Reaction of S-(2-amino-2-carboxyethylsulfonyl)-L-cysteine with thiosulfate: synthesis of L-alanine sulfodisulfane and application to the determination of thiosulfate

A new reaction of S-(2-amino-2-carboxyethylsulfonyl)-L-cysteine (ACESC) with thiosulfate is described. The reaction proceeded quantitatively in formic or acetic acid solutions, yielding equimolar amounts of L-alanine sulfodisulfane (2-amino-2-carboxyethyl sulfodisulfane) and L-alanine 3-sulfinic acid. L-Alanine sulfodisulfane was obtained as pure monosodium salt; the yield was 92% of the theoretical. A new method is described for the determination of thiosulfate. The method is based on the quantitative reaction between ACESC and thiosulfate, and L-alanine sulfodisulfane, one of the reaction products, was determined using acid ninhydrin reagent 2 of M. K. Gaitonde (1967, Biochem. J. 104, 627-633). The recovery was over 95%. When samples contained sulfite in addition to thiosulfate, S-sulfo-L-cysteine (T. Ubuka et al., 1982, Anal. Biochem. 126, 273-277) was produced in addition to L-alanine sulfodisulfane by the treatment with ACESC. Both products were separated by a small Dowex 1 column and determined with the acid ninhydrin reagent 2. The recoveries were over 95%. The new method was applied to the thiosulfate sulfurtransferase reaction, in which thiosulfate, a substrate, and sulfite, a product, were determined separately.     

Reaction of S-(2-amino-2-carboxyethylsulfonyl)-l-cysteine with sulfite: Synthesis of S-sulfo-l-cysteine and l-alanine 3-sulfinic acid and application to the determination of sulfite

A procedure for the simultaneous preparation of S-sulfo-l-cysteine and l-alanine 3-sulfinic acid is described. The method is based on the quantitative reaction between sulfite and S-(2-amino-2-carboxyethylsulfonyl)-l-cysteine. The yield was 95% for S-sulfo-l-cysteine and 91% for l-alanine 3-sulfinic acid. The reaction was also applied to the quantitative determination of sulfite in biological materials. In this procedure, sulfite reacts with S-(2-amino-2-carboxyethylsulfonyl)-l-cysteine. Separation of the reaction product, S-sulfo-l-cysteine, is done by ion-exchange fractionation, and it is determined with acid ninhydrin reagent 2 (M. K. Gaitonde, 1967, Biochem. J.104, 627–663). The recovery was 96.8 ± 0.3%.     

Enzymatic catalysis of the reversible sulfitolysis of glutathione disulfide and the biological reduction of thiosulfate esters

Rat liver supernatants were shown to contain an enzymatic activity catalyzing in both forward and reverse directions the reversible sulfitolysis of glutathione disulfide. The enzymatic sulfitolysis has maximal activity at pH 7. S-Sulfoglutathione, which is a product of the sulfitolysis, was isolated by passage through an ion-exchange column. Three different assays were applied to determine S-sulfoglutathione, viz., methods based on the ninhydrin reaction, the formation of a thiazoline derivative in strong acid, and the use of radioactively labeled glutathione. The reversal of the sulfitolysis, i.e., the reaction of S-sulfoglutathione with glutathione, was studied directly by determination of sulfite with radioactive N-ethylmaleimide, or indirectly by coupling to the NADPH- and glutathione reductase-linked reduction of glutathione disulfide.Chromatographic analysis of rat liver supernatants demonstrated that all fractions catalyzing the reversible sulfitolysis did also catalyze the previously studied thiol-disulfide interchange of glutathione and the mixed disulfide of cysteine and glutathione.The reduction of thiosulfate esters, such as S-sulfocysteine and trimethylammonium-ethylthiosulfate, with glutathione was also catalyzed by the enzyme active in the sulfitolysis, which indicates an important biosynthetic role of the enzyme in microorganisms synthesizing cysteine via S-sulfocysteine. The enzyme is also capable of participating in the formation of the naturally occurring S-sulfoglutathione.     

Homologs from sulfur oxidation (Sox) and methanol dehydrogenation (Xox) enzyme systems collaborate to give rise to a novel pathway of chemolithotrophic tetrathionate oxidation

The SoxXAYZB(CD)₂‐mediated pathway of bacterial sulfur‐chemolithotrophy explains the oxidation of thiosulfate, sulfide, sulfur and sulfite but not tetrathionate. Advenella kashmirensis, which oxidizes tetrathionate to sulfate, besides forming it as an intermediate during thiosulfate oxidation, possesses a soxCDYZAXOB operon. Knock‐out mutations proved that only SoxBCD is involved in A. kashmirensis tetrathionate oxidation, whereas thiosulfate‐to‐tetrathionate conversion is Sox independent. Expression of two glutathione metabolism‐related proteins increased under chemolithotrophic conditions, as compared to the chemoorganotrophic one. Substrate‐dependent oxygen consumption pattern of whole cells, and sulfur‐oxidizing enzyme activities of cell‐free extracts, measured in the presence/absence of thiol inhibitors/glutathione, corroborated glutathione involvement in tetrathionate oxidation. Furthermore, proteome analyses detected a sulfite:acceptor oxidoreductase (SorAB) exclusively under chemolithotrophic conditions, while expression of a methanol dehydrogenase (XoxF) homolog, subsequently named thiol dehydrotransferase (ThdT), was found to increase 3‐ and 10‐fold during thiosulfate‐to‐tetrathionate conversion and tetrathionate oxidation respectively. A thdT knock‐out mutant did not oxidize tetrathionate but converted half of the supplied 40 mM S‐thiosulfate to tetrathionate. Knock‐out of another thiosulfate dehydrogenase (tsdA) gene proved that both ThdT and TsdA individually converted ～ 20 mM S‐thiosulfate to tetrathionate. The overexpressed and isolated ThdT protein exhibited PQQ‐dependent thiosulfate dehydrogenation, whereas its PQQ‐independent thiol transfer activity involving tetrathionate and glutathione potentially produced a glutathione:sulfodisulfane adduct and sulfite. SoxBCD and SorAB were hypothesized to oxidize the aforesaid adduct and sulfite respectively.     

pH-Dependent metabolism of thiosulfate and sulfur globules in the chemolithotrophic marine bacterium Thiomicrospira crunogena

Respiring cells of the chemolithotrophic bacterium Thiomicrospira crunogena produced sulfur globules from the sulfane sulfur of thiosulfate below pH 7, and consumed the globules above pH 7. The switch in metabolism was immediate and reversible upon titration of the culture. The consumed sulfur globules remained in a membrane-bound form and were not oxidized unless the medium was depleted of thiosulfate. Sulfur globule production but not uptake was blocked by azide. Anoxia, thiol-binding agents, and inhibitors of protein synthesis blocked globule uptake. Transitory accumulations of sulfite and polythionates appeared to be reaction products of thiosulfate and sulfur globules. A model depicting the pH sensitivity and biochemistry of sulfur globule production and consumption is proposed.     

A sulfate,sulfite and thiosulfate incorporating system inCandida utilis

Sulfate, sulfite and thiosulfate incorporation in the yeastCandida utilis is inhibited by extracellular sulfate, sulfite and thiosulfate and by sulfate analogues selenate, chromate and molybdate. The three processes are blocked if sulfate, sulfite, thiosulfate, cysteine and homocysteine are allowed to accumulate endogenously. Incorporation of the three inorganic sulfur oxy anions is inactivated by heat at the same rate. Mutants previously shown to be defective in sulfate incorporation are also affected in sulfite and thiosulfate uptake. Revertants of these mutants selected by plating in ethionine-supplemented minimal medium recovered the capacity to incorporate sulfate, sulfite and thiosulfate. These results taken together with previous evidence demonstrate the existence of a common sulfate, sulfite and thiosulfate incorporating system in this yeast.     

Sulfite-oxido-reductase is involved in the oxidation of sulfite in Desulfocapsa sulfoexigens during disproportionation of thiosulfate and elemental sulfur

The enzymatic pathways of elemental sulfur and thiosulfate disproportionation were investigated using cell-free extract of Desulfocapsa sulfoexigens. Sulfite was observed to be an intermediate in the metabolism of both compounds. Two distinct pathways for the oxidation of sulfite have been identified. One pathway involves APS reductase and ATP sulfurylase and can be described as the reversion of the initial steps of the dissimilatory sulfate reduction pathway. The second pathway is the direct oxidation of sulfite to sulfate by sulfite oxidoreductase. This enzyme has not been reported from sulfate reducers before. Thiosulfate reductase, which cleaves thiosulfate into sulfite and sulfide, was only present in cell-free extract from thiosulfate disproportionating cultures. We propose that this enzyme catalyzes the first step in thiosulfate disproportionation. The initial step in sulfur disproportionation was not identified. Dissimilatory sulfite reductase was present in sulfur and thiosulfate disproportionating cultures. The metabolic function of this enzyme in relation to elemental sulfur or thiosulfate disproportionation was not identified. The presence of the uncouplers HQNO and CCCP in growing cultures had negative effects on both thiosulfate and sulfur disproportionation. CCCP totally inhibited sulfur disproportionation and reduced thiosulfate disproportionation by 80% compared to an unamended control. HQNO reduced thiosulfate disproportionation by 80% and sulfur disproportionation by 90%.     

Multiple Forms of Inorganic Pyrophosphatase from the Leaf of Amarantus blitum L.

The existence of a carrier-bound pathway for inorganic sulfate assimilation has been proposed in Chlorella and Escherichia coli. The possibility that the sulfonyl group of active sulfate is transferred to a specific organic acceptor to form thiosulfate ester was examined with Salmonella typhimurium LT-2. Some 11% of the radioactive products from [³⁵S]-3′-phosphoadenosine 5′-phosphosulfate were transferred to high molecular weight compounds, and the remainder of the product is identified as free inorganic sulfite. Apparent thiosulfonate reductase activity was detected in the reaction mixtures containing S-sulfoglutathione and NADPH as conceivable substrates, but not with partially purified sulfite reductase. The former activity was attributable to the nonenzymatic reaction, sulfitolysis. Through these in vitro experiments the existence of the carrier-bound pathway was disproved.     

Purification and properties of thiosulfate reductase from Desulfovibrio gigas.

Thiosulfate reductase of the dissimilatory sulfate-reducing bacterium Desulfovibrio gigas has been purified 415-fold and its properties investigated. The enzyme was unstable during the different steps of purification as well as during storage at - 15 degrees C. The molecular weight of thiosulfate reductase estimated from the chromatographic behaviour of the enzyme on Sephadex G-200 was close to 220000. The absorption spectrum of the purified enzyme exhibited a protein peak at 278 nm without characteristic features in the visible region. Thiosulfate reductase catalyzed the stoichiometric production of hydrogen sulfide and sulfite from thiosulfate, and exhibited tetrathionate reductase activity. It did not show sulfite reductase activity. The optimum pH of thiosulfate reduction occurred between pH 7.4 and 8.0 and its Km value for thiosulfate was calculated to be 5 - 10(-4)M. The sensitivity of thiosulfate reductase to sulfhydryl reagent and the reversal of the inhibition by cysteine indicated that one or more sulfhydryl groups were involved in the catalytic activity. The study of electron transport between hydrogenase and thiosulfate reductase showed that the most efficient coupling was obtained with a system containing cytochromes c3 (Mr = 13000) and c3 (Mr = 26000).     

Purification and properties of thiosulfate reductase from Desulfovibrio vulgaris, Miyazaki F

Thiosulfate reductase was purified to an almost homogeneous state from Desulfovibrio vulgaris, strain Miyazaki F, by ammonium sulfate precipitation, chromatography on DEAE-Toyopearl, Ultrogel AcA 34, and hydroxylapatite, and disc electrophoresis. The specific activity was increased 580-fold over the crude extract. The molecular weight was determined by gel filtration to be 85,000-89,000, differing from those reported for thiosulfate reductases from other Desulfovibrio strains. The enzyme had no subunit structure. When coupled with hydrogenase and methyl viologen, it stoichiometrically reduced thiosulfate to sulfite and sulfide with consumption of hydrogen. It did not reduce sulfite or trithionate. Cytochrome c3 was active as an electron donor. More than 0.75 mM thiosulfate inhibited the enzyme activity. o-Phenanthroline and 2,2'-bipyridine inhibited the enzyme and ferrous ion stimulated the reaction.     

Formation of thiosulfate and trithionate during sulfite reduction by washed cells of Desulfovibrio desulfuricans

Deenergized cells of Desulfovibrio desulfuricans strain Essex 6 formed trithionate and thiosulfate during reduction of sulfite with H₂ or formate. The required conditions were pretreatment with the uncoupler carbonylcyanide m-chlorophenylhydrazone (CCCP), low concentration of the electron donor H₂ or formate (25–200 M) and the presence of sulfite in excess (>250 M). The cells formed up to 20 M thiosulfate, and variable amounts of trithionate (0–9 M) and sulfide (0–62 M). Tetrathionate was not produced. Sulfate could not replace sulfite in these experiments, as deenergized cells cannot activate sulfate. However, up to 5 M thiosulfate was produced by cells growing with H₂ and excess sulfate in a chemostat. Micromolar concentrations of trithionate were incompletely reduced to thiosulfate and sulfide by washed cells in the presence of CCCP. Millimolar trithionate concentrations blocked the formation of sulfide, even in the absence of CCCP, and caused thiosulfate accumulation; sulfide formation from sulfate, sulfite or thiosulfate was stopped, too. Trithionate reduction with H₂ in the presence of thiocyanate was coupled to respiration-driven proton translocation (extrapolated H⁺/H₂ ratios of 1.5±0.6). Up to 150 M trithionate was formed by washed cells during oxidation of sulfite plus thiosulfate with ferricyanide as electron acceptor (reversed trithionate reductase activity). Cell breakage resulted in drastic decrease of sulfide formation. Cell-free extract reduced sulfite incompletely to trithionate, thiosulfate, and sulfide. Thiosulfate was reduced stoichiometrically to sulfite and sulfide (thiosulfate reductase activity). The formation of sulfide from sulfite, thiosulfate or trithionate by cell-free extract was blocked by methyl viologen, leading to increased production of thiosulfate plus trithionate from sulfite, or increased thiosulfate formation from trithionate. Our study demonstrates for the first time the formation of intermediates during sulfite reduction with whole cells of a sulfate-reducing bacterium oxidizing physiological electron donors. All results are in accordance with the trithionate pathway of sulfite reduction.With gratitude dedicated to Prof. Dr. Norbert Pfennig on occasion of his 65th birthday     

OCCURRENCE OF N-ACETYLALANINE IN THE HUMAN BRAIN1

A substance identical with N-acetyl-l -alanine was isolated from an aqueous extract of human brain by a combination of paper and ion-exchange Chromatography. The isolated substance did not react with ninhydrin reagent but yielded alanine upon acid hydrolysis. An acetyl hydrazide was identified by paper chromatography of hydrazinolysates of the isolated substance and N-acetyl-l -alanine. The unknown alanine had the l -configuration. The results of elementary analysis of the isolated compound were in full accord with the analysis calculated for synthetic N-acetyl-l -alanine.     

Anaerobic oxidation of thiosulfate and elemental sulfur in Thiobacillus denitrificans

Thiobacillus denitrificans strain RT could be grown anaerobically in batch culture on thiosulfate but not on other reduced sulfur compounds like sulfide, elemental sulfur, thiocyanate, polythionates or sulfite. During growth on thiosulfate the assimilated cell sulfur was derived totally from the outer or sulfane sulfur. Thiosulfate oxidation started with a rhodanese type cleavage between sulfane and sulfone sulfur leading to elemental sulfur and sulfite. As long as thiosulfate was present elemental sulfur was transiently accumulated within the cells in a form that could be shown to be more reactive than elemental sulfur present in a hydrophilic sulfur sol, however, less reactive than sulfane sulfur of polythionates or organic and inorganic polysulfides. When thiosulfate had been completely consumed, intracellular elemental sulfur was rapidly oxidized to sulfate with a specific rate of 45 natom S°/min·mg protein. Extracellularly offered elemental sulfur was not oxidized under anaerobic conditions.     

The reductive enzymatic cleavage of thiosulfate

Summary Methods presently used for the enzymatic assay of the thiosulfate cleaving reaction in bacterial cell-free systems are critically examined. Conditions under which strong acids are used to terminate the reaction and to release H₂S proved to be unsuitable. A non-enzymatic production of H₂S under such conditions is demonstrated. A reliable procedure for the measurement of H₂S production from the enzymatic cleavage of thiosulfate is described. This method was used to measure the thiosulfate cleaving reaction catalyzed by cell-free extracts of phototrophic bacteria of the genusChromatium. As reductants, hydrogen-hydrogenase/methyl viologen system, reduced glutathione or dihydrolipoate were used. The same extract fraction catalyzed the rhodanese reaction.     

Growth and respiratory oxidation of reduced sulfur compounds by intact cells ofThiobacillus novellus (type strain) grown on thiosulfate

Thiobacillus novellus (type strain) was grown chemolithoautrophically on thiosulfate in batch cultures under microaerophilic conditions. Under these conditions,T. novellus grew exponentially (=0.05–0.06 h^–1). The respiratory oxidation rates of tetrathionate, thiosulfate, elemental sulfur (S^o), and sulfite were measured respirometrically with an oxygen electrode, with exponentially growing cells. Cells growing on thiosulfate as the unique energy source retain thiosulfate-oxidizing activity, S^o-oxidizing activity (SOA), and very high sulfite-oxidizing activity, but lack respiratory tetrathionate-oxidizing activity. HQNO (50 m), an inhibitor of the quinone-cytochrome b region, strongly inhibited the SOA (70%), moderately the sulfite-oxidizing activity (45%), and poorly the thiosulfate-oxidizing activity (15%), 1mm KCN totally inhibited (>89%) all respiratory activities. This study confirms that inThiobacillus novellus, as well as in otherThiobacilli, SOA is present in cells grown with thiosulfate as sole electron donor. SOA appears not to be an oxygenase; it is linked to the respiratory chain, and the electrons are probably released in the quinone-cytochrome b region.     

Hydrogen sulfide-producing kinetics of Shewanella oneidensis in sulfite and thiosulfate respiration

Shewanella oneidensis is a model species for aquatic ecosystems and plays an important role in bioremediation, biofuel cell manufacturing and biogeochemical cycling. S. oneidensis MR-1 is able to generate hydrogen sulfide from various sulfur species; however, its catalytic kinetics have not been determined. In this study, five in-frame deletion mutants of S. oneidensis were constructed and their H₂S-producing activities were analyzed. SirA and PsrA were the two major contributors to H₂S generation under anoxic cultivation, and the optimum SO₃²⁻ concentration for sulfite respiration was approximately 0.8 mM, while the optimum S₂O₃²⁻ concentration for thiosulfate respiration was approximately 0.4 mM. Sulfite and thiosulfate were observed to interfere with each other during respiration, and a high concentration of sulfite or thiosulfate chelated extracellular free-iron but did not repress the expression of sirA or psrA. Nitrite and nitrate were two preferred electron acceptors during anaerobic respiration; however, under energy-insufficient conditions, S. oneidensis could utilize multiple electron acceptors simultaneously. Elucidiating the stoichiometry of H₂S production in S. oneidensis would be helpful for the application of this species in bioremediation and biofuel cell manufacturing, and would help to characterize the ecophysiology of sulfur cycling.     

High-performance liquid chromatographic measurement of exogenous thiosulfate in urine and plasma

A simple technique using reverse-phase ion-pair liquid chromatography for measurement of exogenous thiosulfate is described. Accurate measurement of thiosulfate in plasma and urine was permitted by precolumn derivatization with monobromobimane, a substance that readily yields fluorescent compounds upon reaction with a variety of biologically important nucleophiles including glutathione, cysteine, and sulfite. Using an injection volume of 50 microliters, as little as 0.16 nmol of thiosulfate was reliably measured. The interassay precision of the method was reflected by a coefficient of variation of 7.7% while the coefficient of variation for interassay analysis was 2.6%. Recovery of thiosulfate from plasma was 96.9 +/- 3.2% and greater than 98% from urine. The simplicity, sensitivity, and precision of the method make it ideal for the study of thiosulfate and other important nucleophiles in body fluids.     

Studies of sulfate utilization by algae. 5. Identification of thiosulfate as a major Acid-volatile product formed by a cell-free sulfate-reducing system from chlorella

Separation of the products formed from sulfate-³⁵S by cell-free extracts of Chlorella pyrenoidosa (Emerson Strain 3) has permitted the identification of thiosulfate as a major product which yields acid-volatile radioactivity. The products formed, as separated by Dowex-1-nitrate chromatography, are qualitatively the same whether extracts at pH 7.0 (using TPNH as the reductant) or extracts at pH 9 [using 2,3-dimercaptopropan-1-ol, (BAL) as reductant] are employed. While thiosulfate can be separated without the addition of carrier, the inclusion of carrier improves the recovery. High concentrations of ATP which have been shown previously to inhibit the formation of acid-volatile radioactivity from radioactive sulfate, inhibit the formation of thiosulfate almost completely. Degradation of the thiosulfate formed at normal ATP concentrations reveals that most of the radioactivity is in the SO₃-sulfur of the molecule suggesting that the SH-sulfur is derived from the enzyme extracts. If carrier sulfite is present during thiosulfate formation from sulfate-³⁵S, radioactive sulfite is recovered at the expense of radioactive thiosulfate. Reconstruction experiments utilizing specifically-labeled thiosulfates indicate that radioactive sulfite formation is probably not the result of trapping a normal intermediate, but can be attributed to non-enzymatic exchange between labeled thiosulfate formed from sulfate and the non-radioactive sulfite added, suggesting that free sulfite is not an intermediate in thiosulfate formation from sulfate.     

S-Carboxymethylcysteine Synthase from Escherichia coli

An enzyme that catalyzes the synthesis of S-carboxymethyl- l-cysteine from 3-chloro- l-alanine (3-Cl-Ala) and thioglycolic acid was found in Escherichia coli W3110 and was designated as S- carboxymethyl-l-cysteine synthase. It was purified from the cell-free extract to electrophoretic homogeneity and was crystallized. The enzyme has a molecular weight of 84,000 and gave one band corresponding to a molecular weight of 37,000 on SDS-polyacrylamide gel electrophoresis. The purified enzyme catalyzed the β-replacement reactions between 3-CI-AIa and various thiol compounds. The apparent Km values for 3-Cl-Ala and thioglycolic acid were 40 mM and 15.4 mM. The enzyme showed very low activity as to the α,β-elimination reaction with 3-Cl-Ala and l-serine. It was not inactivated on the incubation with 3-Cl-Ala. The absorption spectrum of the enzyme shows a maximum at 412 nm, indicating that it contains pyridoxal phosphate as a cofactor. The N-terminal amino acid sequence was determined and the corresponding sequence was detected in the protein sequence data bank, but no homogeneous sequence was found.     

Alliinase-like Enzymes in Fruiting Bodies of Lentinus edodes: Their Purification and Substrate Specificity

3-Chloro-d-alanine chloride-lyase, which occurs in the cells of Pseudomonas putida CR 1-1, catalyzes not only the α,β-elimination reaction of 3-chloro-d-alanine to form pyruvate, but also its β-replacement reaction in the presence of a high concentration of sodium hydrosulfide to form d-cysteine. Using the β-replacement reaction, the enzymatic synthesis of d-cysteine by resting cells was investigated. The culture conditions for cell production of the bacterium with high d-cysteine-producing activity and the reaction conditions for d-cysteine production were optimized. Under these optimal reaction conditions, 100% of the added 3-chloro-d-alanine could be converted to d-cysteine and, as the highest yield, 20.6 mg of d-cysteine per 1.0 ml of reaction mixture could be synthesized.