Rat glutathione S-transferases supergene family. Characterization of an anionic Yb subunit cDNA clone

Drosophila glutathione S-transferases

The Drosophila glutathione S-transferases (GSTs; EC2.5.1.18) comprise a host of cytosolic proteins that are encoded by a gene superfamily and a homolog of the human microsomal GST. Biochemical studies of certain recombinant GSTs have linked their enzymatic functions to important substrates such as the pesticide DDT and 4-hydroxynonenal, a reactive lipid metabolite. Moreover, a correspondence has been observed between resistance to insecticide substrates-such as DDT-and elevated enzyme levels in resistant strains. Such significant, recurring connections suggest that these gst genes may feature in a model for the development of insecticide resistance. We have amassed substantial biochemical support for relating the overexpression of a particular gst gene to insecticide resistance but are still short of solid genetic evidence to affirm a causal relationship. With the Drosophila system, we have at our disposal genetic and molecular techniques such as p-element mutagenesis and excision, siRNA technology, and versatile transgenic techniques. We can use these methods to effect loss-of-function and gain-of-function conditions and, in these rendered contexts, study other potentially important functions of the gst gene superfamily. An immediate problem that comes to mind is the possible causal relationship between GST substrate specificity and chemical resistance phenotype(s). In this chapter, we present an analysis of selected strategies and laboratory methods that may be useful in pursuing a variety of interesting problems. We will cover three kinds of approaches-biochemistry, genetics, and genomics-as important instruments in a toolkit for studies of the Drosophila gst superfamily. We make the case that these approaches (biochemistry, genetics, and genomics) have helped us gain important insights and can continue to help the community gain a more complete understanding of the biological functions of GSTs. Such knowledge may be key in addressing questions about the detoxification of pesticides and how oxidative stresses affect life span. We hope that these techniques will prove fruitful in studying a host of other physiologic functions as well.

Pentobarbital-mediated regulation of alternative polyadenylation in Drosophila glutathione S-transferase D21 mRNAs

Two nearly identical, gstD21(L) and gstD21(S) mRNAs, whose polyadenylation sites differ by 19 nucleotides, are transcribed from the intronless glutathione S-transferase D21 gene in Drosophila. Both mRNAs are intrinsically very labile, but exposure to pentobarbital renders them stabilized beyond what can be attributed to transcriptional activation. We have reconstituted this PB-mediated mRNA stabilization in a transgene (D21L) that contains the full-length gstD21(L) sequence. We have also constructed a similar transgene (D21L-UTR), which matches D21L but excluded the native 3'-UTR. D21L-UTR produces a relatively stable RNA, whose stability is unaffected by pentobarbital. Following pentobarbital treatment of wild-type flies, the levels of gstD21(L) and gstD21(S) mRNAs hold at a relatively constant ratio (L/S) of 1.4 +/- 0.2. In transgenic flies, heat shock induction of D21L mRNA changed the L/S ratio to 0.6 +/- 0.1, and it was further reduced to 0.3 +/- 0.1 as D21L mRNA accumulated in the presence of PB. The ratio returned nearly normal (1.1 +/- 0.1) as the D21L mRNA decayed over 12 h after terminating induction. In constrast, when D21L-UTR was present, the ratio remained constant (1.7 +/- 0.2) even under various induction conditions and during recovery. Thus, the 3'-UTR, which was the critical difference between these two transgenes, must have some role in determining the L/S ratio. Induced D21L mRNA alone is not sufficient to cause reversible changes in the ratio. Such changes require the presence of pentobarbital. Therefore, pentobarbital may regulate this L/S ratio by affecting the choice of polyadenylation sites for the gstD21 mRNAs through sensing the concentrations of the native 3'-UTR sequences.

Identification of target genes responsive to JP-8 exposure in the rat central nervous system

Concern for the health risk associated with occupational exposure to jet fuel has emerged in the Department of Defense. Jet propulsion fuel-8 (JP-8) is the fuel used in most US and North Atlantic Treaty Organization (NATO) jet aircraft, and will be the predominant fuel both for military land vehicles and aircraft into the twenty-first century. JP-8 exhibits reduced volatility and lower benzene content as compared to JP-4, the predominant military aircraft fuel before 1992, possibly suggesting greater occupational exposure safety. However, the higher rates of occupational exposure through fueling and maintenance of increasingly larger numbers of aircraft/vehicles raise concerns with respect to toxicity. Clinical studies of workers experiencing long-term exposure to certain jet fuels demonstrated deficits in CNS function, including fatigue, neurobehavioral changes, psychiatric disorders, and abnormal electroencephalogram (EEG). In the present study, cDNA nylon arrays (Atlas Rat 1.2 Array, Clontech Laboratories, Palo Alto, CA) were utilized to measure changes in gene expression in whole brain tissue of rats exposed repeatedly to JP-8, under conditions that simulated possible real-world occupational exposure (6 h/day for 91 days) to JP-8 vapor at 1,000 mg/m3. Gene expression analysis of the exposure group compared to the control group revealed a modulation of several genes, including glutathione S-transferase Yb2 subunit (GST Yb2); cytochrome P450 IIIAl (CYP3A1); glucose-dependent insulinotropic peptide (GIP); alpha1-proteinase inhibitor (alpha1-AT); polyubiquitin; GABA transporter 3 (GAT-3); and plasma membrane Ca2+-transporting ATPase (brain isoform 2) (PMCA2). The implications of these vapor-induced changes in gene expression are discussed.

Specific induction of glutathione S-transferase GSTM2 subunit expression by epigallocatechin gallate in rat liver

The antitumor effect of green tea polyphenols has been well characterized in numerous papers. However, the mechanism of their action is still poorly defined. In this study, epigallocatechin gallate (EGCG), the main ingredient of green tea extract, was studied for its effect on the expression of glutathione S-transferases (GSTs) in rat liver to examine the mechanism of action. Liver samples were collected from Sprague-Dawley rats treated with EGCG in H(2)O by portal vein perfusion and examined for total GST activity and GST expression. The results showed that the induction of GST activity by EGCG was dose- and time-dependent. GST activity was increased about 28-fold at 12 hr after treatment. Three GST subunits (GSTA1/2, GSTM1, and GSTM2) were examined by Western blot for changes in protein level affected by EGCG (1 mg/kg weight). Only GSTM2 revealed a significant time-dependent increase, with a maximal induction of approximately 2.0-fold. The differential effect of EGCG on GST subunit expression was also verified by immunocytochemical examination and showed strong induction of the GSTM2 (but not the GSTA1/2 and GSTM1) level in liver section. This induction occurred as early as 3 hr after treatment and extended gradually outward from the hepatic veins as treatment time increased. The change in the GSTM2 protein level was accompanied by a corresponding alteration in mRNA quantity ( approximately 2.0-fold of control). Our report is the first to demonstrate a specific induction of the GSTM2 subunit by a chemopreventor and suggests a primary influence of EGCG on GSTM2 gene expression.

Binding proteins for cyclic and linear oligopeptides in plasma membranes and the cytosol of rat hepatocytes

Using a cyclolinopeptide A analogue, the hydrophobic cyclic peptide c(-Ala-Lys-Pro-Phe-Phe-Ala-Lys-Pro-Phe-Phe-), termed CDP (cyclodecapeptide), as ligand in affinity chromatography, hepatocellular peptide binding proteins were isolated from the integral part of plasma membranes and the cytosol. The sequence of the isolated protein with MW of 50 kDa from the integral part of the plasma membrane fraction was identical to cytochrome P450 II C13 and cytochrome P450 II C22, whereas the sequence of the 54 kDa protein was identical to 3-hydroxyandrogen-UDP-glucuronosyltransferase. These proteins have also been described as binding proteins for bile acids. As shown in earlier studies, bile acids and CDP also compete for uptake into hepatocytes. In the cytosol, a further known bile acid binding protein, the glutathione-S-transferase (G-S-T) subunit Yb1, was isolated and sequenced as binding protein for CDP and also for a further cyclopeptide, the somatostatin analogue OO8, and a linear peptide with renin-inhibiting activity, EMD 55068. As shown in uptake studies using isolated basolateral plasma membrane vesicles, G-S-T was able to increase the uptake of EMD 51921, a linear peptide with renin-inhibiting potency, into the vesicles when the latter were preloaded with G-S-T. The binding of the substrate to the outside of the preloaded vesicles was not different than binding to unloaded vesicles. The maximal transport rate of the carrier-mediated/facilitated diffusion and the rate of permeation, however, were doubled in the presence of G-S-T, pointing to the involvement of intracellular binding proteins such as G-S-T in the unloading of the carrier protein and in the reduction of the free substrate concentration.

A molecular genetic approach for the identification of essential residues in human glutathione S-transferase function in Escherichia coli

The common substrate for glutathione S-transferases (GSTs), 1-chloro-2,4-dinitrobenzene (CDNB), is an inhibitor of Escherichia coli growth. This growth inhibition by CDNB is enhanced when E. coli expresses a functional GST. Cells under growth inhibition have reduced intracellular GSH levels and form filaments when they resume growth. Based on this differential growth inhibition by CDNB we have developed a simple procedure to select for null-mutants of a human GST in E. coli. Null mutations in the human GST gene from hydroxylamine mutagenesis or oligonucleotide-directed mutagenesis can be selected for on agar plates containing CDNB after transformation. The molecular nature of each mutation can be identified by DNA sequence analysis of the mutant GST gene. We have identified three essential amino acid residues in an alpha class human GST at Glu31, Glu96, and Gly97. Single substitution at each of these residues, E31K, E96K, G97D, resulted in mutant GST proteins with loss of CDNB conjugation activity and failure in binding to the S-hexyl GSH affinity matrix. In contrast, a mutant GST (Y8F) resulting from substitution of the conserved tyrosine near the N terminus has much reduced CDNB conjugation activity but was still capable of binding to the S-hexyl GSH-agarose. Additional mutant GSTs with substitutions at position 96 (E96F, E96Y) and 97 (G97P, G97T, G97S) resulted in changes in both Km and kcat to different extents. The in vitro CDNB conjugation activity of the purified mutant enzymes correlate negatively with the plating efficiencies of strains encoding them in the presence of CDNB. Based on the x-ray structure model of human GST 1-1, two of these residues are involved in salt bridges (Arg19-Glu31, Arg68-Glu96) and the third Gly97 is in the middle of the helix alpha 4. Our results provide evidence in vivo that Tyr8, Gly97, and the two salt bridges are important for GST structure-function. This molecular genetic approach for the identification of essential amino acids in GSTs should be applicable to any GSTs with CDNB conjugation activity. It should also complement the x-ray crystallographic approach in understanding the structure and function of GSTs.

The glutathione S-transferase supergene family: regulation of GST and the contribution of the isoenzymes to cancer chemoprotection and drug resistance

The glutathione S-transferases (GST) represent a major group of detoxification enzymes. All eukaryotic species possess multiple cytosolic and membrane-bound GST isoenzymes, each of which displays distinct catalytic as well as noncatalytic binding properties: the cytosolic enzymes are encoded by at least five distantly related gene families (designated class alpha, mu, pi, sigma, and theta GST), whereas the membrane-bound enzymes, microsomal GST and leukotriene C4 synthetase, are encoded by single genes and both have arisen separately from the soluble GST. Evidence suggests that the level of expression of GST is a crucial factor in determining the sensitivity of cells to a broad spectrum of toxic chemicals. In this article the biochemical functions of GST are described to show how individual isoenzymes contribute to resistance to carcinogens, antitumor drugs, environmental pollutants, and products of oxidative stress. A description of the mechanisms of transcriptional and posttranscriptional regulation of GST isoenzymes is provided to allow identification of factors that may modulate resistance to specific noxious chemicals. The most abundant mammalian GST are the class alpha, mu, and pi enzymes and their regulation has been studied in detail. The biological control of these families is complex as they exhibit sex-, age-, tissue-, species-, and tumor-specific patterns of expression. In addition, GST are regulated by a structurally diverse range of xenobiotics and, to date, at least 100 chemicals have been identified that induce GST; a significant number of these chemical inducers occur naturally and, as they are found as nonnutrient components in vegetables and citrus fruits, it is apparent that humans are likely to be exposed regularly to such compounds. Many inducers, but not all, effect transcriptional activation of GST genes through either the antioxidant-responsive element (ARE), the xenobiotic-responsive element (XRE), the GST P enhancer 1(GPE), or the glucocorticoid-responsive element (GRE). Barbiturates may transcriptionally activate GST through a Barbie box element. The involvement of the Ah-receptor, Maf, Nrl, Jun, Fos, and NF-kappa B in GST induction is discussed. Many of the compounds that induce GST are themselves substrates for these enzymes, or are metabolized (by cytochrome P-450 monooxygenases) to compounds that can serve as GST substrates, suggesting that GST induction represents part of an adaptive response mechanism to chemical stress caused by electrophiles. It also appears probable that GST are regulated in vivo by reactive oxygen species (ROS), because not only are some of the most potent inducers capable of generating free radicals by redox-cycling, but H2O2 has been shown to induce GST in plant and mammalian cells: induction of GST by ROS would appear to represent an adaptive response as these enzymes detoxify some of the toxic carbonyl-, peroxide-, and epoxide-containing metabolites produced within the cell by oxidative stress. Class alpha, mu, and pi GST isoenzymes are overexpressed in rat hepatic preneoplastic nodules and the increased levels of these enzymes are believed to contribute to the multidrug-resistant phenotype observed in these lesions. The majority of human tumors and human tumor cell lines express significant amounts of class pi GST. Cell lines selected in vitro for resistance to anticancer drugs frequently overexpress class pi GST, although overexpression of class alpha and mu isoenzymes is also often observed. The mechanisms responsible for overexpression of GST include transcriptional activation, stabilization of either mRNA or protein, and gene amplification. In humans, marked interindividual differences exist in the expression of class alpha, mu, and theta GST. The molecular basis for the variation in class alpha GST is not known. (ABSTRACT TRUNCATED)

Immunological comparison of cytosolic glutathione S-transferases between rat and two strains of houseflies

Five different antisera, which include three antisera raised against rat liver glutathione S-transferases (GST), one antiserum raised against human pi GST, and one antiserum raised against housefly GST1, were used to examine their cross-reactivity with different classes of GST subunits isolated from rat liver and the housefly. Two classes of rat liver GSTs, alpha and mu, were isolated from rat liver and two classes of housefly GSTs, GST1 and GST2, were isolated from both CSMA and Cornell-R strains. Antiserum against GST 3-3 was the most reactive antiserum and reacted not only with the mu class of GSTs but also with the GST1 class from both CSMA and Cornell-R strains. Antiserum against human pi GST and antiserum against housefly GST1 had weak immunological reactivity toward the GST1 class from both strains of housefly. Antiserum against GST 4-4 and antiserum against GST 1-1 had no immunological reactivity toward any class of GSTs from housefly. None of the five antisera had any immunological cross-reactivity toward subunit 2 of the alpha class of rat GST and the GST2 class of housefly GSTs from both strains.

Starvation-induced expression of SspA and SspB: the effects of a null mutation in sspA on Escherichia coli protein synthesis and survival during growth and prolonged starvation

Maxicell labelling and two-dimensional gel electrophoresis (2-D PAGE) have identified the proteins encoded by sspA and sspB (SspA, SspB) as proteins D27.1 and A25.8, respectively, in the Escherichia coli gene-protein database. SspA expression increases with decreasing growth rate and is induced by glucose, nitrogen, phosphate or amino acid starvation. The promoter, Pssp, is similar to gearbox promoters. Inactivation of SspA (sspA::neo) blocks sspB expression. [35S]-methionine-labelled proteins synthesized during growth and during stationary phase are different in delta sspA strains compared to sspA+ strains. This difference is enhanced during extended stationary phase (24-72 h). Long-term (10 d) viability of arginine-starved isogenic strains shows that sspA+ cultures remain viable significantly longer than delta sspA mutants. 2-D PAGE of proteins expressed during exponential growth shows that expression of at least 11 proteins is altered in delta sspA strains. A functional relA gene is required for sspA to affect protein synthesis.

Vitamin E, ascorbate, glutathione, glutathione disulfide, and enzymes of glutathione metabolism in cultures of chick astrocytes and neurons: evidence that astrocytes play an important role in antioxidative processes in the brain

GSH, GSSG, vitamin E, and ascorbate were measured in 14-day cultures of chick astrocytes and neurons and compared with levels in the forebrains of chick embryos of comparable age. Activities of enzymes involved in GSH metabolism were also measured. These included gamma-glutamylcysteine synthetase, GSH synthetase, gamma-glutamyl cyclotransferase, gamma-glutamyltranspeptidase, glutathione transferase (GST), GSH peroxidase, and GSSG reductase. The concentration of lipid-soluble vitamin E in the cultured neurons was found to be comparable with that in the forebrain. On the other hand, the concentration of vitamin E in the astrocytes was significantly greater in the cultured astrocytes than in the neurons, suggesting that the astrocytes are able to accumulate exogenous vitamin E more extensively than neurons. The concentrations of major fatty acids were higher in the cell membranes of cultured neurons than those in the astrocytes. Ascorbate was not detected in cultured cells although the chick forebrains contained appreciable levels of this antioxidant. GSH, total glutathione (i.e., GSH and GSSG), and GST activity were much higher in cultured astrocytes than in neurons. gamma-Glutamylcysteine synthetase activity was higher in the cultured astrocytes than in the cultured neurons. GSH reductase and GSH peroxidase activities were roughly comparable in cultured astrocytes and neurons. The high levels of GSH and GST in cultured astrocytes appears to reflect the situation in vivo. The data suggest that astrocytes are resistant to reactive oxygen species (and potentially toxic xenobiotics) and may play a protective role in the brain.(ABSTRACT TRUNCATED AT 250 WORDS)

Site-directed mutagenesis and chemical modification of histidine residues on an alpha-class chick liver glutathione S-transferase CL 3-3. Histidines are not needed for the activity of the enzyme and diethylpyrocarbonate modifies both histidine and lysine residues

Each chick liver glutathione S-transferase CL 3 subunit contains three histidine residues: His142, His158 and His228. CL 3-3 can be inactivated by treating with diethylpyrocarbonate. The inactivation process is pH dependent and the pKa of the modified residue is 6.4. The second-order inhibition rate constant is 741 M-1min-1 at pH 7.0. Based on difference-spectrum and kinetic analysis, inactivation coincides with the modification of one histidine residue. However, hydroxylamine treatment of the diethylpyrocarbonate-modified enzyme only partially restored the activity (30-50%) of CL 3-3. By tryptic mapping and amino acid sequence analysis, His228 and Lys14 have been identified as the modified residues. Mutants with histidine to serine replacement (H142S and H158S) or C-terminal histidine deletion (des-H228) were constructed and over-expressed in Spodoptera frugiperda cells using a baculovirus system. The mutants are enzymically active. Furthermore, the des-H228 mutant can be inactivated by diethylpyrocarbonate. These results support the conclusion that histidines are not involved in the enzymic mechanism of CL 3-3.

Glutathione S-transferases: gene structure and regulation of expression

The current knowledge about the structure of GST genes and the molecular mechanisms involved in regulation of their expression are reviewed. Information derived from the study of rat and mouse GST Alpha-class, Ya genes, and a rat GST Pi-class gene seems to indicate that a single cis-regulatory element, composed of two adjacent AP-1-like binding sites in the 5'-flanking region of these GST genes, is responsible for their basal and xenobiotic-inducible activity. The identification of Fos/Jun (AP-1) complex as the trans-acting factor that binds to this element and mediates the basal and inducible expression of GST genes offers a basis for an understanding of the molecular processes involved in GST regulation. The induction of expression of Fos and Jun transcriptional regulatory proteins by a variety of extracellular stimuli is known to mediate the activation of target genes via the AP-1 binding sites. The modulation of the AP-1 activity may account for the changes induced by growth factors, hormones, chemical carcinogens, transforming oncogenes, and cellular stress-inducing agents in the pattern of GST expression. Recent observations implying reactive oxygen as the transduction signal that mediates activation of c-fos and c-jun genes are presently considered to provide an explanation for the induction of GST gene expression by chemical agents of diverse structure. The possibility that these agents may all induce conditions of oxidative stress by various pathways to activate expression of GST genes that are regulated by the AP-1 complex is discussed.

Effects of altered calcium homeostasis on the expression of glutathione S-transferase isozymes in primary cultured rat hepatocytes

The effects of altered Ca2+ homeostasis on glutathione S-transferase (GST) isozyme expression in cultured primary rat hepatocytes were examined. Isolated hepatocytes were cultured on Vitrogen substratum in serum-free modified Chee's essential medium and treated with Ca2+ ionophore A23187 at 120 hr post-plating. GST activity increased slightly, albeit significantly, in a concentration-dependent manner in A23187-treated hepatocytes relative to untreated controls. Western blot analysis using GST class alpha and mu specific antibodies showed an approximately 1.6- and 1.5-fold increase in the class alpha, Ya and Yc subunits, respectively, whereas no significant increase (approximately 1.2-fold) in class mu GST expression was observed following A23187 treatment. Northern blot analysis revealed an approximately 5-fold increase in GST class alpha and an approximately 7-fold increase in class mu GST mRNA levels in ionophore-treated hepatocytes compared to untreated cells. Results of the Western and Northern blot analyses of the ionophore-treated hepatocytes were compared with those obtained for tert-butyl hydroperoxide-treated cells. Immunoblot analysis showed a significant increase in the expression of GST class alpha, Ya and Yc subunits, approximately 1.8- and 1.7-fold, respectively, for tert-butyl hydroperoxide-treated hepatocytes as compared to controls, with little or no increase in class mu GSTs. Northern blot analysis showed approximately 3- and 2-fold increases, respectively, in class alpha and mu GST mRNA levels, following the tert-butyl hydroperoxide treatment. The results of the present investigation show that alterations in Ca2+ homeostasis produced by either Ca2+ ionophore A23187 or tert-butyl hydroperoxide treatment of hepatocytes enhanced the expression of GST isozymes in primary cultured rat hepatocytes.

Mutational substitution of residues implicated by crystal structure in binding the substrate glutathione to human glutathione S-transferase pi

Site-directed substitution mutations were introduced into a cDNA expression vector (pUC120 pi) that encoded a human glutathione S-transferase pi isozyme to non-conservatively replace four residues (Tyr7, Arg13, Gln62 and Asp96). Our earlier X-ray crystallographic analysis implicated these residues in binding and/or chemically activating the substrate glutathione. Each substitution mutation decreased the specific activity of the enzyme to less than 2% of the wild-type. Glutathione-binding was also reduced; however, the Tyr7----Phe mutant still retained 27% of the wild-type capacity to bind glutathione, underlining the primary role that this residue is likely to play in chemically activating the glutathione molecule during catalysis.

Drosophila glutathione S-transferases have sequence homology to the stringent starvation protein of Escherichia coli

The Drosophila glutathione S-transferase D genes encode a family of isozymes. We have determined the amino acid sequence of a new member of this family by nucleotide sequence analysis of a genomic DNA clone. The open reading frame of this intronless gene should encode an isozyme subunit of 211 amino acids. This sequence has significant homology to the E. coli stringent starvation protein, SSP, which is also a protein of two identical 211 amino acid subunits. The two proteins have very similar overall amino acid composition as well. It is possible that SSP may be a glutathione S-transferase(s) in E. coli or is evolutionarily related to glutathione S-transferases. Because SSP is known to be tightly associated with the RNA polymerase holoenzyme during purification, it is conceivable that Drosophila glutathione S-transferase(s) may potentially interact with the transcription machinery in a fashion similar to SSP's interaction with E. coli RNA polymerase holoenzyme.

Glutathione transferases and cancer

The glutathione transferases, a family of multifunctional proteins, catalyze the glutathione conjugation reaction with electrophilic compounds biotransformed from xenobiotics, including carcinogens. In preneoplastic cells as well as neoplastic cells, specific molecular forms of glutathione transferase are known to be expressed and have been known to participate in the mechanisms of their resistance to drugs. In this article, following a brief description of recently identified molecular forms, we review new findings regarding the respective molecular forms involved in carcinogenesis and anticancer drug resistance, with particular emphasis on Pi class forms in preneoplastic tissues. The rat Pi class form, GST-P (GST 7-7), is strongly expressed not only in hepatic foci and hepatomas, but also in initiated cells that occur at the very early stages of chemical hepatocarcinogenesis, and is regarded as one of the most reliable markers for preneoplastic lesions in the rat liver. 12-O-Tetradecanoylphorbol-13-acetate (TPA)-responsive element-like sequences have been identified in upstream regions of the GST-P gene, and oncogene products c-jun and c-fos are suggested to activate the gene. The Pi-class forms possess unique enzymatic properties, including broad substrate specificity, glutathione peroxidase activity toward lipid hydroperoxides, low sensitivity to organic anion inhibitors, and high sensitivity to active oxygen species. The possible functions of Pi class glutathione transferases in neoplastic tissues and drug-resistant cells are discussed.

Characterization of cytoplasmic T3 binding sites by adsorption to hydroxyapatite: effects of drug inhibitors of T3 and relationship to glutathione-S-transferases

To facilitate studies of thyroid hormone (T3) binding to cytoplasmic proteins, we prepared monkey (M. fascicularis) liver cytosol (100,000g supernatant) and examined T3 binding using hydroxyapatite (HAP) separation. HAP adsorbs cytoplasmic and nuclear binding sites but not serum T4 binding proteins. Cytosol was incubated with [125I]T3 for 30 min at 4 degrees C and separated by adding an equal volume of HAP (15 g/100 mL). After a further incubation of 10 min, the HAP pellet was washed three times in buffer containing Triton X-100, 0.5%. With this method, a single class of T3 binding site was observed with Kd 15.8 +/- 1.2 nM, concentration 0.62 +/- 0.17 pmol/mg protein (n = 3, mean +/- SD). We used this assay to assess potential drug inhibitors of cytoplasmic binding and to evaluate the proposal that glutathione-S-transferases (GST) and cytoplasmic T3 binding proteins are identical. Displacement of [125I]T3 by unlabeled iodothyronines relative to T3 (100) was T4 58, Triac 7, rT3 7, Tetrac less than or equal to 1. This hierarchy indicates that this binding site is distinct from nuclear or serum binding sites. T3 binding was displaceable by nonsteroidal anti-inflammatory drugs (NSAID) and nonbile acid cholephils (NBAC). Half-inhibitory concentrations (microM, mean +/- SD, n greater than or equal to 3) were diclofenac 4.9 +/- 1.3, mefenamic acid 13.6 +/- 0.6, bromosulphthalein 45 +/- 3, iopanoic acid approximately 200. Amiodarone and furosemide were inactive up to 100 microM. No displacement was observed with cortisol or the bile acid taurocholate, up to 100 microM. Dithiothreitol, 5 mM, did not change binding affinity or capacity.(ABSTRACT TRUNCATED AT 250 WORDS)

Nucleotide sequence of a class mu glutathione S-transferase from chicken liver

A clone coding for glutathione S-transferase (GST) CL2 was isolated from a chicken liver cDNA library. This clone (819 bp) encodes a polypeptide comprising 219 amino acids with a molecular weight of 25,717, excluding the initiator methionine. The primary amino acid sequence of the enzyme has 47% identical sequence with other class mu GSTs.

The human Hb (mu) class glutathione S-transferases are encoded by a dispersed gene family

The human glutathione S-transferases are products of a gene superfamily which consists of at least four gene families. The various glutathione S-transferase genes are located on different human chromosomes, and new gene(s) are still being added to the gene superfamily. We have characterized a cDNA in pGTH4 encoding human glutathione S-transferase subunit 4 (GST mu) and mapped its gene (or a homologous family member) on chromosome 1 at p31 by in situ hybridization. Genomic Southern analysis with the 3' noncoding region of the cDNA revealed at least four human DNA fragments with highly homologous sequences. Using a panel of DNAs from mouse-human somatic cell hybrids in genomic DNA hybridization we show that the Hb (or B) genes of human glutathione S-transferases are on three separate chromosomes: 1, 6, and 13. Therefore, the glutathione S-transferase B gene family, which encodes the Hb (mu) class subunits, is a dispersed gene family. The GST mu (psi) gene, whose expression is polymorphic in the human population, is probably located on chromosome 13. We propose that the GST mu (psi) gene was created by a transposition or recombination event during evolution. The null phenotype may have resulted from a lack of DNA transposition just as much as from the deletion of an inserted gene.

The Drosophila glutathione S-transferase 1-1 is encoded by an intronless gene at 87B

The Drosophila glutathione S-transferase 1-1 is a dimer of a 209 amino acid subunit, designated DmGST1. DmGST1 is encoded by a member of a multigene family. Sequence analysis of a genomic clone for GST1 revealed that it is encoded by an intronless gene. We designate this gene and its other family members the GST D genes in the glutathione S-transferase gene superfamily. The Drosophila GST D genes are mapped by in situ hybridization to chromosome 3R at 87B of the polytene chromosome, which is flanked by the two clusters of hsp70 genes at 87A7 and 87C1. Cytogenetic data in the literature indicated that a puff occurred in this region under heat shock. We report that the glutathione S-transferase activity in Kco cells as determined by conjugation with 1-chloro-2,4-dinitrobenzene is elevated slightly to two-fold under heat shock. The implication of this finding is discussed.

Identification of rat liver glutathione S-transferase Yb subunits by partial N-terminal sequencing after electroblotting of proteins onto a polyvinylidene difluoride membrane from an analytical isoelectric focusing gel

Rat liver glutathione S-transferases were partially purified using S-hexyl glutathione affinity chromatography, followed by native isoelectric focusing employing a pH 7-11 or pH 3-10 gradient. Proteins were excised and eluted from the gel for determination of subunit composition using sodium dodecyl sulfate-polyacrylamide gel electrophoresis. In separate experiments, isoelectric focusing gels were equilibrated with a sodium dodecyl sulfate-containing buffer at high pH, and proteins on the gel were electroblotted onto a polyvinylidene difluoride membrane, utilizing graphite plates as electrodes. The membrane-bound proteins were visualized by Coomassie Brilliant Blue staining. The protein bands were then excised from the membrane and inserted into a gas phase sequenator for direct sequencing. N-Terminal sequences thus determined were compared with published cDNA sequences. The isoelectric points (pIs) and positions on the isoelectric focusing gel of Yb1Yb1, Yb1Yb2 and Yb2Yb2 subunits were determined. We have also located on the pH 3-10 focusing gel an N-terminal blocked glutathione S-transferase which has a molecular weight similar to Yb subunits.

Expression in Escherichia coli of rat liver cytosolic glutathione S-transferase Yc cDNA

An expression plasmid, pKK-GTB2, containing the complete coding sequence of a rat liver glutathione S-transferase Yc subunit was constructed and expressed in Escherichia coli. The entire Yc cDNA sequence from plasmid pGTB42 (Telakowski-Hopskins et al., 1985, J. Biol. Chem. 260, 5820-5825) was amplified by the polymerase chain reaction, subcloned into modified expression vector A6316 (Schoner et al., 1986, Proc. Natl. Acad. Sci. USA 83, 8506-8510 and Linemeyer et al., 1987, Bio/Technology 5, 960-965) and transformed into E. coli strain AB1899. The colonies were screened by hybridization to pGTB42 and the production of Yc subunit was detected by immunoblot analysis. The purified recombinant Yc subunit was active in the conjugation and peroxidation reactions, and appeared homogeneous as judged by sodium dodecyl sulfate gel electrophoresis. Amino acid sequencing of the expressed Yc subunit revealed that about 40% of the expressed protein was blocked at the N-terminus. Approximately 25% of the sequenceable protein (15% of total protein) contained the initiation methionine residue at the amino terminus whereas the rest of the sequenceable protein had proline as the N-terminus. In contrast, only one molecular species with Pro as the first amino acid was identified when the inducer isopropyl-beta-D-thiogalactopyranoside was omitted in the growth medium. Our observation indicated that under certain growth conditions, the enzymes responsible for protein maturation were not able to complete the processing of the overproduced recombinant Yc in E. coli.

Construction, expression, and preliminary characterization of chimeric class mu glutathione S-transferases with altered catalytic properties

An expression plasmid for isoenzyme 3-3 of rat liver glutathione S-transferase has been constructed from the cDNA clone pGTA/C44 and the pAS expression vector pMG27NS, and used for the efficient production of the enzyme in the Escherichia coli strain M5219. The plasmid has also been manipulated, through the use of synthetic linkers, to encode chimeric polypeptides in which short sequences of the closely related isoenzyme 4-4 have been substituted into the N-terminal and C-terminal variable domains of isoenzyme 3-3. The chimeric polypeptides designated 4(9)3(208), 3(209)4(8), and 4(9)3(200)4(8) are expressed with varying degrees of efficiency in E. coli. The active dimeric holoenzymes 3-3, (4(9)3(208]2, (3(209)4(8]2, and (4(9)3(200)4(8]2 can be isolated. The spectroscopic and kinetic properties of the chimeric enzymes are significantly different than the native enzyme.

Characterization of a variant rat glutathione S-transferase by cDNA expression in Escherichia coli

We have isolated a glutathione S-transferase Yb1 subunit cDNA from a lambda gt11 cDNA collection constructed from rat testis poly(A) RNA enriched for glutathione S-transferase mRNA activities. This Yb1 cDNA, designated pGTR201, is identical to our liver Yb1 cDNA clone pGTR200 except for a shorter 5'-untranslated sequence. Active glutathione S-transferase is expressed from this Yb1 cDNA driven by the tac promoter on the plasmid construct pGTR201-KK. The expressed glutathione S-transferase protein begins with the third codon (Met) of the cDNA, and is missing the N-terminal proline of rat liver glutathione S-transferase 3-3. Therefore, our Escherichia coli expressed glutathione S-transferase protein represents a variant form of glutathione S-transferase 3-3 (Yb1Yb1), designated GST 3-3(-1). The expressed Yb1 subunits are assembled into a dimer as purified from sonicated E. coli crude extracts. In the absence of dithiothreitol three active isomers can be resolved by ion-exchange chromatography. The pure protein has an extinction coefficient of 9.21 x 10(4) M-1 cm-1 at 280 nm or E0.1% 280 = 1.78 and a pI at 8.65. It has a substrate specificity pattern similar to that of the authentic glutathione S-transferase 3-3. The GST 3-3(-1) has a KM of 202 microM for reduced GSH and of 36 microM for 1-chloro-2,4-dinitrobenzene. The turnover number for this conjugation reaction is 57 s-1. Results of kinetic studies of this reaction with GST 3-3(-1) are consistent with a sequential substrate binding mechanism. We conclude that the first amino acid proline of glutathione S-transferase 3-3 is not essential for enzyme activities.

Glutathione-S-transferases are major cytosolic thyroid hormone binding proteins

Thyroid hormone binding proteins of rat liver cytosol were characterized. Glutathione-S-transferases were identified among major cytosolic proteins adsorbed by thyroxine affinity matrices. The Ya and Yb subunits of the glutathione-S-transferases were also principal proteins of cytosol covalently labeled with 3,3',5-triiodo-L-thyronine (T3) or 3,3',5,5'-tetraiodo-L-thyronine (T4) by photoaffinity methods. T3 and T4, but not L-thyronine or iodinated tyrosines, were bound with high affinity to purified glutathione-S-transferases and were potent inhibitors of their enzymatic activities. These results suggest that glutathione-S-transferases have the potential to function in the intracellular binding and transport of thyroid hormones. The proteins provide a means for regulating the action and metabolism of thyroid hormones by acting as high capacity binding components.

Expression of Yb1 glutathione S-transferase using a baculovirus expression system

A full-length cDNA clone was isolated for rat liver Yb1 glutathione S-transferase (EC 2.5.1.18). The coding sequence of Yb1 cDNA was inserted into a baculovirus vector for infection of Spodoptera frugiperda (SF9) cells. The enzymatically active recombinant Yb1 glutathione S-transferase protein has a native molecular weight of 42,000 daltons (by molecular sieve chromatography), a subunit molecular weight of 26,500 daltons (by SDS-polyacrylamide gel electrophoresis), a pI of 8.4 and an extinction coefficient E1%280 of 5.6 +/- 0.4.

Expression of a cDNA encoding a rat liver glutathione S-transferase Ya subunit in Escherichia coli

A full length cDNA clone, pGTB38 (C. B. Pickett et al. (1984) J. Biol. Chem. 259, 5182-5188), complementary to a rat liver glutathione S-transferase Ya mRNA has been expressed in Escherichia coli. The cDNA insert was isolated from pGTB38 using MaeI endonuclease digestion and was inserted into the expression vector pKK2.7 under the control of the tac promoter. Upon transformation of the expression vector into E. coli, two protein bands with molecular weights lower than the full-length Ya subunit were detected by Western blot analysis in the cell lysate of E. coli. These lower-molecular-weight proteins most likely result from incorrect initiation of translation at internal AUG codons instead of the first AUG codon of the mRNA. In order to eliminate the problem of incorrect initiation, the glutathione S-transferase Ya cDNA was isolated from the expression vector and digested with Bal31 to remove extra nucleotides from the 5' noncoding region. The protein expressed by this expression plasmid, pKK-GTB34, comigrated with the Ya subunit on sodium dodecyl sulfate polyacrylamide gels and was recognized by antibodies against the YaYc heterodimer. The expressed Ya homodimer was purified by S-hexylglutathione affinity and ion-exchange chromatographies. Approximately 50 mg pure protein was obtained from 9 liters of E. coli culture. The expressed Ya homodimer displayed glutathione-conjugating, peroxidase, and isomerase activities, which are identical to those of the native enzyme purified from rat liver cytosol. Protein sequencing indicates that the expressed protein has a serine as the NH2 terminus whereas the NH2 terminus of the glutathione S-transferase Ya homodimer purified from rat liver cytosol is apparently blocked.

The glutathione S-transferases: an update

Over the last 15 years, we have passed through an initial period in which multiple forms of GST in various organs and different species were identified and characterized. The focus of current research is to define the role of the numerous isozymes in cell function, to ascertain the relationship between structure and function of different isozymes and to determine how the expression of GST is regulated in different tissues. During these studies, it is expected that new roles for the GST will be proposed, and this family of multifunctional proteins will continue to hold the interest of numerous investigators for many years.

Differential regulation of glutathione S-transferases in cultured hepatocytes

Specific cDNA probes were used to determine steady-state mRNA levels for the multiple glutathione S-transferases in primary hepatocyte cultures. In the first 24 hr of culture, gene transcripts for the Ya family decreased sharply, Yb3 disappeared completely, but changes in levels of mRNA for Yb1 and Yb2 were smaller. These results suggest that the isoenzymes are regulated independently. Yp mRNA, which is present at greatly elevated levels in hyperplastic nodules and hepatocellular carcinomas but not in normal adult livers, was hardly detectable in freshly isolated hepatocytes, but Yp transcripts rapidly accumulated in the first 24 hr in culture and continued to increase for 72 hr. Decreased levels in Ya and Yc and increases in Yp were detected by immunoblotting methods, indicating that translation products changed together with mRNA levels in the cultured cells. The appearance of Yp transcripts in hepatocytes was effectively blocked by addition of dexamethasone to the culture medium. Elevations of Yp levels are characteristic of the cell culture system and factors regulating Yp transcription in nodules and carcinomas may also be operative in cultured hepatocytes.

Purification and partial characterization of the glutathione S-transferase of rat erythrocytes

The single glutathione S-transferase (EC 2.5.1.18) present in rat erythrocytes was purified to apparent homogeneity by affinity chromatography on glutathione-Sepharose and hydroxyapatite chromatography. Approx. 1.86 mg enzyme is found in 100 ml packed erythrocytes and accounts for about 0.01% of total soluble protein. The native enzyme (Mr 48,000) displays a pI of 5.9 and appears to possess a homodimeric structure with a subunit of Mr 23,500. Enzyme activities with ethacrynic acid and cumene hydroperoxide were 24 and 3%, respectively, of that with 1-chloro-2,4-dinitrobenzene. The Km values for 1-chloro-2,4-dinitrobenzene and glutathione were 1.0 and 0.142 mM, respectively. The concentrations of certain compounds required to produce 50% inhibition (I50) were as follows: 12 microM bromosulphophthalein, 34 microM S-hexylglutathione, 339 microM oxidized glutathione and 1.5 mM cholate. Bromosulphophthalein was a noncompetitive inhibitor with respect to 1-chloro-2,4-dinitrobenzene (Ki = 8 microM) and glutathione (Kis = 4 microM; Kii = 11.5 microM) while S-hexylglutathione was competitive with glutathione (Ki = 5 microM).

Purification and biochemical characterization of the rabbit pulmonary glutathione S-transferase: stereoselectivity and activity toward pyrene 4,5-oxide

Two homodimeric isozymes, glutathione S-transferase (GST) 25 kDa and GST 27 kDa, in equal proportion comprise the majority (greater than 75%) of the pulmonary cytosolic GST of untreated rabbits. The subunits of GST 25 kDa and GST 27 kDa are distinguishable by electrophoretic mobility (25 and 27 kDa, respectively), apparent isoelectric points (pI 7.4 and pI 9.1, respectively), and immunoreactivity. Immunoblots indicated that these subunits may be minor components in hepatic cytosol. The pulmonary isozymes could not be distinguished by their activities toward chloro-2,4-dinitrobenzene (CDNB) or activity and stereoselectivity toward pyrene 4,5-oxide (PyO). The purified GST fractions represented less than or equal to 16% of the PyO activity for pulmonary cytosol. The stereoselectivity of the cytosolic GST for the pro-S-configured oxirane carbon of PyO was not maintained in the purified preparations which were virtually nonstereoselective. Immunoprecipitation of pulmonary cytosolic GST with anti-GST 27 kDa and anti-GST 25 kDa indicated that at least 84 and 60% of the activity toward CDNB and PyO, respectively, is mediated by the two isozymes. The specific PyO activities of GST 27 kDa, GST 25 kDa, and the rabbit hepatic preparations (approximately 0.2 unit/mg) were similar to that of hepatic GST purified from horse, cow, and pig, and to human placental GST pi (0.02-0.5 unit/mg) but one-tenth that of rat hepatic GST or human hepatic GST mu. However, the activity of the hepatic cytosol from rat and human was similar to that of rabbit. Thus, some GST isozymes may be particularly susceptible to modulation of activity/stereoselectivity that can be discerned with arene oxide substrates such as PyO.

Developmental regulation of glutathione S-transferases

1. cDNA probes for individual isoenzymes of rat glutathione S-transferases were used to determine steady state levels of their mRNAs in liver and brain during development. 2. Foetal livers were enriched in Yp transcripts (that are characteristic of hyperplastic nodules and hepatocellular carcinomas), but these forms decreased after the first week of postnatal development and were not detected in adult livers. In contrast, in adult brains Yp levels increased. 3. Ya forms that were present at low levels in foetal and neonatal livers, increased markedly during development. Ya was not detected in brain. 4. The Yb1 and Yb2 GSTs were present in higher amounts than Ya in foetal livers, and these isoenzymes also increased in adults.

Inhibition of human glutathione S-transferases by bile acids

Glutathione S-transferase (GST) isoenzymes isolated from various human tissues are differentially inhibited by bile acids. Trihydroxy bile acid (lithocholate) was found to be more inhibitory to all the human GST isoenzymes tested in this study, as compared to the monohydroxy (cholate) and dihydroxy (chenodeoxycholate) bile acids. Among the three major classes of GST, mu class isoenzymes are generally inhibited to a greater extent than the alpha and pi class isoenzymes. The results of this study also indicate that differential inhibition of GST by various bile acids may be used to distinguish closely related GST isoenzymes within the mu class of GST isoenzyme. Likewise, the pi class or the anionic isoenzymes of human kidney, placenta, and erythrocytes can be distinguished using bile acid inhibition studies. These studies also provide further support for tissue-specific expression of GST isoenzymes in humans.

Regulation of glutathione S-transferases of Zea mays in plants and cell cultures

An antiserum to glutathione S-transferase (EC 2.5.1.18) from maize (Zea mays L.) responsible for herbicide detoxification has been raised in rabbit. The antiserum was specific to the Mr 26000 subunit of the enzyme from maize seedlings and suspension-cultured cells, and recognized the isoenzymes active toward both atrazine and metolachlor. When plants were treated for 24 h with the herbicide antidote N,N-diallyl-2-2-dich-loroacetamide (DDCA), enzyme activities toward metolachlor were doubled in the roots and this was associated with a 70% increase in immunodetectable protein. Translation of polysomal RNA in vitro showed that the increase in the transferase in root tissue was brought about by a ninefold increase in mRNA activity encoding the enzyme. Treatment of suspension-cultured cells with cinnamic acid, metolachlor and DDCA raised enzyme activities but did not increase synthesis of glutathione S-transferase. In cultured maize cells, enzyme synthesis was maximal in mid-logarithmic phase, coinciding with the highest levels of enzyme activity. When callus cultures were established from the shoots of a maize line known to conjugate chloro-s-triazines, enzyme activity towards atrazine was lost during primary dedifferentiation. However, levels of total immunodetectable enzyme and activity toward metolachlor were increased in cultured cells compared with the parent shoot tissue.

Electroblotting onto glass-fiber filter from an analytical isoelectrofocusing gel: a preparative method for isolating proteins for N-terminal microsequencing

A new method has been developed for the isolation of proteins for microsequencing. Proteins were separated by isoelectric focusing on polyacrylamide slab gels. Ampholytes in the gel were washed out with 3.5% (v/v) perchloric acid, and the proteins were electroblotted onto unmodified glass-fiber sheets. The immobilized proteins on the glass-fiber sheet were detected with Coomassie blue dye staining. The protein bands were then excised from the sheet and inserted into a gas phase sequenator for direct sequencing. They could also be extracted with sodium dodecyl sulfate buffer for molecular weight determination. Bovine serum albumin, beta-lactoglobulin A, and soybean trypsin inhibitor have been used as standard proteins for the test of this technique. Using this technique, we have determined the partial N-terminal sequence (26 residues) of an acidic (pI 5.6) glutathione S-transferase isolated from the chicken liver.