Methods for in situ visualization and assay of sulfurtransferases

The dansyl derivative 5-dimethylamino-1-naphthalene thiosulfonate (DANTS) can serve as a sulfane sulfur-donor substrate for several of the sulfurtransferases, the reaction being dependent on the acceptor substrates supplied. Enzymatic cleavage of the sulfur-sulfur bond of DANTS releases the intrinsic fluorescence of the molecule, with an emission maximum of 500-510 nm (excitation at 325 nm). This process permits selective visualization of active sulfurtransferase enzymes separated in nondenaturing polyacrylamide gels, even from impure preparations. This technique was used to locate rhodanese (thiosulfate: cyanide sulfurtransferase, EC 2.8.1.1), thiosulfate reductase (EC unassigned), and a recently isolated prokaryotic enzyme that has been called sulfane sulfurtransferase. In addition, a refinement of the thiosulfate reductase assay technique is reported.     

On the molecular weight of thiosulfate sulfurtransferase.

Bovine liver thiosulfate sulfurtransferase (rhodanese) (EC 2.8.1.1) HAS BEEN REPORTED TO EXIST IN SOLUTION IN A RAPID, PH-dependent equilibrium between monomeric and dimeric forms of molecular weights 18 500 and 37 000 (Volini, M., DeToma, F. and Westley, J. (1967), J. Biol. Chem. 242, 5220). We have reinvestigated the proposed dissociation using sodium dodecylsulfate-polyacrylamide gel electrophoresis. The smallest rhodanese species observed has a molecular weight around 35 000, which is not reduced by severe denaturing conditions, including alkylation in 8 M guanidine-HCl or dialysis against 2% sodium dodecylsulfate and 5% mercaptoethanol. After limited CNBr cleavage, intermediate products of greater than 18 500 molecular weight are formed. The apparent molecular weight of these intermediate fragments is not changed by addition of mercaptoethanol. The total apparent molecular weights of the CNBr fragments after exhaustive cleavage is approx. 45 000 plus or minus 15 000. These results are not consistent with a monomer molecular weight of approx. 18 500 for thiosulfate sulfurtransferase.     

The specificity of active-site alkylation by iodoacetic acid in the enzyme thiosulfate sulfurtransferase

The active-site sulfhydryl group in the enzyme thiosulfate sulfurtransferase (rhodanese; thiosulfate:cyanide sulfurtransferase; EC 2.8.1.1) is alkylated rapidly by iodoacetic acid in the free enzyme form, E, with complete loss of sulfurtransferase activity. Iodoacetic acid is completely ineffective with the sulfur-substituted form of the enzyme, ES. Iodoacetamide, on the other hand, has no effect on either enzyme form. The competitive enzyme inhibitor, toluenesulfonic acid, protects against inactivation in a strictly competitive way and analysis gives an apparent binding constant for toluenesulfonic acid of 12.5 mM, which is in agreement with studies of its effect on the catalyzed reaction. These results are taken to indicate that iodoacetic acid is an affinity analog for the substrate, thiosulfate, and inactivates because it can use the specific thiosulfate binding interactions, correctly orient its reactive center and displace intraprotein interactions which appear to protect the active-site sulfhydryl group in the E form.     

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.     

Cardiolipin liposomes sequester a reactivatable partially folded rhodanese intermediate.

The interaction was studied between the mitochondrial enzyme thiosulfate sulfurtransferase and liposomes, in the form of large unilamellar vesicles (LUV), prepared from either cardiolipin (CL), PtdCho or PtdSer. At equivalent concentrations of lipid, more partially folded thiosulfate sulfurtransferase bound to CL/LUV than to PtdSer/LUV, and only traces were bound to PtdCho/LUV. Native thiosulfate sulfurtransferase did not bind to any of these LUV. We show that CL/LUV-sequestered thiosulfate sulfurtransferase is inactive but may be reactivated (approximately 56%) with the aid of detergents, thiosulfate, beta-mercaptoethanol and phosphate buffer. Reactivations in the presence of PtdSer/LUV or PtdCho/LUV was only 9% or 1%, respectively. Analysis of the complex by protease digestion and fluorescence spectroscopy indicated that thiosulfate sulfurtransferase was held by CL/LUV and PtdSer/LUV as a folding intermediate. Data presented here suggest that detergents may not interact directly with the protein, but, rather, their primary role in reactivation is to disrupt the LUV, allowing flexibility to the anchored thiosulfate sulfurtransferase molecule, thereby promoting folding. These studies complement other reports which imply a possible role for CL in protein translocation across the mitochondria, since we find that CL binds to thiosulfate sulfurtransferase and sequesters it in a translocation-competent prefolded conformation, which may readily lead to a correctly folded enzyme.     

Isolation and characterization of a prokaryotic sulfurtransferase

A sulfurtransferase has been purified to apparent homogeneity from the prokaryote Acinetobacter calcoaceticus lwoffi by conventional protein fractionation techniques. Steady-state kinetic studies of the enzyme revealed that its formal mechanism varies with the acceptor substrate employed. With inorganic thiosulfate as the sulfane sulfur-donor substrate and cyanide anion as the acceptor, the enzyme was shown to catalyze the reaction by a double displacement mechanism like that of mammalian rhodanese (thiosulfate:cyanide sulfurtransferase, EC 2.8.1.1). In contrast, with a thiol as the acceptor substrate at relatively high concentrations, the reaction proceeds by a single displacement mechanism, reminiscent of catalysis by another sulfur-transferase, thiosulfate reductase, glutathione-dependent (EC 2.8.1.3). When dithiothreitol is the acceptor substrate, the enzyme cycles through both the single and double displacement pathways, with the flux through each depending differentially on the concentration of dithiothreitol employed. In view of both the relaxed acceptor substrate specificity and the corresponding variability of formal mechanism, the more general name of sulfane sulfurtransferase is proposed for this bacterial enzyme.     

Improved Assay for Rhodanese in Thiobacillus spp

Rhodanese (thiosulfate:cyanide sulfurtransferase; EC 2.8.1.1) catalyzes the conversion of thiosulfate and cyanide to thiocyanate and sulfite. Conventional rhodanese assays colorimetrically measure the formation of one or the other of the products. These assays suffer from the fact that there is significant nonbiological formation of these products in addition to the enzymatically catalyzed reaction. In the present report, we describe a modified procedure for assaying rhodanese in which a separate boiled control was prepared for each assay trial. The boiled control corrected for the nonbiological contributions to product formation.     

Domain structural flexibility in rhodanese examined by quenching of a phosphorescent probe

Rhodanese (thiosulfate:cyanide sulfurtransferase, EC 2.8.1.1) is an enzyme composed of two domains with the catalytic site located in the bottom of the crevice formed by the two domains. In this work, rhodanese was labeled at its catalytic site with the phosphorescence probe eosin isothiocyanide. The accessibility of molecules to the probe was determined by phosphorescence lifetime-quenching studies. The phosphorescent probe was much more accessible to small molecules (I- and thiosulfate, radius about 3-5 A) than to a larger molecule (spin-label probe TEMPO, radius about 8-10 A). It was observed that a temperature-induced change in the rate of quenching occurred at around 28 degrees C. The results are interpreted in terms of structural fluctuations and displacement in the domains.     

A chaperone-mimetic effect of serum albumin on rhodanese

Reactivation of denatured rhodanese (thiosulfate:cyanide sulfurtransferase, EC 2.8.1.1) was found to be aided by the presence of serum albumin. Both the rate and the extent of reactivation of the urea-denatured enzyme were optimal at low rhodanese and moderate serum albumin concentrations. Similarly, stabilization of the sulfurtransferase activity of rhodanese that had been partially unfolded at 40°C was aided by the presence of serum albumin. All the observations are in accord with a model in which enzyme that has been partially refolded from the urea-denatured state or partially unfolded thermally interacts directly with serum albumin in a way that prevents rhodanese self-association. Serum albumin thus acts as a molecular chaperone in these systems.     

Chromogenic substrates for sulfurtransferases

The azo dye 4-(dimethylamino)-4'-azobenzene (DAB) thiosulfonate anion can serve as a sulfur-donor substrate for rhodanese (thiosulfate: cyanide sulfurtransferase, EC 2.8.1.1) and for thiosulfate reductase (EC unassigned) with cyanide anion and GSH, respectively, as acceptor substrates. In either case, the dye product is DAB sulfinate, which differs substantially in light absorption at 500 nm. Moreover, DAB sulfinate can serve as a sulfur-acceptor substrate for rhodanese with either inorganic thiosulfate or a colorless thiosulfonate anion as donor, and this reaction provides a second chromogenic assay procedure.     

Interaction of rhodanese with mitochondrial NADH dehydrogenase

NADH dehydrogenase is an iron-sulfur flavoprotein which is isolated and purified from Complex I (mitochondrial NADH: ubiquinone oxidoreductase) by resolution with NaClO4. The activity of the enzyme (followed as NADH: 2-methylnaphthoquinone oxidoreductase) increases linearly with protein concentration (in the range between 0.2 and 1.0 mg/ml) and decreases with aging upon incubation on ice. In the present work a good correlation was found between enzymic activity and labile sulfide content, at least within the limits of sensitivity of the assays employed. Rhodanese (thiosulfate: cyanide sulfurtransferase (EC 2.8.1.1) purified from bovine liver mitochondria was shown to restore, in the presence of thiosulfate, the activity of the partly inactivated NADH dehydrogenase. Concomitantly, sulfur was transferred from thiosulfate to the flavoprotein and incorporated as acid-labile sulfide. Rhodanese-mediated sulfide transfer was directly demonstrated when the reactivation of NADH dehydrogenase was performed in the presence of radioactive thiosulfate (labeled in the outer sulfur) and the 35S-loaded flavoprotein was re-isolated by gel filtration chromatography. The results indicated that the [35S]sulfide was inserted in NADH dehydrogenase and appeared to constitute the structural basis for the increase in enzymic activity.     

Metabolism ofl-cysteine via transamination pathway (3-mercaptopyruvate pathway)

Summary We have studied the transamination pathway (3-mercaptopyruvate pathway) ofl-cysteine metabolism in rats. Characterization of cysteine aminotransferase (EC 2.6.1.3) from liver indicated that the transamination, the first reaction of this pathway, was catalyzed by aspartate aminotransferase (EC 2.6.1.1). 3-Mercaptopyruvate, the product of the transamination, may be metabolized through two routes. The initial reactions of these routes are reduction and transsulfuration, and the final metabolites are 3-mercaptolactate-cysteine mixed disulfide [S-(2-hydroxy-2-carboxyethylthio)cysteine, HCETC] and inorganic sulfate, respectively. The study using anti-lactate dehydrogenase antiserum proved that the enzyme catalyzing the reduction of 3-mercaptopyruvate was lactate dehydrogenase (EC 1.1.1.27). Formation of HCETC was shown to depend on low 3-mercaptopyruvate sulfurtransferase (EC 2.8.1.2) activity. Results were discussed in relation to HCETC excretion in normal human subjects and patients with 3-mercaptolactate-cysteine disulfiduria. Incubation of liver mitochondria withl-cysteine, 2-oxoglutarate and glutathione resulted in the formation of sulfate and thiosulfate, indicating that thiosulfate was formed by transsulfuration of 3-mercaptopyruvate and finally metabolized to sulfate.     

Rhodanese as a thioredoxin oxidase

A major catalytic difference between the two most common isoforms of bovine liver mitochondrial rhodanese (thiosulfate: cyanide sulfurtransferase, EC 2.8.1.1) has been observed. Both isoforms were shown to be capable of using reduced thioredoxin as a sulfur-acceptor substrate. However, only the less negative form in common with the recombinant mammalian rhodanese expressed in E. coli, can also catalyze the direct oxidation of reduced thioredoxin evidently by reactive oxygen species. These activities are understood in terms of the established persulfide structure (R-S-SH) of the covalently substituted rhodanese in the sulfurtransferase reaction and an analogous sulfenic acid structure (R-S-OH) when the enzyme acts as a thioredoxin oxidase. The observations suggest a role for one rhodanese isoform in the detoxication of intramitochondrial oxygen free radicals.     

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.     

The crystal structure of Leishmania major 3-mercaptopyruvate sulfurtransferase. A three-domain architecture with a serine protease-like triad at the active site

Leishmania major 3-mercaptopyruvate sulfurtransferase is a crescent-shaped molecule comprising three domains. The N-terminal and central domains are similar to the thiosulfate sulfurtransferase rhodanese and create the active site containing a persulfurated catalytic cysteine (Cys-253) and an inhibitory sulfite coordinated by Arg-74 and Arg-185. A serine protease-like triad, comprising Asp-61, His-75, and Ser-255, is near Cys-253 and represents a conserved feature that distinguishes 3-mercaptopyruvate sulfurtransferases from thiosulfate sulfurtransferases. During catalysis, Ser-255 may polarize the carbonyl group of 3-mercaptopyruvate to assist thiophilic attack, whereas Arg-74 and Arg-185 bind the carboxylate group. The enzyme hydrolyzes benzoyl-Arg-p-nitroanilide, an activity that is sensitive to the presence of the serine protease inhibitor N alpha-p-tosyl-L-lysine chloromethyl ketone, which also lowers 3-mercaptopyruvate sulfurtransferase activity, presumably by interference with the contribution of Ser-255. The L. major 3-mercaptopyruvate sulfurtransferase is unusual with an 80-amino acid C-terminal domain, bearing remarkable structural similarity to the FK506-binding protein class of peptidylprolyl cis/trans-isomerase. This domain may be involved in mediating protein folding and sulfurtransferase-protein interactions.     

Transfer of persulfide sulfur from thiocystine to rhodanese.

THiocystine (bis-[2-amino-2-carboxyethyl]trisulfide) is a natural substrate for rhodanese (thiosulfate:cyanide sulfurtransferase, EC 2.8.1.1). Analogs of thiocystine were prepared by eliminating the carboxyl or amino group or by lengthening the carbon chain. Of these only homothiocystine (bis-[2-amino-2-carboxypropyl]trisulfide) had appreciable activity as a substrate. At pH 8.6, the optimum for rhodanese, transfer of sulfane sulfur to cyanide in the presence of rhodanese was nonspecific. Only the sulfane sulfur of 35S-labeled thiocystine was transferred to rhodanese. Thus, thiocystine and thiosulfate both produce a rhodanese persulfide as a stable intermediate in sulfur transfer.     

Rhodanese-Mediated sulfur transfer to succinate dehydrogenase.

The interaction of the sulfurtransferase rhodanese (EC 2.8.1.1) with succinate dehydrogenase (EC 1.3.99.1), yeast alcohol dehydrogenase (EC 1.1.1.1) and bovine serum albumin was studied. Succinate dehydrogenase incorporates the sulfane sulfur of [35S]rhodanese and, in the presence of unlabelled rhodanese, also incorporates that of [35S]thiosulfate. Rhodanese releases most of its transferable sulfur and is re-loaded in the presence of thiosulfate. Rhodanese undergoes similar modifications with yeast alcohol dehydrogenase but this latter does not bind 35S in amounts comparable to those incorporated in succinate dehydrogenase: nearly all the 35S released by [35S]rhodanese is with low-molecular-weight compounds. Bovine serum albumin also binds very little sulfur and [35S]rhodanese present in the reaction mixture does not discharge its radioactive sulfur nor does it take up sulfur from thiosulfate. Sulfur release from rhodanese appears to depend on the presence of - SH groups in the acceptor protein. Sulfur incorporated into succinate dehydrogenase was analytically determined as sulfide. A comparison of the optical spectra of succinate dehydrogenase preparations incubated with or without rhodanese indicates that there is an effect of the sulfurtransferase on the iron-sulfur absorption of the flavorprotein. The interaction of rhodanese with succinate dehydrogenase greatly decreases the catalytic activity of rhodanese with respect to thiocyanate formation. This is attributed to modifications in rhodanese associated with the reduction of sulfane sulfur to sulfide. Thiosulfate in part protects from this deactivation. The reconstitutive capacity of succinate dehydrogenase increased in parallel with sulfur incorporated in that enzyme following its interaction with rhodanese.     

Plant mercaptopyruvate sulfurtransferases: molecular cloning, subcellular localization and enzymatic activities.

Mercaptopyruvate sulfurtransferase (MST, EC 2.8.1.2) and thiosulfate sulfurtransferase (TST, rhodanese, EC 2.8.1.1) are evolutionarily related enzymes that catalyze the transfer of sulfur ions from mercaptopyruvate and thiosulfate, respectively, to cyanide ions. We have isolated and characterized two cDNAs, AtMST1 and AtMST2, that are Arabidopsis homologs of TST and MST from other organisms. Deduced amino-acid sequences showed similarity to each other, although MST1 has a N-terminal extension of 57 amino acids containing a targeting sequence. MST1 and MST2 are located in mitochondria and cytoplasm, respectively, as shown by immunoblot analysis of subcellular fractions and by green fluorescent protein (GFP) analysis. However, some regions of MST1 fused to GFP were found to target not only mitochondria, but also chloroplasts, suggesting that the regions on the targeting sequence recognized by protein import systems of mitochondria and chloroplasts are not identical. Recombinant proteins, expressed in Escherichia coli, exhibited MST/TST activity ratios determined from kcat/Km values of 11 and 26 for MST1 and MST2, respectively. This indicates that the proteins encoded by both AtMST1 and AtMST2 are MST rather than TST type. One of the hypotheses proposed so far for the physiological function of MST and TST concerns iron-sulfur cluster assembly. In order to address this possibility, a T-DNA insertion Arabidopsis mutant, in which the AtMST1 was disrupted, was isolated by PCR screening of T-DNA mutant libraries. However, the mutation had no effect on levels of iron-sulfur enzyme activities, suggesting that MST1 is not directly involved in iron-sulfur cluster assembly.     

The effect of hydrogen sulfide on the metabolism of Solemya velum and enzymes of sulfide oxidation in gill tissue

• 1.1. The addition of sulfide to sea-water in respirometer flasks stimulated oxygen uptake by intact Solemya velum; at concentrations of 0.5 and 0.8 mM, the experimental rates were 1.8 and 2.5 times control rates.
• 2.2. Extracts of gill tissue catalyzed the conversion of thiosulfate to sulfite, the production of adenosine phosphosulfate (APS) from AMP and sulfite and the formation of ATP from APS. The enzymes, thiosulfate sulfurtransferase (EC 2.8.1.1), adenylsulfate reductase (EC 1.8.99.2) and sulfate adenylyl transferase (EC 2.7.7.4) have K_m and V_max in the same range as similar enzymes in other species.
• 3.3. Calculations based on these experiments suggest that adenylylsulfate reduction is ordinarily catalyzed at no more than 8% of maximum velocity.

     

Productive and nonproductive intermediates in the folding of denatured rhodanese

The competition between protein aggregation and folding has been investigated using rhodanese (thiosulfate:cyanide sulfurtransferase, EC 2.8.1.1) as a model. During folding from a urea-denatured state, rhodanese rapidly forms associated species or intermediates, some of which are large and/or sticky. The early removal of such particles by filtration results in a decreased refolding yield. With time, a portion of the smaller aggregates can partition back first to intermediates and then to refolded protein, while a fraction of these irreversibly form unproductive higher aggregates. Dynamic light scattering measurements indicate that the average sizes of the aggregates formed during rhodanese folding increase from 225 to 325 nm over 45 min and they become increasingly heterogeneous. Glycerol addition or the application of high hydrostatic pressure improved the final refolding yields by stabilizing smaller particles. Although addition of glycerol into the refolding mixture blocks the formation of unproductive aggregates, it cannot dissociate them back to productive intermediates. The presence of 3.9 M urea keeps the aggregates small, and they can be dissociated to monomers by high hydrostatic pressure even after 1 h of incubation. These studies suggest that early associated intermediates formed during folding can be reversed to give active species.