyl ester (L-gamma-glutamyl-L-cysteinylglycyl ethyl ester), in contrast to glutathione itself, is effectively transported into many types of cells. The ester is converted intracellularly into glutathione. Intraperitoneal injection of 35S-labeled ester into mice was followed by rapid appearance of isotope in the glutathione of liver, kidney, spleen, pancreas, and heart; the glutathione levels of these tissues also increased. Oral administration of the ester to mice also increased cellular glutathione levels. Relatively little extracellular deesterification was found. Transport of glutathione ester into human erythrocytes and intracellular conversion to glutathione was observed. The findings suggest that the glutathione ester will be useful as a radioprotecting agent and in the prevention and treatment of toxicity due to certain foreign compounds and oxygen. The ester may be useful in experimental work on glutathione transport, metabolism, and function, and in related studies on oxygen toxicity, radiation, mutagenesis, and ageing. Methods for the preparation of glutathione monoethyl ester and several related compounds are given.     

Cytochrome P-450-catalyzed hydroxylation and carboxylic acid ester cleavage of Hantzsch pyridine esters

Cytochrome P-450 (P-450)-catalyzed oxidation of 2,6-dimethyl-4-phenyl-3,5-pyridinedicarboxylic acid diethyl ester gives rise to 2,6-dimethyl-4-phenyl-3,5-pyridinedicarboxylic acid monoethyl ester and to 2-hydroxymethyl-6-methyl-4-phenyl-3,5-pyridinedicarboxylic acid diethyl ester, identified in this work. A pyridine hydroxymethyl diester of the sort of the latter compound is novel; under acidic or dehydrating conditions the diester is readily converted to a cyclic lactone (2-hydroxymethyl-6-methyl-4-phenyl-3,5-pyridinedicarboxylic acid 5-ethyl ester lactone). 2,6-Dimethyl-4-phenyl-3,5-pyridinedicarboxylic acid monoethyl ester was not hydroxylated to form this hydroxymethyl compound or lactone, but 1,4-dihydro-2-hydroxymethyl-4-phenyl-6-methyl-3,5-pyridinedicarboxyli c acid diethyl ester was enzymatically oxidized to give both products. The rates of oxidative carboxylic ester cleavage and methyl hydroxylation varied among individual forms of P-450 tested. Experiments with 2H and 3H labels were used to estimate an intrinsic kinetic deuterium isotope effect of 15 for ethyl ester cleavage by rat liver P-450PB-B in a reconstituted system. Rat liver microsomal systems showed kinetic deuterium and tritium isotope effects of 8 and 11, respectively, and this deuterium isotope effect was not attenuated in either intra- or intermolecular competitive experiments. When deuterium was present in the ethyl (ester) groups, increases in the rate of 2-methyl hydroxylation were observed in rat liver microsomes and with purified P-450 beta NF-B (but not with P-450PB-B). Deuteration of the methyl groups gave rise to kinetic isotope effects of 7-11, but no increases were seen in the rates of ester cleavage. These studies and those on rates of substrate disappearance indicate that isotopically sensitive branching (metabolic switching) observed in these systems is not necessarily bidirectional.     

The involvement of intracellular glutathione in methyl jasmonate signaling in Arabidopsis guard cells

We examined the involvement of intracellular glutathione (GSH) in methyl jasmonate (MeJA) signaling. The chlorina1-1 (ch1-1) mutation decreased GSH in guard cells and narrowed the stomatal aperture. GSH monoethyl ester increased intracellular GSH, diminishing this phenotype. GSH did not affect MeJA-induced reactive oxygen species production or cytosolic Ca(2+) oscillation, suggesting that GSH modulates MeJA signaling downstream of production and oscillation.     

Enzymatic synthesis of sorbitan esters using a low-boiling-point azeotrope as a reaction solvent

Sorbitan esters were prepared by controlled dehydration of sorbitol followed by lipase-catalyzed esterification of the resulting "sorbitan." The reaction was carried out in azeotropic mixtures of tert-butanol/n-hexane. A partial phase diagram to determine the temperature required for the distillation of the azeotrope at a given ratio of the solvents was constructed. The effect of varying concentrations of the two solvents on the rate of esterification and the monoester/diester ratio of the final product was investigated in detail. (c) 1997 John Wiley & Sons, Inc. Biotechnol Bioeng 54: 351-356, 1997.     

Glutathione metabolism at the blood-cerebrospinal fluid barrier

Glutathione metabolism and transport in the choroid plexus were probed by determining the effects of administration to rats of several compounds (buthionine sulfoximine, L-2-oxothiazolidine-4-carboxylate, L-(alpha 5,5S)-alpha-amino-3-chloro-4,5-dihydro-5-isoxazole acetic acid, gamma-glutamyl alanine, and glutathione monoethyl ester) on the levels of glutathione and cysteine in the cerebrospinal fluid. The findings indicate that glutathione is actively metabolized in the choroid plexus by pathways similar to those in kidney and other tissues. The level of glutathione in the cerebrospinal fluid can be decreased or increased by giving compounds that do not, under similar conditions, appreciably alter total brain levels of glutathione. Glutathione monoethyl ester is effectively transported into the cerebrospinal fluid.     

The Involvement of Intracellular Glutathione in Methyl Jasmonate Signaling in Arabidopsis Guard Cells

We examined the involvement of intracellular glutathione (GSH) in methyl jasmonate (MeJA) signaling. The chlorina1-1 (ch1-1) mutation decreased GSH in guard cells and narrowed the stomatal aperture. GSH monoethyl ester increased intracellular GSH, diminishing this phenotype. GSH did not affect MeJA-induced reactive oxygen species production or cytosolic Ca²⁺ oscillation, suggesting that GSH modulates MeJA signaling downstream of production and oscillation.     

Effect of apolipoprotein E-free high density lipoproteins on cholesterol metabolism in cultured pig hepatocytes

We studied cholesterol synthesis from [14C]acetate, cholesterol esterification from [14C]oleate, and cellular cholesterol and cholesteryl ester levels after incubating cells with apoE-free high density lipoproteins (HDL) or low density lipoproteins (LDL). LDL suppressed synthesis by up to 60%, stimulated esterification by up to 280%, and increased cell cholesteryl ester content about 4-fold. Esterification increased within 2 h, but synthesis was not suppressed until after 6 h. ApoE-free HDL suppressed esterification by about 50% within 2 h. Cholesterol synthesis was changed very little within 6 h, unless esterification was maximally suppressed; synthesis was then stimulated about 4-fold. HDL lowered cellular unesterified cholesterol by 13-20% within 2 h and promoted the removal of newly synthesized cholesterol and cholesteryl esters. These changes were transient; by 24 h, both esterification and cellular unesterified cholesterol returned to control levels, and cholesteryl esters increased 2-3-fold. HDL core lipid was taken up selectively from 125I-labeled [3H]cholesteryl ester- and ether-labeled HDL. LDL core lipid uptake was proportional to LDL apoprotein uptake. The findings suggest that 1) the cells respond initially to HDL or LDL with changes in esterification, and 2) HDL mediates both the removal of free cholesterol from the cell and the delivery of HDL cholesteryl esters to the cell.     

Interaction of sulfate and glutathione transport in cultured tobacco cells

Photoheterotrophic and heterotrophic suspension cultures of tobacco (Nicotiana tabacum L.) were grown with 1 mM glutathione (reduced; GSH) as sole source of sulfur. Addition of sulfate to both cultures did not alter the rate of exponential growth, but affected the removal of GSH and sulfate in different ways. In photoheterotrophic suspensions, addition of sulfate caused a decline in the net uptake of GSH, whereas sulfate was taken up by the green cells immediately. In heterotrophic suspensions, however, addition of sulfate did not affect the net uptake of GSH and sulfate was only taken up by the cells after the GSH supply in the medium had been exhausted. Apparently, GSH uptake in photoheterotrophic cells is inhibited by sulfate, whereas sulfate uptake is inhibited by GSH in heterotrophic cells. The differences in the effect of GSH on sulfate uptake in photoheterotrophic and heterotrophic tobacco suspensions cannot be attributed to differences in the kinetic properties of sulfate carriers. In short-time transport experiments, both cultures took up sulfate almost entirely by an active-transport system as shown by experiments with metabolic inhibitors; sulfate transport of both cultures obeyed monophasic Michaelis-Menten kinetics with similar app. K_m (photoheterotrophic cells: 16.0±2.0 M; heterotrophic cells: 11.8±1.8 M) and V_max (photoheterotrophic cells: 323±50 nmol·min^-1·g^-1 dry weight; heterotrophic cells: 233±3 nmol·min^-1·g^-1 dry weight). Temperature- and pH-dependence of sulfate transport showed almost identical patterns. However, the cultures exhibited remarkable differences in the inhibition of sulfur influx by GSH in short-time transport experiments. Whereas 1 mM GSH inhibited sulfate transport into heterotrophic tobacco cells completely, sulfate transport into photoheterotrophic cells proceeded at more than two-thirds of its maximum velocity at this GSH concentration. The mode of action of GSH on sulfate transport in chloroplast-free tobacco cell does not appear to be direct: a 14-h exposure to 1 mM GSH was found to be necessary to completely block sulfate transport; a 4-h time of exposure did not affect this process. Consequently, glutathione does not seem to be a product of sulfur metabolism acting on sulfate-carrier entities by negative feedback control. When transferred to the whole plant, the observed differences in sulfate and glutathione influx into green and chloroplast-free cells may be interpreted as a regulatory device to prevent the uptake of excess sulfate by plants.Abbreviations DCCD N,N-dicyclohexylcarbodiimide - DNP dinitrophenol - DW dry weight - FW fresh weight - GSH reduced glutathione     

The chemical and enzymatic oxidation of hematohemin IX. Identification of hematobiliverdin IX alpha as the sole product of the enzymatic oxidation

Oxidative cleavage of hematohemin IX in pyridine solution in the presence of ascorbic acid (coupled oxidation), followed by esterification of the products with boron trifluoride/methanol produced the four possible hematobiliverdin dimethyl esters in 11.1% overall yield. Transetherifications took place simultaneously with the esterification reaction and resulted in the formation of the dimethyl ester of hematobiliverdin IX gamma 8a,13a-dimethyl ether (1.8%), the dimethyl ester of hematobiliverdin IX beta 13a,18a-dimethyl ether (1.9%), the dimethyl ester of hematobiliverdin IX delta 8a-monomethyl ether (1.4%), and the dimethyl ester of hematobiliverdin IX alpha 18a-monomethyl ether (0.4%). The latter was the sole product obtained after the enzymatic oxidation of hematohemin with heme oxygenase, after esterification of the reaction product with boron trifluoride/methanol. When the esterification step was omitted hematobiliverdin IX alpha was obtained from the enzymatic oxidation. The structures of the hematobiliverdin derivatives were secured by their NMR and mass spectra data. Saponification of the dimethyl esters afforded the hematobiliverdin methyl ethers, which were excellent substrates of biliverdin reductase and were readily reduced to the corresponding bilirubins. Hematobiliverdin IX alpha was also a good substrate of biliverdin reductase. It is concluded that the enzymatic oxidation of hematohemin IX by heme oxygenase is alpha-selective, while biliverdin reductase shows no selectivity in the reduction of the four hematobiliverdin isomers.     

Modulation of endothelial GSH concentrations: effect of exogenous GSH and GSH monoethyl ester

We studied the effects of exogenous glutathione (GSH) and GSH monoethyl ester (GSH-MEE) on the enhancement of endothelial GSH concentrations. The preparation of GSH-MEE used contained 91% GSH-MEE, approximately 9% GSH diethyl ester (GSH-DEE) and a trace amount of GSH. Both GSH and GSH-MEE markedly stimulated the intracellular concentrations of GSH in endothelial cells. GSH-MEE was more potent than GSH. The enhancement of endothelial GSH concentration by exogenous GSH was completely inhibited by buthionine sulfoximine (BSO), a potent inhibitor of gamma-glutamylcysteine synthase, or acivicin (AT-125), an inhibitor of gamma-glutamyl transpeptidase, suggesting that it was due to the extracellular breakdown and subsequent intracellular resynthesis of GSH. In contrast, the effect of GSH-MEE was largely resistant to BSO and acivicin, suggesting that it was primarily due to transport of GSH-MEE followed by intracellular hydrolysis. The GSH-MEE preparation, which contained 9% GSH-DEE, at concentrations of 2 mM or higher caused vacuolization of endothelial cells. The enhancement of GSH concentrations by exogenous GSH, but not by GSH-MEE, protected endothelial cells against H2O2-induced injury.     

Mammalian wax biosynthesis. II. Expression cloning of wax synthase cDNAs encoding a member of the acyltransferase enzyme family

Wax monoesters are synthesized by the esterification of fatty alcohols and fatty acids. A mammalian enzyme that catalyzes this reaction has not been isolated. We used expression cloning to identify cDNAs encoding a wax synthase in the mouse preputial gland. The wax synthase gene is located on the X chromosome and encodes a member of the acyltransferase family of enzymes that synthesize neutral lipids. Expression of wax synthase in cultured cells led to the formation of wax monoesters from straight chain saturated, unsaturated, and polyunsaturated fatty alcohols and acids. Polyisoprenols also were incorporated into wax monoesters by the enzyme. The wax synthase had little or no ability to synthesize cholesteryl esters, diacylglycerols, or triacylglycerols, whereas other acyltransferases, including the acyl-CoA:monoacylglycerol acyltransferase 1 and 2 enzymes and the acyl-CoA:diacylglycerol acyltransferase 1 and 2 enzymes, exhibited modest wax monoester synthesis activities. Confocal light microscopy indicated that the wax synthase was localized in membranes of the endoplasmic reticulum. Wax synthase mRNA was abundant in tissues rich in sebaceous glands such as the preputial gland and eyelid and was present at lower levels in other tissues. Coexpression of cDNAs specifying fatty acyl-CoA reductase 1 and wax synthase led to the synthesis of wax monoesters. The data suggest that wax monoester synthesis in mammals involves a two step biosynthetic pathway catalyzed by fatty acyl-CoA reductase and wax synthase enzymes.     

Impairment of conjunctival glutathione secretion and ion transport by oxidative stress in an adenovirus type 5 ocular infection model of pigmented rabbits.

Conjunctival epithelial cells of pigmented rabbits secrete reduced glutathione (GSH) into the apical (mucosal) fluid. The aim of the current study was to determine the effect of oxidative stress resulting from viral infection and that of GSH supplementation on redox status, GSH, and ion transport in freshly excised conjunctival tissues and epithelial cell layers in primary culture (RCEC) of adenovirus type 5 (Ad5)-infected rabbits. Lipid peroxidation (LPO) products, nitric oxide (NO), and expression of nitric oxide synthase (NOS2) were quantitated as a function of time after viral inoculation. Unidirectional fluxes of [3H]GSH and changes in short-circuit current (Isc) from mucosal supplementation of Ad5-inoculated conjunctival tissues with GSH and glutathione monoethyl ester (GSH-MEE) were also measured. Ad5 inoculation significantly decreased conjunctival GSH level by 19, 45, 48, and 50% at 8, 24, 48, and 72 h postinfection, respectively. LPO product and NO levels increased significantly (2- and 100-fold, respectively) above that of uninfected controls on Day 3 post-Ad5 inoculation, and co-treatment with GSH-MEE and tocopherol succinate abolished this effect. NO levels showed a progressive increase post-Ad5 inoculation, reaching 0.22 +/- 0.06, 8.12 +/- 0.91, and 2.05 +/- 0.65 microM on Days 1, 3, and 5, respectively, and the highest level was observed on the day of maximal viral replication (Day 3). A very significant induction of the expression of NOS2 on Days 1, 3, and 5 post-Ad5 inoculation was observed. Uninfected control conjunctival tissues displayed a net serosal-to-mucosal GSH flux (Jsm), where the mucosal-to-serosal flux (Jms) was approximately 14 pmol h(-1) cm(-2) and the Jsm was approximately 22 pmol h(-1) cm(-2). In Ad5-inoculated rabbits similar GSH flux was observed in both the sm and ms directions, and the net GSH flux was negligible. Isc and potential difference (PD) across conjunctival tissues of Ad5-inoculated rabbits decreased by > or = 50% compared with control, while the transepithelial electrical resistance (TEER) remained unchanged. Mucosal, but not serosal, superfusion of GSH or GSH-MEE in Ad5-inoculated conjunctival tissues increased the Isc by up to 40% in approximately 100 min. Our results show that net secretion of GSH across rabbit conjunctiva is totally blocked after Ad5 inoculation and active ion transport rate decreased by approximately 50%. Decreased net GSH secretion into mucosal fluid after Ad5 infection may have resulted from a decreased intracellular GSH pool due to oxyradical-induced changes in redox status and lower active ion transport. Mucosal treatment of Ad5-infected conjunctival tissues with pharmacological levels of GSH appears to transstimulate mucosal GSH secretion and restore active ion transport activity, suggesting a potentially useful therapeutic regimen for ocular infections.     

Emulsifiers from solid and liquid polyols: different strategies for obtaining optimum conversions and selectivities

The present paper provides a general overview of the factors involved in both the kinetics and the selectivity of partial acylation reactions of polyols (sugars). Different kinetic strategies for maximum production of intermediate esters of various polyols and monosaccharides are reported and discussed. Physicochemical requirements for obtaining maximum selectivities and complementary strategies for reducing reaction times are discussed. The reactions studied include glycerol, glucose, fructose, mannose, sorbitol and an alkyl glucoside as precursors. The high selectivity towards the monoglyceride in the presence and absence of a solvent has been attributed to a combination of the precipitation of the desired ester, use of glycerol in excess and the relatively low solubility of the fatty acid in the system. Unlike the reaction in the presence of a solvent, the reaction in a solvent-free medium produces the diester first. The monoester only accumulates in the medium as a consequence of disproportionation and glycerolysis reactions of the diester formed earlier. Selective esterification of solid sugars (polyols) which have an intermediate solubility in acetone is favored at low temperatures at which a sufficient amount of polyol dissolves and concurrent precipitation of the desired product can be achieved. By contrast, use of elevated temperatures is more appropriate for selective partial esterification of polyols, which are the most soluble in the solvent employed. Polyols (sugars) which are the less soluble into the liquid reaction phase cannot be easily esterified. Diffusional limitations on the rate of dissolution of the solid precursor can be minimized by increasing the surface area of the solid polyol.     

Effect of certain dicarboxylic acid monoesters on growth,chlorophyll content,chlorophyllase and peroxidase activities,and gas-exchange of young maize plants

The effect of some dicarboxylic acid monoesters on growth, chlorophyll content, chlorophyllase (EC 3.1.1.14), and total peroxidase (EC 1.11.1.7.) activities was examined in detached and intact leaves of maize (Zea mays) plants grown in a greenhouse. The -monomethyl ester of itaconic acid (MEIA) at 1250 ppm had no effect on growth. However, application of the monoethyl ester of succinic (MESA) and monoethyl ester of adipic (MEAdA) acids (1250 ppm) resulted in an increased leaf area, fresh and dry weight of leaves and stems. These compounds retarded chlorophyll degradation in both detached and intact leaves. Chlorophyllase activity of the control and treated leaves was measured and related to chlorophyll content. Delaying of senescence by treatment with monoesters resulted in greater chlorophyll and protein content, compared with the control. However, the chlorophyllase activity/chlorophylla ratio in the treated plants decreased. Total peroxidase activity was higher in senescent leaves, but all treatments inhibited the increase of this enzyme activity. Prolonged carbon assimilative activity and enhanced leaf water use efficiency in treated plants was noted.     

Effect of glutathione manipulation on prostaglandin synthesis in renal medullary homogenates.

1. The effect of glutathione (GSH) manipulation on arachidonic acid (AA) metabolism in renal medullary (RM) homogenates was investigated. 2. Diethyl maleate (DEM) depleted GSH initially by 50% (P less than 0.05) and produced a general suppression (P less than 0.05) of all PGs with the exception of TXB2. GSH was further depleted during homogenization and a 30-min incubation period (P less than 0.01). 3. Adding glutathione monoethyl ester (GSH-MEE) (0, 0.8, 1.6 or 3.2 mmol/ml) to RM homogenates increased GSH (P less than 0.01) and decreased RM homogenates' PGs-synthesizing capability (P less than 0.05), with the exception of PGE2 and TXB2 at the highest concentration. 4. The results indicate that homogenization has a significant impact (P less than 0.05) on GSH concentration of the media and alterations in GSH concentration affect the profile and quantity of AA metabolites in renal medullary homogenates.     

Indomethacin attenuation of hepatic perfusion and plasma 6-ketoPGF1 alpha elevations following glutathione depletion in rabbits

Glutathione (GSH) is important in detoxification and regulating cyclooxygenase activity. Since the liver has high levels of GSH, xenobiotic-induced changes in hepatic GSH could affect hepatic tissue blood perfusion (HP) via alterations in prostaglandin synthesis. In anesthetized male New Zealand rabbits, elevating GSH with GSH monoethyl ester had no affect on HP. Treatment of rabbits with diethyl maleate to deplete GSH also had no affect on HP in animals previously given GSH monoethyl ester. However, HP increased within 20 min in rabbits treated with diethyl maleate prior to GSH monoethyl ester. In another experiment, a similar rise in HP following GSH depletion was accompanied by arterial plasma 6-ketoPGF1 alpha (the stable metabolite of prostacyclin) levels that were 4-times higher than in the controls. Plasma TxB2 (the stable metabolite of thromboxane) also increased following diethyl maleate, but only to levels that were 25-times lower than for 6-ketoPGF1 alpha. Since indomethacin blocked the rise in HP, as well as the increases in 6-ketoPGF1 alpha and TxB2, these results indicate changes in HP may occur following GSH depletion as a result of increased synthesis of one or more arachidonic acid metabolites and implicate prostacyclin as a possible mediator of this phenomenon.     

Characterization of Glutathione Uptake in Broad Bean Leaf Protoplasts

Transport of reduced glutathione (GSH) and oxidized glutathione (GSSG) was studied with broad bean (Vicia faba L.) leaf tissues and protoplasts. Protoplasts and leaf discs took up GSSG at a rate about twice the uptake rate of GSH. Detailed studies with protoplasts indicated that GSH and GSSG uptake exhibited the same sensitivity to the external pH and to various chemical reagents. GSH uptake was inhibited by GSSG and glutathione conjugates. GSSG uptake was inhibited by GSH and GS conjugates, and the uptake of metolachlor-GS was inhibited by GSSG. Various amino acids (L-glutamic acid, L-glutamine, L-cysteine, L-glycine, L-methionine) and peptides (glycine-glycine, glycine-glycine-glycine) affected neither the transport of GSH nor GSSG. Uptake kinetics indicate that GSH is taken up by a single saturable transporter, with an apparent Km of 0.4 mM, whereas GSSG uptake exhibits two saturable phases, with an apparent Km of 7 [mu]M and 3.7 mM. It is concluded that the plasma membrane of leaf cells contains a specific transport system for glutathione, which takes up GSSG and GS conjugates preferentially over GSH. Proton flux measurements and electrophysiological measurements indicate that GSH and GSSG are taken up with proton symport. However, a detailed analysis of these measurements suggests that the ion movements induced by GSSG differ from those induced by GSH.     

Glutathione Induces Neuronal Differentiation in Rat Bone Marrow Stromal Cells

It has been reported that rat bone marrow stromal cells (BMSCs) are differentiated into neuronal cells by administration of 2-mercaptoethanol [Woodbury et al (2000) J Neurosci Res 61:364–370]. In this study, we examined the effects of various sulfhydryl (SH) compounds on the differentiation of BMSCs obtained from rat femurs. Neuronal differentiation was detected morphologically and immunocytochemically. It was found that the cells treated with reduced glutathione (GSH) apparently differentiated into neurons, showing extensive processes, and expressing neuron-specific enolase and microtubule-associated protein 2. Glutathione monoethyl ester (GEE), which increased the cellular GSH content, showed no effect on the expression of neuronal markers. It is concluded that the neural differentiation of BMSCs occurs by the administration of GSH. It was suggested that extracellular and not intracellular GSH have effects on the induction of the neuronal differentiation of BMSCs.