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.     

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.     

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.     

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.     

A physical characterization of sulfane sulfurtransferase

The bacterial enzyme sulfane sulfurtransferase has been studied using spectroscopic techniques. The enzyme was characterized in terms of its near-UV absorption spectrum, molar ellipticity, intrinsic fluorescence spectra and the effects of general and ionic quenching reagents upon its fluorescence. Fluorescence model studies are consistent with sulfane sulfurtransferase having only a single tryptophan residue, which accounts for its low UV absorption coefficient and suggested that this residue is at least partially exposed to solvent. Second derivative absorption spectroscopy studies revealed that most of the bacterial enzyme's tyrosine residues are exposed to solvent. Unlike the better known sulfurtransferase, bovine liver rhodanese, sulfane sulfurtransferase does not undergo a detectable increase in quantum yield when shifting from the sulfur-containing covalent enzyme intermediate to the free enzyme form (which lacks sulfur) during catalysis. CD studies suggest that sulfane sulfurtransferase has a significantly higher proportion of alpha-helix than rhodanese. The renaturation of sulfane sulfurtransferase denatured in 6 M guanidine was shown to be rapid and complete provided that the enzyme had not been oxidized while in the denatured state. Sulfane sulfurtransferase, like rhodanese, catalyzes the transfer of sulfur from thiosulfate to cyanide via a persulfide intermediate, and displays remarkably similar kinetics in this process (Aird, B.A., Heinrikson, R.L. and Westley, J. (1987) J. Biol. Chem 262, 17327-17335). In light of this, the results of the structural studies with sulfane sulfurtransferase are compared and contrasted to data from similar experiments with rhodanese in hopes that they would provide insight about which phenomena observed with rhodanese are intrinsic to the process of transferring sulfur atoms.     

Sulfane-Activated Reduction of Cytochrome c by Glutathione

The inorganic sulfane tetrathionate (^-O₃SSSSO₃^-) resembles glutathione trisulfide (GSSSG) in that it remarkably activates the reduction of cytochrome c by GSH, both under aerobic and anaerobic conditions. These observations can be explained by the formation of the persulfide GSS^-, due to nucleophilic displacements of sulfane sulfur. The GSS^- species has previously been proposed to act as a chain carrier in the catalytic reduction of cytochrome c, and perthiyl radicals GSS·, formed in the reduction step, were thought to recycle to sulfane via dimerization to GSSSSG.² The present study provides some arguments in favour of a chain mechanism involving the GSS· + GS^- ⇄ (GSSSG)^- equilibrium and sulfane regeneration by a second electron transfer from (GSSSG)· ^- to cytochrome c.

Thiosulfate sulfurtransferase (rhodanese) is shown to act as a cytochrome c reductase in the presence of thiosulfate and GSH, and again the generation of GSS^- can be envisaged to explain this result.     

A nuclear magnetic relaxation study of conformational changes induced by substrate and temperature in bovine liver thiosulfate sulfurtransferase and yeast hexokinase

Nuclear magnetic relaxation studies have been performed on thiosulfate sulfurtransferase (EC 2.8.1.1) and hexokinase (EC 2.7.1.1). Observation of proton spin-lattice relaxation times T1 indicates that structural transitions occur in these enzymes in the range 0-40 degrees C and that there are different temperature-dependent forms of thiosulfate sulfurtransferase and hexokinase. Thermal transitions between these forms are affected by the binding of the substrates. The results may be due to changes in the interactions between the structural domains into which the single polypeptide chains of thiosulfate sulfurtransferase and hexokinase are folded.     

Rhodanese-thioredoxin system and allyl sulfur compounds

Sodium 2-propenyl thiosulfate, a water-soluble organo-sulfane sulfur compound isolated from garlic, induces apoptosis in a number of cancer cells. The molecular mechanism of action of sodium 2-propenyl thiosulfate has not been completely clarified. In this work we investigated, by in vivo and in vitro experiments, the effects of this compound on the expression and activity of rhodanese. Rhodanese is a protein belonging to a family of enzymes widely present in all phyla and reputed to play a number of distinct biological roles, such as cyanide detoxification, regeneration of iron-sulfur clusters and metabolism of sulfur sulfane compounds. The cytotoxic effects of sodium 2-propenyl thiosulfate on HuT 78 cells were evaluated by flow cytometry and DNA fragmentation and by monitoring the progressive formation of mobile lipids by NMR spectroscopy. Sodium 2-propenyl thiosulfate was also found to induce inhibition of the sulfurtransferase activity in tumor cells. Interestingly, in vitro experiments using fluorescence spectroscopy, kinetic studies and MS analysis showed that sodium 2-propenyl thiosulfate was able to bind the sulfur-free form of the rhodanese, inhibiting its thiosulfate:cyanide-sulfurtransferase activity by thiolation of the catalytic cysteine. The activity of the enzyme was restored by thioredoxin in a concentration-dependent and time-dependent manner. Our results suggest an important involvement of the essential thioredoxin-thioredoxin reductase system in cancer cell cytotoxicity by organo-sulfane sulfur compounds and highlight the correlation between apoptosis induced by these compounds and the damage to the mitochondrial enzymes involved in the repair of the Fe-S cluster and in the detoxification system.     

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.     

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.     

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.

     

Characterization of two sulfurtransferase isozymes from Arabidopsis thaliana.

Sulfurtransferases transfer a sulfane atom from a donor substrate to a thiophilic acceptor molecule. Recently a sulfurtransferase specific for the substrate 3-mercaptopyruvate was isolated from Arabidopsis thaliana [Papenbrock, J. & Schmidt, A. (2000) Eur. J. Biochem. 267, 145-154]. In this study a second sulfurtransferase from Arabidopsis was characterized and compared to the enzyme described previously. Sequences of the mature proteins had an identity of 77.7%. The plant sulfurtransferases formed a distinct group within the known eukaryotic sulfurtransferases. When Southern blots were hybridized with labelled cDNA fragments from each of the plant sulfurtransferases the same pattern of bands was obtained indicating the existence of only these two closely related sulfurtransferases. The new sulfurtransferase was expressed in Escherichia coli fused with an N-terminal His6-tag, purified and tested for enzyme activity. Like the first enzyme, the newly isolated protein preferred 3-mercaptopyruvate to thiosulfate as substrate. The Km of both enzymes determined for 3-mercaptopyruvate and cyanide were almost identical. As a result of database searches it became obvious that sulfurtransferase proteins from higher plants showed high similarities to small senescence- and stress-induced proteins. To prove the involvement of sulfurtransferases in senescence-associated processes 3-mercaptopyruvate sulfurtransferase activity was determined in crude protein extracts from Arabidopsis plants of different ages. 3-mercaptopyruvate sulfurtransferase activity and steady-state RNA levels of sulfurtransferases increased with increasing age. However, steady-state protein levels as measured by using an antibody against the sulfurtransferase protein expressed previously decreased. Putative roles of sulfurtransferases in senescence-associated processes are discussed.     

3-Mercaptopyruvate sulfurtransferase of Leishmania contains an unusual C-terminal extension and is involved in thioredoxin and antioxidant metabolism

Cytosolic 3-mercaptopyruvate sulfurtransferases (EC ) of Leishmania major and Leishmania mexicana have been cloned, expressed as active enzymes in Escherichia coli, and characterized. The leishmanial single-copy genes predict a sulfurtransferase that is structurally peculiar in possessing a C-terminal domain of some 70 amino acids. Homologous genes of Trypanosoma cruzi and Trypanosoma brucei encode enzymes with a similar C-terminal domain, suggesting that this feature, not known in any other sulfurtransferase, is a characteristic of trypanosomatid parasites. Short truncations of the C-terminal domain resulted in misfolded inactive proteins, demonstrating that the domain plays some key role in facilitating correct folding of the enzymes. The leishmanial recombinant enzymes exhibited high activity toward 3-mercaptopyruvate and catalyzed the transfer of sulfane sulfur to cyanide to form thiocyanate. They also used thiosulfate as a substrate and reduced thioredoxin as the accepting nucleophile, the latter being oxidized. The enzymes were expressed in all life cycle stages, and the expression level was increased under peroxide or hypo-sulfur stress. The results are consistent with the enzymes having an involvement in the synthesis of sulfur amino acids per se or iron-sulfur centers of proteins and the parasite's management of oxidative stress.     

Characterization of a new periplasmic single-domain rhodanese encoded by a sulfur-regulated gene in a hyperthermophilic bacterium Aquifex aeolicus

Rhodaneses (thiosulfate cyanide sulfurtransferases) are enzymes involved in the production of the sulfur in sulfane form, which has been suggested to be the relevant biologically active sulfur species. Rhodanese domains occur in the three major domains of life. We have characterized a new periplasmic single-domain rhodanese from a hyperthermophile bacterium, Aquifex aeolicus, with thiosulfate:cyanide transferase activity, Aq-1599. The oligomeric organization of the enzyme is stabilized by a disulfide bridge. To date this is the first characterization from a hyperthermophilic bacterium of a periplasmic sulfurtransferase with a disulfide bridge. The aq-1599 gene belongs to an operon that also contains a gene for a prepilin peptidase and that is up-regulated when sulfur is used as electron acceptor. Finally, we have observed a sulfur-dependent bacterial adherence linked to an absence of flagellin suggesting a possible role for sulfur detection by A. aeolicus.     

Product analysis of bisulfite reductase activity isolated from Desulfovibrio vulgaris.

Bisulfite reductase was purified from extracts of Desulfovibrio vulgaris. By colorimetric analyses trithionate was found to be the major product, being formed in quantities 5 to 10 times more than two other detectable products, thiosulfate and sulfide. When [35S]bisulfite was used as the substrate, all three products were radioactively labeled. Degradation of [35S]trithionate showed that all of its sulfur atoms were equally labeled. In contrast, [35S]thiosulfate contained virtually all of the radioactivity in the sulfonate atom while the sulfane atom was unlabeled. These results, in conjunction with the funding that the sulfide was radioactive, led to the conclusion that bisulfite reductase reduced bisulfite to trithionate as the major product and sulfide as the minor product; the reason for the unusual labeling pattern found in the thiosulfate molecule was not apparent at this time. When bisulfite reductase was incubated with [35S]bisulfite in the presence of another protein fraction, FII, the thiosulfate formed from this reaction contained both sulfur atoms having equal radioactivity. This discovery, plus the fact that trithionate was not reduced to thiosulfate under identical conditions, led to the speculation that bisulfite could be reduced to thiosulfate by another pathway not involving trithionate.     

A new sulfurtransferase from the hyperthermophilic bacterium Aquifex aeolicus. Being single is not so simple when temperature gets high

Sulfur is a functionally important element of living matter. Rhodanese is involved in the enzymatic production of the sulfane sulfur which has been suggested as the biological relevant active sulfur species. Rhodanese domains are ubiquitous structural modules occurring in the three major evolutionary phyla. We characterized a new single-domain rhodanese with a thiosulfate : cyanide transferase activity, Aq-477. Aq-477 can also use tetrathionate and polysulfide. Thermoactivity and thermostability studies show that in solution Aquifex sulfurtranferase exists in equilibrium between monomers, dimers and tetramers, shifting to the tetrameric state in the presence of substrate. We show that oligomerization is important for thermostability and thermoactivity. This is the first characterization of a sulfurtransferase from a hyperthermophilic bacterium, which moreover presents a tetrameric organization. Oligomeric Aq-477 may have been selected in hyperthermophiles because subunit association provides extra stabilization.     

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.     

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 level of sulfane sulfur in the fungus <Emphasis Type="Italic">Aspergillus nidulans</Emphasis> wild type and mutant strains

The interdependence of the sulfane sulfur metabolism and sulfur amino acid metabolism was studied in the fungus Aspergillus nidulans wild type strain and in mutants impaired in genes encoding enzymes involved in the synthesis of cysteine (a precursor of sulfane sulfur) or in regulatory genes of the sulfur metabolite repression system. It was found that a low concentration of cellular cysteine leads to elevation of two sulfane sulfurtransferases, rhodanase and cystathionine γ-lyase, while the level of 3-mercaptopyruvate sulfurtransferase remains largely unaffected. In spite of drastic differences in the levels of biosynthetic enzymes and of sulfur amino acids due to mutations or sulfur supplementation of cultures, the level of total sulfane sulfur is fairly stable. This stability confirms the crucial role of sulfane sulfur as a fine-tuning regulator of cellular metabolism.     

Biochemical studies on sulfate-reducing bacteria. XIV. Enzyme levels of adenylylsulfate reductase, inorganic pyrophosphatase, sulfite reductase, hydrogenase, and adenosine triphosphatase in cells grown on sulfate, sulfite, and thiosulfate.

Sulfate-reducing bacteria, Desulfovibrio vulgaris, strain Miyazaki, were grown on either sulfate, sulfite, or thiosulfate as the terminal electron acceptor. Better growth was observed on sulfite and less growth on thiosulfate than on sulfate. Enzyme levels of adenylylsulfate (APS) reductase [EC 1.8.99.2], reductant-activated inorganic pyrophosphatase [EC 3.6.1.1], sulfite reductase [EC 1.8.99.1] (desulfoviridin), hydrogenase [EC 1.12.2.1], and Mg2+-activated ATPase [EC 3.6.1.3] were compared in crude extracts of these cells at various stages of growth. 1) The specific activity of APS reductase in sulfite-grown cells was only one-fourth that in sulfate-grown cells throughout growth. Thiosulfate-grown cells had an activity intermediate between those of sulfate- and sulfite-grown cells. 2) Cells grown on sulfite had lower specific activity of reductant-activated inorganic pyrophosphatase than cells grown on sulfate or thiosulfate. 3) The specific activity of sulfite reductase (desulfoviridin) was highest in sulfite-grown cells. The sulfite medium gave the enzyme in high yield as well as with high specific activity. 4) The specific activities of hydrogenase and Mg2+-ATPase were not significantly altered by electron acceptors in the growth medium.