1H, 13C and 15N resonance assignments of rhodanese GlpE from Escherichia coli

Rhodanese catalyzes the sulfur-transfer reaction in which a sulfur atom is transferred from thiosulfate to cyanide by a double-displacement mechanism. During the reaction, a persulfide-intermediate form of rhodanese is generated by the reaction of a conserved active cysteine residue with thiosulfate. Escherichia coli GlpE is a prototype for the single-domain rhodanese superfamily. Though there are some studies on rhodaneses, the molecular mechanism of the catalytic activity of rhodaneses is still unclear. Herein, we report the resonance assignments of (1)H, (13)C and (15)N atoms of E. coli GlpE, which provides the basis for further structural, dynamic and functional studies of rhodaneses using NMR technique.     

Fast conformational exchange between the sulfur-free and persulfide-bound rhodanese domain of E. coli YgaP

Rhodanese domains are abundant structural modules that catalyze the transfer of a sulfur atom from thiolsulfates to cyanide via formation of a covalent persulfide intermediate that is bound to an essential conserved cysteine residue. In this study, the three-dimensional structure of the rhodanese domain of YgaP from Escherichia coli was determined using solution NMR. A typical rhodanese domain fold was observed, as expected from the high homology with the catalytic domain of other sulfur transferases. The initial sulfur-transfer step and formation of the rhodanese persulfide intermediate were monitored by addition of sodium thiosulfate using two-dimensional ¹H–¹⁵N correlation spectroscopy. Discrete sharp signals were observed upon substrate addition, indicting fast exchange between sulfur-free and persulfide-intermediate forms. Residues exhibiting pronounced chemical shift changes were mapped to the structure, and included both substrate binding and surrounding residues.     

A study of the apolar interaction of the enzyme rhodanese with octyl substituted agarose gel

The accessibilities of sites on the surface of the enzyme rhodanese for binding to macromolecular apolarity have been measured for the two forms of the enzyme related to obligatory catalytic intermediates: the free enzyme, E and the sulfur substituted enzyme, ES. This study was done using a micromethod developed for this purpose which allows facile assessment of the apolar binding of proteins to commercially available beads of cross-linked agarose on which hydrophobic groups have been immobilized. The results indicate that the enzyme rhodanese can bind to macromolecular apolarity and that there is considerably more binding of the E form than the ES form. The fact that the binding is relatively slow implicates a protein conformational change in the rate limiting binding step. In fact, there is a large increase in the binding when the temperature is raised from 23° to 40° which correlates with previous results showing a conformational change in rhodanese over the same temperature range. These results in comparison with other solution studies and with x-ray studies are consistent with a model for rhodanese which has an apolar active site and a mechanism for catalysis that includes a conformational change.     

The crystal structure of a sulfurtransferase from Azotobacter vinelandii highlights the evolutionary relationship between the rhodanese and phosphatase enzyme families

Rhodanese is an ubiquitous enzyme that in vitro catalyses the transfer of a sulfur atom from suitable donors to nucleophilic acceptors by way of a double displacement mechanism. During the catalytic process the enzyme cycles between a sulfur-free and a persulfide-containing form, via formation of a persulfide linkage to a catalytic Cys residue. In the nitrogen-fixing bacteria Azotobacter vinelandii the rhdA gene has been identified and the encoded protein functionally characterized as a rhodanese. The crystal structure of the A. vinelandii rhodanese has been determined and refined at 1.8 A resolution in the sulfur-free and persulfide-containing forms. Conservation of the overall three-dimensional fold of bovine rhodanese is observed, with substantial modifications of the protein structure in the proximity of the catalytic residue Cys230. Remarkably, the native enzyme is found as the Cys230-persulfide form; in the sulfur-free state the catalytic Cys residue adopts two alternate conformations, reflected by perturbation of the neighboring active-site residues, which is associated with a partly reversible loss of thiosulfate:cyanide sulfurtransferase activity. The catalytic mechanism of A. vinelandii rhodanese relies primarily on the main-chain conformation of the 230 to 235 active-site loop and on a surrounding strong positive electrostatic field. Substrate recognition is based on residues which are entirely different in the prokaryotic and eukaryotic enzymes. The active-site loop of A. vinelandii rhodanese displays striking structural similarity to the active-site loop of the similarly folded catalytic domain of dual specific phosphatase Cdc25, suggesting a common evolutionary origin of the two enzyme families.     

Tetracyanonickelate probes the active site of sulfur-free rhodanese

Tetracyanonickelate (Ni(CN)4(2-)) was used as a probe for the active site of sulfur-free rhodanese (E) in physical and kinetic studies. Ni(CN)4(2-) quenches the intrinsic fluorescence as well as the fluorescence of enzyme-bound 2-anilinonaphthalene-8-sulfonic acid (2,8-ANS), an inhibitor that is competitive with respect to thiosulfate. A facile binding method based on centrifugation was developed to study Ni(CN)4(2-) binding to E. Binding studies performed using either of the electrophoretic variants A and B, fractionated by DE52 column chromatography, showed one high affinity Ni(CN)4(2-)-binding site in each species and additional weak sites on the more electropositive form A. The high affinity Ni(CN)4(2-) binding was corroborated by ultrafiltration binding (Kd = 3.95 +/- 0.35 microM), titration of intrinsic fluorescence (Kd = 1.8 +/- 0.11 microM), and displacement of enzyme-bound 2,8-ANS (Kd = 1.9 +/- 1.1 microM). A nonlinear least squares analysis of kinetic data collected under conditions used for the binding studies gave a Ni(CN)4(2-) inhibition constant of 21 microM. It is concluded that Ni(CN)4(2-) binds to sulfur-free rhodanese in solution near the active site as has been shown in x-ray crystal studies (Lijk, L. J., Kalk, K. H., Brandenburger, N. P., and Hol, W. G. J. (1983) Biochemistry 22, 2952-2957). In keeping with recent suggestions that the conformational state of the enzyme is dynamically determined, the discrepancy between Ni(CN)4(2-) affinity as determined by physical methods and that by kinetic methods suggests that Ni(CN)4(2-) may be able to distinguish the conformation of the working enzyme from those of the idle forms.     

New crystalline derivatives of bovine liver rhodanese

Mitochondrial bovine liver rhodanese (thiosulfate:cyanide sulfurtransferase) has been crystallized in the form deprived of the transferable sulfur. The essential condition for crystallization was the removal of oxygen. Crystals of the sulfur-free enzyme are isomorphous with the previously characterized crystals of the sulfur-substituted enzyme. The new crystal species can react with either thiosulfate or selenosulfate to form the catalytic intermediate and, subsequently, with cyanide to form the corresponding product. Furthermore, the enzyme active site can be alkylated by iodoacetic acid.     

Interaction of rhodanese with intermediates of oxygen reduction

Cyanide-promoted inactivation of the enzyme rhodanese [thiosulfate sulfurtransferase (EC 2.8.1.1)] in the presence of ketoaldehydes is caused by reduced forms of molecular oxygen generated during autoxidation of the reaction products. The requirement of both catalase and superoxide dismutase to prevent rhodanese inactivation indicates that hydroxyl radical could be the most efficient inactivating agent. Rhodanese, also in the less stable sulfur-free form, shows a different sensitivity towards oxygen activated species. While the enzyme is unaffected by superoxide radical, it is rapidly inactivated by hydrogen peroxide. The extent of inactivation depends on the molar ratio between sulfur-free enzyme and oxidizing agent. Fully inactive enzyme is reactivated by reduction with its substrate thiosulfate.     

Surface changes and role of buried water molecules during the sulfane sulfur transfer in rhodanese from Azotobacter vinelandii: a fluorescence quenching and nuclear magnetic relaxation dispersion spectroscopic study

The Azotobacter vinelandii rhodanese is a sulfurtransferase enzyme that catalyzes the transfer of the outer sulfur atom from thiosulfate to cyanide. Recently, investigations by NMR relaxation on the (15)N-enriched protein reported that interdomain contacts are rigidly maintained upon the sulfane sulfur transfer from the enzyme to the substrate. The modality of the enzymatic mechanism is then confined to a surface interaction, including dynamics of water molecules buried in the tertiary structure. Thus, investigations have been carried out by fluorescence, circular dichroism, and nuclear magnetic relaxation dispersion measurements. The comparison of circular dichroism spectra of the persulfurated enzyme and the sulfur-free form indicated that small changes occur. Fluorescence quenching studies have been performed to evaluate the conformational changes during catalysis using the fluorescent probe 8-anilinonaphthalene-2-sulfonic acid, and acrylamide, iodide, and cesium ions as quenchers. Changes in exchange dynamics of water molecules buried in the structure with bulk water, observed by nuclear magnetic relaxation dispersion, are due to local conformational transitions, likely involving residues around the active site, and are consistent with the global correlation time found by (15)N relaxation. These results, taken together, provide important information for elucidating the conformational features of the mechanism of action of the enzyme either in the role of a selective donor of a sulfur atom to small-sized substrates (i.e., to cyanide, transforming it into thiocyanate) or in the role of sulfur insertase for the formation of the Fe(2)S(2) iron-sulfur cluster in sulfur-deprived ferredoxins.     

Low concentrations of guanidinium chloride expose apolar surfaces and cause differential perturbation in catalytic intermediates of rhodanese

The conformations of sulfur-free and sulfur-containing rhodanese were followed with and without the detergent lauryl maltoside after guanidinium chloride (GdmCl) addition to 5 M to study the apparent irreversibility of denaturation. Without lauryl maltoside, sulfur-containing rhodanese denatured in a transition giving, at approximately 2.3 M GdmCl, 50% of the total denaturation induced change observed by activity, CD, or intrinsic fluorescence. Sulfur-free rhodanese gave more complex behavior by intrinsic fluorescence and CD. CD showed loss of secondary structure in a broad, complex, and apparently biphasic transition extending from 0.5 to 3 M GdmCl. The interpretation of the transition was complicated by time-dependent aggregation due to noncovalent interactions. Results with the apolar fluorescence probe 2-anilinonaphthalene-8-sulfonic acid, implicated apolar exposure in aggregation. Sulfhydryl reactivity indicated that low GdmCl concentrations induced intermediates affecting the active site conformation. Lauryl maltoside prevented aggregation with no effect on activity or any conformational parameter of native enzyme. Transitions induced by GdmCl were still observed and consistent with several phases. Even in lauryl maltoside, an increase in apolar exposure was detected by 2-anilinonaphthalene-8-sulfonic acid, and by protein adsorption to octyl-Sepharose well below the major unfolding transitions. These results are interpreted with a model in which apolar interdomain interactions are disrupted, thereby increasing active site accessibility, before the intradomain interactions.     

The "rhodanese" fold and catalytic mechanism of 3-mercaptopyruvate sulfurtransferases: crystal structure of SseA from Escherichia coli

3-Mercaptopyruvate sulfurtransferases (MSTs) catalyze, in vitro, the transfer of a sulfur atom from substrate to cyanide, yielding pyruvate and thiocyanate as products. They display clear structural homology with the protein fold observed in the rhodanese sulfurtransferase family, composed of two structurally related domains. The role of MSTs in vivo, as well as their detailed molecular mechanisms of action have been little investigated. Here, we report the crystal structure of SseA, a MST from Escherichia coli, which is the first MST three-dimensional structure disclosed to date. SseA displays specific structural differences relative to eukaryotic and prokaryotic rhodaneses. In particular, conformational variation of the rhodanese active site loop, hosting the family invariant catalytic Cys residue, may support a new sulfur transfer mechanism involving Cys237 as the nucleophilic species and His66, Arg102 and Asp262 as residues assisting catalysis.     

Properties of an Escherichia coli rhodanese

A rhodanese enzyme of less than 20,000 molecular weight has been purified from Escherichia coli. The enzyme is accessible to substrates upon addition of whole cells to standard assay mixtures. This rhodanese has a Stokes radius of 17 A which for a globular protein corresponds to a molecular weight close to 14,000. It undergoes autoxidation to a polymeric form which is probably an inert dimer. Enzyme inactivated by oxidation can be reactivated by millimolar concentrations of cysteine. Steady-state initial velocity measurements indicate that the enzyme catalyzes the transfer of sulfane sulfur by way of a double displacement mechanism with formation of a covalent enzyme-sulfur intermediate. The turnover number for the enzyme-catalyzed reaction, with thiosulfate as donor substrate and cyanide ion as the sulfur acceptor, is 260 s-1. This value corresponds to a catalytic efficiency 60% of that measured for a previously characterized bovine liver enzyme of more than twice the molecular weight. Furthermore, KmCN is 24 mM which is 2 orders of magnitude higher than the value observed previously for the bovine enzyme. Evidence from chemical inactivation studies implicates an essential sulfhydryl group in the enzyme activity. It is proposed that this group is the site of substrate-sulfur binding in the obligatory enzyme-sulfur intermediate. Furthermore, a cationic site important for binding of the donor thiosulfate is tentatively identified from anion inhibition studies. Tests of alternate acceptor substrates indicate that the physiological dithiol, dihydrolipoate, is a more efficient acceptor than cyanide ion for the enzyme-bound sulfur. Of possibly greater physiological significance, it has been found that the enzyme catalyzes the formation of iron-sulfur centers. Other work indicates the E. coli rhodanese is subject to catabolite repression and suggests a physiological role for the enzyme in aerobic energy metabolism.     

The inhibition of rhodanese by lipoate and iron-sulfur proteins

A study was made on the effects of DL-dihydrolipoate, lipoate and iron-sulfur proteins on the activity of rhodanese (EC 2.8.1.1) with dihydrolipoate or cyanide as acceptors. DL-Dihydrolipoate inactivates rhodanese, lipoate does not, and the opposite occurs with the sulfur-free form of the transferase. The observed effects vary with the sulfane sulfur acceptor from rhodanese (i.e., dihydrolipoate or cyanide) and depend on intramolecular oxidation of the catalytic sulfhydryl or on formation of a mixed disulfide with dihydrolipoate. Thiosulfate protects against inactivation by reloading the active-site cysteine with persulfide sulfur. The inhibition of sulfur transfer by iron-sulfur proteins appears related to the amount of native iron-sulfur structure interacting with rhodanese. The implications of the results for a possible biological role of rhodanese are considered.     

Escherichia coli GlpE is a prototype sulfurtransferase for the single-domain rhodanese homology superfamily.

BACKGROUND: Rhodanese domains are structural modules occurring in the three major evolutionary phyla. They are found as single-domain proteins, as tandemly repeated modules in which the C-terminal domain only bears the properly structured active site, or as members of multidomain proteins. Although in vitro assays show sulfurtransferase or phosphatase activity associated with rhodanese or rhodanese-like domains, specific biological roles for most members of this homology superfamily have not been established. RESULTS: Eight ORFs coding for proteins consisting of (or containing) a rhodanese domain bearing the potentially catalytic Cys have been identified in the Escherichia coli K-12 genome. One of these codes for the 12-kDa protein GlpE, a member of the sn-glycerol 3-phosphate (glp) regulon. The crystal structure of GlpE, reported here at 1.06 A resolution, displays alpha/beta topology based on five beta strands and five alpha helices. The GlpE catalytic Cys residue is persulfurated and enclosed in a structurally conserved 5-residue loop in a region of positive electrostatic field. CONCLUSIONS: Relative to the two-domain rhodanese enzymes of known three-dimensional structure, GlpE displays substantial shortening of loops connecting alpha helices and beta sheets, resulting in radical conformational changes surrounding the active site. As a consequence, GlpE is structurally more similar to Cdc25 phosphatases than to bovine or Azotobacter vinelandii rhodaneses. Sequence searches through completed genomes indicate that GlpE can be considered to be the prototype structure for the ubiquitous single-domain rhodanese module.     

Backbone dynamics in dihydrofolate reductase complexes: role of loop flexibility in the catalytic mechanism

To elucidate the influence of local motion of the polypeptide chain on the catalytic mechanism of an enzyme, we have measured (15)N relaxation data for Escherichia coli dihydrofolate reductase in three different complexes, representing different stages in the catalytic cycle of the enzyme. NMR relaxation data were analyzed by the model-free approach, corrected for rotational anisotropy, to provide insights into the backbone dynamics. There are significant differences in the backbone dynamics in the different complexes. Complexes in which the cofactor binding site is occluded by the Met20 loop display large amplitude motions on the picosecond/nanosecond time scale for residues in the Met20 loop, the adjacent betaF-betaG loop and for residues 67-69 in the adenosine binding loop. Formation of the closed Met20 loop conformation in the ternary complex with folate and NADP(+), results in attenuation of the motions in the Met20 loop and the betaF-betaG loop but leads to increased flexibility in the adenosine binding loop. New fluctuations on a microsecond/millisecond time scale are observed in the closed E:folate:NADP(+) complex in regions that form hydrogen bonds between the Met20 and the betaF-betaG loops. The data provide insights into the changes in backbone dynamics during the catalytic cycle and point to an important role of the Met20 and betaF-betaG loops in controlling access to the active site. The high flexibility of these loops in the occluded conformation is expected to promote tetrahydrofolate-assisted product release and facilitate binding of the nicotinamide ring to form the Michaelis complex. The backbone fluctuations in the Met20 loop become attenuated once it closes over the active site, thereby stabilizing the nicotinamide ring in a geometry conducive to hydride transfer. Finally, the relaxation data provide evidence for long-range motional coupling between the adenosine binding loop and distant regions of the protein.     

Differential binding of the fluorescent probe 8-anilinonaphthalene-2-sulfonic acid to rhodanese catalytic intermediates

Studies have been performed to quantitate the binding of the fluorescent probe 8-anilinonaphthalene-2-sulfonic acid (2,8-ANS) to catalytic intermediates of the enzyme rhodanese: the sulfur-substituted form (ES) and the sulfur-free form (E). The molecular 2,8-ANS has not been extensively used for protein studies, and some characterization is presented to demonstrate its usefulness as a probe for apolar binding sites. The molecule 2,8-ANS binds to at least two classes of sites on rhodanese. One class (class 1) is present in the ES form and has a Kd of 1.7 mM. The E form of rhodanese appears to have a second class of sites (class 2) in addition to the class 1 sites. Two independent fluorometric methods of analyzing the class 2 binding of 2,8-ANS to the E form gave an average value for Kd congruent to 179 microM. These fluorometric titrations, together with a Job plot, clearly indicate that 2,8-ANS binds to more than one site on the E form of rhodanese. The apparent apolarity is slightly higher for class 2 sites than for the class 1 sites, but both give Z factors of greater than 85. The substrate thiosulfate is able to displace the probe that is bound to the class 2 sites on the E form of the enzyme. Further, 2,8-ANS is found to be a competitive inhibitor of the catalyzed reaction with an apparent Kd of 170 microM. Circular dichroism measurements detect no significant changes in the average conformation of rhodanese that can be ascribed to the presence of 2,8-ANS.(ABSTRACT TRUNCATED AT 250 WORDS)     

The structure of bovine liver rhodanese. II. The active site in the sulfur-substituted and the sulfur-free enzyme.

X-ray studies at 2.5 Å resolution show that the active site of bovine liver rhodanese is a depression between the two domains. In sulfur-substituted rhodanese the density of the essential Cys247 corresponds with that of a persulfide. Both sulfur atoms are interacting via hydrogen bonds with several peptide NH and side-chain OH groups. One side of the active site pocket contains mainly hydrophylic, the other side mainly hydrophobic residues. None of these hydrophylic or hydrophobic groups appears to interact strongly with the persulfide.Crystals of the sulfur-substituted enzyme were treated with cyanide, a sulfur acceptor. Subsequent difference Fourier studies show that the extra sulfur atom has been removed. Only minor conformational differences appear to exist between the two rhodanese species studied. These are a movement of the Sγ atom of Cys247 and some rearrangement of solvent molecules near the active site.The combination of these observations with the results of experiments performed by other investigators suggest a mechanism for sulfur transfer by rhodanese in which the thiol group of Cys247 is the essential nucleophile, whereas the positive charges on Arg186 and Lys249 act in various ways as “electrophilic assistants”. The transition state and the persulfide in the sulfur-substituted enzyme are stabilized by several hydrogen bonds.     

Characterization of a rhodanese from the cyanogenic bacterium Pseudomonas aeruginosa

Pseudomonas aeruginosa, the rRNA group I type species of genus Pseudomonas, is a Gram-negative, aerobic bacterium responsible for serious infection in humans. P. aeruginosa pathogenicity has been associated with the production of several virulence factors, including cyanide. Here, the biochemical characterization of recombinant P. aeruginosa rhodanese (Pa RhdA), catalyzing the sulfur transfer from thiosulfate to a thiophilic acceptor, e.g., cyanide, is reported. Sequence homology analysis of Pa RhdA predicts the sulfur-transfer reaction to occur through persulfuration of the conserved catalytic Cys230 residue. Accordingly, the titration of active Pa RhdA with cyanide indicates the presence of one extra sulfur bound to the Cys230 Sgamma atom per active enzyme molecule. Values of K(m) for thiosulfate binding to Pa RhdA are 1.0 and 7.4mM at pH 7.3 and 8.6, respectively, and 25 degrees C. However, the value of K(m) for cyanide binding to Pa RhdA (=14 mM, at 25 degrees C) and the value of V(max) (=750 micromol min(-1)mg(-1), at 25 degrees C) for the Pa RhdA-catalyzed sulfur-transfer reaction are essentially pH- and substrate-independent. Therefore, the thiosulfate-dependent Pa RhdA persulfuration is favored at pH 7.3 (i.e., the cytosolic pH of the bacterial cell) rather than pH 8.6 (i.e., the standard pH for rhodanese activity assay). Within this pH range, conformational change(s) occur at the Pa RhdA active site during the catalytic cycle. As a whole, rhodanese may participate in multiple detoxification mechanisms protecting P. aeruginosa from endogenous and environmental cyanide.     

Active site modifications quench intrinsic fluorescence of rhodanese by different mechanisms

Beef liver rhodanese can be modified covalently at the active site (Cys-247) either reversibly or irreversibly by sulfur, selenium, iodoacetate, and hydrogen peroxide. Each derivative shows an intrinsic fluorescence lower than that of the free enzyme. The reaction of rhodanese with iodoacetate or hydrogen peroxide is time-dependent and accompanied by enzyme inactivation, by the loss of one or two sulfhydryl groups, respectively, by quenching and bathochromic shift of fluorescence, and by an absorbance perturbation in the near UV. The latter findings are indicative for a displacement of some tryptophyl side chains from hydrophobic to hydrophilic environment. The fluorescence decays of the various rhodanese derivatives can be fitted by a double-exponential function with two lifetimes: a shorter one of 1-1.7 ns and a longer one of 2.8-4.6 ns. The S-loaded and Se-loaded rhodanese samples have proportionally shorter lifetimes and lower quantum yields. No such proportionality was observed for the iodoacetate-treated and for the hydrogen peroxide treated enzyme. These findings indicate that two different quenching mechanisms are operating in rhodanese derivatives, a long-range energy transfer from tryptophan to persulfide (or sulfoselenide) group and a static quenching accompanying a conformational change of the protein after modification of the active site.     

Oxidative inactivation of the enzyme rhodanese by reduced nicotinamide adenine dinucleotide

The enzyme rhodanese (thiosulfate sulfurtransferase; EC 2.8.1.1) is inactivated with a half-time of approximately 3 min when incubated with 50 mM NADH. NAD+, however, has virtually no effect on the activity. Inactivation can be prevented by the inclusion of the substrate thiosulfate. The concentration of thiosulfate giving half-protection is 0.038 mM. In addition, NADH, but not NAD+, is a competitive inhibitor with respect to thiosulfate in the catalyzed reaction (Ki = 8.3 mM). Fluorescence studies are consistent with a time-dependent oxidation of NADH in the presence of rhodanese. The sulfur-free form of rhodanese is more rapidly inactivated than the sulfur-containing form. Spectrophotometric titrations show that inactivation is accompanied by the loss of two free SH groups per enzyme molecule. Inactivation is prevented by the exclusion of air and the inclusion of EDTA (1 mM), and the enzyme activity can be largely protected by incubation with superoxide dismutase or catalase. Rhodanese, inactivated with NADH, can be reactivated by incubation with the substrate thiosulfate (75 mM) for 48 h or more rapidly, but only partially, by incubating with 180 mM dithiothreitol. It is concluded that, in the presence of rhodanese, NADH can be oxidized by molecular oxygen and produce intermediates of oxygen reduction, such as superoxide and/or hydrogen peroxide, that can inactivate the enzyme with consequent formation of an intraprotein disulfide. In addition, NADH, but not NAD+, can reversibly bind to the active site region in competition with thiosulfate. These data are of interest in view of x-ray studies that show structural similarities between rhodanese and nucleotide binding proteins.     

Sulfhydryl-directed triggering of conformational changes in the enzyme rhodanese

The enzyme rhodanese in the form without transferred sulfur, (E), was inactivated by carboxymethylation with iodoacetic acid (E.IAA), and its conformation was compared with that of E inactivated by oxidative processes (Eox). Formation of E.IAA led to the exposure of binding sites for the fluorescent apolar probe 1,1'-bi(4-anilino)naphthalene-5,5'-disulfonic acid (BisANS). The dissociation constant for BisANS decreased as the concentration of E.IAA decreased and ranged from approximately 200 microM at 1 mg/ml protein to approximately 2 microM at protein concentrations below 0.1 mg/ml. Centrifugation confirmed that E.IAA, but not the underivatized enzyme, could associate. E.IAA was proteolyzable by chymotrypsin or endoproteinase Glu C (V8), while rhodanese containing bound sulfur, ES, was totally refractory, and E was only clipped to a small extent. This constellation of consequences was only previously observed with oxidatively inactivated rhodanese. Fluorescence depolarization measurements of bound BisANS were consistent with exposure of apolar surfaces and association of the protein. The fluorescence spectra of BisANS bound to E.IAA or Eox were identical and distinct from the spectrum of BisANS bound to phenylglyoxal-inactivated ES. Digestion with chymotrypsin was followed using protein and BisANS fluorescence and showed a similar response for E.IAA and Eox. These results indicate that the consequences of forming Eox and E.IAA are very similar. Thus, reaction of the active site sulfhydryl group apparently triggers a conformational change leading to increased protein flexibility and increased exposure of hydrophobic surfaces. In the case of oxidation, the trigger might involve initial formation of an active site sulfenic acid which ultimately gives higher oxidation states that could include disulfides.