Purification and characterization of an inducible dissimilatory type sulfite reductase from Clostridium pasteurianum

An inducible sulfite reductase was purified from Clostridium pasteurianum. The pH optimum of the enzyme is 7.5 in phosphate buffer. The molecular weight of the reductase was determined to be 83,600 from sodium dodecyl sulfate gel electrophoresis with a proposed molecular structure: ₂₂. Its absorption spectrum showed a maximum at 275 nm, a broad shoulder at 370 nm and a very small absorption maximum at 585 nm. No siroheme chromophore was isolated from this reductase. The enzyme could reduced the following substrates in preferential order: NH₂OH> SeO ₃ ^2- >NO ₂ ^2- at rates 50% or less of its preferred substrate SO ₃ ^2- . The proposed dissimilatory intermediates, S₃O ₆ ^2- or S₂O ₃ ^2- , were not utilized by this reductase while KCN inhibited its activity. Varying the substrate concentration [SO ₃ ^2- ] from 1 to 2.5 mol affected the stoichiometry of the enzyme reaction by alteration of the ratio of H₂ uptake to S^2- formed from 2.5:1 to 3.1:1. The inducible sulfite reductase was found to be linked to ferredoxin which could be completely replaced by methyl viologen or partially by benzyl viologen. Some of the above-mentioned enzyme properties and physiological considerations indicated that it was a dissimilatory type sulfite reductase.Abbreviations SDS sodium dodecyl sulfate - BSA bovine serum albumin - LDH Lactate dehydrogenase     

Buoyant density changes due to intracellular content of sulfur in Chromatium warmingii and Chromatium vinosum

Average specific density of individual cells of pure cultures of Chromatium warmingii and Chromatium vinosum were measured by isopicnic gradient centrifugation with Percoll during growth at constant illumination as a function of the increasing content of intracellular sulfur. Cell number and volume, bacteriochlorophyll a, sulfide, and sulfur were followed in the cultures along with cellular buoyant density. Poly--hydroxybutyrate was monitored at several points during growth of the cultures. The density of C. warmingii changed from 1.071 to 1.108 g cm^-3 (sulfur content per cell varied from 0 to 1.71pg). C. vinosum changed its density from 1.096 to 1.160 g cm^-3 (sulfur content per cell varied from 0 to 0.43 pg). Maximum sulfur content in pg of sulfur per m³ of cell volume were 0.178 for C. warmingii and 0.294 for C. vinosum. Measurement of the differences in buoyant density, volume and sulfur content before and after ethanol extraction of cells with and without intracellular sulfur, allowed tentatively to estimate the density of sulfur inside the cells as 1.219 g cm^-3. Isolation of sulfur globules and centrifugation in density gradients gave a density higher than 1.143 g cm^-3 for these intracellular inclusions.Non-common abbreviations Bchl Bacteriochlorophyll - DMB Density Marker Beads - PHB poly--hydroxybutyrate     

Sulfur metabolism in Thiobacillus denitrificans

The relatively high specific sulfite reductase activity of 25 mU/mg protein was found in extracts from Thiobacillus denitrificans. The absorption spectrum of the partially purified enzyme was similar to the siroheme containing sulfite reductases from other sources. It is suggested that the T. denitrificans sulfite reductase may function during the oxidation of reduced sulfur compounds.     

Sulfate reduction in a cell-free system ofChlorella

Summary During sulfate reduction in a cell-free system ofChlorella activated sulfate of APS is transferred to a thiosulfonate reductase. The sulfate thus bound to the thiosulfonate reductase (i.e. bound sulfite) is reduced to bound sulfide in a ferredoxin dependent reaction. This bound sulfide can be used with O-acetylserine as acceptor for cysteine biosynthesis; serine and O-phosphoserine are not used. An assaysystem for thiosulfonate reductase activity using methylviologen dependent reduction of S₂O₄ ^2– to S^2– is developed and a procedure for isolating thiosulfonate reductase fromChlorella cells is presented. During isolation of thiosulfonate reductase a low weight molecular factor, needed for optimal enzyme activity was lost. The bound sulfite seems to be attached to this factor. Reduction of APS or GS-SO₃H to the level of S^2– is inhibited by cysteine. 50% inhibition of GS-SO₃H reduction was found at a molar cysteine concentration of 6.8×10^–5.Abbreviations APS adenosine-phosphosulfate - PAPS 3-phosphoadenosine-5-phosphosulfate - GSH reduced glutathion - GS-SO₃H S-sulfoglutathion - fd ferredoxin - Mv methylviologen - DTT dithiothreitol     

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     

Reduced inorganic sulfur oxidation supports autotrophic and mixotrophic growth of Magnetospirillum strain J10 and Magnetospirillum gryphiswaldense

Magnetotactic bacteria are present at the oxic–anoxic transition zone where opposing gradients of oxygen and reduced sulfur and iron exist. Growth of non‐magnetotactic lithoautotrophic Magnetospirillum strain J10 and its close relative magnetotactic Magnetospirillum gryphiswaldense was characterized in microaerobic continuous culture. Both strains were able to grow in mixotrophic (acetate + sulfide) and autotrophic (sulfide or thiosulfate) conditions. Autotrophically growing cells completely converted sulfide or thiosulfate to sulfate and produced 7.5 g dry weight per mol substrate at a maximum observed growth rate of 0.09 h^?1 for strain J10 and 0.07 h^?1 for M. gryphiswaldense. The respiratory activity for acetate was repressed in autotrophic and also in mixotrophic cultures, suggesting acetate was used as C‐source in the latter. We have estimated the proportions of substrate used for assimilatory processes and evaluated the biomass yields per mol dissimilated substrate. The yield for lithoheterotrophic growth using acetate as the C‐source was approximately twice the autotrophic growth yield and very similar to the heterotrophic yield, showing the importance of reduced sulfur compounds for growth. In the draft genome sequence of M. gryphiswaldense homologues of genes encoding a partial sulfur‐oxidizing (Sox) enzyme system and reverse dissimilatory sulfite reductase (Dsr) were identified, which may be involved in the oxidation of sulfide and thiosulfate. Magnetospirillum gryphiswaldense is the first freshwater magnetotactic species for which autotrophic growth is shown.     

Cytochromes of the non-thiosulfate-utilizing green sulfur bacterium Chlorobium limicola

Flavocytochrome c-553 of the non-thiosulfateutilizing green sulfur bacterium Chlorobium limicola strain 6330 was partially purified by ion exchange column chromatography and ammonium sulfate fractionation (highest purity index obtained: A ₂₈₀/A _{417 red}=0.96). It is autoxidizable and located in the soluble fraction. This hemoprotein contains a flavin component and one heme per molecule. The dithionite reduced spectrum reveals the typical maxima of a c-type cytochrome: =553,5 nm; =523 nm; =417 nm, while the oxidized form shows a -band at 410 nm and two shoulders at 440 nm and 480 nm indicating the flavin component. The flavocytochrome is a basic protein with an isoelectric point at pH 9.0 (± 0.5), a redox potential of 65 mV, a molecular weight of 56,000. It participates in sulfide oxidation and shows neither adenylylsulfate reductase nor sulfite reductase activity. C. limicola further contains a soluble cytochrome c-555 (highest purity index obtained: A ₂₈₀/A _{412 ox}=0.13; isoelectric point between pH 9.5 and 10) and the non-heme iron-containing proteins rubredoxin and ferredoxin, but lacks cytochrome c-551. Besides these soluble electron transfer proteins a membrane-bound c-type cytochrome (=554,5 nm) can be detected spectrophotometrically.Non-common abbreviations HIPIP high-potential iron sulfur protein - APS adenylylsulfate     

Mechanism of dissimilatory sulfite reduction by Desulfovibrio desulfuricans: purification of a membrane-bound sulfite reductase and coupling iwth cytochrome c 3 and hydrogenase

The localization of the dissimilatory sulfite reductase in Desulfovibrio desulfuricans strain Essex 6 was investigated. After treatment of the cells with lysozyme, 90% of the sulfite reductase activity was found in the membrane fraction, compared to 30% after cell rupture with the French press. Sulfite reductase was purified from the membrane (mSiR) and the soluble (sSiR) fractiion. On SDS-PAGE, both mSiR and sSiR exhibited three bands at 50, 45 and 11 kDa, respectively. From their UV/VIS properties (distinct absorption maxima at 391, 410, 583, 630 nm, enzymes as isolated) and the characteristic red fluorescence in alkaline solution, mSiR and sSiR were identified as desulfoviridin. Sulfite reductase (HSO₃ ^-H₂S) activity was reconstituted by coupling of mSiR to hydrogenase and cytochrome c ₃ from D. desulfuricans. The specific activity of mSiR was 103 nmol H₂ min^-1 mg^-1, and sulfide was the major product (72% of theoretical yield). No coupling was found with sSiR under these conditions. Furthermore, carbon monoxide was used to diferentiate between the membrane-bound and the soluble sulfite reductase. In a colorimetric assay, with photochemically reduced methyl viologen as redox mediator, CO stimulated the activity of sSiR significantly. CO had no effect in the case of mSiR. These studies documented that, as isolated, both forms of sulfite reductase behaved differently in vitro. Clearly, in D. desulfuricans, the six electron conversion HSO₃ ^-H₂S was achieved by a membranebound desulfoviridin without the assistance of artificial redox mediators, such as methyl viologen.Abbreviations SiR sulfite reductase - mSiR sulfite reductase purified from membranes - sSiR sulfite reductase purified from the soluble fraction Enzymes Sulfite reductase, EC 1.8.99.1 Cytochrome c ₃ hydrogenase, EC 1.12.2.1     

Oxidation of H2, organic compounds and inorganic sulfur compounds coupled to reduction of O2 or nitrate by sulfate-reducing bacteria

All of fourteen sulfate-reducing bacteria tested were able to carry out aerobic respiration with at least one of the following electron donors: H₂, lactate, pyruvate, formate, acetate, butyrate, ethanol, sulfide, thiosulfate, sulfite. Generally, we did not obtain growth with O₂ as electron acceptor. The bacteria were microaerophilic, since the respiration rates increased with decreasing O₂ concentrations or ceased after repeated O₂ additions. The amounts of O₂ consumed indicated that the organic substrates were oxidized incompletely to acetate; only Desulfobacter postgatei oxidized acetate with O₂ completely to CO₂. Many of the strains oxidized sulfite (completely to sulfate) or sulfide (incompletely, except Desulfobulbus propionicus); thiosulfate was oxidized only by strains of Desulfovibrio desulfuricans; trithionate and tetrathionate were not oxidized by any of the strains. With Desulfovibrio desulfuricans CSN and Desulfobulbus propionicus the oxidation of inorganic sulfur compounds was characterized in detail. D. desulfuricans formed sulfate during oxidation of sulfite, thiosulfate or elemental sulfur prepared from polysulfide. D. propionicus oxidized sulfite and sulfide to sulfate, and elemental sulfur mainly to thiosulfate. A novel pathway that couples the sulfur and nitrogen cycles was detected: D. desulfuricans and (only with nitrite) D. propionicus were able to completely oxidize sulfide coupled to the reduction of nitrate or nitrite to ammonia. Cell-free extracts of both strains did not oxidize sulfide or thiosulfate, but formed ATP during oxidation of sulfite (37 nmol per 100 nmol sulfite). This, and the effects of AMP, pyrophosphate and molybdate on sulfite oxidation, suggested that sulfate is formed via the (reversed) sulfate activation pathway (involving APS reductase and ATP sulfurylase). Thiosulfate oxidation with O₂ probably required a reductive first step, since it was obtained only with energized intact cells.Abbreviations CCCP carbonyl cyanide m-chlorophenylhydrazone - APS adenosine phosphosulfate or adenylyl sulfate     

Sulfate formation via ATP sulfurylase in thiosulfate- and sulfite-disproportionating bacteria

Disproportionation of thiosulfate or sulfite to sulfate plus sulfide was found in several sulfate-reducing bacteria. Out of nineteen strains tested, eight disproportionated thiosulfate, and four sulfite. Growth with thiosulfate or sulfite as the sole energy source was obtained with three strains (Desulfovibrio sulfodismutans and the strains Bra02 and NTA3); additionally, D. desulfuricans strain CSN grew with sulfite but not with thiosulfate, although thiosulfate was disproportionated. Two sulfur-reducing bacteria, four phototrophic sulfur-oxidizing bacteria (incubated in the dark), and Thiobacillus denitrificans did not disproportionate thiosulfate or sulfite. Desulfovibrio sulfodismutans and D. desulfuricans CSN formed sulfate from thiosulfate or sulfite even when simultaneously oxidizing hydrogen or ethanol, or in the presence of 50 mM sulfate. The capacities of sulfate reduction and of thiosulfate and sulfite disproportionation were constitutively present. Enzyme activities required for sulfate reduction (ATP sulfurylase, pyrophosphatase, APS reductase, sulfite reductase, thiosulfate reductase, as well as adenylate kinase and hydrogenase) were detected in sufficient activities to account for the growth rates observed. ADP sulfurylase and sulfite oxidoreductase activities were not detected. Disproportionation was sensitive to the uncoupler carbonylcyanide m-chlorophenylhydrazone (CCCP) but not to the ATPase inhibitor dicyclohexylcarbodiimide (DCCD). It is proposed that during thiosulfate and sulfite disproportionation sulfate is formed via APS reductase and ATP sulfurylase, but not by sulfite oxidoreductase. Reversed electron transport must be assumed to explain the reduction of thiosulfate and sulfite by the electrons derived from APS reductase.Abbreviations CCCP Carbonylcyanide m-chlorophenylhydrazone - DCCD N,N-dicyclohexylcarbodiimide - APS adenosine 5-phosphosulfate (adenylylsulfate)     

Insight into the molecular mechanism of the sulfur oxidation process by reverse sulfite reductase (rSiR) from sulfur oxidizer <Emphasis Type="Italic">Allochromatium vinosum</Emphasis>

Sulfur metabolism is one of the oldest known biochemical processes. Chemotrophic or phototrophic proteobacteria, through the dissimilatory pathway, use sulfate, sulfide, sulfite, thiosulfate or elementary sulfur by either reductive or oxidative mechanisms. During anoxygenic photosynthesis, anaerobic sulfur oxidizer Allochromatium vinosum forms sulfur globules that are further oxidized by dsr operon. One of the key redox enzymes in reductive or oxidative sulfur metabolic pathways is the DsrAB protein complex. However, there are practically no reports to elucidate the molecular mechanism of the sulfur oxidation process by the DsrAB protein complex from sulfur oxidizer Allochromatium vinosum. In the present context, we tried to analyze the structural details of the DsrAB protein complex from sulfur oxidizer Allochromatium vinosum by molecular dynamics simulations. The molecular dynamics simulation results revealed the various types of molecular interactions between DsrA and DsrB proteins during the formation of DsrAB protein complex. We, for the first time, predicted the mode of binding interactions between the co-factor and DsrAB protein complex from Allochromatium vinosum. We also compared the binding interfaces of DsrAB from sulfur oxidizer Allochromatium vinosum and sulfate reducer Desulfovibrio vulgaris. This study is the first to provide a comparative aspect of binding modes of sulfur oxidizer Allochromatium vinosum and sulfate reducer Desulfovibrio vulgaris.     

Purification of Thiobacillus denitrificans siroheme sulfite reductase and investigation of some molecular and catalytic properties.

A siroheme-containing sulfite reductase was isolated from Thiobacillus denitrificans, purified to an electrophoretically homogenous state, and investigated with regard to some of its molecular and catalytic properties. The enzyme was a tetramer with a molecular weight of 160 000, consisting of two types of subunits arranged to an alpha 2 beta 2-structure. The molecular weight of the alpha-subunit was 38 000, that of the beta-subunit 43 000. As prosthetic groups siroheme and Fe/S groupings could be detected. The absorption spectrum showed maxima at 273 nm, 393 nm, and 594 nm; the molar extinction coefficient at these wavelengths were 280, 181, and 60 . 10(3) cm2 . mmol-1, respectively. With reduced viologen dyes the enzyme reduced sulfite to sulfide, thiosulfate and trithionate. In many properties T. denitrificans sulfite reductase closely resembled desulfoviridin, the dissimilatory sulfite reductase of Dssulfovibrio species. It is proposed that the physiological function of this enzyme is not to reduce but rather to form sulfite from reduced sulfur compounds in the course of dissimilatory sulfur oxidation in T. denitrificans.     

Uptake of sulfate,sulfite and thiosulfate by proton-anion symport in Desulfovibrio desulfuricans

pH changes and sulfide production upon addition of sulfate, sulfite or thiosulfate to non-buffered H₂-saturated cell suspensions of Desulfovibrio desulfuricans were studied by means of electrodes. The addition of these electron acceptors resulted in a rapid alkalinization of the suspension which was accompanied by sulfide production. At-2° C, alkalinization without immediate sulfide production could be obtained. After addition of ³⁵S-labelled sulfate at-2° C, the label was found to be concentrated 7,500-fold in the cells, while 2 protons per sulfate molecule had disappeared from the outer bulk phase. Alkalinization and sulfide production from micromolar electron acceptor additions depended on the transmembraneous proton gradient ( pH), and were reversibly inhibited in alkaline solution (pH>8.0) or by the protonophore carbonylcyanide m-chlorophenylhydrazone (CCCP). Protonophore-inhibited sulfide production from sulfite or thiosulfate could be restored if the cell membranes were permeabilized by the detergent cetyltrimethylammonium bromide (CTAB), or if downhill transport was made possible by the addition of electron acceptors at millimolar concentrations. Sulfate was not reduced under these conditions, presumably because the cells did not contain ATP for its activation. K⁺-and Na⁺-ionophores such as nigericin, valinomycin or monensin appeared to be of limited efficiency in D. desulfuricans. In most experiments, sulfate reduction was inhibited by the K⁺–H⁺ antiporter nigericin in the presence of K⁺, but not by the thiocyanate anion or the K⁺-transporter valinomycin. The results indicate that sulfate, sulfite and thiosulfate are taken up by proton-anion symport, presumably as undissociated acids with an electroneutral mechanism, driven by the transmembraneous pH gradient ( pH) or by a solute gradient. Kinetics of alkalinization and sulfide production in cells grown with different electron acceptors revealed that D. desulfuricans has different specific uptake systems for sulfate and thiosulfate, and obviously also for sulfite. It is proposed that the electron acceptor transport finally will not consume net energy during growth in buffered medium: The protons taken up during active electron acceptor transport leave the cell with the reduced end-product by simple passive diffusion of H₂S.Abbreviations CCCP carbonyl cyanide m-chlorophenylhydrazone - FCCP carbonyl cyanide p-trifluoromethoxy phenylhydrazone - CTAB cethyltrimethylammonium bromide     

Regulation of sulfate assimilation by nitrogen and sulfur nutrition in poplar trees

Plants cover their need for sulfur by taking up inorganic sulfate, reducing it to sulfide, and incorporating it into the amino acid cysteine. In herbaceous plants the pathway of assimilatory sulfate reduction is highly regulated by the availability of the nutrients sulfate and nitrate. To investigate the regulation of sulfate assimilation in deciduous trees we used the poplar hybrid Populus tremula × P. alba as a model. The enzymes of the pathway are present in several isoforms, except for sulfite reductase and -glutamylcysteine synthetase; the genomic organization of the pathway is thus similar to herbaceous plants. The mRNA level of APS reductase, the key enzyme of the pathway, was induced by 3 days of sulfur deficiency and reduced by nitrogen deficiency in the roots, whereas in the leaves it was affected only by the withdrawal of nitrogen. When both nutrients were absent, the mRNA levels did not differ from those in control plants. Four weeks of sulfur deficiency did not affect growth of the poplar plants, but the content of glutathione, the most abundant low molecular thiol, was reduced compared to control plants. Sulfur limitation resulted in an increase in mRNA levels of ATP sulfurylase, APS reductase, and sulfite reductase, probably as an adaptation mechanism to increase the efficiency of the sulfate assimilation pathway. Altogether, although distinct differences were found, e.g. no effect of sulfate deficiency on APR in poplar leaves, the regulation of sulfate assimilation by nutrient availability observed in poplar was similar to the regulation described for herbaceous plants.     

Search for polythionates in cultures of Chromatium vinosum after sulfide incubation

Cultures of Chromatium vinosum, devoid of sulfur globules, were supplemented with sulfide and incubated under anoxic conditions in the light. The concentrations of sulfide, polysulfides, thiosulfate, polythionates and elemental sulfur (sulfur rings) were monitored for 3 days by ion-chromatography and reversed-phase HPLC. While sulfide disappeared rapidly, thiosulfate and elemental sulfur (S₆, S₇ S₈ rings) were formed. After sulfide depletion, the concentration of thiosulfate decreased fairly rapidly, but elemental sulfur was oxidized very slowly to sulfate. Neither polysulfides (S _x ^2– ), polythionates (S_nO ₆ ^2– , n=4–6), nor other polysulfur compounds could be detected, which is in accordance with the fact that sulfide-grown cells were able to oxidize polysulfide without lag. The nature of the intracellular sulfur globules is discussed.     

Urease formation in purple sulfur bacteria (Chromatiaceae) grown on various nitrogen sources

Batch cultures of Thiocapsa roseopersicina strain 6311, Thiocystis violacea strain 2311 and Chromatium vinosum strain 1611, grown anaerobically in the light on sulfide with urea, ammonia, N₂ or casein hydrolysate as nitrogen source exhibited urease activity, while Chromatium vinosum strain D neither showed any degradation of urea nor urease activity on any of the nitrogen sources tested.In T. violacea and C. vinosum strain 1611 urease was little affected by the nitrogen source and seemed to be constitutive. In T. roseopersicina, however, the enzyme was repressed by ammonia (although a low basal level of activity remained) and, to a lesser degree, induced by urea: The presense of urea stimulated a temporary increase in urease activity in the early exponential growth phase. The highest activities, however, were found after growth on N₂, and especially on 0.1% casein hydrolysate (in the absence or after exhaustion of external ammonia), but not before the stationary growth phase was reached. Derepressed urease synthesis required an efficient external source of nitrogen.In cultures of T. roseopersicina urease activity showed a periodic oscillation which depended on the repeated feeding with sulfide and subsequent variation in the sulfur content of the cells. The possible reasons of this oscillation are discussed.     

Purification and Properties of Sulfite Reductase from Desulfovibrio vulgaris,Miyazaki F

The sulfite reductase of Desulfovibrio vulgaris, strain Miyazaki F (MF), was purified by ammonium sulfate precipitation and chromatography on DEAE-cellulose, Ultrogel AcA34, and hydroxylapatite. The molecular weight was estimated to be 180,000 by gel filtration. It had a subunit structure of α₂β₂; the molecular weight of the α subunit was 50,000 and that of β, 39,000. The absorption spectrum with characteristic peaks at 629 and 409 nm and the amino acid composition resembled those of the sulfite reductase from D. vulgaris, Miyazaki K. The MF enzyme reduced sulfite to trithionate, thiosulfate, and sulfide by hydrogen when coupled with a hydrogenase-methyl viologen system, like other sulfite reductases from Desulfovibrio.     

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%.     

Coenzyme F420-dependent sulfite reductase-enabled sulfite detoxification and use of sulfite as a sole sulfur source by Methanococcus maripaludis

Coenzyme F(420)-dependent sulfite reductase (Fsr) of Methanocaldococcus jannaschii, a sulfite-tolerant methanogen, was expressed with activity in Methanococcus maripaludis, a sulfite-sensitive methanogen. The recombinant organism reduced sulfite to sulfide and grew with sulfite as the sole sulfur source, indicating that Fsr is a sulfite detoxification and assimilation enzyme for methanogens and that M. maripaludis synthesizes siroheme.     

Sulfite: Preferential sulfur source and modifier of CO2 fixation in Chlorella vulgaris

Sulfite was added at the time of inoculation to a standard and to a sulfate deficient medium of Chlorella vulgaris. It was not only used as a sulfur source, but besides this, at concentrations <1.0 mmol l^–1, the growth yield was enhanced up to 30% compared to sulfate saturated conditions. Higher sulfite concentrations increasingly inhibited cell growth. Growth rate determinations indicated that the enhancement, and the inhibition respectively, were confined to the very beginning of culture growth; the time period during which the sulfite was not yet oxidized (5–10 h). In contrast, an increased CO₂ fixation rate/unit of protein, occurring up to 5.0 mmol l^–1 sulfite and a shift towards the -carboxylation pathway, are persisting at least during the growth period of 4 days. The preferential uptake of sulfite, also indicated by a marked increase in methionine content of algal protein, presumably causes an increase in thylakoidal sulfolipids, and is such modifying the CO₂ fixation.Abbreviations PGA 3-phosphoglyceric acid - APS adenosine 5-phosphosulfate - PEP phosphoenolpyruvate