Hydrogen sulfide production and fermentative gas production by Salmonella typhimurium require F0F1 ATP synthase activity.

A previously isolated mutant of Salmonella typhimurium lacking hydrogen sulfide production from both thiosulfate and sulfite was shown to have a single mutation which also caused the loss of fermentative gas production and the ability to grow on nonfermentable substrates and which mapped in the vicinity of the atp chromosomal locus. The implication that F0F1 ATP synthase might be essential for H2S and fermentative gas production was explored. The phs plasmid conferring H2S production on wild-type Escherichia coli failed to confer this ability on seven of eight E. coli atp point mutants representing, collectively, the eight genes encoding the subunits of F0F1 ATP synthase. However, it did confer some thiosulfate reductase activity on all except the mutant with a lesion in the ATP synthase catalytic subunit. Localized mutagenesis of the Salmonella atp chromosomal region yielded 500 point mutants unable to reduce thiosulfate to H2S or to produce gas from glucose, but differing in the extents of their ability to grow on succinate, to perform proton translocation as measured in a fluorescence quenching assay, and to reduce sulfite to H2S. Biochemical assays showed that all mutants were completely devoid of both methyl viologen and formate-linked thiosulfate reductase and that N,N'-dicyclohexylcarbodiimide blocked thiosulfate reductase activity by the wild type, suggesting that thiosulfate reductase activity has an absolute requirement for F0F1 ATP synthase. Hydrogenase-linked formate dehydrogenase was also affected, but not as severely as thiosulfate reductase. These results imply that in addition to linking oxidation with phosphorylation, F0F1 ATP synthase plays a key role in the proton movement accompanying certain anaerobic reductions and oxidations.     

Roles for menaquinone and the two trimethylamine oxide (TMAO) reductases in TMAO respiration in Salmonella typhimurium: Mu d(Apr lac) insertion mutations in men and tor.

Three groups of mutants defective in trimethylamine oxide (TMAO) reduction were isolated from Salmonella typhimurium LT2 subjected to transposition mutagenesis with Mu d(Apr lac). Mutants were identified by their acidic reaction on a modified MacConkey-TMAO medium. Group I consisted of pleiotropic chlorate-resistant mutants which were devoid of TMAO reductase activity. None expressed the lac operon. Group II mutants were partially defective in TMAO reductase. Electrophoretic studies revealed that they lacked the inducible TMAO reductase, but retained the constitutive activity. The genotypic designation tor was suggested for these mutants. The tor mutation in one was located between 80 and 83 U on the S. typhimurium chromosome. Expression of the lac operon in these mutants was not affected by air, TMAO, or nitrate. Group III mutants reduced little or no TMAO in vivo, but their extracts retained full capacity to reduce it with methyl viologen. These mutants also failed to produce hydrogen sulfide from thiosulfate and could not grow anaerobically on glycerol-fumarate. Two subgroups were distinguished. Vitamin K5 restored wild-type phenotype in subgroup IIIa only; vitamin K1 restored wild-type phenotype in both IIIa and IIIb isolates. The genotypic designation men (menaquinone) was suggested for group III isolates. The mutation in IIIa mutants was cotransducible with glpT, which corresponds to the menBCD site in Escherichia coli. That in IIIb mutants was cotransducible with glpK, which corresponds to the menA site in E. coli. Expression of the lac operon in IIIa, but not IIIb, mutants was repressed by air. An additional mutant group isolated on the same medium consisted of strains defective in formate hydrogenlyase.     

Characterization of a Thermolabile Sulfite Reductase from Salmonella pullorum

The biochemical basis for sulfite accumulation by sulfate-using revertants of Salmonella pullorum was determined. All of the sulfate-using mutants isolated from wild-type S. pullorum accumulated sulfite when grown at 37 but not at 25 C. The specific activity of reduced nicotinamide adenine dinucleotide (NADPH)-dependent sulfite reductase (H ₂S-NADP oxidoreductase, EC 1.8.1.2) and of reduced methyl viologen (MVH)-dependent sulfite reductase (H ₂S-MV oxidoreductase), in extracts prepared from cells incubated at 37 C, declined as the incubation period lengthened. However, the specific activity of both reductases from cells incubated at 25 C did not decline. Thermolability of cell-free NADPH-dependent sulfite reductase from cells of S. pullorum incubated at 37 C was greater than the lability of this enzyme either from cells of S. typhimurium incubated at 37 C or from cells of S. pullorum incubated at 25 C. Cells cultured at 37 C continued to accumulate sulfite when the incubation temperature was shifted to 25 C; cells cultured at 25 C and shifted to 37 C accumulated no sulfite, whereas these cells shifted to 41 C accumulated sulfite. It was concluded that the configuration of the sulfite reductase of S. pullorum strain 6–18 is a function of the incubation temperature at which synthesis occurs.     

Cloning of the phs genetic locus from Salmonella typhimurium and a role for a phs product in its own induction.

The Salmonella typhimurium phs chromosomal locus essential for the reduction of thiosulfate to hydrogen sulfide was cloned, and some features of its regulation were examined. The phs locus conferred H2S production on Escherichia coli, suggesting that it contains the structural gene for thiosulfate reductase. H2S production by the E. coli host was, as in S. typhimurium, suppressed by nitrate or glucose in the growth medium. The presence of plasmid-borne phs genes in a S. typhimurium chl+ host containing a chromosomal phs::lacZ operon fusion was found to significantly increase the relative induction efficiency of beta-galactosidase by thiosulfate. These results are consistent with a model for phs regulation in which the true inducer is not thiosulfate per se and in which the action of a phs-encoded molybdoprotein, possibly the reductase itself, converts thiosulfate into a compound that resembles the true inducer more closely than does thiosulfate.     

Catabolite repression of thiosulfate reduction bySalmonella typhimurium

The effect of glucose and other carbon sources on thiosulfate reduction and on the expression ofphs bySalmonella typhimurium was examined. Glucose repressed both H₂S production from thiosulfate and methyl viologen-linked thiosulfate reductase activity. Cyclic AMP (2 mM) in the growth medium restored both activities. Cyclic AMP was essential for both activities in acya mutant. Glucose and many other sugars repressedphs expression in both Cya⁺ and Cya^– phs::Mu d1(Ap^r lac) operon fusion mutants. Increasing cyclic AMP to 10 mM increasedphs expression in the presence of some, but not all, sugars. It appears that catabolite repression of thiosulfate reduction inS. typhimurium involves more than a simple requirement for cyclic AMP.     

Chemical modification studies of tryptophan,arginine and lysine residues in maize chloroplast ferredoxin:sulfite oxidoreductase

The ferredoxin-dependent sulfite reductase from maize was treated, in separate experiments, with three different covalent modifiers of specific amino acid side chains. Treatment with the tryptophan-modifying reagent, N-bromosuccinimide (NBS), resulted in a loss of enzymatic activity with both the physiological donor for the enzyme, reduced ferredoxin, and with reduced methyl viologen, a non-physiological electron donor. Formation of the 1:1 ferredoxin/sulfite reductase complex prior to treating the enzyme with NBS completely protected the enzyme against the loss of both activities. Neither the secondary structure, nor the oxidation-reduction midpoint potential (E _m) values of the siroheme and [4Fe–4S] cluster prosthetic groups of sulfite reductase, nor the binding affinity of the enzyme for ferredoxin were affected by NBS treatment. Treatment of sulfite reductase with the lysine-modifying reagent, N-acetylsuccinimide, inhibited the ferredoxin-linked activity of the enzyme without inhibiting the methyl viologen-linked activity. Complex formation with ferredoxin protects the enzyme against the inhibition of ferredoxin-linked activity produced by treatment with N-acetylsuccinimide. Treatment of sulfite reductase with N-acetylsuccinimide also decreased the binding affinity of the enzyme for ferredoxin. Treatment of sulfite reductase with the arginine-modifying reagent, phenylglyoxal, inhibited both the ferredoxin-linked and methyl viologen-linked activities of the enzyme but had a significantly greater effect on the ferredoxin-dependent activity than on the reduced methyl viologen-linked activity. The effects of these three inhibitory treatments are consistent with a possible role for a tryptophan residue the catalytic mechanism of sulfite reductase and for lysine and arginine residues at the ferredoxin-binding site of the enzyme.     

Identification of the molybdenum cofactor in chlorate-resistant mutants of Escherichia coli.

Experiments were performed to determine whether defects in molybdenum cofactor metabolism were responsible for the pleiotropic loss of the molybdoenzymes nitrate reductase and formate dehydrogenase in chl mutants of Escherichia coli. In wild-type E. coli, molybdenum cofactor activity was present in both the soluble and membrane-associated fractions when the cells were grown either aerobically or anaerobically, with and without nitrate. Molybdenum cofactor in the soluble fraction decreased when the membrane-bound nitrate reductase and formate dehydrogenase were induced. In the chl mutants, molybdenum cofactor activity was found in the soluble fraction of chlA, chlB, chlC, chlD, chlE, and chlG, but only chlB, chlC, chlD, and chlG expressed cofactor activity in the membrane fraction. The defect in the chlA mutants which prevented incorporation of the soluble cofactor into the membrane also caused the soluble cofactor to be defective in its ability to bind molybdenum. This cofactor was not active in the absence of molybdate, and it required at least threefold more molybdate than did the wild type in the Neurospora crassa nit-1 complementation assay. However, the cofactor from the chlA strain mediated the dimerization of the nit-1 subunits in the presence and absence of molybdate to yield the 7.9S dimer. Growth of chlA mutants in medium with increased molybdate did not repair the defect in the chlA cofactor nor restore the molybdoenzyme activities. Thus, molybdenum cofactor was synthesized in all the chl mutants, but additional processing steps may be missing in chlA and chlE mutants for proper insertion of cofactor in the membrane.     

Involvement of a protein with molybdenum cofactor in the in vitro activation of nitrate reductase from a chlA mutant of Escherichia coli K12

Chlorate-resistant mutants are pleiotropically defective in molybdoenzyme activities. The inactive derivative of the molybdoenzyme, respiratory nitrate reductase (nitrite: (acceptor) oxidoreductase, EC 1.7.99.4), which is present in cell-free extracts of chlA mutants can be activated by addition of purified protein PA, the presumed active product of the chlA+ locus, but the activity of the purified protein PA is low, since comparatively large amounts of protein PA are required for the activation. Addition of 10 mM tungstate to the growth medium of a chlBchlC double mutant leads to inactivation of both the molybdenum cofactor and protein PA. Protein PA prepared from such cells was unable to potentiate the in vitro activation of nitrate reductase present in the soluble fraction of a chlA mutant. Quantitation of inactive protein PA was determined immunologically using protein PA-specific antiserum. When a heat-treated extract of a wild-type strain was added to purified protein PA or to the supernatant fraction of a chlBchlC double mutant grown with tungstate, a large stimulation in the ability of these preparations to activate chlA nitrate reductase was found. We equate the activator of protein PA with molybdenum cofactor because: (1) both are absent from heated extracts of tungstate-grown chlBchlC double mutant and cofactor defective chlA and chlE mutants; (2) both are present in heated extracts of wild-type strain; and (3) they behave identically on molecular-sieve columns.     

Coupled enzymatic production of sulfite, thiosulfate, and hydrogen sulfide from sulfur: purification and properties of a sulfur oxygenase reductase from the facultatively anaerobic archaebacterium Desulfurolobus ambivalens.

From aerobically grown cells of the extremely thermophilic, facultatively anaerobic chemolithoautotrophic archaebacterium Desulfurolobus ambivalens (DSM 3772), a soluble oxygenase reductase (SOR) was purified which was not detectable in anaerobically grown cells. In the presence of oxygen but not under a hydrogen atmosphere, the enzyme simultaneously produced sulfite, thiosulfate, and hydrogen sulfide from sulfur. Nonenzymatic control experiments showed that thiosulfate was produced mainly in a chemical reaction between sulfite and sulfur. The maximum specific activity of the purified SOR in sulfite production was 10.6 mumol/mg of protein at pH 7.4 and 85 degrees C. The ratio of sulfite to hydrogen sulfide production was 5:4 in the presence of zinc ions. The temperature range of enzyme activity was 50 to 108 degrees C, with a maximum at 85 degrees C. The molecular mass of the native SOR was 550 kilodaltons, determined by gel filtration. It consisted of identical subunits with an apparent molecular mass of 40 kilodaltons in sodium dodecyl sulfate-gel electrophoresis. The particle diameter in electron micrographs was 15 /+- 1.5 nm. The enzyme activity was inhibited by the thiol-binding reagents p-chloromercuribenzoic acid, N-ethyl maleimide, and 2-iodoacetic acid and by flavin adenine dinucleotide, Fe3+, and Fe2+. It was not affected by CN-, N3-, or reduced glutathione.     

A common pathway for the activation of several molybdoenzymes in Escherichia coli K12

Three molybdoenzymes, nitrate reductase, formate benzyl-viologen oxidoreductase and trimethylamine-N-oxide reductase which form part of different systems, have been studied in a parental strain of Escherichia coli K12. When the organism is grown in the presence of 10 mM tungstate, these three enzymes are present in an inactive form which may be activated in vivo by the addition of 1 mM sodium molybdate. The mixing of soluble fractions from chlA and chlB mutants grown under the appropriate conditions leads to the activation of nitrate reductase, formate benzyl-viologen oxidoreductase and trimethylamine-N-oxide reductase. The activation of each enzyme is maximal when the mutants are grown under conditions that lead to the induction of that enzyme in the wild-type strain. The employment of purified proteins, the association factor FA and the Protein PA, which are presumed to be the products of the chlA and chlB genes, has shown that these proteins are responsible for the activation of the three enzymes during the complementation process.     

Proton translocation coupled to trimethylamine N-oxide reduction in anaerobically grown Escherichia coli.

Proton translocation coupled to trimethylamine N-oxide reduction was studied in Escherichia coli grown anaerobically in the presence of trimethylamine N-oxide. Rapid acidification of the medium was observed when trimethylamine N-oxide was added to anaerobic cell suspensions of E. coli K-10. Acidification was sensitive to the proton conductor 3,5-di-tert-butyl-4-hydroxybenzylidenemalononitrile (SF6847). No pH change was shown in a strain deficient in trimethylamine N-oxide reductase activity. The apparent H+/trimethylamine N-oxide ratio in cells oxidizing endogenous substrates was 3 to 4 g-ions of H+ translocated per mol of trimethylamine N-oxide added. The addition of trimethylamine N-oxide and formate to ethylenediaminetetraacetic acid-treated cell suspension caused fluorescence quenching of 3,3'-dipropylthiacarbocyanine [diS-C3-(5)], indicating the generation of membrane potential. These results indicate that the reduction of trimethylamine N-oxide in E. coli is catalyzed by an anaerobic electron transfer system, resulting in formation of a proton motive force. Trimethylamine N-oxide reductase activity and proton extrusion were also examined in chlorate-resistant mutants. Reduction of trimethylamine N-oxide occurred in chlC, chlG, and chlE mutants, whereas chlA, chlB, and chlD mutants, which are deficient in the molybdenum cofactor, could not reduce it. Protons were extruded in chlC and chlG mutants, but not in chlA, chlB, and chlD mutants. Trimethylamine N-oxide reductase activity in a chlD mutant was restored to the wild-type level by the addition of 100 microM molybdate to the growth medium, indicating that the same molybdenum cofactor as used by nitrate reductase is required for the trimethylamine N-oxide reductase system.     

Sequence analysis of the phs operon in Salmonella typhimurium and the contribution of thiosulfate reduction to anaerobic energy metabolism.

The phs chromosomal locus of Salmonella typhimurium is essential for the dissimilatory anaerobic reduction of thiosulfate to hydrogen sulfide. Sequence analysis of the phs region revealed a functional operon with three open reading frames, designated phsA, phsB, and phsC, which encode peptides of 82.7, 21.3, and 28.5 kDa, respectively. The predicted products of phsA and phsB exhibited significant homology with the catalytic and electron transfer subunits of several other anaerobic molybdoprotein oxidoreductases, including Escherichia coli dimethyl sulfoxide reductase, nitrate reductase, and formate dehydrogenase. Simultaneous comparison of PhsA to seven homologous molybdoproteins revealed numerous similarities among all eight throughout the entire frame, hence, significant amino acid conservation among molybdoprotein oxidoreductases. Comparison of PhsB to six other homologous sequences revealed four highly conserved iron-sulfur clusters. The predicted phsC product was highly hydrophobic and similar in size to the hydrophobic subunits of the molybdoprotein oxidoreductases containing subunits homologous to phsA and phsB. Thus, phsABC appears to encode thiosulfate reductase. Single-copy phs-lac translational fusions required both anaerobiosis and thiosulfate for full expression, whereas multicopy phs-lac translational fusions responded to either thiosulfate or anaerobiosis, suggesting that oxygen and thiosulfate control of phs involves negative regulation. A possible role for thiosulfate reduction in anaerobic respiration was examined. Thiosulfate did not significantly augment the final densities of anaerobic cultures grown on any of the 18 carbon sources tested. on the other hand, washed stationary-phase cells depleted of ATP were shown to synthesize small amounts of ATP on the addition of the formate and thiosulfate, suggesting that the thiosulfate reduction plays a unique role in anaerobic energy conservation by S typhimurium.     

The octahaem SirA catalyses dissimilatory sulfite reduction in Shewanella oneidensis MR-1

Shewanella oneidensis MR-1 is a metal reducer that uses a large number of electron acceptors including thiosulfate, polysulfide and sulfite. The enzyme required for thiosulfate and polysulfide respiration has been recently identified, but the mechanisms of sulfite reduction remained unexplored. Analysis of MR-1 cultures grown anaerobically with sulfite suggested that the dissimilatory sulfite reductase catalyses six-electron reduction of sulfite to sulfide. Reduction of sulfite required menaquinones but was independent of the intermediate electron carrier CymA. Furthermore, the terminal sulfite reductase, SirA, was identified as an octahaem c cytochrome with an atypical haem binding site. The sulfite reductase of S. oneidensis MR-1 does not appear to be a sirohaem enzyme, but represents a new class of sulfite reductases. The gene that encodes SirA is located within a 10-gene locus that is predicted to encode a component of a specialized haem lyase, a menaquinone oxidase and copper transport proteins. This locus was identified in the genomes of several Shewanella species and appears to be linked to the ability of these organisms to reduce sulfite under anaerobic conditions.     

Oxidation of protoporphyrinogen in the obligate anaerobe Desulfovibrio gigas.

The anaerobic oxidation of protoporphyrinogen to protoporphyrin was demonstrated in extracts of Desulfovibrio gigas. Protoporphyrin formation occurred in the presence of nitrite, hydroxylamine, sulfite, thiosulfate, ATP plus sulfate, NAD+, NADP+, flavin adenine dinucleotide, flavin mononucleotide, fumarate, 2,6-dichlorophenol-indophenol, methyl viologen, and 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide. With dialyzed cell extracts, highest activities were observed with sulfite, NAD+, and NADP+ as electron acceptors. The enzyme for protoporphyrinogen oxidation was localized in the membrane of D. gigas and displayed optimal activity at pH 7.3 and 28 degrees C.     

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.     

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).     

Regulation of the chlA locus of Escherichia coli K12; involvement of molybdenum cofactor

The chlA locus encodes functions required for the biosynthesis of the molybdopterin part of the molybdenum cofactor. Mutants, carrying gene fusions at the chlA locus, which place beta-galactosidase expression under the control of the chlA promoter, have been isolated employing lambda placMu1 as the mutagen. The mutants exhibited beta-galactosidase expression which was greatly enhanced when grown anaerobically. Secondary mutations at the chlB, D, E or G loci did not affect the high level of expression. The fnr gene product was not required for the anaerobic expression. Bacteriophage lambda transducing phages were isolated which carried the phi(chlA-lac) mutations and were used to construct chlA+/phi(clA-lac) merodiploids. The merodiploids exhibited a much lower level of expression but showed the same characteristics as strains carrying lac fusions to the single chromosomal chlA locus. Genetic evidence is presented which strongly suggests that the molybdenum cofactor is a repressor of chlA expression. The anaerobic enhancement of chlA expression is mediated via a mechanism that is distinct from the molybdenum cofactor effect.     

Synthesis of nitrate reductase components in chlorate-resistant mutants of Escherichia coli.

Specific antibody to purified nitrate reductase from Escherichia coli was used to identify enzyme components present in mutants which lack functional nitrate reductase. chlA and B mutants contained all three subunits present in the wild-type enzyme. Different peptides with a broad range of molecular weights could be precipitated from chlCmutants, and chlE mutants contained either slightly degraded enzyme subunits or no precipitable protein. No mutants produced significant amounts of cytoplasmic enzyme. The chlA and B loci are suggested to function in the synthesis and attachment of a molybdenum-containing factor. The chlC locus is suggested to be the structural gene for nitrate reductase subunit A and chlE is suggested to be involved in the synthesis of the cytochrome b1 apoprotein.