Dissimilatory Sulfite Reductase (Desulfoviridin) of the Taurine-Degrading, Non-Sulfate-Reducing Bacterium Bilophila wadsworthia RZATAU Contains a Fused DsrB-DsrD Subunit

doi:10.1128/JB.183.5.1727-1733.2001

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Journal of Bacteriology, March 2001, p. 1727-1733, Vol. 183, No. 5
0021-9193/01/$04.00+0 DOI: 10.1128/JB.183.5.1727-1733.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.

Dissimilatory Sulfite Reductase (Desulfoviridin) of the Taurine-Degrading, Non-Sulfate-Reducing Bacterium Bilophila wadsworthia RZATAU Contains a Fused DsrB-DsrD Subunit

Heike Laue,¹^,^* Michael Friedrich,² Jürgen Ruff,¹ and Alasdair M. Cook¹

Fachbereich Biologie, Universität Konstanz, D-78457 Konstanz,¹ and Max-Planck-Institut für Terrestrische Mikrobiologie, D-35043 Marburg,² Germany

Received 16 June 2000/Accepted 6 December 2000

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

A dissimilatory sulfite reductase (DSR) was purified from the anaerobic, taurine-degrading bacterium Bilophila wadsworthiaRZATAU to apparent homogeneity. The enzyme is involved in energyconservation by reducing sulfite, which is formed during the degradationof taurine as an electron acceptor, to sulfide. According to itsUV-visible absorption spectrum with maxima at 392, 410, 583, and630 nm, the enzyme belongs to the desulfoviridin type of DSRs.The sulfite reductase was isolated as an $alpha$ ₂ $beta$ ₂ $gamma$ _n (n $>=$ 2) multimer with a native size of 285 kDa as determined by gelfiltration. We have sequenced the genes encoding the $alpha$ and $beta$ subunits(dsrA and dsrB, respectively), which probably constitute one operon.dsrA and dsrB encode polypeptides of 49 ( $alpha$ ) and 54 kDa ( $beta$ ) whichshow significant similarities to the homologous subunits of otherDSRs. The dsrB gene product of B. wadsworthia is apparently afusion protein of dsrB and dsrD. This indicates a possible functionalrole of DsrD in DSR function because of its presence as a fusionprotein as an integral part of the DSR holoenzyme in B. wadsworthia.A phylogenetic analysis using the available Dsr sequences revealedthat B. wadsworthia grouped with its closest 16S rDNA relativeDesulfovibrio desulfuricans Essex6.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Bilophila wadsworthia is a strictly anaerobic, gram-negative bacterium (2) which belongs to the family Desulfovibrionaceaein the delta subdivision of the Proteobacteria, but does not reducesulfate (2, 25). B. wadsworthia has been found quite frequentlyin patients with appendicitis and its complications and is thethird most common anaerobic isolate in such infections (11),but can also be isolated from a wide variety of other infections,e.g., biliary tract infection (41), liver abscess (41), andear infections (39). B. wadsworthia has also been found in thenormal fecal flora (2). The organism lacks classical virulencefactors like capsules, fimbriae, and extracellular enzymes (2).However, preliminary studies have indicated that B. wadsworthiaexerts cytotoxic effects on two cell lines, and endotoxic activityof B. wadsworthia has been described (2, 34).

We recently isolated from a communal sewage plant a strain of B. wadsworthia which utilizes organic sulfonates (e.g., taurine[2-aminoethanesulfonate]) as a carbon source and electron sink.B. wadsworthia respires taurine anaerobically with electrons derivedmainly from formate oxidation and oxidation of the taurine carbon(25). Taurine is transaminated to sulfoacetaldehyde (22),which is cleaved to sulfite and an unidentified organic product(K. Denger and A. M. Cook, unpublished). Finally, sulfite is reducedto sulfide by a dissimilatory sulfite reductase (DSR) (6, 25).In addition, sulfite or thiosulfate serves as an electron acceptorfor anaerobic respiration with formate as the electron donor inB. wadsworthia (25).

DSR, a key enzyme in dissimilatory sulfate reduction, occurs in all organisms capable of reducing sulfite during anaerobicrespiration investigated so far (9, 33). Otherwise, DSRsare rare. An apparently dissimilatory type of sulfite reductaseinducible in the presence of sulfite under anoxic conditions hasbeen found in Salmonella enterica serovar Typhimurium, but thefunction of dissimilatory sulfite reduction by this organism isnot clear (16). The sulfite reductase characterized in Clostridiumpasteurianum was also proposed to be of the dissimilatory typebut differs in its properties from DSRs of sulfate-reducing organisms(12). In contrast to DSRs, assimilatory sulfite reductases areinvolved in assimilation of sulfate in manyorganisms.

DSRs are multisubunit enzymes (167 to 225 kDa) that catalyze the six-electron reduction of sulfite to sulfide. They all containsiroheme and [4Fe-4S] prosthetic centers and are classified accordingto their spectroscopic properties in four major groups (47).Sulfite reductases of the desulfoviridin type are found in Desulfovibriospecies (27). Their subunit structure was initially describedas $alpha$ ₂ $beta$ ₂, with a molecular mass of 50 kDa for the $alpha$ and 40 kDafor the $beta$ subunits (28), but a third subunit, $gamma$ (11 kDa), wasdiscovered, and an $alpha$ ₂ $beta$ ₂ $gamma$ ₂ structure was proposed for Desulfovibriovulgaris (Hildenborough), D. vulgaris oxamicus (Monticello), D.gigas, and D. desulfuricans ATCC 27774 (36).

The dsrA ( $alpha$ subunit) and dsrB ( $beta$ subunit) genes of DSR have been sequenced completely in six organisms: the sulfate-reducingbacterium D. vulgaris (19), the sulfate-reducing archaea Archaeoglobusfulgidus (9) and Archaeoglobus profundus (21), the thermophilic,gram-positive bacterium Desulfotomaculum thermocisternum (21),the sulfur-reducing archaeon Pyrobaculum islandicum (33), andthe "reverse sulfite reductase" of the phototrophic Allochromatiumvinosum (14). The $gamma$ subunit (dsrC) is apparently encoded ina separate locus (18). In all cases except for A. vinosum (14),a third gene, dsrD, encoding a protein of unknown function, wasfound downstream of dsrB. Recently, Wagner et al. developed aPCR assay for the specific amplification of large parts of thedsrA and dsrB genes, which allows the detection of many organismscapable of dissimilatory sulfate reduction (45).

We report here on purification and properties of the DSR that is involved in energy conservation from taurine metabolism inthe anaerobic respiration of B. wadsworthia RZATAU as well asthe relationship of the DsrA and DsrB sequences of B. wadsworthiato those of its sulfate-reducingrelatives.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Bacteria and growth conditions. B. wadsworthia RZATAU (DSM 11045) was routinely grown in batch culture (0.1 or 10 liters) in an anoxic freshwater mineralsalts medium containing 12 mM taurine and 80 mM formate (25).Alternatively, 12 mM isethionate (2-hydroxyethanesulfonate) or12 mM cysteate (2-amino-3-sulfopropionate) plus formate, 12 mMtaurine plus 25 mM pyruvate, or 12 mM thiosulfate plus 20 mM DL-lactatewas used. B. wadsworthia^T was grown in taurine-plus-formate medium. D. vulgaris was grownin the same salts medium in the presence of 20 mM sulfate and20 mM DL-lactate. Desulfovibrio sp. strain RZACYSA was grown insalts medium containing 10 mM cysteate and 20 mM DL-lactate (25).The sources of the chemicals and gases (N₂ and CO₂) used are givenelsewhere (25).

Preparation of cell extracts and enzyme purification. Cells for the purification of DSR were harvested and stored as described elsewhere (23). Preparation of crude extracts bydisruption of suspended cells in a French pressure cell, removalof membrane particles by ultracentrifugation, and precipitationof DNA with streptomycin sulfate are detailed elsewhere (17,23).

DSR from B. wadsworthia RZATAU was purified from the cytosolic fraction of the crude extract in a two-step protocol involvinganion-exchange and gel filtration chromatography. The 2.5-fold-dilutedcrude extract was applied to a Mono Q column (HR 10/10; Pharmacia)equilibrated with 20 mM MOPS (morpholinepropanesulfonic acid,pH 6.5) at a flow rate of 2 ml min¹. Proteins were eluted with an increasing linear gradient to 1M Na₂SO₄ and collected in 5-ml fractions. DSR was identified byits green color, and the identity was confirmed spectroscopicallyand by red fluorescence under alkaline conditions (37). Enrichmentof the protein was monitored by the A₆₃₀/A₂₈₀ ratio (purity indexderived from reference 9; defined as A₆₃₀/A₂₈₀ × 10³). DSR eluted at about 130 mM Na₂SO₄ in one fraction and had apurity index of 174. Concentrated protein was loaded onto a Superose12 column (HR 10/30; Pharmacia) equilibrated at a flow rate of0.4 ml min¹ with 50 mM MOPS (pH 6.5) containing 150 mM Na₂SO₄, and 0.5-mlfractions were collected. The molecular masses of the proteinsused to calibrate the column are described elsewhere (23). Thepurity index of the purified DSR was estimated to be249.

The presence of DSR in crude extract of B. wadsworthia RZATAU grown with different substrates was detected qualitatively byits red fluorescence (37).

Sulfite reductase activity. Formation of sulfide from taurine was investigated in cell extracts from B. wadsworthia RZATAU grown with taurine plus formate.The assay was performed in 100 mM potassium phosphate buffer (pH7.0) containing 5 mM taurine, 5 mM pyruvate, 0.5 mM NAD⁺, 0.1 mM pyridoxal-5'-phosphate, 0.1 mM thiamine pyrophosphate,and 20 mM formate under anoxic conditions in 16-ml serum bottlesclosed with butyl rubber septa. The center of the bottle containeda tube with a filter soaked with cadmium(II) acetate (10%, wt/wt)and NaOH (10%, wt/wt). The reaction was started by addition of0.5 mg of protein, and the bottles were incubated on a shakerat 30°C. Sulfide was determined in aliquots of the reaction mixtureor in the filter by the formation of methylene blue (5).

Gel electrophoresis and N-terminal sequence analysis. Proteins were separated by sodium dodecyl sulfate-12% polyacrylamide gel electrophoresis (SDS-12% PAGE) according to the methodof Laemmli (20) or of Schägger and Jagow (38) and subsequentlystained with Coomassie brilliant blue G-250 (35). Blotting andN-terminal sequencing were done as described elsewhere (23).

Analytical methods. Protein concentrations were determined by the method of Bradford (4) with bovine serum albumin as the standard. UV-visible(UV/VIS) spectra were recorded by an Uvikon 922 spectrophotometer(Kontron). Taurine and alanine were quantified by high-pressureliquid chromatography after derivatization with 2,4-dinitrofluorobenzene(10, 26). The G+C content of B. wadsworthia^T was determined by the German Culture Collection (Braunschweig,Germany) in a sample of 0.8 g (wet weight) ofcells.

Isolation of nucleic acids and DNA amplification procedures. Total DNA was prepared from stationary-phase cultures of B. wadsworthia RZATAU (0.5 liter), D. desulfuricans (0.5 liter),or Desulfovibrio sp. strain RZACYSA (0.2 liter) by the cetyltrimethylammoniumbromide precipitation method (1). The primer pair DSR1F andDSR4R was used to amplify by PCR a 1.9-kb DNA fragment encodingmost of the $alpha$ and $beta$ subunits of DSR (45). PCR was performedas described previously (45) except for the buffer [2.25 mMMgCl₂, 50 mM Tris-HCl (pH 9.2), 14 mM (NH₄)₂SO₄, 10% dimethylsulfoxide] and for the Taq polymerase (MBI) in a Master Cyclergradient thermocycler (Eppendorf). Washed and concentrated cellsof B. wadsworthia RZATAU were also added directly to the PCR mixturesinstead of purified DNA as thetemplate.

PCR amplification of the adenosine phosphosulfate (APS) reductase genes with degenerate primer sets (wh53, wh54, and wh62)involved the thermal profile described by Hipp et al. (14).The reaction buffer described above for the DSR primer set wasused. DNAs from D. desulfuricans and from Desulfovibrio sp. strainRZACYSA were used as positivecontrols.

DNA sequencing and analysis. The nucleotide sequence of the 1.9-kb PCR product from the dsr region was determined by cycle sequencing and primer walkingusing the ABI Prism BigDye Terminator Cycle Sequencing Ready Reactionkit and an ABI 377 DNA sequencer (GATC GmbH). We then used adaptor-ligatedPCR to obtain the complete sequences of the genes encoding the $alpha$ and $beta$ subunits of DSR. Genomic DNA was digested with differentrestriction enzymes and ligated to an adaptor of known sequence(Universal Genome Walker kit; Clontech). Nested PCR was done withthe Advantage Tth polymerase mix (Clontech) and primer deducedfrom specific dsrA or dsrB gene sequences in combination withthe adaptor primer. The dsr primer sequences for amplificationof the upstream region were CAT GCA CGG TTC CAC CGG CGA CAT CGTGCT (primary PCR) and GGA GCC ACG GAG TTC CCA AAT GTC GCA CAG(nested PCR). To amplify the 3' end of dsrB, two adaptor-ligatedPCRs were done successively using primers GCG CCG TGC ACT GCTCCG ACA TCG GTA TCG (primary PCR) and GGT ATC CAC CGC AAG CCTCCG ATG ATC GAC (nested PCR) for the first and AGG ACT TCC TTGAAC TCT TCC CCA CCA AGG (primary PCR) and GTC CGT GCT CGT GTCCGA AGA GTC TCT GGA (nested PCR) for the second PCR. Upstreamof the 1.9-kb sequence, a 1.8-kb amplification product was obtained,while downstream a 0.9-kb DNA fragment was amplified and sequenced.Sequence alignments were done using ClustalX (44).

Phylogeny of DsrA and DsrB. The phylogenetic analysis (i.e., sequence alignments and treeing) was performed by using the ARB software package (version2.5b; O. Strunk and W. Ludwig, Technische Universität München,Munich, Germany [http://www.biol.chemie.tu-muenchen.de/pub/ARB/]).Deduced DSR amino acid sequences were fitted manually into analignment of DSR sequences retrieved from public databases (3)using the Genetic Data Environment (version 2.2) as implementedin the ARB software package. Prior to treeing analysis, aminoacid frequency filters (20 to 100% sequence similarity) were generatedfor a concatenated data set comprising the amino acid sequencesof the $alpha$ (364 positions) and $beta$ (238 positions) subunit data sets.Treeing was performed on the concatenated $alpha$ and $beta$ subunit datasets using distance matrix analysis [FITCH (PHYLIP version 3.5)and neighbor-joining (ARB)], parsimony [PROTPARS (PHYLIP version3.5)], and maximum likelihood [PROTML (PHYLIP version 3.5)] asoutlined previously (45). Bootstrap analysis (100 resamplings)was performed using parsimony analysis as implemented in the PHYLIPpackage.

Nucleotide sequence accession numbers. The sequences encoding the $alpha$ and $beta$ subunits of DSR from B. wadsworthia RZATAU (accession no. AF269147) and D. desulfuricans(accession no. AF273034) have been deposited inGenBank.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Activity and purification of DSR from B. wadsworthia RZATAU. In cell extracts of B. wadsworthia RZATAU, 1.6 mM alanine and 80 µM sulfide were formed from taurine (5 mM) and formate (20mM). However, sulfide was only detectable when trapped from thegas phase with cadmium acetate. In the absence of taurine, negligibleamounts of sulfide were formed. We thus presume that there isDSR activity in the extract but that sulfide reacts with othercomponents in the aqueous mixture (13) and that formation ofsulfide is underestimated. The enzyme rapidly lost activity, soits purification depended on assaying its physical properties.DSR was detected by fluorescence in crude extracts of cells grownwith taurine plus formate or pyruvate, cysteate or isethionateplus formate, thiosulfate plus lactate, or pyruvate as the solecarbon and energy source. We purified DSR from a soluble extractof B. wadsworthia RZATAU grown with taurine and formate. The proteinfrom anion-exchange chromatography was about 90% pure, and apparenthomogeneity was obtained by gel filtration chromatography (notshown). Based on the purity index (A₆₃₀/A₂₈₀), it can be calculatedthat DSR was purified 11-fold and represents about 9% of the solubleprotein of B. wadsworthia.

Molecular properties. SDS-PAGE of the protein showed three bands with apparent molecular masses of 53, 49, and 11 kDa (Fig. 1), so DSR seems tobe composed of three different subunits. The protein eluted fromgel filtration under nondenaturing conditions with an apparentmolecular mass of 285 kDa.

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FIG. 1. Purification of DSR from B. wadsworthia RZATAU monitored by SDS-PAGE. Protein was separated on an SDS-12% PAGE gel and subsequently stained with Coomassie brilliant blue. Lanes: M, molecular mass standards (in kilodaltons); 1, fraction from Mono Q chromatography (10 µg); 2, fraction from gel filtration on Superose 12 (10 µg).

DSR had a UV/VIS spectrum with absorption maxima at 392, 410, 583, and 630 nm (not shown), characteristic of desulfoviridin(27). The molar extinction coefficients of B. wadsworthia DSRat 392, 410, 583, and 630 nm were estimated to be 5.5 × 10⁵, 5.8 × 10⁵, 1.1 × 10⁵, and 2.0 × 10⁵ M¹ cm¹, respectively. Under alkaline conditions, the enzyme showed redfluorescence, also characteristic of desulfoviridin (37).

The N-terminal sequences of the three subunits were determined by Edman degradation (Table 1). A comparison was done withthe amino acid sequence of the subunits of the DSRs from D. vulgarisand D. desulfuricans (Table 1). The N-terminal sequences of the $alpha$ , $beta$ , and $gamma$ subunits of the three organisms were each highly conserved.The data indicated, however, that the largest subunit (53 kDa)from B. wadsworthia exhibited similarities to the $beta$ subunit fromD. vulgaris (40 kDa) and D. desulfuricans (45 kDa), whereas the49-kDa subunit of the B. wadsworthia enzyme was similar to the $alpha$ subunits (50 kDa) from the same organisms.

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TABLE 1. Alignment of the N-terminal amino acid sequences of DSR subunits ( $alpha$ , $beta$ , and $gamma$ ) determined by Edman degradation from D. vulgaris Hildenborough, D. desulfuricans Essex 6, and B. wadsworthia RZATAU^a

Nucleotide sequence analysis. A 1.9-kb DNA region encoding most of the $alpha$ and $beta$ subunits of DSR was amplified by PCR from B. wadsworthia. The sequence showedhigh similarities to those determined for D. vulgaris and otherorganisms. This was in contrast to the different sizes of the $beta$ subunits (53 kDa rather than 40 to 45 kDa; Table 1), so weamplified and sequenced the complete dsrAB region. A total of4.3 kb of double-stranded sequence was examined. It comprisedthree open reading frames, ORF1, dsrA, and dsrB. The gene dsrA(1,317 bp) was identified because the deduced amino acid sequenceincluded the N-terminal sequence that we observed in the $alpha$ subunit.Similarly, dsrB (1,452 bp) was identified because the N-terminalamino acid sequence of the $beta$ subunit corresponded to the deducedsequence.

In contrast to the published value for the G+C content of B. wadsworthia^T (39 to 40 mol% [2]), we now report the G+C content to be 59.2%,so the G+C content of dsrA and dsrB (59.4 and 60.2%, respectively)corresponds to the overall G+C content of the organism. A putativepromoter sequence was located 123 nucleotides upstream of thetranslational start of the dsrA gene, and a putative transcriptionterminator was found downstream of the stop codon of dsrB. Thestart codons of dsrA and dsrB are both preceded by a putativeribosome-binding site (not shown). The intergenic distance betweenthe 3' end of the dsrA and the 5' end of the dsrB gene comprised18 nucleotides, analogous to the dsr operons of D. vulgaris andA. fulgidus (19).

The amino acid sequences deduced from dsrA and dsrB consisted of 438 and 483 residues, respectively, but the initiating methionineresidue was obviously removed from each protein after synthesis.The derived sizes of the $alpha$ (49.0 kDa) and $beta$ (53.6 kDa) subunitsare in good agreement with the data determined for the purifiedsulfite reductase (49 and 53 kDa, respectively). The isoelectricpoints calculated for DsrA and DsrB were 5.3 and 6.5,respectively.

The third open reading frame, ORF1 (711 bp), was located at the 5' end of the 4.3-kb DNA fragment, 618 bp upstream of thetranslational start codon of dsrA. Parts of the deduced aminoacid sequence exhibited similarities to the rare lipoprotein A(rlpA) from Escherichia coli (39% identity) (42). The regionbetween ORF1 and dsrA contained no open reading frames of morethan 130 bp inlength.

Sequence similarities. The deduced amino acid sequences of dsrA and dsrB were highly similar to the $alpha$ and $beta$ subunits of DSRs from other sulfate-reducingmicroorganisms (Table 2). Analysis of partial DSR sequence data(available via the ~1.9-kb DSR PCR fragment) revealed that DsrAof B. wadsworthia RZATAU was most similar to that of D. desulfuricansEssex 6 on both the nucleotide and deduced amino acid levels (88.3and 86.0%, respectively; Table 2), whereas DsrB was slightlymore similar to that of D. vulgaris (83.6 and 82.3%, respectively;Table 2).

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TABLE 2. Sequence similarities of DSR $alpha$ and $beta$ subunit gene fragments (dsrA and dsrB) and their deduced amino acid sequences (DsrA and DsrB)^a

Full amino acid sequences (all positions) of DsrA were 84% identical to DsrA from D. vulgaris (19) and 57% identical toDsrA from A. fulgidus (9). Amino acids 1 to 381 of DsrB exhibited83% identity to DsrB from D. vulgaris (19) and 56% identityto DsrB from A. fulgidus (9), while the C-terminal amino acidsexhibited no similarity to other DsrBs. However, the C-terminalamino acids 405 to 483 of DsrB were 59% identical to DsrD fromD. vulgaris (19), 42% identical to DsrD from Desulfotomaculumthermocisternum (21), and 46% identical to DsrD from A. fulgidus(9) (Fig. 2). Amino acids 382 to 404 of the B. wadsworthiaDsrB showed similarities neither to other DsrBs nor to other DsrDs.Between the 3' end of dsrB and the 5' end of dsrD in D. vulgarisand A. fulgidus are 58 and 41 bp of intergenic sequence, respectively.

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FIG. 2. Sequence comparisons with DSR from B. wadsworthia RZATAU. (A) Amino acid sequences derived from dsrB (upper line) aligned with those of DsrB from D. vulgaris (lower line). The amino acid sequence positions are indicated in the margins. Highly conserved cysteine residues proposed to coordinate siroheme-[4Fe-4S] binding (9) are indicated by boxes. Amino acids which do not show any homologies are in boldface. (B) Alignment of amino acids 405 to 483 of DsrB from B. wadsworthia DSR (Bw), with DsrD from D. vulgaris (Dv), Desulfotomaculum thermocisternum (Dt), A. fulgidus (Af), and A. profundus (Ap). Conserved lysine and arginine residues are indicated by boxes; a conserved stretch of eight amino acids is shown in boldface. *, positions with a conserved residue; :, positions with a conservative replacement.

Phylogeny of DsrA and DsrB. Phylogenetic trees for the DSR $alpha$ and $beta$ subunits (not shown) and for a region representing $alpha$ and $beta$ subunits (Fig. 3) were estimatedfrom deduced amino acid data sets of the ~1.9-kb PCR product bydistance matrix, parsimony, and maximum-likelihood methods. Consistently,B. wadsworthia RZATAU grouped with its closest 16S rDNA relativeD. desulfuricans Essex 6 (91.5% 16S rDNA sequence similarity).This tree topology was supported by all treeing algorithms utilized,by high bootstrap scores, and by individual analyses of both subunitsas well as analysis of the concatenated $alpha$ and $beta$ subunit data sets.

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FIG. 3. Phylogenetic tree reflecting the relationship of the B. wadsworthia RZATAU DSR to the DSRs from Desulfovibrio sp. and other sulfate-reducing microorganisms (21, 45). Tree topology was estimated by using FITCH distance matrix analysis of the concatenated $alpha$ and $beta$ subunit amino acid data sets (546 positions, including D. vulgaris positions 73 to 421 [DsrA] and 18 to 257 [DsrB]). Parsimony analysis was used to determine bootstrap values with an identical data set. Bootstrap values are only indicated for branches, which were recovered in the majority of bootstrap replicates (>50%). The scale bar indicates the number of expected amino acid substitutions per site per unit of branch length. GenBank accession numbers used: U58114, U58115, U58118 to U58127, M95624, AF071499, AF074396, U16723, AF273034, and AF269147.

Investigation of presence of genes encoding APS reductase. PCR conditions and primer sets (14) to amplify regions of the apr genes (encoding APS reductase) were applied to investigatethe presence of these genes in B. wadsworthia. However, we didnot obtain specific PCR fragments of the apr gene in B. wadsworthia,though in the Desulfovibrio control strains the corresponding1.6- or 2.2-kb products were detected. The presumed absence ofthe apr genes is also reflected by the fact that B. wadsworthiais not able to reduce sulfate (6).

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

DSR was purified from B. wadsworthia as an inactive protein which we initially identified by its spectral and fluorescenceproperties and confirmed by sequence homologies. No other greenprotein was detected in separated extracts (H. Laue, unpublishedresults). We detected three subunits, $alpha$ (49 kDa), $beta$ (53 kDa),and $gamma$ (11 kDa) (Fig. 2), and we interpret the native structureto be $alpha$ ₂ $beta$ ₂ $gamma$ _n (n $>=$ 2), as suggested for D. desulfuricansEssex 6 (40). The function of the 11-kDa $gamma$ subunit that wascopurified in most sulfite reductases (36) except that fromA. fulgidus (9) is not clear at present. Whereas Pierik etal. reported that the $gamma$ subunit was tightly associated in theDSR of D. vulgaris (36), it was shown that in D. desulfuricansEssex 6, this subunit can be separated during gel filtration,which indicated a less tight association of DsrC with the $alpha$ and $beta$ subunits in that organism (40). The presence and positionof the putative promoter 123 nucleotides upstream of the translationalstart of the dsrA gene and putative termination sequences downstreamof the stop codon of dsrB indicate that dsrA and dsrB constitutea single transcription unit and that the genes are coordinatelyexpressed.

The order and sequences of the dsrAB genes of DSR from bacteria and archaea are highly conserved. Whereas in all organismssequenced so far except A. vinosum, the operon consists of dsrA,dsrB, and dsrD, in B. wadsworthia there are only two genes, dsrAand dsrB. Apparently, the dsrB gene product of B. wadsworthiais a fusion of dsrB and dsrD. A function for DsrD has not beendetected in earlier biochemical work (19); however, the presenceof DsrD as an integral part of the DSR holoenzyme in B. wadsworthiaas a DsrB-DsrD fusion suggests a possible involvement in DSR function.This hypothesis is further corroborated by the high degree ofconservation of DsrD sequences (Fig. 2) among the microorganismssequenced so far, which suggests an essential role of this proteinin dissimilatory sulfite reduction in general. Because of itshigh content and significant conservation of Lys residues amongDsrDs, a function as a sulfite-binding protein was proposed (19),but spectroscopic analysis of DsrD indicated that it bound neithersulfite nor sulfide (15). Alignment of DsrD from five differentorganisms shows in addition to the conserved Lys residues, a short,remarkably conserved stretch of eight amino acids (Y W/F S S/TG S T T) (Fig. 2) (21). Recently, DsrD from D. vulgaris Hildenboroughhas been crystallized, and preliminary results concerning thecrystal structure have been described (32). The forthcominghigh-resolution three-dimensional structure may provide a clueto the function ofDsrD.

The stretch of 23 residues between the sequences homologous to dsrB and dsrD in the DSR of B. wadsworthia revealed no homologiesto these genes. The presence of several small residues like alanine(nine residues) and glycine (two residues) may indicate a functionas a linker between the DsrB and DsrD domains, possibly necessaryto allow correctassembly.

DSRs usually contain two sirohemes and additional iron-sulfur clusters, possibly four of the [4Fe-4S] type (9). By sequencealignment of different siroheme [4Fe-4S]-binding proteins, Dahlet al. identified highly conserved cysteine-containing clusters(C-X₅-C)-X_n-(C-X₃-C) proposed to coordinate siroheme-[4Fe-4S]binding (9). This arrangement was also present in the predictedDsrA and DsrB amino acid sequence from B. wadsworthia, which indicatesthe same content of siroheme. Analogous to DsrB from A. fulgidus(9) and D. vulgaris (19), the first Cys residue of this motifin DsrB is replaced by a Thr residue (Fig. 2), so that the $alpha$ subunitis most likely to bind siroheme, with no binding of the $beta$ subunit.Crane et al. showed that based on the crystallographic structureof E. coli sulfite reductase hemoprotein (8), key residuesimportant for stability and function of siroheme-containing sulfiteand nitrite reductases are clustered in five homology regions,H1 to H5 (7). As has been shown for the $alpha$ and $beta$ subunits ofDSR from D. vulgaris (7), the corresponding subunits of theB. wadsworthia enzyme also contained conserved sequences belongingto the homologyregions.

The codon usage of the dsr genes of B. wadsworthia is very similar to the codon usage of the dsr genes of D. vulgaris, e.g.,the arginine codons in B. wadsworthia are, as in D. vulgaris (19),almost exclusively CGT or CGC (41 of 43 codons). This is alsoreflected by the nearly identical G+C content of these genes (60.4%for D. vulgaris [19] and 59.8% for B. wadsworthia). B. wadsworthiadiffers in the prevalence of GAA for glutamate (65 of 70 codons)from D. vulgaris, which utilizes the codons GAA and GAG (36 and24 of 60 codons,respectively).

The similar codon usage is perhaps not surprising, because B. wadsworthia is phylogenetically a member of the Desulfovibrionaceae,and its nearest defined neighbor is D. desulfuricans^T (25). The phylogeny is based on the similarity of the 16S rDNAsequences, which is not reflected in the published G+C contentsof these bacteria, 59% for D. desulfuricans^T (46) and 40% for B. wadsworthia^T (2). The latter value was obtained when cells had to be harvestedfrom plates and worked up for melting points (2), whereas therecent discovery of ready growth in liquid culture facilitateshigh growth yields of metabolically active cells (22, 23),from which DNA was separated and hydrolyzed, and the monomerswere subjected to chromatographic separation and determination.The newly obtained value (59.2%) for the G+C content correspondsto the G+C content of the B. wadsworthia genes sequenced in thiswork and elsewhere (22, 23) and is consistent with the valuesfor the family Desulfovibrionaceae, e.g., 59% for D. desulfuricansand 66% for D. vulgaris (46).

One might speculate that B. wadsworthia, which does not reduce sulfate, was once a sulfate reducer and that the capacity forsulfate reduction was lost. The coupling of putative sulfite generationfrom organosulfonates with energy conservation involving DSR iswell known in Desulfovibrio spp. (24, 29, 30) as it is inB. wadsworthia (25). What probably distinguishes most Desulfovibriospp. from B. wadsworthia is clinical importance (2, 11, 39,41), though recent papers suggest pathogenic roles for someDesulfovibrio spp. (31, 43).

	ACKNOWLEDGMENTS

This work was supported by the Deutsche Forschungsgemeinschaft (H.L.) and the Max Planck Society (M.F.).

M. Claros (Leipzig) kindly made B. wadsworthia^T available. We thank K. Sulger (Konstanz) for providing purified desulfoviridinfrom D. vulgaris, L. Cobianchi (Konstanz) for N-terminal sequencing,B. Wagner (Marburg) for excellent technical assistance, and J.Fritz-Steuber (Zürich), U. Schumacher (Tübingen), and C. Kisker(Stony Brook) for valuablediscussions.

	FOOTNOTES

^* Corresponding author. Mailing address: Fachbereich Biologie, Universität Konstanz, Universitätsstr. 10, D-78457 Konstanz,Germany. Phone: 7531 88 4385. Fax: 7531 88 29 66. E-mail: heike_laue{at}hotmail.com.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

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2. Baron, E. J., P. Summanen, J. Downes, M. C. Roberts, H. Wexler, and S. M. Finegold. 1989. Bilophila wadsworthia, gen. nov. and sp. nov., a unique gram-negative anaerobic rod recovered from appendicitis specimens and human faeces. J. Gen. Microbiol. 135:3405-3411[Medline].

3. Benson, O. D. A., I. Karsch-Mizrachi, D. J. Lipman, J. Ostell, B. A. Rapp, and D. L. Wheeler. 2000. GenBank. Nucleic Acids Res. 28:15-18[Abstract/Free Full Text].

4. Bradford, M. 1976. A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Anal. Biochem. 72:248-254[CrossRef][Medline].

5. Cline, J. D. 1969. Spectrophotometric determination of hydrogen sulfide in natural waters. Limnol. Oceanogr. 14:454-458.

6. Cook, A. M., H. Laue, and F. Junker. 1999. Microbial desulfonation. FEMS Microbiol. Rev. 22:399-419[CrossRef].

7. Crane, B. R., and E. D. Getzoff. 1996. The relationship between structure and function for the sulfite reductases. Curr. Opin. Struct. Biol. 6:744-756[CrossRef][Medline].

8. Crane, B. R., L. M. Siegel, and E. D. Getzoff. 1995. Sulfite reductase structure at 1.6 Å: evolution and catalysis for reduction of inorganic anions. Science 270:59-67[Abstract/Free Full Text].

9. Dahl, C., N. M. Kredich, R. Deutzmann, and H. G. Trüper. 1993. Dissimilatory sulphite reductase from Archaeoglobus fulgidus: physico-chemical properties of the enzyme and cloning, sequencing and analysis of the reductase genes. J. Gen. Microbiol. 139:1817-1828[Medline].

10. Denger, K., H. Laue, and A. M. Cook. 1997. Anaerobic taurine oxidation: a novel reaction by a nitrate-reducing Alcaligenes sp. Microbiology (Reading UK) 143:1919-1924[Abstract].

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13. Heunisch, G. W. 1976. Stoichiometry of the reaction of sulfites with hydrogen sulfide ion. Inorg. Chem. 16:1411-1413[CrossRef].

14. Hipp, W. M., A. S. Pott, N. Thum-Schmitz, I. Faath, C. Dahl, and H. G. Trüper. 1997. Towards the phylogeny of APS reductases and sirohaem sulfite reductases in sulfate-reducing and sulfur-oxidizing prokaryotes. Microbiology (Reading UK) 143:2891-2902[Abstract].

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19. Karkhoff-Schweizer, R. R., D. P. W. Huber, and G. Voordouw. 1995. Conservation of the genes for dissimilatory sulfite reductase from Desulfovibrio vulgaris and Archaeoglobus fulgidus allows their detection by PCR. Appl. Environ. Microbiol. 61:290-296[Abstract].

20. Laemmli, U. K. 1970. Cleavage of structural proteins during the assembly of the head of bacteriophage T4. Nature (London) 227:680-685[CrossRef][Medline].

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31. Loubinoux, J., F. Mory, I. A. C. Pereira, and A. E. Le Faou. 2000. Bacteremia caused by a strain of Desulfovibrio related to the provisionally named Desulfovibrio fairfieldensis. J. Clin. Microbiol. 38:931-934[Abstract/Free Full Text].

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	ALL ASM JOURNALS

1.	Ausubel, F. M., R. Brent, R. E. Kingston, D. D. Moore, J. G. Seidman, J. A. Smith, and K. Struhl (ed.). 1987. Current protocols in molecular biology. Wiley, New York, N.Y.
2.	Baron, E. J., P. Summanen, J. Downes, M. C. Roberts, H. Wexler, and S. M. Finegold. 1989. Bilophila wadsworthia, gen. nov. and sp. nov., a unique gram-negative anaerobic rod recovered from appendicitis specimens and human faeces. J. Gen. Microbiol. 135:3405-3411[Medline].
3.	Benson, O. D. A., I. Karsch-Mizrachi, D. J. Lipman, J. Ostell, B. A. Rapp, and D. L. Wheeler. 2000. GenBank. Nucleic Acids Res. 28:15-18[Abstract/Free Full Text].
4.	Bradford, M. 1976. A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Anal. Biochem. 72:248-254[CrossRef][Medline].
5.	Cline, J. D. 1969. Spectrophotometric determination of hydrogen sulfide in natural waters. Limnol. Oceanogr. 14:454-458.
6.	Cook, A. M., H. Laue, and F. Junker. 1999. Microbial desulfonation. FEMS Microbiol. Rev. 22:399-419[CrossRef].
7.	Crane, B. R., and E. D. Getzoff. 1996. The relationship between structure and function for the sulfite reductases. Curr. Opin. Struct. Biol. 6:744-756[CrossRef][Medline].
8.	Crane, B. R., L. M. Siegel, and E. D. Getzoff. 1995. Sulfite reductase structure at 1.6 Å: evolution and catalysis for reduction of inorganic anions. Science 270:59-67[Abstract/Free Full Text].
9.	Dahl, C., N. M. Kredich, R. Deutzmann, and H. G. Trüper. 1993. Dissimilatory sulphite reductase from Archaeoglobus fulgidus: physico-chemical properties of the enzyme and cloning, sequencing and analysis of the reductase genes. J. Gen. Microbiol. 139:1817-1828[Medline].
10.	Denger, K., H. Laue, and A. M. Cook. 1997. Anaerobic taurine oxidation: a novel reaction by a nitrate-reducing Alcaligenes sp. Microbiology (Reading UK) 143:1919-1924[Abstract].
11.	Finegold, S., and H. Jousimies-Somer. 1997. Recently described clinically important anaerobic bacteria: medical aspects. Clin. Infect. Dis. 25:S88-S93.
12.	Harrison, G., C. Curle, and E. J. Laishley. 1984. Purification and characterization of an inducible dissimilatory type sulfite reductase from Clostridium pasteurianum. Arch. Microbiol. 138:72-78[CrossRef][Medline].
13.	Heunisch, G. W. 1976. Stoichiometry of the reaction of sulfites with hydrogen sulfide ion. Inorg. Chem. 16:1411-1413[CrossRef].
14.	Hipp, W. M., A. S. Pott, N. Thum-Schmitz, I. Faath, C. Dahl, and H. G. Trüper. 1997. Towards the phylogeny of APS reductases and sirohaem sulfite reductases in sulfate-reducing and sulfur-oxidizing prokaryotes. Microbiology (Reading UK) 143:2891-2902[Abstract].
15.	Hittel, D. S., and G. Voordouw. 2000. Overexpression, purification and immunodetection of DsrD from Desulfovibrio vulgaris Hildenborough. Antonie van Leeuwenhoek 77:271-280.
16.	Huang, C. J., and E. L. Barret. 1991. Sequence analysis and expression of the Salmonella typhimurium asr operon encoding production of hydrogen sulfide from sulfite. J. Bacteriol. 173:1544-1553[Abstract/Free Full Text].
17.	Junker, F., T. Leisinger, and A. M. Cook. 1994. 3-Sulphocatechol 2,3-dioxygenase and other dioxygenases (EC 1.13.11.2 and EC 1.14.12.-) in the degradative pathways of 2-aminobenzenesulphonic, benzenesulphonic and 4-toluenesulphonic acids in Alcaligenes sp. strain O-1. Microbiology (Reading UK) 140:1713-1722[Abstract].
18.	Karkhoff-Schweizer, R. R., M. Bruschi, and G. Voordouw. 1993. Expression of the $gamma$ -subunit genes of desulfoviridin-type dissimilatory sulfite reductase and of the $alpha$ - and $beta$ -subunit genes is not coordinately regulated. Eur. J. Biochem. 211:501-507[Medline].
19.	Karkhoff-Schweizer, R. R., D. P. W. Huber, and G. Voordouw. 1995. Conservation of the genes for dissimilatory sulfite reductase from Desulfovibrio vulgaris and Archaeoglobus fulgidus allows their detection by PCR. Appl. Environ. Microbiol. 61:290-296[Abstract].
20.	Laemmli, U. K. 1970. Cleavage of structural proteins during the assembly of the head of bacteriophage T4. Nature (London) 227:680-685[CrossRef][Medline].
21.	Larsen, O., T. Lien, and N. K. Birkeland. 1999. Dissimilatory sulfite reductase from Archaeoglobus profundus and Desulfotomaculum thermocisternum: phylogenetic and structural implication from gene sequences. Extremophiles 3:63-70[CrossRef][Medline].
22.	Laue, H., and A. M. Cook. 2000. Biochemical and molecular characterization of taurine:pyruvate aminotransferase from the anaerobe Bilophila wadsworthia. Eur. J. Biochem. 267:6847-6848.
23.	Laue, H., and A. M. Cook. 2000. Purification, properties and primary structure of alanine dehydrogenase involved in taurine metabolism in the anaerobe Bilophila wadsworthia. Arch. Microbiol. 174:162-167[CrossRef][Medline].
24.	Laue, H., K. Denger, and A. M. Cook. 1997. Fermentation of cysteate by a sulfate-reducing bacterium. Arch. Microbiol. 168:210-214[CrossRef].
25.	Laue, H., K. Denger, and A. M. Cook. 1997. Taurine reduction in anaerobic respiration of Bilophila wadsworthia RZATAU. Appl. Environ. Microbiol. 63:2016-2021[Abstract].
26.	Laue, H., J. A. Field, and A. M. Cook. 1996. Bacterial desulfonation of the ethanesulfonate metabolite of the chloroacetanilide herbicide metazachlor. Environ. Sci. Technol. 30:1129-1132[CrossRef].
27.	Lee, J.-P., and H. D. Peck. 1971. Purification of the enzyme reducing bisulfite to trithionate and its identification as desulfoviridin. Biochem. Biophys. Res. Commun. 45:583-589[CrossRef][Medline].
28.	Lee, J.-P., J. LeGall, and H. D. Peck. 1973. Isolation of assimilatory- and dissimilatory-type sulfite reductases from Desulfovibrio vulgaris. J. Bacteriol. 115:529-542[Abstract/Free Full Text].
29.	Lie, T. J., J. R. Leadbetter, and E. R. Leadbetter. 1998. Metabolism of sulfonic acids and other organosulfur compounds by sulfate-reducing bacteria. Geomicrobiol. J. 15:135-149.
30.	Lie, T. J., T. Pitta, E. R. Leadbetter, W. Godchaux III, and J. R. Leadbetter. 1996. Sulfonates: novel electron acceptors in anaerobic respiration. Arch. Microbiol. 166:204-210[CrossRef][Medline].
31.	Loubinoux, J., F. Mory, I. A. C. Pereira, and A. E. Le Faou. 2000. Bacteremia caused by a strain of Desulfovibrio related to the provisionally named Desulfovibrio fairfieldensis. J. Clin. Microbiol. 38:931-934[Abstract/Free Full Text].
32.	Mizuno, N., D. S. Hittel, K. Miki, G. Voordouw, and Y. Higuchi. 2000. Preliminary X-ray crystallographic study of DsrD protein from the sulfate-reducing bacterium Desulfovibrio vulgaris. Acta Crystallogr. Sect. D Biol. Crystallogr. 56:754-755[CrossRef][Medline].
33.	Molitor, M., C. Dahl, I. Molitor, U. Schäfer, N. Speich, R. Huber, R. Deutzmann, and H. G. Trüper. 1998. A dissimilatory sirohaem-sulfite reductase-type protein from the hyperthermophilic archaeon Pyrobaculum islandicum. Microbiology (Reading UK) 144:529-541[Abstract].
34.	Mosca, A., M. D'Alagni, R. Del Prete, G. P. De Michele, P. H. Summanen, S. M. Finegold, and G. Miragliotta. 1995. Preliminary evidence of endotoxic activity of Bilophila wadsworthia. Anaerobe 1:21-24.
35.	Neuhoff, V., N. Arold, D. Taube, and W. Ehrhardt. 1988. Improved staining of proteins in polyacrylamide gels including isoelectric focusing gels with clear background at nanogram sensitivity using Coomassie brilliant blue G-250 and R-250. Electrophoresis 9:255-262[CrossRef][Medline].
36.	Pierik, A. J., G. Duyvis, J. M. L. M. van Helvoort, R. B. G. Wolbert, and W. R. Hagen. 1992. The third subunit of desulfoviridin-type dissimilatory sulfite reductases. Eur. J. Biochem. 205:111-115[Medline].
37.	Postgate, J. R. 1959. A diagnostic reaction of Desulphovibrio desulphuricans. Nature (London) 183:481-482.
38.	Schägger, H., and G. von Jagow. 1987. Tricine-sodium dodecyl sulfate-polyacrylamide gel electrophoresis for the separation of proteins in the range from 1 to 100 kDa. Anal. Biochem. 166:368-379[CrossRef][Medline].
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