Energy-dependent export of the 13-oxooctadecadienoic acid-glutathione conjugate from HT-29 cells and plasma membrane vesicles

Numerous studies have identified members of the multidrug resistance protein (MRP) family of ABC transporters as ATP-dependent GS-X pumps responsible for export of various xenobiotic conjugates, and the few known glutathione conjugates of endogenous metabolites. In the present study we have investigated the possibility that the glutathione conjugate of 13-oxooctadecadienoic acid (13-OXO-SG), is exported from HT-29 cells by one of these GS-X pumps. The precursor 13-oxooctadecadienoic acid (13-OXO) is a metabolic oxidation product of linoleic acid. The transport of 13-OXO-SG is compared to that of the glutathione conjugate of chlorodinitrobenzene (DNP-SG). The results show that the efflux of 13-OXO-SG is ATP-dependent. In cultured HT-29 cells as well as in inside-out vesicles prepared from these cells, significant inhibition of conjugate export is achieved by the energy disrupters, beta,gamma-methylene ATP, sodium vanadate, and 2-deoxyglucose. Significant inhibition of the vesicle-mediated transport is also observed in the presence of genistein and verapamil. In inside-out vesicles, the transport of both conjugates exhibits saturation with an apparent K(m) of 325.5 microM and a V(max) of 0.0669 nmol/mg protein per min for 13-OXO-SG and a K(m) of 169 microM and a V(max) of 0.496 nmol/mg protein per min for DNP-SG. Furthermore, co-inhibition is observed when both conjugates are present simultaneously which is consistent with the involvement of common pumps. The data in this report demonstrate the involvement of an ATP-dependent pump in the metabolic disposition of endogenously derived metabolites of linoleic acid.     

Functions of ABC transporters in plants

ABC (ATP-binding cassette) proteins are ubiquitously found in prokaryotes and eukaryotes and generally serve as membrane-intrinsic primary active pumps. In higher plants, ABC proteins constitute a large family, grouped phylogenetically into eight clusters, subfamilies ABCA-ABCI (ABCH is not found in plants). ABC transporters shuttle substrates as diverse as lipids, phytohormones, carboxylates, heavy metals, chlorophyll catabolites and xenobiotic conjugates across a variety of biological membranes. To date, the largest proportions of characterized members have been localized to the plasma membrane and the tonoplast, with dominant implications in cellular secretion and vacuolar sequestration, but they are also found in mitochondrial, plastidal and peroxisomal membranes. Originally identified as tonoplast-intrinsic proteins that shuttle xenobiotic conjugates from the cytosol into the vacuole, thus being an integral part of the detoxification machinery, ABC transporters are now recognized to participate in a multitude of physiological processes that allow the plant to adapt to changing environments and cope with biotic and abiotic stresses.     

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.     

Transport routes of metalloids into and out of the cell: a review of the current knowledge

Except for their extra- and intra-cellular interfaces, cell membranes are hydrophobic and inhibit the transport of hydrophilic molecules. Metalloids in aqueous solutions form chemical species with oxygen and hydroxyl groups and, therefore, exist as hydrophilic neutral polar solutes or as hydrophilic anions. This characteristic of metalloids introduces a large barrier for their passage through the cell membrane via unaided diffusion. The necessity for an uptake mechanism for metalloids arises from the requirement of these species for the maintenance of life, such as the need of boron for plant cells. Conversely, the transport of these species out of the cell is necessary because some metalloids are toxic, such as arsenic and antimony, and their entrance into the cell is undesirable. The undesired uptake of these toxic species is possible via pathways designed for the uptake of other structurally and chemically similar essential compounds. Therefore, the extrusion of arsenic and antimony out of the cell is an example of a detoxification mechanism. As a consequence of the hydrophobic character of the cell membrane in all living systems, the main route for the uptake and efflux of metalloids is facilitated by transmembrane proteins, driven either by concentration gradients or by energy-fueled pumps. However, metalloids forming or embedded in nano-sized particles escape the need to cross the cell membrane because these particles can be taken into the cell by endocytosis. Here, we review the uptake and efflux pathways of boron, silicon, arsenic, and antimony through the cell membranes of different organisms and the protein channels involved in these processes. In particular, passive diffusion via aquaglyceroporins, active transport via primary and secondary ion pumps, extrusion into vacuoles of metalloid-thiol conjugates via ATP-binding cassette, the efflux of methylated metalloids, and endocytosis are summarized.     

Energy-dependent export of the 13-oxooctadecadienoic acid–glutathione conjugate from HT-29 cells and plasma membrane vesicles

Numerous studies have identified members of the multidrug resistance protein (MRP) family of ABC transporters as ATP-dependent GS-X pumps responsible for export of various xenobiotic conjugates, and the few known glutathione conjugates of endogenous metabolites. In the present study we have investigated the possibility that the glutathione conjugate of 13-oxooctadecadienoic acid (13-OXO-SG), is exported from HT-29 cells by one of these GS-X pumps. The precursor 13-oxooctadecadienoic acid (13-OXO) is a metabolic oxidation product of linoleic acid. The transport of 13-OXO-SG is compared to that of the glutathione conjugate of chlorodinitrobenzene (DNP-SG). The results show that the efflux of 13-OXO-SG is ATP-dependent. In cultured HT-29 cells as well as in inside-out vesicles prepared from these cells, significant inhibition of conjugate export is achieved by the energy disrupters, β,γ-methylene ATP, sodium vanadate, and 2-deoxyglucose. Significant inhibition of the vesicle-mediated transport is also observed in the presence of genistein and verapamil. In inside-out vesicles, the transport of both conjugates exhibits saturation with an apparent K_m of 325.5 μM and a V_max of 0.0669 nmol/mg protein per min for 13-OXO-SG and a K_m of 169 μM and a V_max of 0.496 nmol/mg protein per min for DNP-SG. Furthermore, co-inhibition is observed when both conjugates are present simultaneously which is consistent with the involvement of common pumps. The data in this report demonstrate the involvement of an ATP-dependent pump in the metabolic disposition of endogenously derived metabolites of linoleic acid.     

Conjugate export pumps of the multidrug resistance protein (MRP) family: localization, substrate specificity, and MRP2-mediated drug resistance

The membrane proteins mediating the ATP-dependent transport of lipophilic substances conjugated to glutathione, glucuronate, or sulfate have been identified as members of the multidrug resistance protein (MRP) family. Several isoforms of these conjugate export pumps with different kinetic properties and domain-specific localization in polarized human cells have been cloned and characterized. Orthologs of the human MRP isoforms have been detected in many different organisms. Studies in mutant rats lacking the apical isoform MRP2 (symbol ABCC2) indicate that anionic conjugates of endogenous and exogenous substances cannot exit from cells at a sufficient rate unless an export pump of the MRP family is present in the plasma membrane. Several mutations in the human MRP2 gene have been identified which lead to the absence of the MRP2 protein from the hepatocyte canalicular membrane and to the conjugated hyperbilirubinemia of Dubin-Johnson syndrome. Overexpression of recombinant MRP2 confers resistance to multiple chemotherapeutic agents. Because of its function in the terminal excretion of cytotoxic and carcinogenic substances, MRP2 as well as other members of the MRP family, play an important role in detoxification and chemoprevention.     

Multidrug resistance protein 4 (MRP4/ABCC4) mediates efflux of bimane-glutathione

Multidrug resistance proteins (MRPs) are ATP-dependent export pumps that mediate the export of organic anions. ABCC1 (MRP1), ABCC2 (MRP2) and ABCC3 (MRP3) are all able to facilitate the efflux of anionic conjugates including glutathione (GSH), glucuronide and sulfate conjugates of xenobiotics and endogenous molecules. Earlier studies showed that ABCC4 functions as an ATP-driven export pump for cyclic AMP and cyclic GMP, as well as estradiol-17-beta-D-glucuronide. However, it was unclear if other conjugated metabolites can be transported by ABCC4. Hence in this study, a fluorescent substrate, bimane-glutathione (bimane-GS) was used to further examine the transport activity of ABCC4. Using cells stably overexpressing ABCC4, this study shows that ABCC4 can facilitate the efflux of the glutathione conjugate, bimane-glutathione. Bimane-glutathione efflux increased with time and >85% of the conjugate was exported after 15min. This transport was abolished in the presence of 2.5microM carbonylcyanide m-chlorophenylhydrasone (CCCP), an uncoupler of oxidative phosphorylation. Inhibition was also observed with known inhibitors of MRP transporters including benzbromarone, verapamil and indomethacin. In addition, 100microM methotrexate, an ABCC4 substrate or 100microM 6-thioguanine (6-TG), a compound whose monophosphate metabolite is an ABCC4 substrate, reduced efflux by >40%. A concentration-dependent inhibition of bimane-glutathione efflux was observed with 1-chloro-2,4-dinitrobenzene (CDNB) which is metabolized intracellularly to the glutathione conjugate, 2,4-dinitrophenyl-glutathione (DNP-GS). The determination that ABCC4 can mediate the transport of glucuronide and glutathione conjugates indicates that ABCC4 may play a role in the cellular extrusion of Phase II detoxification metabolites.     

Methylglyoxal production in bacteria: suicide or survival?

Methylglyoxal is a toxic electrophile. In Escherichia coli cells, the principal route of methylglyoxal production is from dihydroxyacetone phosphate by the action of methylglyoxal synthase. The toxicity of methylglyoxal is believed to be due to its ability to interact with the nucleophilic centres of macromolecules such as DNA. Bacteria possess an array of detoxification pathways for methylglyoxal. In E. coli, glutathione-based detoxification is central to survival of exposure to methylglyoxal. The glutathione-dependent glyoxalase I-II pathway is the primary route of methylglyoxal detoxification, and the glutathione conjugates formed can activate the KefB and KefC potassium channels. The activation of these channels leads to a lowering of the intracellular pH of the bacterial cell, which protects against the toxic effects of electrophiles. In addition to the KefB and KefC systems, E. coli cells are equipped with a number of independent protective mechanisms whose purpose appears to be directed at ensuring the integrity of the DNA. A model of how these protective mechanisms function will be presented. The production of methylglyoxal by cells is a paradox that can be resolved by assigning an important role in adaptation to conditions of nutrient imbalance. Analysis of a methylglyoxal synthase-deficient mutant provides evidence that methylglyoxal production is required to allow growth under certain environmental conditions. The production of methylglyoxal may represent a high-risk strategy that facilitates adaptation, but which on failure leads to cell death. New strategies for antibacterial therapy may be based on undermining the detoxification and defence mechanisms coupled with deregulation of methylglyoxal synthesis. Received: 30 March 1998 / Accepted: 22 June 1998     

Oxidative species and S-glutathionyl conjugates in the apoptosis induction by allyl thiosulfate

Natural allyl sulfur compounds show antiproliferative effects on tumor cells, but the biochemical mechanisms underlying the antitumorigenic properties of the organ sulfur compounds are not yet fully understood. Sodium 2-propenyl-thiosulfate is a garlic water-soluble organo-sulfane sulfur compound able to promote apoptosis in cancer cells, affecting the 'managing' of the redox state in the cell. Our studies show that sodium 2-propenyl-thiosulfate reacts spontaneously with reduced glutathione at physiological pH, leading to the formation of S-allyl-mercapto-glutathione, radicals and peroxyl species, which are able to induce inhibition of enzymes with cysteine in the catalytic site, such as sulfurtransferases. S-Allyl-mercapto-glutathione was purified and characterized by NMR and MS, and its cytotoxic effect at 500 μm on HuT 78 cells was analyzed, showing activation of the p38-MAPK pathway. Many allyl sulfur compounds are also able to promote chemoprevention by induction of xenobiotic-metabolizing enzymes, inducing down-activation or detoxification of the carcinogens. Thus, the effects of the S-allyl-mercapto-glutathione on proteins involved in the cellular detoxification system, such as glutathione S-transferase, have been evaluated both in vitro and in HuT 78 cells. Although the antitumor properties of water-soluble sulfur compounds may arise from several mechanisms and it is likely that more cellular events occur simultaneously, a relevant role is played by the formation of both reduced glutathione conjugates and radical species that affect the activity of the thiol-proteins involved in fundamental cellular processes.     

Detoxification of diphtheria and tetanus toxin with formaldehyde. Detection of protein conjugates.

In a model system of purified diphtheria and tetanus toxins it was shown that conjugates between the two proteins are formed during detoxification with formaldehyde. Detoxification mixtures were fractionated by HPLC. Two protein conjugates with different molecular weights were detected and quantified by capture ELISA assay. In vivo the existence of the largest diphtheria-tetanus toxoid conjugate was demonstrated by its antibody response in mice vaccinated with a calcium phosphate adjuvated column fraction of detoxification mixture. To eliminate the risk of cross-linking foreign proteins to toxoids in an attempt to reduce the frequency of adverse reactions in vaccination programmes, it is preferable to purify toxins before treatment with formaldehyde.     

Mutation of the RGD sequence does not affect plasma membrane association and growth inhibitory effects of elevated IGFBP-2 in vivo

Vacuolar sequestration or cellular extrusion of glutathione-conjugated xenobiotics and catabolites by ATP-binding cassette (ABC) transporters is an important detoxification mechanism operating in many species. In this study, we show that the yeast ABC transporter Bpt1p, a paralogue of Ycf1p, acts as an ATP-dependent vacuolar pump for glutathione conjugates. Bpt1p, which is inhibited by vanadate and glibenclamide, accounts for one third of the total vacuolar transport of glutathione conjugates. Furthermore, immunoblot analyses show that Bpt1p levels are strongly elevated in early stationary phase, consistent with a function of Bpt1p in vacuolar detoxification.     

Detoxification of xenobiotics in plant cells by glutathione conjugation and vacuolar compartmentalization: a fluorescent assay using monochlorobimane

Monochlorobimane (BmCl), a non-fluorescent cell-per-meant compound that reacts with glutathione to yield a strong blue fluorescent conjugate bimane-glutathione (Bm-SG), was used to trace the glutathione-dependent detoxification of xenobiotics in plant cells and protoplasts. In BmCl-labelled cells and protoplasts, fluorescence developed rapidly and was quickly concentrated in the vacuole. The rate of fluorescence development was dependent on the concentration of BmCl and the only metabolite formed was the conjugate Bm-SG. The formation of Bm-SG was correlated with a decrease in the amount of intracellular GSH. Compounds which reduced the intracellular levels of GSH severely reduced the formation of Bm-SG. Bm-SG was shown to be transported into isolated vacuoles by an ATP-dependent vana-date-sensitive mechanism. Kinetic analysis of cellular Bm-SG formation implicated both spontaneous conjugation and enzyme catalysis. Our results demonstrate a cellular pathway for xenobiotic detoxification in plants, starting with conjugation to glutathione in the cytoplasm, followed by the transport of the conjugates into the vacuole. This pathway is used to counter the toxic effects of some herbicides and environmental pollutants and overlaps with or parallels the pathway used for the biosynthesis of anthocyanins.     

The GS-X Pump in Plant, Yeast, and Animal Cells: Structure, Function, and Gene Expression

This review addresses the recent molecular identification of several members of the glutathione S-conjugate (GS-X) pump family, a new class of ATP-binding cassette (ABC) transporters responsible for the elimination and/or sequestration of pharmacologically and agronomically important compounds in mammalian, yeast and plant cells. The molecular structure and function of GS-X pumps encoded by MRP, cMOAT, YCF1. and AtMRP genes, have been conserved throughout molecular evolution. The physiologic function of GS-X pumps is closely related with cellular detoxification, oxidative stress, inflammation, and cancer drug resistance. Coordinated expression of GS-X pump genes, e.g., MRP1 and YCF1, and -glutamylcystaine synthetase, a rate-limiting enzyme of cellular glutathione (GSH) biosynthesis, has been frequently observed.     

The role of the plasmalemma in metal tolerance in angiosperms

Evidence for the role of the plasmalemma in metal tolerance of metal resistant ecotypes, cultivars and clones is presented. A range of tolerance mechanisms involving the plasmalemma are discussed including alterations to protein carrier and channel function and synthesis, efflux pumps and maintenance of plasmalemma integrity. Specific examples of such alterations from the literature on Al, As and Cu tolerance, where the plasmalemma has been shown to have a role in tolerance are considered. Tolerance by alterations to plasmalemma function in tolerant ecotypes may also rely on internal metal detoxification mechanisms constitutive in tolerant and non-tolerant plants.     

Spodoptera littoralis detoxifies neurotoxic 3-nitropropanoic acid by conjugation with amino acids

Spodoptera littoralis is a phytophagous generalist. Its host range includes more than 40 plant species, some of which produce 3-nitropropanoic acid (3-NPA), an irreversible inhibitor of mitochondrial succinate dehydrogenase. Growth in larvae fed an artificial diet with a sublethal admixture of 3-NPA (4.2 μmol per g) was slowed significantly, but larvae experienced no increase in mortality. In contrast, larvae injected with 25.2 μmol/g (bodyweight) 3-NPA experienced acute toxicity and death. To study the detoxification mechanism of 3-NPA in S. littoralis, the insect frass was analyzed by HPLC-MS. Comparative analysis of 3-NPA-treated and -untreated control samples using HR-MS² revealed a group of differential signals that were identified as amino acid amides of 3-NPA with glycine, alanine, serine, and threonine. When sublethal amounts of stable isotope-labeled 3-NPA were injected into a larva's hemolymph, 3-NPA amino acid conjugates were identified as putative detoxification products. Bioassays with synthetic standards confirmed that the toxicity of the amides was negligible in comparison to the toxicity of free 3-NPA, demonstrating that amino acid conjugation in S. littoralis represents an efficient way to detoxify 3-NPA. Furthermore, biosynthetic studies using crude fractions of the gut tissue indicated that conjugation of 3-NPA with amino acids occurs in epithelial cells of the insect's gut. Taken together, these results suggest that the detoxification of 3-NPA in S. littoralis proceeds via conjugation to specific amino acids within the epithelial cells followed by export of the nontoxic amino acid conjugates to the hemolymph via as yet uncharacterized mechanisms, most likely involving the Malpighian tubules.     

Cytosolic sulfotransferases

Sulfoconjugation (Sulfation or Sulfonation) is an important reaction in the phase II biotransformation of a wide number of endogenous and foreign chemicals, including: drugs, toxic chemicals, hormones, and neurotransmitters. The reaction is catalyzed by the members of the cytosolic sulfotransferase (SULT) superfamily, consisting of ten functional genes in humans. Sulfation reaction in living cells is reversed by sulfatase, which hydrolyses the sulfonated conjugates. It has a major role in regulating the endocrine status of an individual by modulating the activity of steroid hormones, their biosynthesis, and the metabolism of catecholamines. Sulfonation is a key reaction in the body's 'chemical' defense against xenobiotics. Although the primary function of sulfoconjugation is to permit detoxification of the compound, it also results in the activation of chemical procarcinogens, such as certain dietary and environmental agents into carcinogens. In this review, we summarize our current understanding of the structure of mammalian cytosolic sulfotransferases and their role in human steroid associated cancers and in the bioactivation of chemical carcinogens.     

Effects of CKS-17, a synthetic retroviral envelope peptide,on cell-mediated immunity in vivo: Immunosuppression,immunogenicity, and relation to immunosuppressive tumor products

Summary CKS-17 is a heptadecapeptide corresponding to a region highly conserved in retroviral transmembrane proteins such as p15E. Because a relationship had previously been determined between p15E and immunosuppressive tumor cell products, we examined the effect of CKS-17, control peptides and conjugates thereof on the expression of cell-mediated immunity (delayed-type hypersensitivity, DTH) in mice. Conjugates of CKS-17 inhibited DTH reactions to sheep erythrocytes in the feet of mice. The degree of inhibition was dose-dependent. Unconjugated CKS-17 had almost no effect, and control peptide conjugates had no inhibitory effect. Immunization of mice with CKS-17 conjugates, but not with control conjugates, rendered them resistant to the depression of DTH reactions, not only by CKS-17 conjugates, but also by products of cultured tumor cells. CKS-17 conjugates, but not control conjugates, also depressed the cellular inflammatory reactions induced in mouse footpads by concanavalin A (ConA) and immunized mice against the depression of ConA reactions by products of cultured tumor cells. Injections of globulin from sera of mice immunized with CKS-17 conjugates conferred upon normal recipients resistance to the depression of footpad reactions to ConA by products of cultured tumor cells. Globulin from sera of normal mice or control immunized mice did not confer such resistance. Thus conjugates of a synthetic peptide not only mimic the immunosuppressive effects of tumor products in vivo, but can also immunize mice against those effects.     

Functional role of bacterial multidrug efflux pumps in microbial natural ecosystems

Multidrug efflux pumps have emerged as relevant elements in the intrinsic and acquired antibiotic resistance of bacterial pathogens. In contrast with other antibiotic resistance genes that have been obtained by virulent bacteria through horizontal gene transfer, genes coding for multidrug efflux pumps are present in the chromosomes of all living organisms. In addition, these genes are highly conserved (all members of the same species contain the same efflux pumps) and their expression is tightly regulated. Together, these characteristics suggest that the main function of these systems is not resisting the antibiotics used in therapy and that they should have other roles relevant to the behavior of bacteria in their natural ecosystems. Among the potential roles, it has been demonstrated that efflux pumps are important for processes of detoxification of intracellular metabolites, bacterial virulence in both animal and plant hosts, cell homeostasis and intercellular signal trafficking.