Heterodimers of glutathione S-transferase can form between isoenzyme classes pi and mu.

Glutathione S-transferases constitute a family of enzymes that detoxify xenobiotics by conjugating glutathione with a range of electrophilic substrates. The cytosolic glutathione S-transferase dimeric isoenzymes are currently divided into at least eight classes on the basis of their physical and chemical properties. Previously, heterodimers have only been detected within a given class of isoenzymes; however, here we describe for the first time the generation of a heterodimer between a pi class and mu class glutathione S-transferase. The heterodimer forms under mild conditions (dialysis against phosphate buffer, pH 6.5) and is best detected when one of the isoenzyme subunits is in excess. The activity of the pi-mu heterodimer toward several substrates indicates that interaction between these two dissimilar subunits influences the catalytic activity of this dimer. The production of this new heterodimer provides a new approach in glutathione S-transferase research to study the influence of one subunit on the catalytic activity of its partner subunit and to identify those amino acid residues which contribute to subunit interactions.

3-Methyleneoxindole: an affinity label of glutathione S-transferase pi which targets tryptophan 38.

The compound 3-methyleneoxindole (MOI), a photooxidation product of the plant auxin indole-3-acetic acid, functions as an affinity label of the dimeric pi class glutathione S-transferase (GST) isolated from pig lung. MOI inactivates the enzyme to a limit of 14% activity. The k for inactivation by MOI is decreased 20-fold by S-hexylglutathione but only 2-fold by S-methylglutathione, suggesting that MOI does not react entirely within the glutathione site. The striking protection against inactivation provided by S-(hydroxyethyl)ethacrynic acid indicates that MOI reacts in the active site region involving both the glutathione and the xenobiotic substrate sites. Incorporation of [(3)H]MOI up to approximately 1 mol/mol of enzyme dimer concomitant with maximum inactivation suggests that there are interactions between subunits. Fractionation of the proteolytic digest of [(3)H]MOI-modified GST pi yielded Trp38 as the only labeled amino acid. The crystal structure of the human GST pi-ethacrynic acid complex (2GSS) shows that the indole of Trp38 is less than 4 A from ethacrynic acid. Similarly, MOI may bind in this substrate site. In contrast to its effect on the pi class GST, MOI inactivates much less rapidly and extensively alpha and mu class GSTs isolated from the rat. These results show that MOI reacts preferentially with GST pi. Such a compound may be useful in novel combination chemotherapy to enhance the efficacy of alkylating cancer drugs while minimizing toxic side effects.

Adenosine 5'-0-[S-(4-succinimidyl-benzophenone)thiophosphate]: a new photoaffinity label of the allosteric ADP site of bovine liver glutamate dehydrogenase.

By reaction of adenosine 5'-monothiophosphate with benzophenone-4-maleimide, we synthesized adenosine 5'-O-[S-(4-succinimidyl-benzophenone)thiophosphate] (AMPS-Succ-BP) as a photoreactive ADP analogue. Bovine liver glutamate dehydrogenase is known to be allosterically activated by ADP, but the ADP site has not been located in the crystal structure of the hexameric enzyme [Peterson, P. E., and Smith, T. J. (1999) Structure 7, 769-782]. In the dark, AMPS-Succ-BP reversibly activates GDH. Irradiation of the complex of glutamate dehydrogenase and AMPS-Succ-BP at lambda >300 nm causes a time-dependent, irreversible 2-fold activation of the enzyme. The k(obs) for photoactivation shows nonlinear dependence on the concentration of AMPS-Succ-BP, with K(R) = 4.9 microM and k(max) = 0.076 min(-)(1). The k(obs) for photoreaction by 20 microM AMPS-Succ-BP is decreased 10-fold by 200 microM ADP, but is reduced less than 2-fold by NAD, NADH, GTP, or alpha-ketoglutarate. Modified enzyme is no longer activated by ADP, but is still inhibited by GTP and high concentrations of NADH. These results indicate that reaction of AMPS-Succ-BP occurs within the ADP site. The enzyme incorporates up to 0.5 mol of [(3)H]AMPS-Succ-BP/mol of enzyme subunit or 3 mol of reagent/mol of hexamer. The peptide Lys(488)-Glu(495) has been identified as the only reaction target, and the data suggest that Arg(491) is the modified amino acid. Arg(491) (in the C-terminal helix close to the GTP #2 binding domain of GDH) is thus considered to be at or near the enzyme's allosteric ADP site. On the basis of these results, the AMPS-Succ-BP was positioned within the crystal structure of glutamate dehydrogenase, where it should also mark the ADP binding site of the enzyme.

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.

A key role in catalysis for His89 of adenylosuccinate lyase of Bacillus subtilis.

Adenylosuccinate lyase of Bacillus subtilis is a tetrameric enzyme which catalyzes the cleavage of adenylosuccinate to AMP and fumarate. We have mutated His(89), one of three conserved histidines, to Gln, Ala, Glu, and Arg. The enzymes were expressed in Escherichia coli and purified to homogeneity. As compared to a specific activity of 1. 56 micromol of adenylosuccinate converted/min/mg protein for wild-type enzyme, the mutant enzymes exhibit specific activities of 0.0225, 0.0036, 0.0036, and 0.0009 for H89Q, H89A, H89E, and H89R, respectively. Circular dichroism and FPLC gel filtration reveal that mutant enzymes have a similar conformation and oligomeric state to that of wild-type enzyme. In H89Q, the K(M) for adenylosuccinate increases slightly to 2.5-fold that of wild-type, the K(M) for fumarate is elevated 3.3-fold, and the K(M) for AMP is 13 times higher than that observed in wild-type enzyme. The catalytic efficiency of the H89Q enzyme is compromised, with k(cat)/K(M) reduced 174-fold in the direction of AMP formation. These data suggest that His(89) plays a role in both the binding of the AMP portion of the substrate and in correctly orienting the substrate for catalysis. Incubation of H89Q with inactive H141Q enzyme [Lee, T. T., Worby, C., Bao, Z.-Q., Dixon, J. E., and Colman, R. F. (1999) Biochemistry 38, 22-32] leads to a 30-fold increase in activity. This intersubunit complementation indicates that His(89) and His(141) from different subunits participate in the active site and that both are required for catalysis.

Inactivation of platelet PDE2 by an affinity label: 8-[(4-bromo-2, 3-dioxobutyl)thio]cAMP.

Cyclic GMP-stimulated cyclic nucleotide phosphodiesterase (PDE2) is the second most abundant of this class of enzymes in platelets. PDE2 probably plays an important role in the regulation of elevated intracellular concentrations of cAMP and cGMP in platelets inhibited by prostacyclin and/or nitric oxide. The cAMP and cGMP PDEs have catalytic domains with 28-40% identity, but vary in their substrate specificity and affinity. As a first step toward the goal of identifying important amino acids in the substrate binding site pocket, we have employed the affinity analog 8-[(4-bromo-2, 3-dioxobutyl)thio]adenosine-3'5' cyclic monophosphate (8-BDB-TcAMP) to inactivate PDE2 and observe the pattern of protection by substrates and their products. Incubation of purified platelet PDE2 with 8-BDB-TcAMP (2-10 mM) resulted in a time-dependent, irreversible inactivation of the enzyme with a second-order rate constant of 0.013 min(-1) mM(-1). Both substrates, cAMP and cGMP, as well as the products of hydrolysis by PDE2, AMP and GMP, exhibited concentration-dependent protection against inhibition by 8-BDB-TcAMP, but no protection was noted with ADP or ATP, which are not hydrolyzed by the enzyme. This compound, 8-BDB-TcAMP, and similar affinity reagents should prove useful in delineating amino acids in the active site of PDE2.

Affinity cleavage at the divalent metal site of porcine NAD-specific isocitrate dehydrogenase.

A divalent metal ion, such as Mn2+, is required for the catalytic reaction and allosteric regulation of pig heart NAD-dependent isocitrate dehydrogenase. The enzyme is irreversibly inactivated and cleaved by Fe2+ in the presence of O2 and ascorbate at pH 7.0. Mn2+ prevents both inactivation and cleavage. Nucleotide ligands, such as NAD, NADPH, and ADP, neither prevent nor promote inactivation or cleavage of the enzyme by Fe2+. The NAD-specific isocitrate dehydrogenase is composed of three distinct subunits in the ratio 2alpha:1beta:1gamma. The results indicate that the oxidative inactivation and cleavage are specific and involve the 40 kDa alpha subunit of the enzyme. A pair of major peptides is generated during Fe2+ inactivation: 29.5 + 10.5 kDa, as determined by SDS-PAGE. Amino-terminal sequencing reveals that these peptides arise by cleavage of the Val262-His263 bond of the alpha subunit. No fragments are produced when enzyme is incubated with Fe2+ and ascorbate under denaturing conditions in the presence of 6 M urea, indicating that the native structure is required for the specific cleavage. These results suggest that His263 of the alpha subunit may be a ligand of the divalent metal ion needed for the reaction catalyzed by isocitrate dehydrogenase. Isocitrate enhances the inactivation of enzyme caused by Fe2+ in the presence of oxygen, but prevents the cleavage, suggesting that inactivation occurs by a different mechanism when metal ion is bound to the enzyme in the presence of isocitrate: oxidation of cysteine may be responsible for the rapid inactivation in this case. Affinity cleavage caused by Fe2+ implicates alpha as the catalytic subunit of the multisubunit porcine NAD-dependent isocitrate dehydrogenase.

Evaluation by site-directed mutagenesis of aspartic acid residues in the metal site of pig heart NADP-dependent isocitrate dehydrogenase.

Pig heart NADP-dependent isocitrate dehydrogenase requires a divalent metal cation for catalysis. On the basis of affinity cleavage studies [Soundar and Colman (1993) J. Biol. Chem. 268, 5267] and analysis of the crystal structure of E. coli NADP-isocitrate dehydrogenase [Hurley et al. (1991) Biochemistry 30, 8671], the residues Asp(253), Asp(273), Asp(275), and Asp(279) were selected as potential ligands of the divalent metal cation in the pig heart enzyme. Using a megaprimer PCR method, the Asp at each of these positions was mutated to Asn. The wild-type and mutant enzymes were expressed in Escherichia coli and purified. D253N has a specific activity, K(m) values for Mn(2+), isocitrate, and NADP, and also a pH-V(max) profile similar to those of the wild-type enzyme. Thus, Asp(253) is not involved in enzyme function. D273N has an increased K(m) for Mn(2+) and isocitrate with a specific activity 5% that of wild type. The D273N mutation also prevents the oxidative metal cleavage seen with Fe(2+) alone in the wild-type enzyme. As compared to wild type, D275N has greatly increased K(m) values for Mn(2+) and isocitrate, with a specific activity <0.1% that of wild type, and a large increase in pK(a) for the enzyme-substrate complex. D279N has only small increases in K(m) for Mn(2+) and isocitrate, but a specific activity <0.1% that of wild type and a major change in the shape of its pH-V(max) profile. These results suggest that Asp(273) and Asp(275) contribute to metal binding, whereas Asp(279), as well as Asp(275), is critical for catalysis. Asp(279) may function as the catalytic base. Using the Modeler program of Insight II, a structure for porcine NADP-isocitrate dehydrogenase was built based on the X-ray coordinates of the E. coli enzyme, allowing visualization of the metal-isocitrate site.

Probing subunit interactions in alpha class rat liver glutathione S-transferase with the photoaffinity label glutathionyl S-[4-(succinimidyl)benzophenone].

Glutathionyl S-[4-(succinimidyl)benzophenone] (GS-Succ-BP), an analogue of the product of glutathione and electrophilic substrate, acts as a photoaffinity label of dimeric rat liver glutathione S-transferase (GST), isoenzyme 1-1. A time-dependent loss of enzyme activity is observed upon irradiation of the enzyme with long wavelength UV light in the presence of the reagent. The initial rate of inactivation exhibits nonlinear dependence on the concentration of the reagent, characterized by an apparent dissociation constant of the enzyme-reagent complex (K(R)) of 99 +/- 2 microM and k(max) of 0.082 +/- 0.005 min(-1). Protection against this inactivation is provided by the electrophilic substrate (ethacrynic acid), electrophilic substrate analogue (dinitrophenol), and product analogues (S-hexylglutathione and p-nitrobenzylglutathione) but not by steroids (Delta(5)-androstene-3,17-dione and 17beta-estradiol-3, 17-disulfate). These results suggest that GS-Succ-BP binds and reacts with the enzyme within the xenobiotic substrate binding site, and this reaction site is distinct from the substrate and nonsubstrate steroid binding sites of the enzyme. About 1 mol of reagent is incorporated into 1 mol of enzyme dimer when the enzyme is completely inactivated. Met-208 is the only amino acid target of the reagent, and modification of this residue in one enzyme subunit of the GST 1-1 dimer completely abolishes the enzyme activity of both subunits. In order to evaluate the role of subunit interactions in the Alpha class glutathione S-transferases, inactive GS-Succ-BP-modified GST 1-1 was mixed with unlabeled, active GST 2-2. The enzyme subunits were dissociated in dilute trifluoroacetic acid and then renatured at pH 7.8 and separated by chromatofocusing into GST 1-1, 1-2, and 2-2. The specific activities of the heterodimer toward several substrates indicate that the loss of catalytic activity in the unmodified subunit of the modified GST 1-1 is the indirect result of the interaction between the two enzyme subunits and that this subunit interaction is absent in the heterodimer GST 1-2.

Identification by mutagenesis of arginines in the substrate binding site of the porcine NADP-dependent isocitrate dehydrogenase.

Pig heart mitochondrial NADP-dependent isocitrate dehydrogenase is the most extensively studied among the mammalian isocitrate dehydrogenases. The crystal structure of Escherichia coli isocitrate dehydrogenase and sequence alignment of porcine with E. coli isocitrate dehydrogenase suggests that the porcine Arg(101), Arg(110), Arg(120), and Arg(133) are candidates for roles in substrate binding. The four arginines were separately mutated to glutamine using a polymerase chain reaction method. Wild type and mutant enzymes were each expressed in E. coli, isolated as maltose binding fusion proteins, then cleaved with thrombin, and purified to yield homogeneous porcine isocitrate dehydrogenase. The R120Q mutant has a specific activity, as well as K(m) values for isocitrate, Mn(2+), and NADP(+) similar to wild type enzyme, indicating that Arg(120) is not needed for function. The specific activities of R101Q, R110Q, and R133Q are 1.73, 1.30, and 19.7 micromols/min/mg, respectively, as compared with 39.6 units/mg for wild type enzyme. The R110Q and R133Q enzymes exhibit K(m) values for isocitrate that are increased more than 400- and 165-fold, respectively, as compared with wild type. The K(m) values for Mn(2+), but not for NADP(+), are also elevated indicating that binding of the metal-isocitrate complex is impaired in these mutants. It is proposed that the positive charges of Arg(110) and Arg(133) normally strengthen the binding of the negatively charged isocitrate by electrostatic attraction. The R101Q mutant shows smaller, but significant increases in the K(m) values for isocitrate and Mn(2+); however, the marked decrease in k(cat) suggests a role for Arg(101) in catalysis. The V(max) of wild type enzyme depends on the ionized form of an enzymic group of pK 5.5, and this pK(aes) is similar for the R101Q and R120Q enzymes. In contrast, the pK(aes) for R110Q and R133Q enzymes increases to 6.4 and 7.4, respectively, indicating that the positive charges of Arg(110) and Arg(133) normally lower the pK of the nearby catalytic base to facilitate its ionization. These results may be understood in terms of the structure of the porcine NADP-specific isocitrate dehydrogenase generated by the Insight II Modeler Program, based on the x-ray coordinates of the E. coli enzyme.

8-(4-Bromo-2,3-dioxobutylthio)guanosine 5'-triphosphate: a new affinity label for purine nucleotide sites in proteins.

A new affinity label, 8-(4-bromo-2,3-dioxobutylthio)guanosine 5'-triphosphate (8-BDB-TGTP), has been synthesized by initial reaction of GTP to form 8-Br-GTP, followed by its conversion to 8-thio-GTP, and finally coupling with 1,4-dibromobutanedione to produce 8-BDB-TGTP. 8-BDB-TGTP and its synthetic intermediates were characterized by thin-layer chromatography, UV, (31)P NMR spectroscopy, as well as by bromide and phosphorus analysis. Escherichia coli adenylosuccinate synthetase is inactivated by 8-BDB-TGTP at pH 7.0 at 25 degrees C. Pretreatment of the enzyme with N-ethylmaleimide (NEM) blocks the exposed Cys(291) and leads to simple pseudo-first-order kinetics of inactivation. The inactivation exhibits a nonlinear relationship of initial inactivation rate versus 8-BDB-TGTP concentration, indicating the reversible association of 8-BDB-TGTP with the enzyme prior to the formation of a covalent bond. The inactivation kinetics exhibit an apparent K(I) of 115 microM and a k(max) of 0.0262 min(-1). Reaction of the NEM-treated adenylosuccinate synthetase with 8-BDB-[(3)H]TGTP results in 1 mol of reagent incorporated/mol of enzyme subunit. Adenylosuccinate or IMP plus GTP completely protects the enzyme against 8-BDB-TGTP inactivation, whereas IMP or GTP alone provide partial protection against inactivation. AMP is much less effective in protection. The results of ligand protection studies suggest that E. coli adenylosuccinate synthetase may accommodate 8-BDB-TGTP as a GTP analog. The new affinity label may be useful for identifying catalytic amino acid residues of protein proximal to the guanosine ring.

Implication of arginine-131 and arginine-303 in the substrate site of adenylosuccinate synthetase of Escherichia coli by affinity labeling with 6-(4-bromo-2,3-dioxobutyl)thioadenosine 5'-monophosphate.

Adenylosuccinate synthetase from Escherichia coli is inactivated in a biphasic reaction by 6-(4-bromo-2,3-dioxobutyl)thioadenosine 5'-monophosphate (6-BDB-TAMP) at pH 7.0 and 25 degrees C. The initial fast-phase inactivation is not affected by the presence of active-site ligands and can be completely eliminated by blocking Cys291 of the enzyme with N-ethylmaleimide (NEM). Reaction of the NEM-treated enzyme with 6-BDB-[32P]TAMP results in 2 mol of reagent incorporated/mol of enzyme subunit. The inactivation kinetics of the slow-phase exhibit an apparent KI of 40.6 microM and kmax of 0.0228 min-1. Active-site ligands, either adenylosuccinate or IMP and GTP, completely prevent inactivation of the enzyme by 6-BDB-TAMP, whereas IMP or IMP and aspartate is much less effective in protection. 6-BDB-TAMP-inactivated enzyme has a 3-fold increase in Km for aspartate with no change in Km for IMP or GTP. Protease digestion of 6-BDB-[32P]TAMP inactivated enzyme reveals that both Arg131 and Arg303 are modified by the affinity-labeling reagent. The crystal structure [Poland, B. W., Fromm, H. J., and Honzatko, R. B. (1996) J. Mol. Biol. 264, 1013-1027] and site-directed mutagenesis [Kang, C., Sun, N., Poland, B. W., Gorrell, A., and Fromm, H. J. (1997) J. Biol. Chem. 272, 11881-11885] of E. coli adenylosuccinate synthetase show that Arg303 interacts with the carboxyl group of aspartate and the 2'-OH of the ribose of IMP and Arg131 is involved in stabilizing aspartate in the active site of the enzyme. We conclude that 6-BDB-TAMP functions as a reactive adenylosuccinate analogue in modifying both Arg131 and Arg303 in the active site of adenylosuccinate synthetase.

Affinity labeling of pig lung glutathione S-transferase pi by 4-(fluorosulfonyl)benzoic acid.

The compound 4-(fluorosulfonyl)benzoic acid (4-FSB) functions as an affinity label of the dimeric pig lung pi class glutathione S-transferase yielding a completely inactive enzyme. Protection against inactivation is provided by glutathione-based ligands, suggesting that the reaction target is near or part of the glutathione binding site. Radioactive 4-FSB is incorporated to the extent of 1 mol per mole of enzyme subunit. Peptide mapping revealed that 4-FSB reacts with two tyrosine residues in the ratio 69% Tyr7 and 31% Tyr106. The ratio is not changed by the addition of ligands. The results suggest that only one of the tyrosine residues can be labeled in the active site of a given subunit; i.e., reactions with Tyr7 and Tyr106 are mutually exclusive. We propose that the difference in labeling of these tyrosine residues is related to their pKa values, with Tyr7 exhibiting the lower pKa. The modified enzyme no longer binds to a S-hexylglutathione-agarose affinity column, even when only one of the active sites contains 4-FSB; these results may reflect interaction between the subunits. We conclude that Tyr7 and Tyr106 of the pig lung class pi glutathione S-transferase are important for function and are located at or close to the substrate binding site of the enzyme.

His68 and His141 are critical contributors to the intersubunit catalytic site of adenylosuccinate lyase of Bacillus subtilis.

Mutant adenylosuccinate lyases of Bacillus subtilis were prepared by site-directed mutagenesis with replacements for His141, previously identified by affinity labeling as being in the active site [Lee, T. T., Worby, C., Dixon, J. E., and Colman, R. F. (1997) J. Biol. Chem. 272, 458-465]. Four substitutions (A, L, E, Q) yield mutant enzyme with no detectable catalytic activity, while the H141R mutant is about 10(-)5 as active as the wild-type enzyme. Kinetic studies show, for the H141R enzyme, a Km that is only 3 times that of the wild-type enzyme. Minimal activity was also observed for mutant enzymes with replacements for His68 [Lee, T. T., Worby, C., Bao, Z. -Q., Dixon, J. E., and Colman, R. F. (1998) Biochemistry 37, 8481-8489]. Measurement of the reversible binding of radioactive adenylosuccinate by inactive mutant enzymes with substitutions at either position 68 or 141 shows that their affinities for substrate are decreased by only 10-40-fold. These results suggest that His141, like His68, plays an important role in catalysis, but not in substrate binding. Evidence is consistent with the hypothesis that His141 and His68 function, respectively, as the catalytic base and acid. Circular dichroism spectroscopy and gel filtration chromatography conducted on wild-type and all His141 and His68 mutants reveal that none of the mutant enzymes exhibits major structural changes and that all the enzymes are tetramers. Mixing inactive His141 with inactive His68 mutant enzymes leads to striking increases in catalytic activity. This complementation of mutant enzymes indicates that His141 and His68 come from different subunits to form the active site. A tetrameric structure of adenylosuccinate lyase was constructed by homology modeling based on the known structures in the fumarase superfamily, including argininosuccinate lyase, delta-crystallin, fumarase, and aspartase. The model suggests that each active site is constituted by residues from three subunits, and that His141 and His68 come from two different subunits.

Photoaffinity labeling of rat liver glutathione S-transferase, 4-4, by glutathionyl S-[4-(succinimidyl)-benzophenone].

Glutathionyl S-[4-(succinimidyl)benzophenone] (GS-Succ-BP), an analogue of the product of glutathione and xenobiotic substrate, was synthesized and shown to act as a photoaffinity label of rat liver glutathione S-transferase, 4-4. A time-dependent photoinactivation occurs upon irradiation at long wavelength UV light of the complex of enzyme and GS-Succ-BP. The rate of inactivation exhibits nonlinear dependence on [GS-Succ-BP], characterized by an apparent KI of 115 microM and kmax of 0.469 min-1. Effective protection against photoinactivation by 150 microM GS-Succ-BP is provided by dinitrophenol, nitrobenzene, ethacrynic acid, and S-hexylglutathione, analogues of xenobiotic substrates and product. These results suggest that GS-Succ-BP reacts with the enzyme within the active site, probably in the xenobiotic substrate-binding site. Upon complete inactivation, reagent incorporation of about 1 mol/mol of enzyme dimer is measured by radioactivity and MALDI-TOF mass spectrometry. Isolation of modified peptides followed by gas-phase sequencing and mass spectrometry indicates that Met-112 is the only reaction target of GS-Succ-BP. Although only one subunit of the enzyme dimer is modified, catalytic activity of both subunits is lost. Molecular modeling suggests that the benzophenone moiety of the compound binds in the cleft between the two enzyme subunits and modification of Met-112 on one subunit excludes reaction of the corresponding methionine on the other subunit. It is proposed that the new compound, glutathionyl S-[4-(succinimidyl)benzophenone], may have general applicability as a photoaffinity label of other enzymes with glutathione binding sites.

Implication of His68 in the substrate site of Bacillus subtilis adenylosuccinate lyase by mutagenesis and affinity labeling with 2-[(4-bromo-2,3-dioxobutyl)thio]adenosine 5'-monophosphate.

Adenylosuccinate lyase of Bacillus subtilis is inactivated by 2-[(4-bromo-2,3-dioxobutyl)thio]adenosine 5'-monophosphate (2-BDB-TAMP) at pH 7.0. As the reagent concentration is increased, a maximum rate constant is approached, indicative of reversible enzyme-reagent complex formation (KR = 68 +/- 9 microM) prior to irreversible modification (kmax = 0.081 +/- 0.004 min-1). Complete inactivation occurs concomitant with about 1 mol of 2-BDB-[14C]TAMP incorporated/mol of enzyme subunit. Adenylosuccinate, or a combination of AMP and fumarate, decreases the inactivation rate and reduces incorporation of [14C] reagent, whereas either AMP or fumarate alone is much less effective. These observations suggest that 2-BDB-TAMP attacks the adenylosuccinate binding site. Proteolytic digestion of inactivated enzyme, followed by purification of the digest by HPLC, yields the radioactive peptide Ile62-Ala72, in which Arg67 and His68 are the most likely targets. Thus 2-BDB-TAMP reacts with adenylosuccinate lyase at a site distinct from the His141 attacked by 6-BDB-TAMP (Lee, Worby, Dixon, and Colman (1997) J. Biol. Chem. 272, 458-465). Site-directed mutagenesis was used to construct mutant enzymes with replacements for both Arg67 and His68, and either Arg67 or His68. The R67M mutant enzyme has almost the same specific activity as the wild-type enzyme under standard assay conditions, whereas the single mutant H68Q and double mutant R67M-H68Q enzymes exhibit specific activities that are decreased more than 100-fold. These results indicate that while Arg67 and His68 may both be in the region of the substrate site, only His68 is important for the catalytic activity of B. subtilis adenylosuccinate lyase. A role is proposed for His68 as a general acid-base catalyst.

Identification of the subunit and important target peptides of pig heart NAD-dependent isocitrate dehydrogenase modified by the affinity label adenosine 5'-O-[S-(4-bromo-2, 3-dioxobutyl)thiophosphate].

Pig heart NAD-dependent isocitrate dehydrogenase is inactivated by adenosine 5'-O-[S-(4-bromo-2,3-dioxobutyl)thiophosphate] (AMPS-BDB) with incorporation of 1.78 mol of reagent/mol of average subunit. Complete protection against the inactivation is provided by 20 mM isocitrate + 1 mM Mn2+, and the incorporation is decreased to about 1.3 mol of reagent/mol of average subunit. The addition of NAD, NADH, or Mn2+ alone has little effect on the functional changes produced by AMPS-BDB, while ADP gives only partial protection against the inactivation. The ability of ADP to decrease the Km for isocitrate is not affected by the AMPS-BDB modification of the enzyme. These results indicate that the isocitrate substrate site is the target of AMPS-BDB. The enzyme has three types of subunits with a tetramer having the composition alpha2 beta gamma. Here, [2-3H]AMPS-BDB-modified subunits are separated by HPLC on a C4 reverse-phase column, after the treatment of the modified enzyme with 4 M urea. The predominant radioactivity is distributed in alpha and gamma subunits. However, evidence based on recombination of subunits from modified and unmodified enzymes indicates that only labeling of the alpha subunit is responsible for inactivation by AMPS-BDB. Subsequently, the separated modified subunits were chemically cleaved by CNBr and then purified by HPLC using a C18 column. The labeled peptides were further digested by pepsin, purified by HPLC, and sequenced. These results indicate that R88 and R98 from the alpha subunit are the major targets of AMPS-BDB which cause inactivation and that these are at or near the isocitrate site of the enzyme.

Identification of the subunits and target peptides of pig heart NAD-specific isocitrate dehydrogenase modified by the affinity label 8-(4-bromo-2,3-dioxobutylthio)NAD.

Pig heart NAD-dependent isocitrate dehydrogenase reacts with 8-(4-bromo-2,3-dioxobutylthio)-NAD (8-BDB-TNAD) with incorporation of 1.21 mol of reagent/mol of average subunit when the enzyme reaches the limit of 25% residual activity (Kumar, A., and Colman, R. F., Arch. Biochem. Biophys. 308, 357-366, 1994). Inclusion of NADPH decreases both the extent of inactivation and the reagent incorporation to 0.55 mol/mol of average subunit. We have now isolated the peptides labeled by radioactive 8-(4-bromo-2,3-dioxobutylthio)-[2-3H]NAD and have located them within the sequence of pig heart NAD-dependent isocitrate dehydrogenase. The enzyme is composed of three types of subunits, present as alpha 2 beta gamma. We have separated the subunits from unmodified and 8-BDBT[2-3H]NAD-modified enzymes by HPLC on a C4 reverse-phase column, after pretreatment of the enzymes with sodium dodecyl sulfate or urea, and compared the subunit sequences of the porcine enzyme with those of the corresponding subunits from other mammalian NAD-dependent isocitrate dehydrogenases. The predominant radioactivity of 8-BDBT[2-3H]NAD is observed in the alpha and gamma peaks, and the NADPH-protected enzyme exhibits marked reduction in incorporation into these peaks. However, evidence based on recombination of subunits from modified and unmodified enzymes indicates that only labeling of the alpha-subunit is responsible for inactivation by 8-BDB-TNAD. Cyanogen bromide was used to cleave the modified enzyme, and we purified one labeled peptide from the alpha-subunit (amino acids 84-177) as well as one from the gamma-subunit (amino acids 67-186). In the alpha-subunit, decreased modification by [7-14C]-phenylglyoxal of Arg88 and Arg98 after prior labeling of the enzyme by 8-BDB-TNAD indicates that these residues are the critical target sites of the reactive nucleotide analogue. We conclude that alpha subunit's Arg88 and Arg98 are both at or near the allosteric NADPH sites of the pig heart isocitrate dehydrogenase.

Identification of the nonsubstrate steroid binding site of rat liver glutathione S-transferase, isozyme 1-1, by the steroid affinity label, 3beta-(iodoacetoxy)dehydroisoandrosterone.

3beta-(Iodoacetoxy)dehydroisoandrosterone (3beta-IDA), an analogue of the electrophilic substrate, Delta5-androstene-3,17-dione, as well as an analogue of several other steroid inhibitors of glutathione S-transferase, was tested as an affinity label of rat liver glutathione S-transferase, isozyme 1-1. A time-dependent loss of enzyme activity is observed upon incubation of 3beta-IDA with the enzyme. The rate of enzyme inactivation exhibits a nonlinear dependence on 3beta-IDA concentration, yielding an apparent Ki of 21 microM. Upon complete inactivation of the enzyme, a reagent incorporation of approximately 1 mol/mol of enzyme subunit or 2 mol/mol of enzyme dimer is observed. Protection against inactivation and incorporation is afforded by alkyl glutathione derivatives and nonsubstrate steroid ligands such as 17beta-estradiol-3,17-disulfate but, surprisingly, not by Delta5-androstene-3,17-dione or any other electrophilic substrate analogues tested. These results suggest that the site of reaction is within the nonsubstrate steroid binding site of the enzyme, which is distinguishable from the electrophilic substrate binding site, near the active site of the enzyme. Two cysteine residues, Cys17 and Cys111, are modified in nearly equal amounts, despite an average reagent incorporation of 1 mol/mol enzyme subunit. Isolation of enzyme subunits indicates the presence of unmodified, singly labeled, and doubly labeled subunits, consistent with mutually exclusive modification of cysteine residues across enzyme subunits; i.e., modification of Cys111 on subunit A prevents modification of Cys111 on subunit B and similarly for Cys17. Molecular modeling analysis suggests that Cys17 and Cys111 are located in the nonsubstrate steroid binding site, within the cleft between the subunits of the dimeric enzyme.

Modulation of platelet responses by 2-[3-(bromo-2-oxopropylthio)]adenosine-5'-diphosphate involves its binding to as well as covalent modification of an ADP-receptor, aggregin.

The 2-substituted ADP derivatives are known to activate human blood platelets with varying degrees of potency. For example, 2-(4-bromo-2,3-dioxobutylthio)adenosine-5'-diphosphate [2-BDB-TADP], an ADP-affinity analog, was previously shown by us to be 50% as potent as ADP in inducing human blood platelet responses [Puri, R. N., Colman, R. F., and Colman, R. W. (1996) Eur. J. Biochem. 236, 862-870]. 2-Methylthio-ADP (2-MeS-ADP) has been known to be a far more potent agonist than ADP. However, the molecular basis for defining the rank order of potency of the 2-substituted ADP derivatives as agonists of platelet responses have been incompletely understood. We now report that 2-BOP-TADP (a one carbon atom lower homolog of 2-BDB-TADP) at equimolar concentration is as potent as ADP in inducing platelet responses. Prolonged incubation of platelets with 2-BOP-TADP abolished its ability to elicit cellular responses. An autoradiogram of the gel obtained by sodium dodecyl sulfate-polyacrylamide gel electrophoresis of solubilized platelets labeled by incubating the platelets with 2-BOP-TADP for 1 h followed by reduction by NaB[3H]4 showed the presence of a single covalently radiolabeled protein band at 100 kDa. Preincubation of platelets with either ADP or ATP reduced the intensity of the band corresponding to the 100-kDa protein radiolabeled by 2-BOP-TADP and NaB[3H]4. The results show that (i) 2-BOP-TADP modulates ADP-induced platelet responses by interacting with aggregin and (ii) 2-BOP-TADP was twice as potent as 2-BDB-TADP, and (iii) the chain length of the substituent in a homologous series has an important bearing on the potency of a 2-substituted ADP analog.