Inhibition of microsomal lipid peroxidation by glutathione and glutathione transferases B and AA. Role of endogenous phospholipase A2.

Lipid peroxidation in vitro in rat liver microsomes (microsomal fractions) initiated by ADP-Fe3+ and NADPH was inhibited by the rat liver soluble supernatant fraction. When this fraction was subjected to frontal-elution chromatography, most, if not all, of its inhibitory activity could be accounted for by the combined effects of two fractions, one containing Se-dependent glutathione (GSH) peroxidase activity and the other the GSH transferases. In the latter fraction, GSH transferases B and AA, but not GSH transferases A and C, possessed inhibitory activity. GSH transferase B replaced the soluble supernatant fraction as an effective inhibitor of lipid peroxidation in vitro. If the microsomes were pretreated with the phospholipase A2 inhibitor p-bromophenacyl bromide, neither the soluble supernatant fraction nor GSH transferase B inhibited lipid peroxidation in vitro. Similarly, if all microsomal enzymes were heat-inactivated and lipid peroxidation was initiated with FeCl3/sodium ascorbate neither the soluble supernatant fraction nor GSH transferase B caused inhibition, but in both cases inhibition could be restored by the addition of porcine pancreatic phospholipase A2 to the incubation. It is concluded that the inhibition of microsomal lipid peroxidation in vitro requires the consecutive action of phospholipase A2, which releases fatty acyl hydroperoxides from peroxidized phospholipids, and GSH peroxidases, which reduce them. The GSH peroxidases involved are the Se-dependent GSH peroxidase and the Se-independent GSH peroxidases GSH transferases B and AA.     

The amount and nature of glutathione transferases in rat liver microsomes determined by immunochemical methods

The amount and nature of glutathione transferases in rat liver microsomes were determined using immunological techniques. It was shown that cytosolic glutathione transferase subunits A plus C, and B plus L were present at levels of 2.4 ± 0.6 and 1.5 ± 0.1 μg/mg microsomal protein, respectively. These levels are 10-times higher than those for non-specific binding of cytosolic components judging from the distribution of lactate dehydrogenase, a cytosolic marker. The possibility that a portion of these glutathione transferases is functionally localized on the endoplasmic reticulum is discussed. A previously described microsomal glutathione transferase which is distinct from the cytosolic enzymes is present in an amount of 31 ± 6 μg/mg microsomal protein.     

Studies on membrane proteins involved in ribosome binding on the rough endoplasmic reticulum. Ribophorins have no ribosome-binding activity.

A membrane protein fraction showing affinity for ribosomes was isolated from rat liver microsomes (microsomal fractions) in association with ribosomes by treatment of the microsomes with Emulgen 913 and then solubilized from the ribosomes with sodium deoxycholate. This protein fraction was separated into two fractions, glycoproteins, including ribophorins I and II, and non-glycoproteins, virtually free from ribophorins I and II, on concanavalin A-Sepharose columns. The two fractions were each reconstituted into liposomes to determine their ribosome-binding activities. The specific binding activity of the non-glycoprotein fraction was approx. 2.3-fold higher than that of the glycoprotein fraction. The recovery of ribosome-binding capacity of the two fractions was about 85% of the total binding capacity of the material applied to a concanavalin A-Sepharose column, and about 90% of it was found in the non-glycoprotein fraction. The affinity constants of the ribosomes for the reconstituted liposomes were somewhat higher than those for stripped rough microsomes. The mode of ribosome binding to the reconstituted liposomes was very similar to that to the stripped rough microsomes, in its sensitivity to proteolytic enzymes and its strong inhibition by increasing KCl concentration. These results support the idea that ribosome binding to rat liver microsomes is not directly mediated by ribophorins I and II, but that another unidentified membrane protein(s) plays a role in ribosome binding.     

Reconstitution of liver monooxygenase system in solution from cytochrome P-450 and NADPH-specific flavoprotein monomers

Microsomal monooxygenase system was reconstituted in the presence of non-ionic detergent Emulgen 913 from cytochrome P-450 and NADPH-specific flavoprotein isolated from phenobarbital-induced rabbit liver microsomes. At Emulgen 913 concentration of 0.05 g/l mixed complex between flavoprotein and cytochrome was formed with 5: 5 protein molar ratio and molecular weight of 700 kD. The 2-hour incubation of the enzymes with 0.25 g/l Emulgen 913 at 4 degrees C was accompanied by dissociation of protein oligomers to monomers. The reconstituted systems containing flavoprotein and cytochrome as mixed complexes or monomers were able to catalyze NADPH-dependent cytochrome P-450 reduction and benzphetamine N-demethylation. Taking into consideration the effective concentrations of the enzymes the apparent second order rate constants of these reactions with monomers were 100 times those with complexes.     

Ribosome-inactivating proteins from the seeds of Saponaria officinalis L. (soapwort), of Agrostemma githago L. (corn cockle) and of Asparagus officinalis L. (asparagus), and from the latex of Hura crepitans L. (sandbox tree).

A hitherto unknown cytosolic glutathione S-transferase from rat liver was discovered and a method developed for its purification to apparent homogeneity. This enzyme had several properties that distinguished it from other glutathione S-transferases, and it was named glutathione S-transferase X. The purification procedure involved DEAE-cellulose chromatography, (NH4)2SO4 precipitation, affinity chromatography on Sepharose 4B to which glutathione was coupled and CM-cellulose chromatography, and allowed the isolation of glutathione S-transferases X, A, B and C in relatively large quantities suitable for the investigation of the toxicological role of these enzymes. Like glutathione S-transferase M, but unlike glutathione S-transferases AA, A, B, C, D and E, glutathione S-transferase X was retained on DEAE-cellulose. The end product, which was purified from rat liver 20 000 g supernatant about 50-fold, as determined with 1-chloro-2,4-dinitrobenzene as substrate and about 90-fold with the 1,2-dichloro-4-nitrobenzene as substrate, was judged to be homogeneous by several criteria, including sodium dodecyl sulphate/polyacrylamide-gel electrophoresis, isoelectric focusing and immunoelectrophoresis. Results from sodium dodecyl sulphate/polyacrylamide-gel electrophoresis and gel filtration indicated that transferase X was a dimer with Mr about 45 000 composed of subunits with Mr 23 500. The isoelectric point of glutathione S-transferase X was 6.9, which is different from those of most of the other glutathione S-transferases (AA, A, B and C). The amino acid composition of transferase X was similar to that of transferase C. Immunoelectrophoresis of glutathione S-transferases A, C and X and precipitation of various combinations of these antigens by antisera raised against glutathione S-transferase X or C revealed that the glutathione S-transferases A, C and X have different electrophoretic mobilities, and indicated that transferase X is immunologically similar to transferase C, less similar to transferase A and not cross-reactive to transferases B and E. In contrast with transferases B and AA, glutathione S-transferase X did not bind cholic acid, which, together with the determination of the Mr, shows that it does not possess subunits Ya or Yc. Glutathione S-transferase X did not catalyse the reaction of menaphthyl sulphate with glutathione, and was in this respect dissimilar to glutathione S-transferase M; however, it conjugated 1,2-dichloro-4-nitrobenzene very rapidly, in contrast with transferases AA, B, D and E, which were nearly inactive towards that substrate.(ABSTRACT TRUNCATED AT 400 WORDS)     

Functional and structural membrane topology of rat liver microsomal glutathione transferase

The membrane topology of rat liver microsomal glutathione transferase was investigated by comparing the tryptic cleavage products from intact and permeabilized microsomes. It was shown that lysine-4 of microsomal glutathione transferase is accessible at the luminal surface of the endoplasmic reticulum, whereas lysine-41 faces the cytosol. These positions are separated by a hydrophobic stretch of 25 amino acids (positions 11–35) which comprises the likely membrane-spanning region. Reaction of cysteine-49 of the microsomal glutathione transferase with the charged sulfhydryl reagent DTNB (2,2′-dithiobis(5-nitrobenzoic acid))) in intact microsomes further supports the cytosolic localization of this portion of the polypeptide chain. The role of two other potential membrane-spanning/associated segments in the C-terminal half of the polypeptide chain was examined by investigating the association of the protein to the membrane after trypsin cleavage at lysine-41. Activity measurements and Western blot analysis after washing with high concentrations of salt, as well as after phase separation in Triton X-114, indicate that this portion of the protein also binds to the membrane. It is also shown that cleavage of the purified protein at Lys-41 and subsequent separation of the fragments obtained yields a functional C-terminal polypeptide with the expected length for the product encompassing positions 42–154. The location of the active site of microsomal glutathione transferase was investigated using radiolabelled glutathione together with a second substrate. Since isolated rat liver microsomes do not take up glutathione or release the glutathione conjugate into the lumen, it can be concluded that the active site of rat liver microsomal glutathione transferase faces the cytosolic side of the endoplasmic reticulum.     

Bile acid inhibition of basic and neutral glutathione S-transferases in rat liver.

A purification scheme is described for the neutral glutathione S-transferases of rat liver. Discontinuous sodium dodecyl sulphate/polyacrylamide-gel electrophoresis revealed that one of these enzymes contains a previously unidentified subunit, which has a molecular mass of 23 000 Da and has been designated Yn. Bile acids inhibited the activity of all the basic and neutral transferases investigated, but marked differences in the effects of bile acids on individual enzymes were observed. The activity of each transferase was inhibited more by lithocholate 3-sulphate than by chenodeoxycholate, which in turn was more inhibitory than cholate. The enzymes that were most sensitive to cholate inhibition were not found to be as readily inhibited as other transferases by chenodeoxycholate or lithocholate 3-sulphate. Conversely, the activity of transferase AA was more resistant to cholate, chenodeoxycholate and lithocholate 3-sulphate inhibition than was any of the other enzymes studied.     

Microsomal glutathione transferase. Purification in unactivated form and further characterization of the activation process, substrate specificity and amino acid composition

The procedure developed for purification of the N-ethylmaleimide-activated microsomal glutathione transferase was applied successfully to isolation of this same enzyme in unactivated form. The microsomal glutathione transferases, the unactivated and activated forms, were shown to be identical in terms of molecular weight, immunochemical properties, and amino acid composition. In addition the microsomal glutathione transferase purified in unactivated form could be activated 15-fold with N-ethylmaleimide to give the same specific activity with 1-chloro-2,4-dinitrobenzene as that observed for the enzyme isolated in activated form. This activation involved the binding of one molecule N-ethylmaleimide to the single cysteine residue present in each polypeptide chain of the enzyme, as shown by amino acid analysis, determination of sulfhydryl groups by 2,2'-dithiopyridyl and binding of radioactive N-ethylmaleimide. Except for the presence of only a single cysteine residue and the total absence of tryptophan, the amino acid composition of the microsomal glutathione transferase is not remarkable. The contents of aspartic acid/asparagine + glutamic acid/glutamine, of basic amino acids, and of hydrophobic amino acids are 15%, 12% and 54% respectively. The isoelectric point of the enzyme is 10.1. Microsomal glutathione transferase conjugates a wide range of substrates with glutathione and also demonstrates glutathione peroxidase activity with cumene hydroperoxide, suggesting that it may be involved in preventing lipid peroxidation. Of the nine substrates identified here, the enzymatic activity towards only two, 1-chloro-2,4-dinitrobenzene and cumene hydroperoxide, could be increased by treatment with N-ethylmaleimide. This treatment results in increases in both the apparent Km values and V values for 1-chloro-2,4-dinitrobenzene and cumene hydroperoxide. Thus, although clearly distinct from the cytosolic glutathione transferases, the microsomal enzyme shares certain properties with these soluble enzymes, including a relative abundance, a high isoelectric point and a broad substrate specificity. The exact role of the microsomal glutathione transferase in drug metabolism, as well as other possible functions, remains to be established.     

Hepatic microsomal glucuronidation of bilirubin in unilamellar liposomal membranes. Implications for intracellular transport of lipophilic substrates

It has been assumed that following hepatic uptake, bilirubin is bound exclusively to cytosolic proteins prior to conjugation by microsomal UDP-glucuronyl-transferase. Since bilirubin partitions into lipid rather than the aqueous phase at neutral pH, we postulated that bilirubin reaches the sites of glucuronidation by rapid diffusion within membranes. To examine this hypothesis, [14C]bilirubin was incorporated into the membrane bilayer of small unilamellar liposomes of egg phosphatidylcholine. Radiochemical assay of this membrane-bound substrate in a physiologic concentration, using native rat liver microsomes, demonstrated immediate formation of bilirubin glucuronides at a more rapid initial velocity than for bilirubin bound to the high-affinity sites of purified cytosolic binding proteins, i.e. glutathione S-transferases (p less than 0.025) or native liver cytosol (p less than 0.05). Kinetic analysis suggested that the mechanisms of substrate transfer from liposomal membranes and from purified glutathione S-transferases to microsomal UDP-glucuronyltransferase were similar. The exchange of 3H- and 14C-labeled bilirubin substrate between binding proteins and liposomal membranes was then investigated using Sepharose 4B chromatography. As the concentration of bilirubin was increased relative to that of protein, net transfer of substrate from the protein to the membrane pool was observed. These findings indicate that bilirubin is efficiently transported by membrane-membrane transfer to hepatic microsomes, where it undergoes rapid conjugation. Bilirubin entering hepatocytes may partition between membrane and cytosolic protein pools, but as intracellular bilirubin concentration increases, the membrane pool is likely to provide a greater proportion of the substrate for glucuronidation.     

Ubiquinone biosynthesis in rat liver peroxisomes

The possibility that ubiquinone biosynthesis is present in rat liver peroxisomes was investigated. The specific activity of trans-prenyltransferase was 30% that of microsomes, with a pH optimum of around 8. trans-Geranyl pyrophosphate was required as a substrate and maximum activity was achieved with Mn(2+). Several detergents specifically inactivated the peroxisomal enzyme. The peroxisomal transferase is present in the luminal soluble contents, in contrast to the microsomal enzyme which is a membrane component. The treatment of rats with a number of drugs has demonstrated that the activities in the two organelles are subjected to separate regulation. Nonaprenyl-4-hydroxybenzoate transferase has about the same specific activity in peroxisomes as in microsomes and like the transferase activity, its regulation differs from the microsomal enzyme. The results demonstrate that peroxisomes are involved in ubiquinone biosynthesis, and at least two enzymes of the biosynthetic sequence are present in this organelle.     

Studies of the relationship between the catalytic activity and binding of non-substrate ligands by the glutathione S-transferases.

The dimeric enzyme glutathione S-transferase B is composed of two dissimilar subunits, referred to as Ya and Yc. Transferase B (YaYc) and two other transferases that are homodimers of the individual Ya and Yc subunits were purified from rat liver. Inhibition of these three enzymes by Indocyanine Green, biliverdin and several bile acids was investigated at different values of pH (range 6.0-8.0). Indocyanine Green, biliverdin and chenodeoxycholate were found to be effective inhibitors of transferases YaYc and YcYc at low (pH 6.0) but not high (pH 8.0) values of pH. Between these extremes of pH intermediate degrees of inhibition were observed. Cholate and taurochenodeoxycholate, however, were ineffective inhibitors of transferase YcYc at all values of pH. The observed differences in bile acids appeared to be due, in part, to differences in their state of ionization. In contrast with the above results, transferase YaYa was inhibited by at least 80% by the non-substrate ligands at all values of pH. These effects of pH on the three transferases could not be accounted for by pH-induced changes in the enzyme's affinity for the inhibitor. Thus those glutathione S-transferases that contain the Yc subunit are able to act simultaneously as both enzymes and binding proteins. In addition to enzyme structure, the state of ionization of the non-substrate ligands may also influence whether the transferases can perform both functions simultaneously.     

SUBCELLULAR AND SUBMICROSOMAL DISTRIBUTION OF GLYCOLIPID-SYNTHESIZING TRANSFERASES IN YOUNG RAT BRAIN

The subcellular and submicrosomal distributions of four glycolipid-synthesizing transferases were studied in young rat brains. (1) Two galactosyl transferases involved in the synthesis of cerebrosides, the cerebroside sulphotransferase which catalyses the synthesis of sulphatides, and the glucosyl transferase which plays an important role in the ganglioside biosynthesis were localized essentially in the microsomal fraction. Only low activities were detected in the crude mitochondrial and synaptosome-enriched fractions. (2) A comparison of the activities of these enzymes in the crude myelin and two myelin subfractions showed that the galactosyl transferases and the cerebroside sulphotransferase had similar activities in the crude myelin and myelin-like fractions. A considerable galactosyl transferase activity was found in purified myelin. In this respect these two enzymes were different from cerebroside sulphotransferase, whose activity was much lower in purified myelin. On the other hand, glucosyl transferase had a relatively low specific activity in all three myelin fractions. Analysis of different markers showed that the activities were considerably higher than those expected from the maximum microsomal contamination calculated. (3) Subfractionation of the microsomes demonstrated that the galactosyl transferases were more concentrated in the lower parts of the gradient, containing vesicles with attached ribosomes. Cerebroside sulphotransferase and glucosyl transferase were found predominantly in the upper and intermediate parts of the gradient, which were composed essentially of smooth-surfaced vesicles and membrane fragments. Chemical analysis of submicrosomal fractions confirmed the morphological observations.     

Interaction of 1,4-benzoquinone and 2,4-dichlorophenoxyacetic acid with microsomal glutathione transferase from rat liver

Glutathione transferase (GST) was purified from the microsomes of rat liver by glutathione affinity chromatography. The interaction of 2,4-dichlorophenoxyacetic acid (2,4-D) and 1,4-benzoquinone with microsomal GST was investigated and compared with cytosolic GST. The kinetic inhibition pattern of 1,4-benzoquinone towards microsomal GST was found to be different from that towards cytosolic GST. Microsomal GST purified by affinity chromatography was inhibited by 2,4-D in a non dose-dependent manner, while the crude microsomal GST was inhibited in a dose-dependent manner. This difference was shown to be induced by a reaction on the affinity column, and not by Triton X-100 (also shown to be a GST inhibitor), glutathione, or the elution buffer 0.2% Triton X-100 and 5 mM glutathione in 50 mM Tris-HCl, pH 9.6. The binding of microsomal GST to the affinity matrix caused a partial inactivation of the active site for 2,4-D interaction. The results show that the properties of soluble GST enzymes may not be extrapolated to the microsomal ones.     

The effects of in vitro lipid peroxidation on the activity of rat liver microsomal glutathione S-transferase from rats supplemented or deficient in antioxidants

Glutathione S-transferases are a group of multifunctional isozymes that play a central role in the detoxification of hydrophobic xenobiotics with electrophilic centers (1). In this study we investigated the effects of in vitro lipid peroxidation on the activity of liver microsomal glutathione S-transferases from rats either supplemented or deficient in both vitamin E and selenium. Increased formation of malondialdehyde (MDA), a by-product of lipid peroxidation, was associated with a decreased activity of rat liver microsomal glutathione S-transferase. The inhibition of glutathione S-transferase occurred rapidly in microsomes from rats fed a diet deficient in both vitamin E and selenium (the B diet) but was delayed for 15 minutes in microsomes from rats fed the same diet but supplemented with these micro-nutrients (B+E+Se diet). Lipid peroxidation inhibits microsomal glutathione S-transferase and this inhibition is modulated by dietary antioxidants.     

Inhibition of hepatic and extrahepatic glutathione S-transferases by primary and secondary bile acids.

Glutathione S-transferases are a complex family of dimeric proteins that play a dual role in cellular detoxification; they catalyse the first step in the synthesis of mercapturic acids, and they bind potentially harmful non-substrate ligands. Bile acids are quantitatively the major group of ligands encountered by the glutathione S-transferases. The enzymes from rat liver comprise Yk (Mr 25 000), Ya (Mr 25 500), Yn (Mr 26 500), Yb1, Yb2 (both Mr 27 000) and Yc (Mr 28 500) monomers. Although bile acids inhibited the catalytic activity of all transferases studied, the concentration of a particular bile acid required to produce 50% inhibition (I50) varies considerably. A comparison of the I50 values obtained with lithocholate (monohydroxylated), chenodeoxycholate (dihydroxylated) and cholate (trihydroxylated) showed that, in contrast with all other transferase monomers, the Ya subunit possesses a relatively hydrophobic bile-acid-binding site. The I50 values obtained with lithocholate and lithocholate 3-sulphate showed that only the Ya subunit is inhibited more effectively by lithocholate than by its sulphate ester. Other subunits (Yk, Yn, Yb1 and Yb2) were inhibited more by lithocholate 3-sulphate than by lithocholate, indicating the existence of a significant ionic interaction, in the bile-acid-binding domain, between (an) amino acid residue(s) and the steroid ring A. By contrast, increasing the assay pH from 6.0 to 7.5 decreased the inhibitory effect of all bile acids studied, suggesting that there is little significant ionic interaction between transferase subunits and the carboxy group of bile acids. Under alkaline conditions, low concentrations (sub-micellar) of nonsulphated bile acids activated Yb1, Yb2 and Yc subunits but not Yk, Ya and Yn subunits. The diverse effects of the various bile acids studied on transferase activity enables these ligands to be used to help establish the quaternary structure of individual enzymes. Since these inhibitors can discriminate between transferases that appear to be immunochemically identical (e.g. transferases F and L), bile acids can provide information about the subunit composition of forms that cannot otherwise be distinguished.     

Activation of microsomal glutathione transferase activity by reactive intermediates formed during the metabolism of phenol

The activity of microsomal glutathione transferase was increased 1.7-fold in rat liver microsomes which carried out NADPH dependent metabolism of phenol. Known phenol metabolites were therefore tested for their ability to activate the microsomal glutathione transferase. The phenol metabolites benzoquinone and 1,2,4-benzenetriol both activated the glutathione transferase in microsomes 2-fold independently of added NADPH. However, NADPH was required to activate the enzyme in the presence of hydroquinone. Catechol did not activate the enzyme in microsomes. The purified enzyme was activated 6-fold and 8-fold by 5 mM benzenetriol and benzoquinone respectively. Phenol, catechol or hydroquinone had no effect on the purified enzyme. When microsomal proteins that had metabolized [14C]phenol were examined by SDS polyacrylamide gel electrophoresis and fluorography it was found that metabolites had bound covalently to a protein which comigrated with the microsomal glutathione transferase enzyme. We therefore suggest that reactive metabolites of phenol activate the enzyme by covalent modification. It is discussed whether the binding and activation has general implications in the regulation of microsomal glutathione transferase and, since some reactive metabolites might be substrates for the enzyme, their elimination through conjugation.     

BIOSYNTHESIS OF PHOSPHATIDIC ACID IN RAT BRAIN VIA ACYL DIHYDROXYACETONE PHOSPHATE

Abstract— The enzymes for the biosynthesis of phosphatidic acid from acyl dihydroxyacetone phosphate were shown to be present in rat brain. These enzymes were mainly localized in the microsomal fraction of 12–14 day old rat brains. The brain microsomal acyl CoA: dihydroxyacetone phosphate acyl transferase (EC 2.3.1.42), exhibited a broad pH optimum between pH 5 and 9 with maximum activity at pH 5.4. K _m for DHAP at pH 5.4 was 0.1 m m and V _max was 0.86nmol/min/mg of microsomal protein. The corresponding microsomal enzyme for the glycerophosphate pathway (acyl CoA: sn -glycerol-3-phosphate acyl transferase EC 2.3.1.15) was shown to have a different pH optimum (pH 7.6). On the basis of the differences in pH optima, differential effects of sodium cholate in the enzymes and a common substrate competition study, these acyl transferases were postulated to be two different microsomal enzymes.
Acyl DHAP:NADPH oxidoreductase (EC 1.1.1.101) in brain microsomes was found to be quite specific for NADPH as cofactor, being able to utilize NADH only at very high concentrations. This enzyme exhibited a K _m of 8.6 μ m with NADPH and V _mx of 0.81 nmol/min/mg protein. The presence of these two enzymes and the known presence of l-acyl- sn -glycerol-3-phosphate: acyl CoA acyl transferase in brain (F leming & H ajra , 1977) demonstrated the biosynthesis of phosphatidic acid in brain via acyl dihydroxyacetone phosphate. Phosphatidic acid was shown to form when dihydroxyacetone phosphate, acyl CoA, NADPH and other cofactors were incubated together with brain microsomes. Further properties of the enzymes and the probable importance of the presence of this pathway in brain were discussed.     

Identification of a basic hybrid glutathione S-transferase from human liver. Glutathione S-transferase delta is composed of two distinct subunits (B1 and B2).

The purification of a hybrid glutathione S-transferase (B1 B2) from human liver is described. This enzyme has an isoelectric point of 8.75 and the B1 and B2 subunits are distinguishable immunologically and are ionically distinct. Hybridization experiments demonstrated that B1 B1 and B2 B2 could be resolved by CM-cellulose chromatography and have pI values of 8.9 and 8.4 respectively. Transferase B1 B2, and the two homodimers from which it is formed, are electrophoretically and immunochemically distinct from the neutral enzyme (transferase mu) and two acidic enzymes (transferases rho and lambda). Sodium dodecyl sulphate/polyacrylamide-gel electrophoresis demonstrated that B1 and B2 both have an Mr of 26 000, whereas, in contrast, transferase mu comprises subunits of Mr 27 000 and transferases rho and lambda both comprise subunits of Mr 24 500. Antisera raised against B1 or B2 monomers did not cross-react with the neutral or acidic glutathione S-transferases. The identity of transferase B1 B2 with glutathione S-transferase delta prepared by the method of Kamisaka, Habig, Ketley, Arias & Jakoby [(1975) Eur. J. Biochem. 60, 153-161] has been demonstrated, as well as its relationship to other previously described transferases.     

Activation of microsomal glutathione S-transferase activity by sulfhydryl reagents.

Rat liver microsomes exhibit glutathione S-transferase activity with 1-chloro-2,4-dinitrobenzene as the second substrate. This activity can be stimulated 8-fold by treatment of the microsomes with N-ethylmaleimide and 4-fold with iodoacetamide. The corresponding glutathione S-transferase activity of the supernatant fraction is not affected by such treatment. These findings suggest that rat liver microsomes contain glutathione S-transferase distinct from those found in the cytoplasmic and that the microsomal transferase can be activated by modification of microsomal sulfhydryl group(s).