Identification of Tyr115 labeled by S-(4-bromo-2,3-dioxobutyl)glutathione in the hydrophobic substrate binding site of glutathione S-transferase, isoenzyme 3-3.

Incubation of S-(4-bromo-2,3-dioxobutyl)glutathione (S-BDB-G), a reactive analogue of glutathione, with the 3-3 isoenzyme of rat liver glutathione S-transferase at pH 6.5 and 25 degrees C results in a time-dependent inactivation of the enzyme. The kobs exhibits a nonlinear dependence on S-BDB-G concentration from 50 to 900 microM, with a kmax of 0.073 min-1 and KI = 120 microM. The addition of 5 mM S-hexylglutathione, a competitive inhibitor with respect to glutathione, completely protects against inactivation by S-BDB-G. About 2.0 mol of [3H]S-BDB-G/mol of enzyme subunit is incorporated concomitant with 100% inactivation, whereas only 0.96 mol of reagent/mol subunit is incorporated in the presence of S-hexylglutathione when activity is fully retained. Modified enzyme, prepared by incubating glutathione S-transferase with [3H]S-BDB-G in the absence or in the presence of S-hexylglutathione, was reduced with NaBH4, reacted with N-ethylmaleimide, and digested with trypsin. Analysis of the tryptic digests, fractionated by reverse-phase high-performance liquid chromatography, revealed Tyr115 as the amino acid whose reaction with S-BDB-G correlates with inactivation. Examination of the stability of S-(4-bromo-2,3-dioxobutyl)glutathione and modified enzyme in the absence and presence of dithiothreitol and under acidic conditions suggests that for stable linkage to peptides, the carbonyl moieties of the reagent should be reduced immediately after modification of a protein. Comparison of results from the 4-4 and 3-3 isoenzymes of rat liver glutathione S-transferase (both of the mu gene class) indicates: the 4-4 isoenzyme exhibits a greater affinity for S-BDB-G; Cys86 is labeled by [3H]S-BDB-G in both isoenzymes but is nonessential for activity; in the 3-3 isoenzyme, Cys86 is more accessible to S-BDB-G; and Tyr115 is an important residue in the hydrophobic binding site of both enzymes.     

Mutagenic activity and DNA adduct formation by 1, 2-epoxy-3-(p-nitrophenoxy)propane, an HIV-1 protease inhibitor and GST substrate.

Acid protease inhibitor 1,2-epoxy-3-(p-nitrophenoxy)propane (ENPP) is commonly used in research as a substrate for glutathione-S-transferase activity (GST) and recently was found to inhibit human immunodeficiency virus 1 (HIV-1) protease. The question of DNA-adduct formation and mutagenicity was investigated and found that ENPP causes DNA damage and acts directly to induce mutagenicity in Salmonella. Using HPLC analysis, ENPP was shown to bind covalently to guanine residues. The Salmonella mutagenicity assay indicated that ENPP enhanced the mutation frequencies in the base-substitution strain TA00 by more than 20 times above the background. Its mutagenic potency was comparable to that of well-known carcinogens, N-methyl-N-nitrosourea (MNU) and aflatoxin B(1)-8,9-epoxide (AFB(1)-8,9-epoxide). The results suggest that ENPP should be classified as a mutagenic compound and a potential carcinogen.     

5-(Pentafluorobenzoylamino)fluorescein: A selective substrate for the determination of glutathione concentration and glutathione S-transferase activity

5-(Pentafluorobenzoylamino)fluorescein (PFB-F), a new thiol-reactive molecule was synthesized to improve the detection limits and specificity of the assays for glutathione S-transferase (GST) activity and glutathione (GSH). A rapid assay method to measure GSH concentration or GST activity and the simultaneous analysis of multiple samples is possible because the glutathione adduct, GS-TFB-F, is separated from PFB-F by thin-layer chromatography (TLC) and can be quantitated by a fluorescence scanner. The detection limits for GSH and for GST activity using TLC were found to be as low as 10 pmol/microl and 1 ng/microl using equine liver GST, respectively. Determination of GSH concentration or GST activity in bovine pulmonary artery endothelial (BPAE) cell lysates gave a linear response for samples corresponding to 500-2500 cells. PFB-F could also measure GST activities of GST fusion proteins and prove to be a suitable substrate for determining the activities of human GST isozymes and other sources of mammalian GST. The selectivity of PFB-F with GSH was proven by comparing trace amount of the adducts that formed with cysteine and beta-galactosidase to that formed with GSH. The HPLC profile of a reaction mixture where cell lysate was used in place of purified GST, also shows only two main peaks, corresponding to GS-TFB-F and unreacted PFB-F. The selectivity of PFB-F for GSH was further confirmed by exposing BPAE cells to dl-buthionine-[S,R]-sulfoximine (BSO). Our results of GS-TFB-F determination indicate that 12-, 24-, or 36-h incubations with BSO caused 2-, 6-, or 7.6-fold reductions in GSH levels, respectively.     

Amino acid substitutions at positions 207 and 221 contribute to catalytic differences between murine glutathione S-transferase Al-1 and A2-2 toward (+)-anti-7,8-dihydroxy-9,10-epoxy-7,8,9, 10-tetrahydrobenzo[a]pyrene.

We have previously identified a novel Alpha class murine glutathione (GSH) S-transferase isoenzyme (designated mGSTAl-2) which is exceptionally efficient in catalyzing the GSH conjugation of (+)-anti-7,8-dihydroxy-9,10-epoxy-7,8,9,10-tetrahydrobenzo[a]pyrene [(+)-anti-BPDE], the ultimate carcinogen of widespread environmental pollutant benzo[a]pyrene. Furthermore, we have demonstrated that the Al-type subunit of this isoenzyme is significantly more active toward (+)-anti-BPDE than the other subunit (mGSTA2). To establish the basis for catalytic differences between mGSTAl and mGSTA2, which differ in their primary structures by 10 amino acids [distributed in three sections (I-III) as clusters of two (residues 65 and 95), three (residues 157, 162, and 169), and five (residues 207, 213, 218, 221, and 222) amino acids], three chimeric enzymes were expressed and tested for their activity toward (+)-anti-BPDE. These studies revealed that amino acid substitution(s) in section III determined the high catalytic activity of mGSTAl. Molecular modeling studies suggested that amino acid substitutions at positions 207 and/or 221, but not at positions 213, 218, and 222, may be responsible for such a difference. To test this possibility, amino acids at positions 207 and 221 of mGSTAl were mutated with the equivalent residues of mGSTA2. Kinetic analysis of the wild type and the mutant enzymes revealed that both methionine-207 and isoleucine-221 are critical for higher activity of mGSTA1-1 toward (+)-anti-BPDE compared with that of mGSTA2-2.     

Genetic polymorphisms of glutathione S-transferase Z1 (GSTZ1) and susceptibility to preeclampsia

Preeclampsia (PE) is a complex disorder affected by genetic and environmental factors. Although the exact genes involved in development of PE are still not fully discovered, an important role for oxidative stress in its pathogenesis is accepted. In the present study, the association between the functional genetic polymorphisms in codons 32, 42 and nucleotide -1002 of glutathione S-transferases Z1 (GSTZ1) and susceptibility to PE was investigated. The present case-control study was performed on 151 preeclapmtic patients, and a total of 200 normal pregnant women, as a control group. The healthy control group was frequency matched with the age of the preeclamptic patients. Control subjects had no history of previous pregnancies with PE. Genotypes were determined by PCR-RFLP assay. There was no significant association between G-1002A and Glu32Lys polymorphisms of GSTZ1 with PE risk. The variant allele of Gly42Arg polymorphism decreased the risk of PE (OR = 0.24, 95 % CI 0.08-0.73, P = 0.012). The haplotype of "-1002A, 32Lys, 42Arg" (having three variant alleles) versus to the other haplotypes significantly decreased among PE patients compared to the control group (5.0 vs. 0.9 percent among control and PE patient groups, respectively; χ(2) = 9.328, df = 1, P = 0.002). The present results indicate that the haplotype of "-1002A, 32Lys, 42Arg" (containing three variant alleles) of GSTZ1 have protective effect compared to the other haplotypes.     

A bireactant, irreversible, active-site-directed inhibitor of beta-D-galactosidase (Escherichia coli). Synthesis and properties of (1/2,5,6)-2-(3-azibutylthio)-5,6-epoxy-3-cyclohexen-1-ol

(1/2,5,6)-2-(3-Azibutylthio)-5,6-epoxy-3-cyclohexen-1-ol (1) was synthesized and was found to irreversibly inactivate beta-D-galactosidase (Escherichia coli). The inactivation was prevented by the presence of isopropyl 1-thio-beta-D-galactopyranoside (IPTG). The vinyloxirane group of 1 reacted with water and other nucleophiles, especially at higher pH values. Reaction of 1 with beta-D-galactosidase was slow enough so that a competitive-inhibition constant (Ki) of 29mM could be determined. The inhibition constant for (1,2/3,6)-6-(3-azibutylthio)-2-bromo-4-cyclohexene-1,3-diol (2), the precursor of the bireactant inhibitor 1, was 13 mM, while that of (1,3/2,4)-3-(3-azibutylthio)-5-cyclohexene-1,2,4-triol (3), the product formed when the reactant is allowed to react with water, was 23mM. After irradiation by light, beta-D-galactosidase that had initially been treated with the bireactant compound and then digested with trypsin, showed a new pattern of elution from h.p.l.c., indicating that there was reaction at two regions of the beta-D-galactosidase molecule.     

Proteolytic enzymes in green wheat-leaves III. Inactivation of acid proteinase II by diazoacetyl-DL-norleucine methyl ester and 1,2-epoxy-3-(p-nitrophenoxy)-propane

Acid proteinase II isolated from green wheat leaves in a purifiedform was rapidly inactivated at pH=5.5 to 6.0 by a 50-fold molarexcess of diazoacetyl-DL-norleucine methyl ester (DAN) in thepresence of cupric ions which were essential for inactivation.The acid proteinase was also inactivated by reaction with 1,2-epoxy-3-(p-nitrophenoxy)-propane(EPNP). The inactivation by EPNP was much slower than by DANand the half-life of the activity was 24 hr. (Received February 6, 1978; )     

Tyrosine 8 contributes to catalysis but is not required for activity of rat liver glutathione S-transferase, 1-1.

Reaction of rat liver glutathione S-transferase, isozyme 1-1, with 4-(fluorosulfonyl)benzoic acid (4-FSB), a xenobiotic substrate analogue, results in a time-dependent inactivation of the enzyme to a final value of 35% of its original activity when assayed at pH 6.5 with 1-chloro-2,4-dinitrobenzene (CDNB) as substrate. The rate of inactivation exhibits a nonlinear dependence on the concentration of 4-FSB from 0.25 mM to 9 mM, characterized by a KI of 0.78 mM and kmax of 0.011 min-1. S-Hexylglutathione or the xenobiotic substrate analogue, 2,4-dinitrophenol, protects against inactivation of the enzyme by 4-FSB, whereas S-methylglutathione has little effect on the reaction. These experiments indicate that reaction occurs within the active site of the enzyme, probably in the binding site of the xenobiotic substrate, close to the glutathione binding site. Incorporation of [3,5-3H]-4-FSB into the enzyme in the absence and presence of S-hexylglutathione suggests that modification of one residue is responsible for the partial loss of enzyme activity. Tyr 8 and Cys 17 are shown to be the reaction targets of 4-FSB, but only Tyr 8 is protected against 4-FSB by S-hexylglutathione. DTT regenerates cysteine from the reaction product of cysteine and 4-FSB, but does not reactivate the enzyme. These results show that modification of Tyr 8 by 4-FSB causes the partial inactivation of the enzyme. The Michaelis constants for various substrates are not changed by the modification of the enzyme. The pH dependence of the enzyme-catalyzed reaction of glutathione with CDNB for the modified enzyme, as compared with the native enzyme, reveals an increase of about 0.9 in the apparent pKa, which has been interpreted as representing the ionization of enzyme-bound glutathione; however, this pKa of about 7.4 for modified enzyme remains far below the pK of 9.1 for the -SH of free glutathione. Previously, it was considered that Tyr 8 was essential for GST catalysis. In contrast, we conclude that Tyr 8 facilitates the ionization of the thiol group of glutathione bound to glutathione S-transferase, but is not required for enzyme activity.     

Effects of cyclic 12-, 8-, and 6-carbon compounds on glutathione S-transferase activity

The effects of feeding $\text{ICR}\text{Ha}$ mice cyclic 12-, 8-, and 6-carbon compounds on glutathione S-transferase (GST) activity in the liver, intestinal mucosa, and the forestomach were determined. The compounds used for this study were 1,5,9-trans,trans,cis-cyclododecatriene, 1,2-trans-5,6-trans-9,10-cis-cyclododecatriene-1,2-oxide, cyclododecanol, cyclododecene oxide, cyclododecane, 1,5-cyclooctadiene, cyclooctene oxide, cyclohexene, and cyclohexene oxide. The unsaturated cyclic 12-carbon compounds elicited the greatest increase in GST activity. Thus, feeding 1,5,9-trans,trans,cis-cyclododecatriene increased this activity almost 4-fold in the livers and the intestinal mucosa of experimental animals. Cyclic 8-carbon compounds were less effective and feeding the cyclic 6-carbon compounds did not result in any significant increase in GST activity. None of the compounds elicited increased GST activity in the fore-stomach. Previous studies have shown that compounds inducing increased GST activity can protect against chemical carcinogens. It remains to be determined whether the compounds identified in the present investigation as inducers of this enzyme system will have such protective capacities.     

Curcumin-glutathione interactions and the role of human glutathione S-transferase P1-1

Curcumin (diferuloylmethane), a yellow pigment of turmeric with antioxidant properties has been shown to be a cancer preventative in animal studies. It contains two electrophilic alpha, beta-unsaturated carbonyl groups, which can react with nucleophilic compounds such as glutathione (GSH), but formation of the GSH-curcumin conjugates has not previously been demonstrated. In the present studies, we investigated the reactions of curcumin with GSH and the effect of recombinant human glutathione S-transferase(GST)P1-1 on reaction kinetics. Glutathionylated products of curcumin identified by FAB-MS and MALDI-MS included mono- and di-glutathionyl-adducts of curcumin as well as cyclic rearrangement products of GSH adducts of feruloylmethylketone (FMK) and feruloylaldehyde (FAL). The presence of GSTP1-1 significantly accelerated the initial rate of GSH-mediated consumption of curcumin in 10 mM potassium phosphate, pH 7.0, and 1 mM GSH. GSTP1-1 kinetics determined using HPLC indicated substrate inhibition (apparent K(m) for curcumin of 25+/-11 microM, and apparent K(i) for curcumin of 8+/-3 microM). GSTP1-1 was also shown to catalyze the reverse reaction leading to the formation of curcumin from GSH adducts of FMK and FAL.     

The glutathione S-transferase activity in the kidney of rainbow trout (Salmo gairdneri)

Trout kidney contains 2.3 mmol GSH/kg. The cytosolic glutathione S-transferase activity with 1-chloro-2,4-dinitrobenzene as substrate is 0.35 mumol/min/mg protein. There is no detectable activity with 1,2-epoxy-3-(p-nitrophenoxy)propane, ethacrynic acid, p-nitrobenzyl chloride or p-nitrophenyl acetate. A variable proportion of the activity does not bind to a glutathione-affinity matrix. Its Km values for GSH and 1-chloro-2,4-dinitrobenzene are 3.0 and 5.1 mM, respectively. The rest of the activity is eluted from the affinity matrix as one main and two minor peaks. The main peak has Km values for GSH and 1-chloro-2,4-dinitrobenzene of 0.4 and 4.5 mM, respectively. Its subunit Mr is 22,900. The activity in the main peak is inhibited progressively by 1-chloro-2,4-dinitrobenzene with a rate constant of 0.11/min.     

Contribution of aromatic-aromatic interactions to the anomalous pK(a) of tyrosine-9 and the C-terminal dynamics of glutathione S-transferase A1-1

Most cytosolic glutathione S-transferases (GSTs) exploit a hydrogen bond between an active site Tyr and the bound glutathione (GSH) cofactor to lower the pK(a) of the GSH and generate the nucleophilic thiolate anion, GS(-). In human (hGSTA1-1) and rat (rGSTA1-1) homologues, the active site Tyr-9 has a low pK(a) of 8.1-8.3, for which the functional significance is unknown. Crystal structures of GSTA1-1 suggest that weakly polar interactions between the electropositive ring edge of Phe-10 and the pi-cloud of Tyr-9, in the apoenzyme, could stabilize the tyrosinate anion and also modulate the pK(a) of GSH. Upon binding a product GSH conjugate, Phe-10 moves away from Tyr-9, allowing the highly dynamic C-terminus to "close" over the active site. To explore the role of Phe-10 in modulating the Tyr-9 pK(a) and in ligand binding, rGSTA1-1 mutants F10Y, F10L, and F10A were characterized. The pK(a)s of Tyr-9 in the apoenzymes were 8.2 +/- 0.2, 8.7 +/- 0.2, and 9.3 +/- 0.1, respectively, for F10Y, F10L, and F10A, compared to 8.3 +/- 0.2 for the "wild type". The experimentally determined pK(a)s qualitatively paralleled the energies required to remove a proton predicted by ab initio calculations using model compounds constrained to the coordinates of rGSTA1-1. The pK(a) of GSH in the binary complex was significantly less affected by these substitutions. In contrast, F220I and F220Y C-terminal mutations caused the pK(a) of Tyr-9 to decrease modestly. For the binary complex with S-hexyl-GSH, which induces the "closed" conformation, Tyr-9 retains a low pK(a) and the Phe-10 substitutions have significant effects. Presumably, Phe-10 plays a critical structural role in stabilizing the closed conformation. The mutations F10L and F10A also slowed the rate of GSH conjugate binding by 10-20-fold, as measured by stopped-flow fluorescence. The effects of Phe-10 substitution were large for both steps of the biphasic binding reaction, suggesting the importance of aromatic interactions throughout the reaction coordinate. A unified view of the C-terminal dynamics of GSTA1-1 is discussed, which emphasizes the coupling between Tyr-9 ionization, active site solvation, and C-terminal dynamics.     

Affinity labeling of rat glutathione S-transferase isozyme 1-1 by 17beta -iodoacetoxy-estradiol-3-sulfate

Rat liver glutathione S-transferase, isozyme 1-1, catalyzes the glutathione-dependent isomerization of Delta(5)-androstene-3,17-dione and also binds steroid sulfates at a nonsubstrate inhibitory steroid site. 17beta-Iodoacetoxy-estradiol-3-sulfate, a reactive steroid analogue, produces a time-dependent inactivation of this glutathione S-transferase to a limit of 60% residual activity. The rate constant for inactivation (k(obs)) exhibits a nonlinear dependence on reagent concentration with K(I) = 71 microm and k(max) = 0.0133 min(-1). Complete protection against inactivation is provided by 17beta-estradiol-3,17-disulfate, whereas Delta5-androstene-3,17-dione and S-methylglutathione have little effect on k(obs). These results indicate that 17beta-iodoacetoxy-estradiol-3-sulfate reacts as an affinity label of the nonsubstrate steroid site rather than of the substrate sites occupied by Delta5-androstene-3,17-dione or glutathione. Loss of activity occurs concomitant with incorporation of about 1 mol 14C-labeled reagent/mol enzyme dimer when the enzyme is maximally inactivated. Isolation of the labeled peptide from the chymotryptic digest shows that Cys(17) is the only enzymic amino acid modified. Covalent modification of Cys(17) by 17beta-iodoacetoxy-estradiol-3-sulfate on subunit A prevents reaction of the steroid analogue with subunit B. These results and examination of the crystal structure of the enzyme suggest that the interaction between the two subunits of glutathione S-transferase 1-1, and the electrostatic attraction between the 3-sulfate of the reagent and Arg(14) of subunit B, are important in binding steroid sulfates at the nonsubstrate steroid binding site and in determining the specificity of this affinity label.     

Mutagenic activity of the glutathione S-transferase substrate 1-chloro-2,4-dinitrobenzene (CDNB) in the Salmonella mutagenicity assay

The mutagenicity of the commonly used glutathione S-transferase substrates 1-chloro-2,4-dinitrobenzene (CDNB) and 1,2-dichloro-4-nitrobenzene (DCNB) was investigated in the Salmonella mutagenicity assay. CDNB induced a concentration-dependent mutagenic response in Salmonella typhimurium strain TA98. Incorporation of an activation system derived from Aroclor 1254-induced rats did not influence mutagenic response. Under the same conditions DCNB failed to display mutagenic activity. The mutagenic activity of CDNB was attenuated in bacterial strains under-expressing nitroreductase or O-acetylase activity but, in contrast, it was exaggerated in an O-acetylase over-expressing strain. It is inferred that CDNB exhibits a mutagenic response following reduction of the nitro-group to the hydroxylamine, which is further acetylated to form the acetoxy derivative that presumably breaks down spontaneously to generate the nitrenium ion, the likely ultimate mutagen.     

Contribution of tyrosine 6 to the catalytic mechanism of isoenzyme 3-3 of glutathione S-transferase.

The role of the hydroxyl group of tyrosine 6 in the catalytic mechanism of isoenzyme 3-3 of rat glutathione S-transferase has been examined by x-ray crystallography and site-specific replacement of the residue with phenylalanine and evaluation of the catalytic properties of the mutant enzyme. This particuar tyrosine residue is conserved in the sequences of all of the cytosolic enzymes and is found, in crystal structures of both isoenzyme 3-3 from the mu-gene class and an isoenzyme from the pi-gene class, to be proximal to the sulfur of glutathione (GSH) or glutathione sulfonate bound at the active site. The 2.2-A structure of the binary complex of isoenzyme 3-3 and GSH indicates that the hydroxyl group of Tyr6 is located 3.2-3.5 A from the sulfur of GSH, well within hydrogen bonding distance. Removal of the hydroxyl group of Tyr6 has essentially no effect on the dissociation constant (22 +/- 3 microM) for GSH. Nevertheless the Y6F mutant exhibits a turnover number which is only about 1% that of the native enzyme when assayed at pH 6.5 with either 1-chloro-2,4-dinitrobenzene (CDNB) or 4-phenyl-3-buten-2-one. UV difference spectra of the binary enzyme-GSH complexes suggest that the predominant ionization state of GSH in the active site of the Y6F mutant is the neutral thiol (e.g. EY6F.GSH) which is in contrast to the native enzyme in which the thiol is substantially deprotonated (e.g. E.GS-). Spectrophotometric titration suggests that the pKa of the thiol is 6.9 +/- 0.3 in the E.GSH complex and greater than or equal to 8 in the EY6F.GSH binary complex. In addition, the pH dependence of kcat/KmCDNB reveals that the reactions catalyzed by the native enzyme and the Y6F mutant are dependent on a single ionization in the E.GSH and EY6F.GSH complexes with pKa = 6.2 +/- 0.1 and 7.8 +/- 0.3, respectively. The results suggest that the hydrogen bond between Tyr6 and the enzyme-bound nucleophile helps to lower the pKa of GSH in the binary enzyme-substrate complex.     

The effect of environmental parameters on growth,cholinesterase activity and glutathione S-transferase activity in the earthworm (Apporectodea caliginosa)

The effect of age and environmental parameters on growth, cholinesterase (ChE), and glutathione S-transferase (GST) activities were assessed in juvenile Apporectodea caliginosa earthworms. Earthworms were maintained in three types of soil- loam, sandy, and clay- at a range of moisture contents (15-30%), and temperatures (5-20 C). Earthworm age (1-3 months) had no significant affect on ChE activity. Growth rates were influenced by all environmental parameters tested and these effects were interrelated. Optimum conditions for growth appeared to be in loam or sandy soil with 25-30% moisture at 10-15 C. The GST activity was influenced by soil temperature and activity was significantly higher at 15 C than at 5 C and 10 C. Soil type also influenced GST activity and this influence was dependent on moisture content. In sandy soil GST activity was significantly lower at 30% moisture than at lower moisture contents, in loam soil GST activity was significantly higher at 15% moisture than at higher moisture contents, while in clay soil GST activity was not affected by moisture content. These results indicate that in field experiments when evaluating GST activity soil temperature and soil type need to be consistent between control and 'contaminated sites'. ChE activity was only affected by temperature, so this should be considered when comparing control and treatedareas.     

The effect of environmental parameters on growth, cholinesterase activity and glutathione S-transferase activity in the earthworm (Apporectodea caliginosa)

The effect of age and environmental parameters on growth, cholinesterase (ChE), and glutathione S-transferase (GST) activities were assessed in juvenile Apporectodea caliginosa earthworms. Earthworms were maintained in three types of soil- loam, sandy, and clay- at a range of moisture contents (15-30%), and temperatures (5-20 C). Earthworm age (1-3 months) had no significant affect on ChE activity. Growth rates were influenced by all environmental parameters tested and these effects were interrelated. Optimum conditions for growth appeared to be in loam or sandy soil with 25-30% moisture at 10-15 C. The GST activity was influenced by soil temperature and activity was significantly higher at 15 C than at 5 C and 10 C. Soil type also influenced GST activity and this influence was dependent on moisture content. In sandy soil GST activity was significantly lower at 30% moisture than at lower moisture contents, in loam soil GST activity was significantly higher at 15% moisture than at higher moisture contents, while in clay soil GST activity was not affected by moisture content. These results indicate that in field experiments when evaluating GST activity soil temperature and soil type need to be consistent between control and 'contaminated sites'. ChE activity was only affected by temperature, so this should be considered when comparing control and treatedareas.