Identification of a glutathione S-transferase associated with microsomes of tumor cells resistant to nitrogen mustards

Walker 256 rat mammary carcinoma cells resistant to chlorambucil (WR) exhibited an approximate 4-fold increase in glutathione S-transferase (GST) activity using 1-chloro-2,4-dinitrobenzene as compared to the sensitive parent cell line (WS). WR cells maintained without biannual exposure to chlorambucil (WRr) reverted to the sensitive phenotype and possessed GST levels equivalent to WS. Mitochondria, microsomes and cytosol were isolated from WS, WR and WRr cell lines and analyzed for their GST composition. GST activity in each subcellular compartment of resistant cells was increased over the sensitive cells. Antibodies raised against total rat liver cytosolic GST crossreacted in resistant cells with two microsomal proteins (25.7 kD and 29 kD). The 29 kD protein was not detected in microsomal fractions from either WS or WRr and this protein was found to be dissimilar from cytosolic GST subunits in its isoelectric point (pI 6.7) and migration on two-dimensional polyacrylamide gels. In addition, the 29 kD microsome-associated GST from WR cells was immunologically distinct from a 14 kD GST subunit previously identified in rat liver microsomes. These data implicate the induction of a specific microsomal GST subunit in WR cells following drug selection and suggest its potential involvement in the establishment of cellular resistance to chlorambucil.     

A comparative analysis of drug-induced DNA effects in a nitrogen mustard resistant cell line expressing sensitivity to nitrosoureas

In the Walker 256 rat mammary carcinoma cell line, WR, resistance to nitrogen mustards (NM) is accompanied by collateral sensitivity to chloroethylnitrosoureas (CENUs). DNA-interstrand cross-links, DNA-protein cross-links, and sister chromatid exchange (SCE) induction were assayed in WR and the parent cell line (WS) after treatment with nitrogen mustard (HN2), phosphoramide mustard (PM), chlorozotocin (CLZ) and 1-(2-chloroethyl)-3-cyclohexyl-1-nitrosourea (CCNU). Treatment of cells with HN2 caused extensive levels of cross-links, approximately 50% of which were DNA-interstrand, equal in both WR and WS, whereas PM caused no detectable cross-links in either cell line. CLZ induced low levels of DNA-interstrand cross-links, similar in WR and WS, but no DNA-interstrand cross-links could be detected in either cell line after treatment with CCNU. Both CLZ and CCNU induced low levels of DNA-protein cross-links in both cell lines, though higher in WR than WS. There was no difference in the rate of removal of HN2-induced DNA-interstrand or DNA-protein cross-links or total CLZ-induced cross-links by the two cell lines, suggesting that differential repair was not relevant to the expression of resistance. Both HN2 and PM caused more SCEs in WS than in WR, whereas CLZ and CCNU induced more SCEs in WR. Thus, NM-induced SCEs were related to cell killing but not cross-linking, whilst CENU-induced SCEs were related to cell killing and DNA-protein but not DNA-interstrand cross-links. Furthermore, the collateral sensitivity of WR cells to CENUs was not due to the differential induction of DNA-interstrand cross-links or repair of total cross-links, or repair of total cross-links, although higher levels of DNA-protein cross-links occurred in WR, and these may be either a cause or a consequence of increased susceptibility of these cells to CENUs. Presumably NMs and CENUs have several distinct and separate macromolecular targets which result in differential cell killing. It is concluded that a range of lesions occurred after treatment of WR and WS cells with either NMs or CENUs and that, in these cell lines, there is no simple correlation between drug-induced cross-linking, SCE induction and cytotoxicity.     

Protective activity of different hepatic cytosolic glutathione S-transferases against DNA-binding metabolites of aflatoxin B1

To evaluate the role of glutathione S-transferase (GST) isoenzymes in induced resistance of hepatocytes to aflatoxin B1 (AFB1), we compared DNA protective activities of different hepatic cytosol preparations and purified GSTs from normal rats, rats exposed to different polychlorinated biphenyls (PCBs), and rats with carcinogen-induced hepatocellular neoplasms, with cytosols or purified GSTs from mouse, rainbow trout, and human livers. These comparisons were performed in an in vitro assay for [3H]AFB1-DNA binding after activation by rat liver microsomes. Cytosol and S-hexylglutathione-affinity-purified GST preparations from livers of mice consistently had strong protective activity against AFB1-DNA binding. The majority of this activity was dependent on the presence of reduced glutathione (GSH) but some GSH-independent protection was observed in mouse hepatic cytosol, but not in purified GST preparations. We found that all of the GSH-dependent DNA-protective activity in mouse liver eluted as a single GST isoenzyme by hydroxyapatite chromatography. Preparations of cytosol and purified GSTs from normal rat liver, rainbow trout liver, and human liver had much less AFB1-specific DNA protective activity than GSTs found in mouse liver preparations. Cytosol from rats with carcinogen-generated liver neoplasms and livers induced with 3,3',4,4'-tetrachlorobiphenyl and 2,2',4,4',5,5'-hexachlorobiphenyl had more GST activity toward CDNB than cytosol from normal rat liver. When equivalent units of GST activity (CDNB) were compared, there was little difference observed between the DNA-protective activities of PCB-induced and normal rat liver cytosols, yet cytosol from rat liver neoplasms was more protective. Purified GST-P (7-7), the GST isoenzyme most induced in carcinogen-generated rat liver neoplasms, was not protective when added at protein concentrations found to be protective for total GSTs isolated from these neoplasms. These studies demonstrate that the resistance of mouse liver to AFB1 can be explained primarily by a single constitutive GST isoenzyme (YaYa or 4-4) with a relatively high activity toward DNA-binding metabolites of AFB1. GST isoenzymes with such high specific DNA protective activity against AFB1 metabolites were not evident in human, rat, or rainbow trout liver or in PCB-induced or neoplastic rat liver preparations.     

Dog liver glutathione S-transferase and its strong immunoreactivity with rat transferase-P(7-7)

Dog liver cytosolic glutathione S-transferases (GSTs) were investigated to characterize their properties in comparison with rat liver transferases. Dog liver GSTs after the glutathione affinity column chromatography showed three subunit bands on SDS-polyacrylamide gel electrophoresis. These three subunits, designated as Yd1 (mol.wt 26,000), Yd2 (mol.wt 27,000) and Yd3 (mol.wt 28,000), were distinctly different from rat liver GST subunits, i.e. Ya(1) (mol.wt 26,500), Yb1(3)/Yb2(4) (mol.wt 27,500) and Yc(2) (mol.wt 28,500). Western blot analysis revealed that Yd1, Yd2 and Yd3 were immunoreacted with anti-rat GST 7-7, 1-1 and 3-3 antibodies, respectively. Four transferase activity fractions, I (pH greater than 7.63), II (pH 6.92), III (pH 5.80) and IV (pH 5.65), were obtained from affinity purified GSTs by chromatofocusing. Each fraction exhibited a characteristic substrate specificity. GST-II, III and IV were all strongly immunoreacted with anti-rat GST 7-7 antibody by immunoblotting, thus suggesting the occurrence of the heterogeneity of transferases immunologically related to rat GST subunit 7 in dog liver. Immunohistochemical examination showed that transferases immunoreacted with anti-GST 7-7 antibody have diffusely distributed throughout the lobule, while enzymes related to subunit 3 have been localized in a narrow range of cells around the central vein. These data suggest that GSTs immunologically associated with rat transferase subunit 7 may be major forms in dog liver.     

Selection of nitrogen mustard resistance in a rat tumor cell line results in loss of guanine-O6-alkyl transferase activity

Cell killing, DNA-interstrand crosslinks, and DNA-protein crosslinks were assayed in nitrogen mustard-resistant Walker 256 carcinoma (WR) cells and the parent cell line (WS) after treatment with 5-[3-(2-chloroethyl)-1-triazenyl]imidazo-4-carboxamide (MCTIC). The WR cells, which also express collateral sensitivity to chloroethylnitrosoureas, were approximately twice as sensitive to the cytotoxic effects of MCTIC as were WS cells. Following treatment with 100 microM MCTIC, there was a rapid accumulation of both DNA-interstrand and DNA-protein crosslinks in the WR cell line, which reached a maximum at 6 and 12 hr, respectively. There was considerably less crosslinking in the WS cells and both cell lines were proficient in repairing most of the crosslinks by 24 hr. Measurement of guanine-O6-alkyl transferase activity showed the enzyme to be present in WS but not in WR cells. These data indicate that the collateral sensitivity of nitrogen mustard-resistant WR cells to chloroethylating drugs is in part due to the loss of guanine-O6-alkyl transferase activity which is present in the parent line.     

Sex and species differences in glutathione S-transferase activities

Glutathione S-transferases (GSTs) are one of the important enzymes in terms of not only drug metabolism but also physiological functions. The marked sex difference in GST activity has been found in rat and mouse liver cytosol, and such differences in rat liver are suggested to be primarily due to the differences in the subunit composition of GSTs in both sexes. In addition, GST activities of rat liver cytosol are known to be largely influenced by treatment with inducers such as phenobarbital and 3-methylcholanthrene and various hormones. GSTs are widely distributed in mammalian species, and multiplicity of GST has been demonstrated so far. The present review also describes multiple forms of GST from the viewpoint of enzymology and immunology.     

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.     

Regulation of glutathione S-transferase enzymes in primary cultures of rat hepatocytes maintained under various matrix configurations.

Primary rat hepatocytes were cultured under various matrix and media conditions and examined after 1 week for the expression and regulation of cytosolic glutathione S-transferase (GST) enzymes. Striking effects on cell morphology were observed in relation to the different matrix conditions, whereas media effects were less prominent. Hepatocytes cultured in serum-free Dulbecco's modified Eagle's medium (DMEM) or modified Chee's medium (MCM) maintained similar levels of total GST protein regardless of the matrix configuration or corresponding cell integrity. However, HPLC analysis showed a differential expression pattern of individual GST subunits in both a time- and medium-dependent fashion. A variable, but pronounced, matrix and medium effect was observed on the induction of total GST expression by various prototypical inducers. Dexamethasone (10 microM) induced subunits A2, M1 and M2 in a medium- and matrix-dependent fashion, whereas phenobarbital (100 microM) induced significantly only subunit A2. beta-Naphthoflavone (50 microM) suppressed all GST subunit expression except subunit P1, which was induced in a matrix- and medium-dependent fashion. These studies show that total basal level expression of GSTs in vitro is reflective of a concomitant increase in mu and pi class subunits and a decrease in alpha class subunits. Moreover, the matrix and medium conditions influence both the basal and inducible expression of GST subunits in cultured rat hepatocytes.     

Inhibition of human term placental and fetal liver glutathione-S-transferases by fatty acids and fatty acid esters.

Glutathione-S-transferase (GST) activity from human term placenta and human fetal liver towards 1-chloro-2,4-dinitrobenzene as the second substrate was significantly inhibited by the saturated fatty acids, stearic (SA) and palmitic (PA) acids and fatty acid esters, ascorbyl stearate (Asc-S) and ascorbyl palmitate (Asc-P). The nature of inhibition of human placental GST was competitive towards CDNB with Ki values of 3.1, 10.0, 13.5 and 18.5 microM for Asc-S, Asc-P, PA and SA, respectively. The inhibitory effect of Asc-S on human term placental GST was reversible. I50 values for Asc-S, Asc-P, SA and PA were 15, 45, 83 and 78 microM, respectively, for partially purified human fetal liver GSTs and 21, 6, 88 and 117 microM, respectively, for partially pure rat liver GSTs. The evidence suggests that Asc-S, Asc-P, SA and PA are potent inhibitors especially of the pi-class of GST.     

Purification and characterization of hepatic glutathione transferases from an insectivorous marsupial,the brown antechinus (Antechinus stuartii)

1. Five unique glutathione transferase isoenzymes were purified from the hepatic cytosol of an insectivorous marsupial, the brown antechinus. The purified GSTs were characterized by structural and catalytic properties including apparent molecular weight andisoelectricpoint,specificity towards modelsubstrates,kineticparameters,sensitivityto inhibitors and cross-reactivity with antisera raised against human GSTs. 2. An alpha class GST, Antechinus GST 1-1, predominated in the hepatic cytosol, representing 71% of the total GST purified. The substrate specificity of Antechinus GST 1-1 was similar to that of other alpha class GSTs, particularly with respect to its high activity with cumene hydroperoxide. The mu class was represented by three GST isoenzymes, Antechinus GST 3-3, GST 3-4 and GST 4-4. These isoenzymes represented 8, 2 and 10% of the total GST purified respectively. A single GST, Antechinus GST 22, belonged to the pi class of GSTs and represented 12% of the total GST purified. The hepatic GST isoenzyme ratio (by class) observed in the brown antechinus was more similar to that observed in the human than in rat. 3. A previous study investigating a herbivorous marsupial, the brushtail possum (Trichosurus vulpecula) also identified a predominant hepatic GST belonging to the alpha class and displaying peroxidase activity. The evolutionary conservation of a similar predominant GST isoenzyme in these marsupials suggests that they play an important role in the detoxication metabolism of these unique mammals.     

Reduced DNA double strand breaks in chlorambucil resistant cells are related to high DNA-PKcs activity and low oxidative stress

Modulation of DNA repair represents a strategy to overcome acquired drug resistance of cells to genotoxic chemotherapeutic agents, including nitrogen mustards (NM). These agents induce DNA inter-strand cross-links, which in turn produce double strand breaks (dsbs). These breaks are primarily repaired via the nonhomologous end-joining (NHEJ) pathway. A DNA-dependent protein kinase (DNA-PK) complex plays an important role in NHEJ, and its increased level/activity is associated with acquired drug resistance of human tumors. We show in this report that the DNA-PK complex has comparable levels and kinase activity of DNA-PK catalytic subunit (DNA-PKcs) in a nearly isogenic pair of drug-sensitive (A2780) and resistant (A2780/100) cells; however, treatment with chlorambucil (Cbl), a NM-type of drug, induced differential effects in these cells. The kinase activity of DNA-PKcs was increased up to 2h after Cbl treatment in both cell types; however, it subsequently decreased only in sensitive cells, which is consistent with increased levels of DNA dsbs. The decreased kinase activity of DNA-PKcs was not due to a change in its amount or the levels of Ku70 and Ku86, their subcellular distribution, cell cycle progression or caspase-mediated degradation of DNA-PK. In addition to DNA cross-links, Cbl treatment of cells causes a 2.2-fold increase in the level of reactive oxygen species (ROS) in both cell types. However, the ROS in A2780/100 cells were reduced to the basal level after 3-4h, while sensitive cells continued to produce ROS and undergo apoptosis. Pre-treatment of A2780 cells with the glutathione (GSH) precursor, N-acetyl-L-cysteine prevented Cbl-induced increase in ROS, augmented the kinase activity of DNA-PKcs, decreased the levels of DNA dsbs and increased cell survival. Depletion in GSH from A2780/100 cells by L-buthionine sulfoximine (BSO) resulted in sustained production of ROS, lowered DNA-PKcs kinase activity, enhanced levels of DNA dsbs, and increased cell killing by Cbl. We propose that oxidative stress decreases repair of DNA dsbs via lowering kinase activity of DNA-PKcs and that induction of ROS could be the basis for adjuvant therapies for sensitizing tumor cells to nitrogen mustards and other DNA cross-linking drugs.     

Glutathione S-transferase and P-glycoprotein in multidrug resistant Chinese hamster cells

Glutathione S-transferases (GSTs) have been reported to be elevated in some forms of hepatic carcinogenesis, in multidrug resistant (MDR) cells exhibiting elevated P-glycoprotein, and in cells resistant to alkylating agents independent of the MDR phenotype. The reported elevation of GST in association with the MDR phenotype and the overexpression of P-glycoprotein along with induction of GST in hepatic carcinogenesis suggest a correlation in the two mechanisms of cellular detoxification. To evaluate this hypothesis we examined the expression of GSTs in an MDR Chinese hamster fibroblast cell line overexpressing P-glycoprotein. We were unable to demonstrate concordant elevation of GST in these MDR cells. We conclude that GST expression is independent of P-glycoprotein expression in MDR Chinese hamster fibroblasts. The overexpression of GSTs in certain cells may provide an alternative mechanism for the development of drug resistance, either in association with or independent of P-glycoprotein overexpression, but is not essential for the MDR phenotype.     

Hepatocytes isolated from preneoplastic rat livers are resistant to ethacrynic acid cytotoxicity

Glutathione S-transferases (GSTs) are involved in the detoxification of xenobiotics, such as several cytostatic drugs, through conjugation with glutathione (GSH). Pi class GST (GST P) liver expression is associated with preneoplastic and neoplastic development and contributes with the drug-resistance phenotype. Ethacrynic acid (EA) is an inhibitor of rat and human GSTs. In addition, causes lipid peroxidation in isolated rat hepatocytes. Therefore, we decided to evaluate the role of the GST/GSH system in isolated hepatocytes from preneoplastic rat livers (IP) in the presence of EA and determine the cytotoxicity of the drug. Our results showed a resistance to the toxic effects of EA since viability and cellular integrity values were significantly higher than control. Initial levels of thiobarbituric acid reactive substances (TBARS) in IP hepatocytes were significantly higher than control and the presence of EA did not change TBARS levels. A diminution in intracellular total GSH was observed by treating with EA isolated hepatocytes from both groups. However, the initial total GSH levels were higher in IP hepatocytes than in control. Immunoblotting analysis showed the presence of GST P in IP animals only. Although alpha and mu class isoenzymes levels were decreased in IP hepatocytes, total GST activity was 1.5-fold higher than in control. In addition, multidrug-resistance protein 2 (Mrp2) showed fivefold decreased levels in IP hepatocytes. In conclusion, increased total GSH, decreased Mrp2 levels and the presence of GST P could be critical factors involved in the resistance of IP hepatocytes to the toxicity of EA.     

Expression of tandem glutathione S-transferase recombinant genes in COS cells for analysis of efficiency of protein expression and associated drug resistance.

Expression vectors were designed and constructed to achieve optimum production of two different isozymes of rat glutathione S-transferase (GST) (EC 2.5.1.18) in COS cells, for studies of drug resistance. Promoter-enhancer elements from the simian virus 40 (SV40) early-region or the mouse alpha 2(I)-collagen gene, GST cDNAs encoding the rat Ya or Yb1 isozymes, and an SV40 replicative origin (ori) were positioned in the vector to express two GSTs at high levels in the same cell. The optimized construct yielded levels of both GST proteins (1% of postmitochondrial protein fraction) that were up to 1.3-fold greater than the sum of those produced individually by two single-unit expression constructs. The best production of the tandem recombinant gene products was observed when the genes were placed in a head to head orientation in close proximity (1 kilobase). With the recombinant genes configured in this way, the plasmid DNA was also amplified in COS cells to higher levels (30% increase over single-unit expression constructs), as ori elements were placed on both DNA strands. Cells expressing the recombinant GSTs were viably sorted by flow cytometry on the basis of a GST-catalyzed conjugation of glutathione to monochlorobimane. Sorted COS cells that expressed both GST Ya and Yb1 from recombinant genes in a tandem, head to head configuration were 25 or 70% more resistant to the alkylating agent chlorambucil than cells that expressed GST Ya or Yb1 alone.     

The Cruciferous Nitrile, Crambene, Induces Rat Hepatic and Pancreatic Glutathione S-Transferases

Indoles and isothiocyanates found in cruciferous vegetableshave been implicated as chemopreventive agents against carcino-genesis.The bioactivities of chemically related cruciferous nitriles,including 1-cyano-2-hydroxy-3-butene (crambene), however, havenot been thoroughly evaluated. Crambene causes a prolonged elevationof rat hepatic and pancreatic glutathione and induces the GSHS-transferases (GSTs). Because elevated GST activity againstthe model substrate chlorodinitrobenzene does not reflect individualisoenzyme induction, quantitative HPLC evaluation of specificGST subunits is necessary to fully assess the range of GST isoenzymesinduced by crambene. Accordingly, male Fischer 344 rats weregiven, via esophageal intubation, either 100 (Experiment 1)or 50 mg crambene/kg body wt (Experiment 2) once daily for 7days. GSTs were extracted from hepatic cytosol by affinity chro-matography,and the individual subunits that comprise the various isoenzymeswere quantified by reverse-phase HPLC to gain an estimate ofinduction. In addition, pancreatic GST subunits were assessedin the low-dose experiment. In parallel with increased GST activity,crambene caused a generalized induction of GST subunits in bothliver and pancreas, but the pattern of subunit induction wastissue dependent. In the liver,     

Glutathione S-transferase-dependent conjugation of leukotriene A4-methyl ester to leukotriene C4-methyl ester in mammalian skin.

The glutathione S-transferase (GST)-dependent conjugation of reduced glutathione (GSH) with leukotriene A4 (LTA4)-methyl ester in rodent and human skin was investigated. Incubation of [3H]LTA4-methyl ester (1 nmole, approximately 200,000 dpm) with cytosol prepared from rat, mouse and human skin or with affinity purified GST from rat skin cytosol in the presence of GSH resulted in the formation of LTC4-methyl ester. Maximum enzyme activity was observed in rat skin followed by mouse and human skin. With heat-denatured cytosol or in the absence of GSH, the product formation was negligible. GST purified from rat skin cytosol by GSH-agarose affinity chromatography exhibited a several-fold increase in the specific activity of enzyme with 1-chloro-2,4-dinitrobenzene (55-fold), ethacrynic acid (67-fold) and LTA4-methyl ester (12-fold) as substrates. Western blot analysis of the affinity purified GST indicated a predominant expression of the Pi class of GST isozyme followed by Mu and Alpha classes of isozymes. The formation of LTC4-methyl ester was established by its radioactivity profile on high pressure liquid chromatography and absorption spectroscopy. These results suggest that, in addition to xenobiotic metabolism, cutaneous GSTs may also be capable of metabolizing physiological substrates such as LTA4.     

Complementary DNA cloning, protein expression, and characterization of alpha-class GSTs from Macaca fascicularis liver.

Large species differences exist in sensitivity to aflatoxin B(1) (AFB(1))-induced liver cancer. Mice are resistant to AFB(1)-induced liver cancer because they express an alpha-class GST (mGSTA3-3) that has high activity toward the reactive intermediate aflatoxin B(1)-8,9-epoxide (AFBO). Rats constitutively express only small amounts of a GST with high AFBO activity (rGSTA5-5) and thus are sensitive to AFB(1)-induced hepatocarcinogenesis, although induction of rGSTA5-5 can confer resistance in rats. In contrast to rodents, constitutively expressed human hepatic alpha-class GSTs have little or no AFBO detoxifying activity. Recently, we found that the nonhuman primate, Macaca fascicularis (Mf), has significant constitutive hepatic GST activity toward AFBO and most of this activity belongs to mu-class GSTs. To determine if any alpha-class GSTs in Mf liver have AFBO activity, a cDNA library from a male Mf liver was constructed and screened using the human alpha-class GstA1 cDNA as a probe. Three different cDNA clones with full-length open reading frames were identified from the Mf hepatic cDNA library. Analyses of the cDNA deduced protein sequences indicated that these three alpha-class cDNA clones were 97-98% homologous with each other, and shared 93, 95, and 95% identity with human GSTA1, and were named mfaGSTA1, mfaGSTA2, and mfaGSTA3, respectively. Bacterially expressed mfaGSTA1-1 recombinant protein had similar activities toward classic GST substrates such as DCNB, CHP, and ECA, but slightly lower CDNB conjugating activity relative to human GSTA1-1. However, similar to hGSTA1-1, mfaGSTA1-1 had no AFBO conjugating activity. In addition, similar to human GSTA1 gene, cDNA-derived amino acid sequence analyses demonstrated that all of these Mf alpha-class GSTs genes (mfaGSTA1, mfaGSTA2, and mfaGSTA3) had none of the six critical residues that were identified previously to confer high AFBO activity in mouse alpha-class GSTA3-3. Thus, in contrast to rodents but similar to humans, alpha-class GSTs from the nonhuman primate, Mf, have little conjugating activity toward AFBO.