Purification and characterization of the first archaeal aconitase from the thermoacidophilic Sulfolobus acidocaldarius.

The first archaeal aconitase was isolated from the cytosol of the thermoacidophilic Sulfolobus acidocaldarius. Interestingly, the enzyme was copurified with an isocitrate lyase. This enzyme, directly converting isocitrate, the reaction product of the aconitase reaction, was also unknown in crenarchaeota, thus far. Both proteins could only be separated by SDS gel electrophoresis yielding apparent molecular masses of 96 kDa for the aconitase and 46 kDa for the isocitrate lyase. Despite of its high oxygen sensitivity, the aconitase could be enriched 27-fold to a specific activity of approximately 55 micromol x min(-1) x mg(-1), based on the direct aconitase assay system. Maximal enzyme activities were measured at pH 7.4 and the temperature optimum for the archaeal enzyme was recorded at 75 degrees C, slightly under the growth optimum of S. acidocaldarius around 80 degrees C. Thermal inactivation studies of the aconitase revealed the enzymatic activity to be uninfluenced after one hour incubation at 80 degrees C. Even at 95 degrees C, a half-life of approximately 14 min was determined, clearly defining it as a thermostable protein. The apparent K(m) values for the three substrates cis-aconitate, citrate and isocitrate were found as 108 microM, 2.9 mM and 370 microM, respectively. The aconitase reaction was inhibited by the typical inhibitors fluorocitrate, trans-aconitate and tricarballylate. Amino-acid sequencing of three internal peptides of the S. acidocaldarius aconitase revealed the presence of highly conserved residues in the archaeal enzyme. By amino-acid sequence alignments, the S. acidocaldarius sequence was found to be highly homologous to either other putative archaeal or known eukaryal and bacterial sequences. As shown by EPR-spectroscopy, the enzyme hosts an interconvertible [3Fe--4S] cluster.     

Binding of cytosolic aconitase to the iron responsive element of porcine mitochondrial aconitase mRNA.

The 5' end of porcine mitochondrial aconitase mRNA contains an iron responsive element (IRE)-like secondary structure (T. Dandekar, R. Stripecke, N. K. Gray, B. Goosen, A. Constable, H. E. Johansson, and M. W. Hentze (1991) EMBO J. 10, 1903-1909). A protein from a liver extract binds to a mitochondrial aconitase RNA probe and supports the identification of this sequence as an IRE. Purified cytosolic aconitase but not the mitochondrial enzyme binds to this IRE as well as to a ferritin IRE. All forms of cytosolic aconitase, [4Fe-4S] enzyme, [3Fe-4S] enzyme and apoenzyme bind with similar affinity. A Kd of 0.25 nM was calculated for the apoaconitase-IRE interaction from Scatchard analysis. These results support the conclusion that cytosolic aconitase is an IRE-binding protein which may regulate translation of mitochondrial aconitase mRNA.     

Redox-dependent modulation of aconitase activity in intact mitochondria

It has previously been reported that exposure of purified mitochondrial or cytoplasmic aconitase to superoxide (O(2)(-)(*) or hydrogen peroxide (H(2)O(2)) leads to release of the Fe-alpha from the enzyme's [4Fe-4S](2+) cluster and to inactivation. Nevertheless, little is known regarding the response of aconitase to pro-oxidants within intact mitochondria. In the present study, we provide evidence that aconitase is rapidly inactivated and subsequently reactivated when isolated cardiac mitochondria are treated with H(2)O(2). Reactivation of the enzyme is dependent on the presence of the enzyme's substrate, citrate. EPR spectroscopic analysis indicates that enzyme inactivation precedes release of the labile Fe-alpha from the enzyme's [4Fe-4S](2+) cluster. In addition, as judged by isoelectric focusing gel electrophoresis, the relative level of Fe-alpha release and cluster disassembly does not reflect the magnitude of enzyme inactivation. These observations suggest that some form of posttranslational modification of aconitase other than release of iron is responsible for enzyme inactivation. In support of this conclusion, H(2)O(2) does not exert its inhibitory effects by acting directly on the enzyme, rather inactivation appears to result from interaction(s) between aconitase and a mitochondrial membrane component responsive to H(2)O(2). Nevertheless, prolonged exposure of mitochondria to steady-state levels of H(2)O(2) or O(2)(-)(*) results in disassembly of the [4Fe-4S](2+) cluster, carbonylation, and protein degradation. Thus, depending on the pro-oxidant species, the level and duration of the oxidative stress, and the metabolic state of the mitochondria, aconitase may undergo reversible modulation in activity or progress to [4Fe-4S](2+) cluster disassembly and proteolytic degradation.     

Evidence for the formation of a linear [3Fe-4S] cluster in partially unfolded aconitase

Beef heart aconitase, as isolated under aerobic conditions, is inactive and contains a [3Fe-4S]1+ cluster. On incubation at pH greater than 9.5 (or treatment with 4-8 M urea) the color of the protein changes from brown to purple. This purple form is stable and can be converted back in good yield to the active [4Fe-4S]2+ form by reduction in the presence of iron. Active aconitase is converted to the purple form at alkaline pH only after oxidative inactivation. The Fe/S2- ratio of purple aconitase is 0.8, indicating the presence of [3Fe-4S] clusters. The number of SH groups readily reacting with 5,5'-dithiobis(2-nitrobenzoic acid) is increased from approximately 1 in the enzyme as isolated to 7-8 in the purple form, indicating a partial unfolding of the protein. On conversion of inactive aconitase to the purple form, the EPR signal at g = 2.01 (S = 1/2) is replaced by signals at g = 4.3 and 9.6 (S = 5/2). M?ssbauer spectroscopy shows that purple aconitase has high-spin ferric ions, each residing in a tetrahedral environment of sulfur atoms. The three iron sites are exchange-coupled to yield a ground state with S = 5/2. Analysis of the data within a spin coupling model shows that J13 congruent to J23 and 2 J12 less than J13, where the Jik describe the antiferromagnetic (J greater than 0) exchange interactions among the three iron pairs. Comparison of our data with those reported for synthetic Fe-S clusters (Hagen, K. S., Watson, A. D., and Holm, R. H., (1983) J. Am. Chem. Soc. 105, 3905-3913) shows that purple aconitase contains a linear [3Fe-4S]1+ cluster, a structural isomer of the S = 1/2 cluster of inactive aconitase. Our studies also show that protein-bound [2Fe-2S] clusters can be generated under conditions where partial unfolding of the protein occurs.     

Properties of pig heart aconitase

Comparison of pig heart aconitase (Kennedy et al., 1972) with yeast (Candida lipolytica) aconitase (Suzuki et al., 1973) reveals similarities in molecular weight and iron content but not in sulphide content. Comparison with the Mildvan & Villafranca (1971) pig heart aconitase preparation reveals differences in iron ligands, specific activity and other properties; these differences possibly arise from protein association as pig heart protein associates under a variety of conditions. The electron spin resonance spectrum, g 4.25, and the low molar relaxivity, 473m⁻¹·s⁻¹, of water H⁺ suggest the presence of high-spin Fe(III) unco-ordinated to water in the enzyme. The iron chromophore on acid titration at 320nm gives a curve with an inflexion at pH4.2. Ten of 16 expected thiol equivalents are titrated with p-hydroxymercuribenzoate suggesting the presence of cystine as well as cysteine residues. Inhibition of the activation of inactive (activatable) enzyme is sigmoidally related to the molar ratio, p-hydroxymercuribenzoate/enzyme with 10–11mol of mercurial compound causing complete inhibition. Active enzyme, free from activating reagents, requires high molar ratios of mercurial compound for rapid inhibition. In terms of p-hydroxymercuribenzoate the enzyme then lacks an essential thiol group.     

Optical and EPR characterization of different species of active and inactive aconitase

It has been shown by spectroscopic (Kent, T. A., Dreyer, J-L., Kennedy, M.C., Huynh, B.H., Emptage, M.H., Beinert, H., and Münck, E. (1982) Proc. Natl. Acad. Sci. U.S.A. 79, 1096-1100) and chemical (Kennedy, M.C., Emptage, M.H., Dryer, J-L., and Beinert, H. (1983) J. Biol. Chem. 258, 11098-11105) methods that interconversion of [3Fe-4S] and [4Fe-4S] clusters underlies activation and inactivation of aconitase. Since Fe-S clusters can assume different oxidation states, a number of different species of the enzyme can be expected to exist. Observations on activation-inactivation, as well as light absorption and EPR spectra, can be interpreted in terms of four species: [3Fe-4S]1+, the oxidized inactive enzyme as obtained on aerobic preparation from mitochondria; [3Fe-4S]0, the reduced inactive form as obtained on reduction in the presence of EDTA; [4Fe-4S]2+, the oxidized active form as obtained on reductive activation; and [4Fe-4S]1+, the reduced active form prepared by photoreduction of active aconitase. The light absorption spectra of each species are presented. Oxidized inactive aconitase shows EPR spectra typical of oxidized 3Fe clusters (g = 2.01), and reduced active enzyme shows spectra typical of reduced ferredoxins (g1,2,3 = 2.06, 1.93, 1.86). The EPR spectrum of the latter is drastically changed (g1,2,3 = 2.04, 1.85, 1.78) on addition of substrate. The active enzyme can be quantitatively converted to inactive enzyme by titration with ferricyanide in the presence of substrate. The correlation of EPR and optical spectra with enzymatic activity observed during titration demonstrates further that active aconitase requires an intact [4Fe-4S] cluster. A model of aconitase incorporating the four cluster species is presented, and explanations for some previous conflicting data concerning aconitase are offered.     

The soluble "high potential" type iron-sulfur protein from mitochondria is aconitase.

Properties of soluble high potential type iron-sulfur protein (HiPIP) from beef heart mitochondria were compared to those of aconitase from pig heart. The two proteins when purified to homogeneity by the criteria of sodium dodecyl sulfate (SDS)-polyacrylamide electrophoresis show identical light absorption characteristics. EPR signals of the HiPIP type centered at g = 2.01 when oxidized, isoelectric points at pH 8.5 to 8.6, are inseparable by SDS-polyacrylamide electrophoresis, and exhibit aconitase activity when activated by reducing agents in the presence of ferrous iron. The requirement for activation goes parallel to the intensity of the signal from the oxidized iron-sulfur cluster, i.e. the cluster is reduced in the active enzyme. We conclude that the soluble mitochondrial HiPIP is identical with aconitase. The relationships of iron to labile sulfide, molecular weight and unpaired spins in the EPR signal, and implications of our findings for the role of iron in aconitase are discussed.     

Mitochondrial aconitase reaction with nitric oxide, S-nitrosoglutathione, and peroxynitrite: mechanisms and relative contributions to aconitase inactivation

Using highly purified recombinant mitochondrial aconitase, we determined the kinetics and mechanisms of inactivation mediated by nitric oxide (*NO), nitrosoglutathione (GSNO), and peroxynitrite (ONOO(-)). High *NO concentrations are required to inhibit resting aconitase. Brief *NO exposures led to a reversible inhibition competitive with isocitrate (K(I)=35 microM). Subsequently, an irreversible inactivation (0.65 M(-1) s(-1)) was observed. Irreversible inactivation was mediated by GSNO also, both in the absence and in the presence of substrates (0.23 M(-1) s(-1)). Peroxynitrite reacted with the [4Fe-4S] cluster, yielding the inactive [3Fe-4S] enzyme (1.1 x 10(5) M(-1) s(-1)). Carbon dioxide enhanced ONOO(-)-dependent inactivation via reaction of CO(3)*(-) with the [4Fe-4S] cluster (3 x 10(8) M(-1) s(-1)). Peroxynitrite also induced m-aconitase tyrosine nitration but this reaction did not contribute to enzyme inactivation. Computational modeling of aconitase inactivation by O(2)*(-) and *NO revealed that, when NO is produced and readily consumed, measuring the amount of active aconitase remains a sensitive method to detect variations in O(2)*(-) production in cells but, when cells are exposed to high concentrations of NO, aconitase inactivation does not exclusively reflect changes in rates of O(2)*(-) production. In the latter case, extents of aconitase inactivation reflect the formation of secondary reactive species, specifically ONOO(-) and CO(3)*(-), which also mediate m-aconitase tyrosine nitration, a footprint of reactive *NO-derived species.     

Oxidation of propionate to pyruvate in Escherichia coli. Involvement of methylcitrate dehydratase and aconitase.

The pathway of the oxidation of propionate to pyruvate in Escherichia coli involves five enzymes, only two of which, methylcitrate synthase and 2-methylisocitrate lyase, have been thoroughly characterized. Here we report that the isomerization of (2S,3S)-methylcitrate to (2R,3S)-2-methylisocitrate requires a novel enzyme, methylcitrate dehydratase (PrpD), and the well-known enzyme, aconitase (AcnB), of the tricarboxylic acid cycle. AcnB was purified as 2-methylaconitate hydratase from E. coli cells grown on propionate and identified by its N-terminus. The enzyme has an apparent Km of 210 micro m for (2R,3S)-2-methylisocitrate but shows no activity with (2S,3S)-methylcitrate. On the other hand, PrpD is specific for (2S,3S)-methylcitrate (Km = 440 micro m) and catalyses in addition only the hydration of cis-aconitate at a rate that is five times lower. The product of the dehydration of enzymatically synthesized (2S,3S)-methylcitrate was designated cis-2-methylaconitate because of its ability to form a cyclic anhydride at low pH. Hence, PrpD catalyses an unusual syn elimination, whereas the addition of water to cis-2-methylaconitate occurs in the usual anti manner. The different stereochemistries of the elimination and addition of water may be the reason for the requirement for the novel methylcitrate dehydratase (PrpD), the sequence of which seems not to be related to any other enzyme of known function. Northern-blot experiments showed expression of acnB under all conditions tested, whereas the RNA of enzymes of the prp operon (PrpE, a propionyl-CoA synthetase, and PrpD) was exclusively present during growth on propionate. 2D gel electrophoresis showed the production of all proteins encoded by the prp operon during growth on propionate as sole carbon and energy source, except PrpE, which seems to be replaced by acetyl-CoA synthetase. This is in good agreement with investigations on Salmonella enterica LT2, in which disruption of the prpE gene showed no visible phenotype.     

Studies on two isozymes of aconitase from Bacilluscereus T. II. Further evidence on two distinct activities

In our previous communication, we had reported the existence of an early and a late aconitase in $\text{Bacillus}\text{cereus}$ T, active during 5 and 12 hr age of culture, respectively. This report was based on their partial purification and stability pattern studies. Present investigations deal with their specific separation by DEAE-cellulose column chromatography, polyacrylamide gel electrophoresis and Sephadex G-100 gel column chromatography, both individually and in mixture. On DEAE-cellulose column chromatography, early and late aconitase (EC.4.2.1.3) are eluted at 183 ml (265 mM NaCl concontration) and 160 ml (110 mM NaCl concentration)elution volume indicating former to be more anionic. In contrast to this, on polyacrylamide gel electrophoresis, early aconitase moves slower towards anode as compared to late aconitase, indicating former to be less anionic than later. The discrepancy has been ascribed to the molecular sieving effect of polyacrylamide, since Sephadex G-100 gel column chromatography has suggested the molecular weight of early aconitase (160,000) to be twice that of late aconitase. Our attempts to demonstrate that early aconitase was a dimer could not succeed.     

Enhanced expression of aconitase raises acetic acid resistance in Acetobacter aceti

Acetobacter spp. are used for industrial vinegar production because of their high ability to oxidize ethanol to acetic acid and high resistance to acetic acid. Two-dimensional gel electrophoretic analysis of a soluble fraction of Acetobacter aceti revealed the presence of several proteins whose production was enhanced, to various extents, in response to acetic acid in the medium. A protein with an apparent molecular mass of 100 kDa was significantly enhanced in amount by acetic acid and identified to be aconitase by NH2-terminal amino acid sequencing and subsequent gene cloning. Amplification of the aconitase gene by use of a multicopy plasmid in A. aceti enhanced the enzymatic activity and acetic acid resistance. These results showed that aconitase is concerned with acetic acid resistance. Enhancement of the aconitase activity turned out to be practically useful for acetic acid fermentation, because the A. aceti transformant harboring multiple copies of the aconitase gene produced a higher concentration of acetic acid with a reduced growth lag-time.     

Electrophoretic variation of aconitase and phosphoglucomutase detected in Microtus californicus.

Four electrophoretic variants of cytoplasmic aconitase (citrate (isocitrate) hydro-lyase, EC 4.2.1.3) were detected in a population of Microtus californicus when samples were screened by starch gel electrophoresis using Tris/citrate buffers at pH 7.0 and pH 8.7. Variation at what is presumed to be the phosphoglucomutase-3 locus (alpha-D-glucose-1,6-diphosphate:alpha-D-glucose-1-phosphate phosphotransferase, EC 2.7.5.1) was also detected with liver samples but was not detected in kidney samples or red blood cells lysates. This nongenetic variation is due to oxidation of free sulfhydryl groups.     

Studies on two isozymes of aconitase from Bacillus cereus T. III. Enzymatic properties.

The present communication describes a comparative study of some enzymatic properties of an early and a late aconitase (EC.4.2.1.3) present in $\text{Bacillus}\text{cereus}$ T cells of 5 and 12 hr culture age, respectively. The activity of both enzymes increased linearly with increase in enzyme concentration. They demonstrated similar pH *7.5) and temperature (30 C) optima, but differed in their activation energy and affinity for substrate. Late aconitase had higher activation energy (16,100 cal) as compared to early aconitase (9,200 cal). Early aconitase showed a Km value of 100 × 10^?4M for sodium citrate and 33.3 × 10^?4M for isocitrate. Late aconitase exhibited 5 to 7 times greater affinity for citrate and isocitrate yielding Km values 14 × 10^?4M and 7 × 10^?4M, respectively. On the basis of available evidence, it is suggested that early and late aconitase present in 5 and 12 hr aged cells of $\text{Bacillus}\text{cereus}$ T behave as isozymes, and may be designated as aconitase (EC.4.2.1.3) isozyme I and aconitase (EC.4.2.1.3) isozyme II, respectively. The significance of their plausible role during growth and sporulation has been discussed.     

Superoxide sensitivity of the Escherichia coli aconitase.

Mutants of Escherichia coli lacking superoxide dismutase (SOD) activity were used to explore the sensitivity of aconitase toward O2 and O2-. The aconitase activity in SOD-free extracts was rapidly lost under aerobic conditions and exogenous SOD afforded a concentration-dependent protection. The rate of the inactivating reaction between O2- and aconitase was estimated to be of the order of 10(9) M-1 s-1. The competitive inhibitors fluorocitrate and tricarballylate provided some protection, and at saturating concentrations, they decreased the rate of the inactivating reaction by 100- and 10-fold, respectively. Aconitase was markedly less sensitive to O2 than it was to O2-. Aerobic growth on succinate involves a greater dependence upon aconitase than does growth on glucose and, as expected, the deleterious consequences of SOD deficiency were more pronounced on succinate than on glucose. Moreover, aconitase activity was lower in extracts of aerobically grown SOD mutants, than it was in the parental strain. We suppose that inactivation of aconitase by O2- involves oxidative attack on the prosthetic iron-sulfur cluster. The extreme sensitivity of aconitase to inactivation by O2- suggests that its inactivation will be an early event in the oxidative stress imposed by hyperoxia, ultraviolet irradiation or redox-cycling agents, such as viologens or quinones.     

The aconitase of Escherichia coli. Nucleotide sequence of the aconitase gene and amino acid sequence similarity with mitochondrial aconitases, the iron-responsive-element-binding protein and isopropylmalate isomerases.

The nucleotide sequence of the aconitase gene (acn) of Escherichia coli was determined and used to deduce the primary structure of the enzyme. The coding region comprises 2670 bp (890 codons excluding the start and stop codons) which define a product having a relative molecular mass of 97,513 and an N-terminal amino acid sequence consistent with those determined previously for the purified enzyme. The acn gene is flanked by the cysB gene and a putative riboflavin biosynthesis gene resembling the ribA gene of Bacillus subtilis. The 1004-bp cysB--acn intergenic region contains several potential promoter and regulatory sequences. The amino acid sequence of the E. coli aconitase is similar to the mitochondrial aconitases (27-29% identity) and the isopropylmalate isomerases (20-21% identity) but it is most similar to the human iron-responsive-element-binding protein (53% identity). The three cysteine residues involved in ligand binding to the [4Fe-4S] centre are conserved in all of these proteins. Of the remaining 17 active-site residues assigned for porcine aconitase, 16 are conserved in both the bacterial aconitase and the iron-responsive-element-binding protein and 14 in the isopropylmalate isomerases. It is concluded that the bacterial and mitochondrial aconitases, the isopropylmalate isomerases and the iron-responsive-element-binding protein form a family of structurally related proteins, which does not include the Fe-S-containing fumarases. These relationships raise the possibility that the iron-responsive-element-binding protein may be a cytoplasmic aconitase and that the E. coli aconitase may have an iron-responsive regulatory function.     

The mechanism of aconitase: 1.8 A resolution crystal structure of the S642a:citrate complex

The crystal structure of the S642A mutant of mitochondrial aconitase (mAc) with citrate bound has been determined at 1.8 A resolution and 100 K to capture this binding mode of substrates to the native enzyme. The 2.0 A resolution, 100 K crystal structure of the S642A mutant with isocitrate binding provides a control, showing that the Ser --> Ala replacement does not alter the binding of substrates in the active site. The aconitase mechanism requires that the intermediate product, cis-aconitate, flip over by 180 degrees about the C alpha-C beta double bond. Only one of these two alternative modes of binding, that of the isocitrate mode, has been previously visualized. Now, however, the structure revealing the citrate mode of binding provides direct support for the proposed enzyme mechanism.     

Crystal structures of aconitase with isocitrate and nitroisocitrate bound.

The crystal structures of mitochondrial aconitase with isocitrate and nitroisocitrate bound have been solved and refined to R factors of 0.179 and 0.161, respectively, for all observed data in the range 8.0-2.1 A. Porcine heart enzyme was used for determining the structure with isocitrate bound. The presence of isocitrate in the crystals was corroborated by M?ssbauer spectroscopy. Bovine heart enzyme was used for determining the structure with the reaction intermediate analogue nitroisocitrate bound. The inhibitor binds to the enzyme in a manner virtually identical to that of isocitrate. Both compounds bind to the unique Fe atom of the [4Fe-4S] cluster via a hydroxyl oxygen and one carboxyl oxygen. A H2O molecule is also bound, making Fe six-coordinate. The unique Fe is pulled away approximately 0.2 A from the corner of the cubane compared to the position it would occupy in a symmetrically ligated [4Fe-4S] cluster. At least 23 residues from all four domains of aconitase contribute to the active site. These residues participate in substrate recognition (Arg447, Arg452, Arg580, Arg644, Gln72, Ser166, Ser643), cluster ligation and interaction (Cys358, Cys421, Cys424, Asn258, Asn446), and hydrogen bonds supporting active site side chains (Ala74, Asp568, Ser571, Thr567). Residues implicated in catalysis are Ser642 and three histidine-carboxylate pairs (Asp100-His101, Asp165-His147, Glu262-His167). The base necessary for proton abstraction from C beta of isocitrate appears to be Ser642; the O gamma atom is proximal to the calculated hydrogen position, while the environment of O gamma suggests stabilization of an alkoxide (an oxyanion hole formed by the amide and side chain of Arg644). The histidine-carboxylate pairs appear to be required for proton transfer reactions involving two oxygens bound to Fe, one derived from solvent (bound H2O) and one derived from substrate hydroxyl. Each oxygen is in contact with a histidine, and both are in contact with the side chain of Asp165, which bridges the two sites on the six-coordinate Fe.     

Sites and mechanisms of aconitase inactivation by peroxynitrite: modulation by citrate and glutathione

Aconitases are iron-sulfur cluster-containing proteins present both in mitochondria and cytosol of cells; the cubane iron-sulfur (Fe-S) cluster in the active site is essential for catalytic activity, but it also renders aconitase highly vulnerable to reactive oxygen and nitrogen species. This study examined the sites and mechanisms of aconitase inactivation by peroxynitrite (ONOO-), a strong oxidant and nitrating agent readily formed from superoxide anion and nitric oxide generated by mitochondria. ONOO- inactivated aconitase in a dose-dependent manner (half-maximal inhibition was observed with approximately 3 microM ONOO-). Low levels of ONOO- caused the conversion of the Fe-S cluster from the [4Fe-4S]2+ form to the inactive [3Fe-4S]1+ form with the loss of labile iron, as confirmed by low-temperature EPR analysis. In the presence of the substrate, citrate, 66-fold higher concentrations of ONOO- were required for half-maximal inhibition. The protective effects of citrate corresponded to its binding to the active site. The inactivation of aconitase in the presence of citrate was due to ONOO--mediated cysteine thiol loss and tyrosine nitration in the enzyme as shown by Western blot analyses. LC/MS/MS analyses revealed that ONOO- treatment to aconitase resulted in nitration of tyrosines 151 and 472 and oxidation to sulfonic acid of cysteines 126 and 385. The latter is one of the three cysteine residues in aconitase that binds to the Fe-S cluster. All other modified tyrosine and cysteine residues were adjacent to the binding site, thus suggesting that these modifications caused conformational changes leading to active-site disruption. Aconitase cysteine thiol modifications other than oxidation to sulfonic acid, such as S-glutathionylation, also decreased aconitase activity, thus indicating that glutathionylation may be an important means of modulating aconitase activity under oxidative and nitrative stress. Taken together, these results demonstrate that the Fe-S cluster in the active site, cysteine 385 bound to the Fe-S cluster, and tyrosine and cysteine residues in the vicinity of the active site are important targets of oxidative and/or nitrative attack, which is selectively controlled by the mitochondrial matrix citrate levels. The mechanisms inherent in aconitase inactivation by ONOO- are discussed in terms of the mitochondrial matrix metabolic and thiol redox state.