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.     

Sulfur requirement of Gonium (Volvocaceae)

The sulfur requirement of six strains of three species of Goniumhas been investigated. These strains can grow well with sulfide,sulfite, bisulfite, thiosulfate or sulfate in light and darkness.They are the first algae shown to utilize sulfide as a sulfursource. However, organic sulfur sources (methionine, cystine,cysteine, homocysteine, homocystine and taurine) were ineffectivefor growth of Gonium. (Received December 6, 1975; )     

Polysulfides as Intermediates in the Oxidation of Sulfide to Sulfate by Beggiatoa spp.

Zero-valent sulfur is a key intermediate in the microbial oxidation of sulfide to sulfate. Many sulfide-oxidizing bacteria produce and store large amounts of sulfur intra- or extracellularly. It is still not understood how the stored sulfur is metabolized, as the most stable form of S⁰ under standard biological conditions, orthorhombic α-sulfur, is most likely inaccessible to bacterial enzymes. Here we analyzed the speciation of sulfur in single cells of living sulfide-oxidizing bacteria via Raman spectroscopy. Our results showed that under various ecological and physiological conditions, all three investigated Beggiatoa strains stored sulfur as a combination of cyclooctasulfur (S₈) and inorganic polysulfides (S_n²⁻). Linear sulfur chains were detected during both the oxidation and reduction of stored sulfur, suggesting that S_n²⁻ species represent a universal pool of bioavailable sulfur. Formation of polysulfides due to the cleavage of sulfur rings could occur biologically by thiol-containing enzymes or chemically by the strong nucleophile HS⁻ as Beggiatoa migrates vertically between oxic and sulfidic zones in the environment. Most Beggiatoa spp. thus far studied can oxidize sulfur further to sulfate. Our results suggest that the ratio of produced sulfur and sulfate varies depending on the sulfide flux. Almost all of the sulfide was oxidized directly to sulfate under low-sulfide-flux conditions, whereas only 50% was oxidized to sulfate under high-sulfide-flux conditions leading to S⁰ deposition. With Raman spectroscopy we could show that sulfate accumulated in Beggiatoa filaments, reaching intracellular concentrations of 0.72 to 1.73 M.     

Thiosulfate production from cystine by the keratinolytic prokaryote Streptomyces fradiae

In cultures of Streptomyces fradiae on wool as the only source of nutrition inorganic thiosulfate (in amounts up to 0.5 mg of Na₂S₂O₃·5 H₂O/ml) was formed as the final product of metabolization of sulfur from cystine of keratin proteins. The presence of thiosulfate was proved by qualitative tests and thin-layer chromatography and estimated quantitatively by spectrophotometry, titrimetry, and capillary isotachophoresis. Metabolization of organic sulfur to thiosulfate excreted into the medium is a process not yet described in microorganisms.     

In vitro utilization of L-cystine by keratinophilic fungi inhabiting a gelatin factory

Twenty-six different species of keratinophilic fungi were examined to determine their ability to utilize free cystine. Of the fungi tested, the majority metabolized free L-cystine in a glucose-peptone culture medium. Cystine was used as source of sulfur, and carbon and nitrogen as well. Excess sulfur was excreted into the culture fluid, as thiosulfate and sulfate, following oxidation. The rate of cystine oxidation varied with the different fungal strains, but was maximal for Graphium penicilloideus (88.5%). Low quantities of thiols were found in the medium. Cystine oxidation and inorganic thiosulfate excretion were found to correlate significantly (r = 0.94).     

Fate of ($ ) S-methyl-L-cysteine sulfoxide in Chinese cabbage, Brassica pekinensis RUPR.

($) S-methyl-L-cysteine sulfoxide (MCS) was scarcely found inseeds of Chinese cabbage, but was present in relatively largeamounts in all plant parts after germination. Changes in MCScontent paralleled those for soluble sulfur content of tissue. When Na₂³⁵SO₄ was fed to plants, the ³⁵S was predominantly incorporatedinto MCS in the free amino acid fraction in both sulfur-sufficientand deficient plants, but it was incorporated to a greater extentin the former. ³⁵S-MCS was metabolized more readily in deficientthan in sufficient plants, and its sulfur was found not onlyin various soluble compounds but in the insoluble fractionsfrom plants as well. These results indicate that MCS is a conspicuousconstituent in the free amino acid pool of Chinese cabbage andmay play an important role in sulfur metabolism by acting asa soluble pool for organic sulfur. (Received June 22, 1970; )     

Regulation of exocellular protease in Neurospora crassa: induction and repression under conditions of nitrogen starvation.

Exponential-phase cells of Neurospora crassa require the continued presence of a protein inducer and nitrogen starvation to induce exocellular protease under conditions where protein is the sole nitrogen source. The nature of the protein inducer appears relatively unimportant, since both soluble proteins (e.g., myoglobin) and insoluble proteins (e.g., corn zein) will effect induction. Nonstarved cells of N. crassa appear to have small nitrogen pools, since nitrogen starvation of exponential cells prior to transfer into a medium where protein is the sole nitrogen source effects starvation-time-dependent decreases in protease biosynthesis. Ammonium ion represses protease synthesis, with apparent specificity at low concentrations. The amino acids arginine, tryptophan, and threonine effect repression of protease biosynthesis under conditions of nitrogen starvation. Under conditions of sulfur starvation, the amino acids cysteine, methionine, and cystine repress protease biosynthesis. In carbon-starved cells, all of the above amino acids, plus histidine, isoleucine, leucine, lysine, phenylalanine, and valine, effect repression. Examination of amino acid pools formed when cells are grown on protein as the sole nitrogen source demonstrated that the amino acids which repress protease biosynthesis under conditions where protein is the sole carbon source accumulate in significant amounts during the course of protease induction, with kinetics consonant with the induction process.     

Dimethylsulfoniopropionate and Methanethiol Are Important Precursors of Methionine and Protein-Sulfur in Marine Bacterioplankton

Organic sulfur compounds are present in all aquatic systems, but their use as sources of sulfur for bacteria is generally not considered important because of the high sulfate concentrations in natural waters. This study investigated whether dimethylsulfoniopropionate (DMSP), an algal osmolyte that is abundant and rapidly cycled in seawater, is used as a source of sulfur by bacterioplankton. Natural populations of bacterioplankton from subtropical and temperate marine waters rapidly incorporated 15 to 40% of the sulfur from tracer-level additions of [³⁵S]DMSP into a macromolecule fraction. Tests with proteinase K and chloramphenicol showed that the sulfur from DMSP was incorporated into proteins, and analysis of protein hydrolysis products by high-pressure liquid chromatography showed that methionine was the major labeled amino acid produced from [³⁵S]DMSP. Bacterial strains isolated from coastal seawater and belonging to the α-subdivision of the division Proteobacteria incorporated DMSP sulfur into protein only if they were capable of degrading DMSP to methanethiol (MeSH), whereas MeSH was rapidly incorporated into macromolecules by all tested strains and by natural bacterioplankton. These findings indicate that the demethylation/demethiolation pathway of DMSP degradation is important for sulfur assimilation and that MeSH is a key intermediate in the pathway leading to protein sulfur. Incorporation of sulfur from DMSP and MeSH by natural populations was inhibited by nanomolar levels of other reduced sulfur compounds including sulfide, methionine, homocysteine, cysteine, and cystathionine. In addition, propargylglycine and vinylglycine were potent inhibitors of incorporation of sulfur from DMSP and MeSH, suggesting involvement of the enzyme cystathionine γ-synthetase in sulfur assimilation by natural populations. Experiments with [methyl-³H]MeSH and [³⁵S]MeSH showed that the entire methiol group of MeSH was efficiently incorporated into methionine, a reaction consistent with activity of cystathionine γ-synthetase. Field data from the Gulf of Mexico indicated that natural turnover of DMSP supplied a major fraction of the sulfur required for bacterial growth in surface waters. Our study highlights a remarkable adaptation by marine bacteria: they exploit nanomolar levels of reduced sulfur in apparent preference to sulfate, which is present at 10⁶- to 10⁷-fold higher concentrations.     

Incorporation of methionine by a soluble enzyme system from Escherichia coli

A soluble fraction from Escherichia coli B was found to incorporate methionine into 95°C CCl₃COOH-insoluble fraction. The incorporation required methionyl-tRNA synthetase, methionine tRNA, ATP, Mg²⁺ and bovine milk casein. The casein could be replaced by arginylated bovine serum albumin and arginylated bovine α-lactalbumin. A mixture of 19 amino acids other than methionine and GTP had no effect on the incorporation. KCl was rather inhibitory. Puromycin, RNase A and trypsin inhibited the incorporation, while DNase I did not. The soluble fraction also incorporated the methionyl moiety of methionyl-tRNA. This incorporation was not affected by the addition of free methionine.     

Axonal transport of proteoglycans to the goldfish optic tectum

The study addressed the question of whether³⁵SO₄ labeled molecules that the have been delivered to the goldfish optic nerve terminals by rapid axonal transport include soluble proteoglycans. For analysis, tectal homogenates were subfractionated into a souluble fraction (soluble after centrifugation at 105,000g), a lysis fraction (soluble after treatment with hypotonic buffer followed by centrifugation at 105,000g) and a final 105,000g pellet fraction. The soluble fraction contained 25.7% of incorporated radioactivity and upon DEAE chromatographys was resolved into a fraction of sulfated glycoproteins eluting at 0–0.32 M NaCl and containing 39.5% of total soluble label and a fraction eluting at 0.32–0.60 M NaCl containing 53.9% of soluble label. This latter fraction was included on columns of Sepharose CL-6B with or without 4 M guanidine and after pronase digestion was found to have 51% of its radioactivity contained in the glycosaminoglycans (GAGs) heparan sulfate and chondroitin (4 or 6) sulfate in the ratio of 70% to 30%. Mobility of both intact proteoglycans and constituent GAGs on Sepharose CL-6B indicated a size distribution that is smaller than has been observed for proteoglycans and GAGs from cultured neuronal cell lines. Similar analysis of lysis fraction, containing 11.5% of incorporated³⁵SO₄, showed a mixture of heparan sulfate and chondroitin sulfate containing proteoglycans, apparent free heparan sulfate and few, if any, sulfated glycoproteins. Overall, the result support the hypothesis that soluble proteoglycans are among the molecules axonally transported in the visual system.     

Phloem transport of sulfur in Ricinus

Mature leaves of Ricinus communis fed with ³⁵SO ₄ ^2- in the light export labeled sulfate and reduced sulfur compounds by phloem transport. Only 1–2% of the absorbed radiosulfur is exported to the stem within 2–3 h, roughly 12% of ³⁵S recovered was in reduced form. The composition of phloem translocate moving down the stem toward the root was determined from phloem exudate: 20–40% of the ³⁵S moved in the form of organic sulfur compounds, however, the bulk of sulfur was transported as inorganic sulfate. The most important organic sulfur compound translocated was glutathione, carrying about 70% of the label present in the organic fraction. In addition, methionine and cysteine were involved in phloem sulfur transport and accounted for roughly 10%. Primarily, the reduced forms of both, glutathione and cysteine are prsent in the siever tubes.Abbreviations CySH cysteine - GSH glutathione - GSSG glutathione disulfide - NEM N-ethylmaleimide - CyS-SCy cystine     

Studies of Sulfate Utilization by Algae. 6. Adenosine-3'-Phosphate-5'-Phosphosulfate (PAPS) as an Intermediate in Thiosulfate Formation From Sulfate by Cell-Free Extracts of Chlorella

When cell-free preparations of Chlorella pyrenoidosa Chick (Emerson strain 3) form thiosulfate from labeled sulfate, another radioactive compound also appears. This compound has been isolated in quantity and is shown to be identical with adenosine-3′-phosphate-5′-phosphosulfate (PAPS) on the basis of its chromatographic and electrophoretic behavior, chemical composition, sensitivity to selective degradative enzymes, and its ability to serve as a substrate for rat liver aryl sulphotransferase. In addition, as expected for PAPS, the compound on mild acid treatment yields all of its radioactive sulfur as sulfate, and is converted to a compound identical with adenosine-3′,5′-diphosphate (PAP). Replacement of sulfate and ATP by this PAP³⁵S in the usual incubation mixture yields the same product, thiosulfate, which can be isolated as such or detected as acid-volatile radioactivity. This conversion of PAP³⁵S to thiosulfate still requires the addition of Mg²⁺ and a reductant such as 2,3-dimercaptopropan-1-ol (BAL). The cause of our previous result that high concentrations of ATP inhibit thiosulfate formation from sulfate can be ascribed to a small amount of PAP contaminating the ATP preparations, since PAP proves to be an exceedingly effective inhibitor of the conversion of PAP³⁵S to thiosulfate. Sulfate reduction to thiosulfate by Chlorella extracts is discussed and compared with similar systems from other organisms.     

Studies of sulfate utilization by algae 18. identification of glutathione as a physiological carrier in assimilatory sulfate reduction by Chlorella

Adenosine 5′-phosphosulfate-sulfotransferase is the first enzyme in the pathway of assimilatory sulfate reduction in Chlorella, and transfers the sulfo group from APS (adenosine 5′-phosphosulfate) to a thiol acceptor forming an organic thiosulfate. In vitro, adenosine 5′-phosphosulfate-sulfotransferase transfers to a variety of thiol acceptors, the best among the monothiols is glutathione, the only one to show a regulatory interaction with adenosine 5′-phosphosulfate-sulfotransferase. To identify the physiological acceptor, adenosine 5′-phosphosulfate-sulfotransferase is assayed without thiols; the cell fraction which stimulates adenosine 5′-phosphosulfate-sulfotransferase activity is expected to contain the physiological acceptor. Boiled Chlorella extract contains physiological acceptor when assayed in the presence of adenosine 5′-phosphosulfate-sulfotransferase and NADPH. Physiological acceptor is dialyzable but is retained by filters of 1000 daltons cut off. After passage through DEAE—Sephadex A-25 and Sephadex G-25, physiological acceptor is found to be ninhydrin-positive and shows co-electrophoresis with oxidized glutathione. Upon reduction with dithiothreitol, physiological acceptor moves with reduced glutathione and on acid hydrolysis yields amino acids identical with those from authentic oxidized glutathione. Physiological acceptor, with adenosine 5′-phosphosulfate-sulfotransferase and AP³⁵ S, yields labeled glutathione—S—SO₃⁻. Thiosulfonate reductase from Chlorella reduces glutathione—S—SO₃⁻ to bound sulfide. Only one active accepting component is found in the boiled extracts.     

Effect of oxygen on viability and substrate utilization in Chromatium

Chromatium D can be exposed to oxygen for prolonged periods without any loss in motility or viability. Oxygen did not affect the rate of thiosulfate disappearance from the media, the oxidation of the inner sulfur atom of thiosulfate to sulfate, or the conversion of the outer sulfur atom of thiosulfate to intracellular sulfur, but it did inhibit the oxidation of intracellular sulfur to sulfate. Oxygen partially inhibited the uptake of pyruvate from the medium, but had little effect on the uptake of acetate. The distribution of label from pyruvate-2-¹⁴C into various cell fractions under aerobic conditions differed only slightly from that obtained under anaerobic conditions. Cells utilizing acetate-2-¹⁴C aerobically converted the majority of the metabolized acetate into a cell fraction with the solubility characteristics of poly-β-hydroxybutyric acid, whereas under anaerobic conditions the acetate was distributed throughout the other cell fractions. Oxygen completely prevented the synthesis of bacteriochlorophyll.     

Production of methanethiol and volatile sulfur compounds by the archaeon “Ferroplasma acidarmanus”

Acidophiles are typically isolated from sulfate-rich ecological niches yet the role of sulfur metabolism in their growth and survival is poorly defined. Studies of heterotrophically grown “Ferroplasma acidarmanus” showed that its growth requires a minimum of 100 mM of a sulfate-containing salt. Headspace gas analyses by GC/MS determined that the volatile sulfur compound emitted by active “F. acidarmanus” cultures is methanethiol. In “F. acidarmanus” cultures grown either heterotrophically or chemolithotrophically, methanethiol was produced constitutively. Radiotracer studies with ³⁵S-labeled methionine, cysteine, and sulfate showed that all three were used in methanethiol production. Additionally, ³H-labeled methionine was incorporated into methanethiol and was probably used as a methyl-group donor. Methanethiol production in whole cell lysates supplied with SO₃²⁻ indicated that NADPH-dependant sulfite reductase and methyltransferase activities were present. Cell lysates also contained enzymatic activity for methionine-γ-lyase that cleaved the side chain of either methionine to form methanethiol or cysteine to produce H₂S. Since methanethiol was detected from the degradation of cysteine, it is likely that sulfide was methylated by a thiol methyltransferase. Collectively, these data demonstrate that “F. acidarmanus” produces methanethiol through the metabolism of methionine, cysteine, or sulfate. This is the first report of a methanethiol-producing acidophile, thus identifying a new contributor to the global sulfur cycle.     

Capacity of Azospirillum thiophilum for lithotrophic growth coupled to oxidation of reduced sulfur compounds

Capacity for lithotrophic growth coupled to oxidation of reduced sulfur compounds was revealed in an Azospirillum strain, A. thiophilum BV-S ^T . Oxygen concentration in the medium was the major factor determining the type of energy metabolism (organotrophic or lithotrophic) in the presence of thiosulfate. Under aerobic conditions, metabolism of A. thiophilum BV-S^T was organoheterotrophic, with thiosulfate oxidation to tetrathionate resulting from the interaction with reactive oxygen species, mostly H₂O₂, which was formed in the electron transport chain in the course of oxidation of organic electron donors. Under microaerobic conditions (2 mg/L O₂ in liquid medium), A. thiophilum BV-S^T carried out lithoheterotrophic (mixotrophic) metabolism; enzymes of the dissimilatory type of sulfur metabolism were responsible for thiosulfate oxidation to tetrathionate and sulfate. Two enzyme systems were found in the cells: thiosulfate dehydrogenase, which catalyzes incomplete oxidation of thiosulfate to tetrathionate and the thiosulfate-oxidizing Sox enzyme complex, which is involved in complete oxidation of thiosulfate to sulfate. The genetic determinant of a Sox complex component in A. thiophilum BV-S^T was revealed. The soxB gene was found, and its expression under microaerobic conditions was observed to increase 32-fold compared to aerobic cultivation.     

Assimilatory Sulfate Reduction by the Hemoflagellate Leishmania tarentolae1

SYNOPSIS. Continuous growth of one cell line (UCI variant) of Leishmania tarentolae was achieved in the absence of organic sulfur. These cells were able to use sodium sulfate, and, to a limited extent, sodium sulfite as their sole sulfur source and could utilize methionine sulfoxide in place of L-methionine. A related cell line (RU variant) was unable to grow in organic sulfate-free media nor could these cells utilize methionine sulfoxide. UCI promastigotes incorporated significant amounts of ³⁵S sodium sulfate; killed cells did not take up the label. ³⁵S incorporation was inhibited by sodium molybdate (5 × 10^?4 M), sodium arsenite (5 × 10^?4 M), 2,4-dinitrophenol (1 × 10^?4 M), or KCN (5 × 10^?4 M). RU promastigotes did not incorporate significant amounts of ³⁵S sodium sulfate. Thin layer chromatographs of protein hydrolysates from UCI cells incubated in ³⁵S sodium sulfate revealed several radio opaque spots, one of which had chromatographic properties of cystine. UCI variants of L. tarentolae were therefore capable of assimilatory sulfate reduction whereas RU cells lacked this ability.     

Partitioning of carbon an SO2-sulfur in a native grassland

Summary The seasonal assimilation and within-plant partitioning of ¹⁴CO₂-carbon and ³⁵SO₂-sulfur in field plots of mixed-grass prairie was investigated, as was the dry deposition of ³⁵SO₂ onto surfaces of dead leaves, litter, and soil, and possible effects of continuous low-level SO₂ fumigation on these processes. The proportion of total net-assimilated carbon found below-ground was 45% in May, 51% in July, and 17% in September. As the season progressed, greater proportions of assimilate were partitioned to 5–20 cm depths and less to the 0–5 cm depth. Rhizomes and crowns received greater proportions in late season. Significant fractions of total ³⁴SO₂-deposited sulfur were recovered on dead leaf surfaces as well as litter and soil, suggesting estimates of SO₂ removal based on stomatal resistance alone are inadequate. Only 4% to 7% of total deposited sulfur was translocated belowground, with most going to 0–5 cm roots. In July much greater proportions of the total translocated SO₂-sulfur were found in deeper depths than in September. On SO₂-fumigated plots roots had lower total sulfur concentrations than controls. Furthermore, while on control plots total sulfur in roots at 5–20 cm increased from May to July and decreased from July to September, on fumigated plots there was a decrease followed by an increase suggesting that SO₂ uptake by shoots interferes with the normal pattern of root sulfur uptake and redistribution within the plant. Continuous SO₂ fumigation also seemed to stimulate root growth in July, possibly through a stimulation of photosynthesis.     

Studies on the metabolism of a sulfur-oxidizing bacterium IV.1 Growth and oxidation of sulfur compounds in Thiobacillus thiooxidans

By immersing a few small cellophane bags containing BaCO³ powderin STARKEY's medium, the duration of lag phase in the growthof Thiobacillus thiooxidans is minimized and the yield of cellsis increased ten times that of the previous method. The activitiesof oxidation for sulfur and sulfite change with growth. Sulfiteis oxidized at a comparable rate to that of sulfur oxidationat pH values between 6.0 and 6.5. In the presence of cysteineor glutathione, thiosulfate can be oxidized at a pH above 5.0.At pH values below 4.5, apparent oxidation of thiosulfate andtetrathionate to sulfate is observed. This result is accountedfor by the facts that thiosulfate is decomposed to sulfur andsulfite under the acidic condition at pH values below 4.5, andthat tetrathionate is reduced to thiosulfate enzymatically.In the oxidation of tetrathionate, oxygen uptake begins aftera lag phase, the duration of which depends on the concentrationsof cells and of tetrathionate. Cysteine is oxidized to cystine.The oxidation is strongly inhibited by metal-chelating agents.The cysteine oxidizing activity is, however, quite stable andis not lost by treating cells with organic solvents, sonic oscillation,by heating or lyophilization. ¹III=References (11). ²Partly supported by a grant from the Ministry of Education.