Interaction of selenoprotein PA and the thioredoxin system, components of the NADPH-dependent reduction of glycine in Eubacterium acidaminophilum and Clostridium litorale [corrected]

Phylogenomic analysis of the family Peptostreptococcaceae (Clostridium cluster XI) and proposal for reclassification of Clostridium litorale (Fendrich et al. 1991) and Eubacterium acidaminophilum (Zindel et al. 1989) as Peptoclostridium litorale gen. nov. comb. nov. and Peptoclostridium acidaminophilum comb. nov

In 1994, analyses of clostridial 16S rRNA gene sequences led to the assignment of 18 species to Clostridium cluster XI, separating them from Clostridium sensu stricto (Clostridium cluster I). Subsequently, most cluster XI species have been assigned to the family Peptostreptococcaceae with some species being reassigned to new genera. However, several misclassified Clostridium species remained, creating a taxonomic conundrum and confusion regarding their status. Here, we have re-examined the phylogeny of cluster XI species by comparing the 16S rRNA gene-based trees with protein- and genome-based trees, where available. The resulting phylogeny of the Peptostreptococcaceae was consistent with the recent proposals on creating seven new genera within this family. This analysis also revealed a tight clustering of Clostridium litorale and Eubacterium acidaminophilum. Based on these data, we propose reassigning these two organisms to the new genus Peptoclostridium as Peptoclostridium litorale gen. nov. comb. nov. (the type species of the genus) and Peptoclostridium acidaminophilum comb. nov., respectively. As correctly noted in the original publications, the genera Acetoanaerobium and Proteocatella also fall within cluster XI, and can be assigned to the Peptostreptococcaceae. Clostridium sticklandii, which falls within radiation of genus Acetoanaerobium, is proposed to be reclassified as Acetoanaerobium sticklandii comb. nov. The remaining misnamed members of the Peptostreptococcaceae, [Clostridium] hiranonis, [Clostridium] paradoxum and [Clostridium] thermoalcaliphilum, still remain to be properly classified.

First Insights into the Genome of the Amino Acid-Metabolizing Bacterium Clostridium litorale DSM 5388

Clostridium litorale is a Gram-positive, rod-shaped, and spore-forming bacterium, which is able to use amino acids such as glycine, sarcosine, proline, and betaine as single carbon and energy sources via Stickland reactions. The genome consists of a circular chromosome (3.41 Mb) and a circular plasmid (27 kb).

Selenoproteins in Archaea and Gram-positive bacteria

Selenium is an essential trace element for many organisms by serving important catalytic roles in the form of the 21st co-translationally inserted amino acid selenocysteine. It is mostly found in redox-active proteins in members of all three domains of life and analysis of the ever-increasing number of genome sequences has facilitated identification of the encoded selenoproteins. Available data from biochemical, sequence, and structure analyses indicate that Gram-positive bacteria synthesize and incorporate selenocysteine via the same pathway as enterobacteria. However, recent in vivo studies indicate that selenocysteine-decoding is much less stringent in Gram-positive bacteria than in Escherichia coli. For years, knowledge about the pathway of selenocysteine synthesis in Archaea and Eukarya was only fragmentary, but genetic and biochemical studies guided by analysis of genome sequences of Sec-encoding archaea has not only led to the characterization of the pathways but has also shown that they are principally identical. This review summarizes current knowledge about the metabolic pathways of Archaea and Gram-positive bacteria where selenium is involved, about the known selenoproteins, and about the respective pathways employed in selenoprotein synthesis.

Peroxidase activity of selenoprotein GrdB of glycine reductase and stabilisation of its integrity by components of proprotein GrdE from Eubacterium acidaminophilum

The anaerobe Eubacterium acidaminophilum has been shown to contain an uncharacterized peroxidase, which may serve to protect the sensitive selenoproteins in that organism. We purified this peroxidase and found that it was identical with the substrate-specific "protein B"-complex of glycine reductase. The "protein B"-complex consists of the selenocysteine-containing GrdB subunit and two subunits, which derive from the GrdE proprotein. The specific peroxidase activity was 1.7 U (mg protein)(-1) with DTT and cumene hydroperoxide as substrates. Immunoprecipitation experiments revealed that GrdB was important for DTT- and NADH-dependent peroxidase activities in crude extracts, whereas the selenoperoxiredoxin PrxU could be depleted without affecting these peroxidase activities. GrdB could be heterologously produced in Escherichia coli with coexpression of selB and selC from E. acidaminophilum for selenocysteine insertion. Although GrdB was sensitive to proteolysis, some full-size protein was present which accounted for a peroxidase activity of about 0.5 U (mg protein)(-1) in these extracts. Mutation of the potentially redox-active UxxCxxC motif in GrdB resulted in still significant, but decreased activity. Heterologous GrdB was protected from degradation by full-length GrdE or by GrdE-domains. The GrdB-GrdE interaction was confirmed by copurification of GrdE with Strep-tagged GrdB. The data suggest that GrdE domains serve to stabilise GrdB.

A novel genetic locus outside the symbiotic island is required for effective symbiosis of Bradyrhizobium japonicum with soybean Glycine max

In order to investigate the symbiotic interaction between soybean and Bradyrhizobium japonicum, TnphoA mutagenesis of the microsymbiont was performed. Mutant strain 2-10 was found to induce a strongly reduced number of ineffective nodules. Ultrastructural analysis of the soybean nodule central tissue revealed the presence of numerous starch granules and vacuoles in the infected cells. In addition, the number of symbiosomes was extremely low, indicating an impaired interaction between the plant and invading bacteria. Cloning and sequencing of the mutated DNA region uncovered four open reading frames (ORFs) lacking any data base similarities. ORFs srrA1 and srrA2, the 2-10 TnphoA insertion site, are encoded in the same reading frame. A 35-kDa expression product in Escherichia coli indicated the presence of a common protein, called SrrA (symbiotically relevant region) in B. japonicum 110spc4, encoded by combined srrA1 and srrA2 genes. The analysis of gene disruption mutants revealed that srrB and srrC were also required for effective symbiosis with soybeans. Further downstream the gene for a putative inner membrane protein (pipA) of unknown function was encoded on the opposite strand. Primer extension studies led to the conclusion that the organization of genes differed from the RhizoBase annotation in this particular region of B. japonicum USDA110.

A selenocysteine-containing peroxiredoxin from the strictly anaerobic organism Eubacterium acidaminophilum

A strongly 75Se-labeled 22 kDa protein detected previously showed in its N-terminal sequence the highest similarity to the family of thiol-dependent peroxidases, now called peroxiredoxins. The respective gene prxU was cloned and analyzed. prxU encodes a protein of 203 amino acids (22,470 Da) and contains an in-frame UGA codon (selenocysteine) at the position of the so far strictly conserved and catalytically active Cys47. The second conserved cysteine present in 2-Cys peroxiredoxins was replaced by alanine. Heterologous expression of the Eubacterium acid-aminophilum PrxU as a recombinant selenoprotein in Escherichia coli was not possible. A cysteine-encoding mutant gene, prxU47C, containing UGC instead of UGA was strongly expressed. This recombinant PrxU47C mutant protein was purified to homogeneity by its affinity tag, but was not active as a thiol-dependent peroxidase. The identification of prxU reveals that the limited class of natural selenoproteins may in certain organisms also include isoenzymes of peroxiredoxins, previously only known as non-selenoproteins containing catalytic cysteine residues.

Identification of D-proline reductase from Clostridium sticklandii as a selenoenzyme and indications for a catalytically active pyruvoyl group derived from a cysteine residue by cleavage of a proprotein

Highly active D-proline reductase was obtained from Clostridium sticklandii by a modified purification scheme. The cytoplasmic enzyme had a molecular mass of about 870 kDa and was composed of three subunits with molecular masses of 23, 26, and 45 kDa. The 23-kDa subunit contained a carbonyl group at its N terminus, which could either be labeled with fluorescein thiosemicarbazide or removed by o-phenylenediamine; thus, N-terminal sequencing became feasible for this subunit. L-[14C]proline was covalently bound to the 23-kDa subunit if proline racemase and NaBH4 were added. Selenocysteine was detected in the 26-kDa subunit, which correlated with an observed selenium content of 10.6 g-atoms in D-proline reductase. No other non-proteinaceous cofactor was identified in the enzyme. A 4.8-kilobase pair (kb) EcoRI fragment was isolated and sequenced containing the two genes prdA and prdB. prdA coding for a 68-kDa protein was most likely translated as a proprotein that was posttranslationally cleaved at a threonine-cysteine site to give the 45-kDa subunit and most probably a pyruvoyl-containing 23-kDa subunit. The gene prdB encoded the 26-kDa subunit and contained an in frame UGA codon for selenocysteine insertion. prdA and prdB were transcribed together on a transcript of 4.5 kb; prdB was additionally transcribed as indicated by a 0.8-kb mRNA species.

Substrate-specific selenoprotein B of glycine reductase from Eubacterium acidaminophilum. Biochemical and molecular analysis

The substrate-specific selenoprotein B of glycine reductase (PBglycine) from Eubacterium acidaminophilum was purified and characterized. The enzyme consisted of three different subunits with molecular masses of about 22 (alpha), 25 (beta) and 47 kDa (gamma), probably in an alpha 2 beta 2 gamma 2 composition. PBglycine purified from cells grown in the presence of [75Se]selenite was labeled in the 47-kDa subunit. The 22-kDa and 47-kDa subunits both reacted with fluorescein thiosemicarbazide, indicating the presence of a carbonyl compound. This carbonyl residue prevented N-terminal sequencing of the 22-kDa (alpha) subunit, but it could be removed for Edman degradation by incubation with o-phenylenediamine. A DNA fragment was isolated and sequenced which encoded beta and alpha subunits of PBglycine (grdE), followed by a gene encoding selenoprotein A (grdA2) and the gamma subunit of PBglycine (grdB2). The cloned DNA fragment represented a second GrdB-encoding gene slightly different from a previously identified partial grdBl-containing fragment. Both grdB genes contained an in-frame UGA codon which confirmed the observed selenium content of the 47-kDa (gamma) subunit. Peptide sequence analyses suggest that grdE encodes a proprotein which is cleaved into the previously sequenced N-terminal 25-kDa (beta) subunit and a 22-kDa (alpha) subunit of PBglycine. Cleavage most probably occurred at an -Asn-Cys- site concomitantly with the generation of the blocking carbonyl moiety from cysteine at the alpha subunit.

Various functions of selenols and thiols in anaerobic gram-positive, amino acids-utilizing bacteria

Electron transfer reactions for the reduction of glycine in Eubacterium acidaminophilum involve many selenocysteine (U)- and thiol-containing proteins, as shown by biochemical and molecular analysis. These include an unusual thioredoxin system (-CXXC-), protein A (-CXXU-) and the substrate-specific protein B of glycine reductase (-UXXCXXC-). Most probably a selenoether is formed at protein B by splitting the C-N-bond after binding of the substrate. The carboxymethyl group is then transferred to the selenocysteine of protein A containing a conserved motif. The latter protein acts as a carbon and electron donor by giving rise to a protein C-bound acetyl-thioester and a mixed selenide-sulfide bond at protein A that will be reduced by the thioredoxin system. The dithiothreitol-dependent D-proline reductase of Clostridium sticklandii exhibits many similarities to protein B of glycine reductase including the motif containing selenocysteine. In both cases proprotein processing at a cysteine residue gives rise to a blocked N-terminus, most probably a pyruvoyl group. Formate dehydrogenase and some other proteins from E. acidaminophilum contain selenocysteine, e.g., a 22 kDa protein showing an extensive homology to peroxiredoxins involved in the detoxification of peroxides.

Conserved cysteines in the type 1 deiodinase selenoprotein are not essential for catalytic activity

The iodothyronine deiodinases are a family of oxidoreductases that catalyze the removal of iodide from thyroid hormones. Each of the three isoforms contain selenocysteine at its active site and several cysteine residues that may be important for catalytic activity. Of particular interest in the type I deiodinase (D1) is Cys124, which is vicinal to the selenocysteine at position 126, and Cys194, which has been conserved in all deiodinases identified to date. In the present studies, we have characterized the functional properties of C124A, C194A, and C124A/C194A D1 mutants, which were prepared by site-directed mutagenesis and expressed in COS-7 cells. In broken cell preparations, the sensitivity of the mutants to the selective D1 inhibitors propylthiouracil and aurothioglucose were unaltered. Mutagenesis at the Cys124 position was associated with a 7-11-fold increase in the Km of dithiothreitol, whereas Vmax values remained largely unchanged. However, both mutations resulted in marked decreases in Vmax values when glutathione or a reconstituted thioredoxin cofactor system were used in the assay. In contrast to the results of these in vitro studies, no impairment in deiodinating capability was noted in intact cells expressing equivalent levels of the mutant constructs. These studies demonstrate that Cys124 and Cys194 influence the reactivity of the D1 with thiol cofactors in in vitro assay systems but are not determinants of the sensitivity of the enzyme to propylthiouracil and aurothioglucose. Furthermore, the observation that the cysteine mutants are fully active in intact cells demonstrates that the results of commonly used broken cell assays do not accurately predict the activity of the D1 in intact cells and suggests that glutathione and thioredoxin are not the major thiols utilized in vivo to support D1 activity.

Sirohaem sulfite reductase and other proteins encoded by genes at the dsr locus of Chromatium vinosum are involved in the oxidation of intracellular sulfur

The sequence of the dsr gene region of the phototrophic sulfur bacterium Chromatium vinosum D (DSMZ 180) was determined to clarify the in vivo role of 'reverse' sirohaem sulfite reductase. The dsrAB genes encoding dissimilatory sulfite reductase are part of a gene cluster, dsrABEFHCMK, that encodes four small, soluble proteins (DsrE, DsrF, DsrH and DsrC), a transmembrane protein (DsrM) with similarity to haem-b-binding polypeptides and a soluble protein (DsrK) resembling [4Fe-4S]-cluster-containing heterodisulfide reductase from methanogenic archaea. Northern hybridizations showed that expression of the dsr genes is increased by the presence of reduced sulfur compounds. The dsr genes are not only transcribed from a putative promoter upstream of dsrA but primary transcripts originating from (a) transcription start site(s) downstream of dsrB are also formed. Polar insertion mutations immediately upstream of dsrA, and in dsrB, dsrH and dsrM, led to an inability of the cells to oxidize intracellularly stored sulfur. The capability of the mutants to oxidize sulfide, thiosulfate and sulfite under photolithoautotrophic conditions was unaltered. Photoorganoheterotrophic growth was also unaffected. 'Reverse' sulfite reductase and DsrEFHCMK are, therefore, not essential for oxidation of sulfide or thiosulfate, but are obligatory for sulfur oxidation. These results, together with the finding that the sulfur globules of C. vinosum are located in the extracytoplasmic space whilst the dsr gene products appear to be either cytoplasmic or membrane-bound led to the proposal of new models for the pathway of sulfur oxidation in this phototrophic sulfur bacterium.

Fast purification of thioredoxin reductases and of thioredoxins with an unusual redox-active centre from anaerobic, amino-acid-utilizing bacteria

Thioredoxin reductase and thioredoxin are primarily involved in catabolic metabolism as important electron carriers in anaerobic, amino-acid-degrading bacteria. A general and fast procedure was developed for the purification of thioredoxin reductase and thioredoxin from Eubacterium acidaminophilum, Clostridium litorale, C. sticklandii, C. sporogenes, C. cylindrosporum and 'Tissierella creatinophila' based upon their properties: the binding to 2',5'-AMP-Sepharose by thioredoxin reductase and the inability of thioredoxins to bind to a DEAE-Sephacel column. The consensus sequence at the active site of thioredoxins (-WCGPC-) was found to be modified in all of these anaerobes: Trp-31 (Escherichia coli nomenclature) was replaced by Gly or Ser, Gly-33 by Val or Glu. None of these thioredoxins reacted with thioredoxin reductase of E. coli or vice versa, but they did interact with the thioredoxin reductases obtained from the other anaerobes studied. Based upon their distinguishing features it is suggested that these thioredoxins might form an evolutionarily separate group.

Purification and characterization of protein PB of betaine reductase and its relationship to the corresponding proteins glycine reductase and sarcosine reductase from Eubacterium acidaminophilum

Simple complementation assay systems were developed for the substrate-specific proteins PB of glycine reductase, sarcosine reductase, and betaine reductase, in which acetyl phosphate was detected as the product in all three cases. The betaine-specific subunits of protein B (PB betaine) responsible for betaine reductase activity were purified to homogeneity from cells of Eubacterium acidaminophilum. The molecular masses of the two different subunits were 45 kDa and 48 kDa according to SDS/PAGE. The molecular mass of the native protein was about 200 kDa, indicating and alpha 2 beta 2 structure. The glycine-specific protein B (PB glycine) was partially purified and subunits of 47 kDa and 27 kDa were N-terminally sequenced. The latter subunits cross-reacted with antibodies raised against PB betaine and showed high sequence similarity to the 45-kDa and 48-kDa subunits of PB betaine, respectively. [2-14C]Glycine could be covalently coupled to the 47-kDa subunit by treatment with borohydride. By the same procedure, [2-14C]sarcosine labeled a protein of the same size. Like the sarcosine reductase activity, this protein was not present in glycine-grown cells, indicating its specific involvement in sarcosine metabolism. The labile viologen-dependent formate dehydrogenase purified with the respective PB proteins and could be tentatively assigned to a 95-kDa protein.

Glycine reductase of Clostridium litorale. Cloning, sequencing, and molecular analysis of the grdAB operon that contains two in-frame TGA codons for selenium incorporation

A 2.8-kb HindIII fragment, containing three open reading frames, has been cloned and sequenced from Clostridium litorale. The first gene grdA encoded the selenocysteine-containing protein PA of the glycine reductase complex, a protein of 159 amino acids with a deduced molecular mass of 16.7 kDa. The second gene (grdB) encoded the 47-kDa subunit of the substrate-specific selenoprotein PB glycine that is composed of 437 amino acids. The third gene contained the 5'-region of the gene for thioredoxin reductase, trxB. All gene products shared high similarity with the corresponding proteins from Eubacterium acidaminophilum. In both genes grdA and grdB, the opal termination codon (TGA) was found inframe, indicating the presence of selenocysteine in both polypeptides. Northern-blot analysis showed that grdA and grdB are organized as one operon. Unlike Escherichia coli, no stable secondary structures of the corresponding mRNA were found immediately downstream of the UGA codons to direct an insertion of selenocysteine into the grdA and grdB transcripts of C. litorale. Instead, a secondary structure was identified in the 3'-untranslated region of grdB.

Glycine reductase selenoprotein A is not a glycoprotein: the positive periodic acid-Schiff reagent test is the result of peptide bond cleavage and carbonyl group generation

The complete amino acid sequence of Clostridium sticklandii selenoprotein A, a selenocysteine-containing protein component of the glycine reductase complex, has been established. Both the intact protein and peptide fragments produced by Staphylococcus aureus V8 protease or trypsin were purified by reversed-phase high-performance liquid chromatography and subjected to electrospray ionization mass spectrometric analysis and standard Edman degradation. Selenoprotein A consists of 157 amino acids with a chemical molecular weight of 17,011, in reasonable agreement with the observed molecular weight (17,022.7) determined from its ionization mass spectrum. The sequence of the amino-terminal region of the isolated native protein is Ser-Arg-Phe-Thr-Gly-Lys- Lys-Ile-Val-Ile-Ile-Gly-Asp-Arg-Asp-. An N-terminal methionine residue deduced from the gene sequence was not present. Although selenoprotein A reacted positively in a glycoprotein stain when using either the periodic acid-Schiff reagent procedure or a commercial glycan detection kit, no saccharide was detected by carbohydrate analyses after acid hydrolysis or methanolysis. Identity of the amino acid sequence determined by analysis with that deduced from the gene sequence is further evidence of the absence of bound carbohydrate.

Glycine metabolism in anaerobes

Some strict anaerobic bacteria catalyze with glycine as substrate an internal Stickland reaction by which glycine serves as electron donor being oxidized by glycine-cleavage system or as electron acceptor being reduced by glycine reductase. In both cases, energy is conserved by substrate level phosphorylation. Except for the different substrate-activating proteins PB, reduction of sarcosine or betaine to acetyl phosphate involves in Eubacterium acidaminophilum the same set of proteins as observed for glycine, e.g. a unique thioredoxin system as electron donor and an acetyl phosphate-forming protein PC interacting with the intermediarily formed Secarboxymethylselenoether bound to protein PA.

Components of glycine reductase from Eubacterium acidaminophilum. Cloning, sequencing and identification of the genes for thioredoxin reductase, thioredoxin and selenoprotein PA

The genes encoding thioredoxin reductase (trxB), thioredoxin (trxA), protein PA of glycine reductase (grdA) and the first 23 amino acids of the large subunit of protein PC of glycine reductase (grdC) belonging to the reductive deamination systems present in Eubacterium acidaminophilum were cloned and sequenced. The proteins were products of closely linked genes with 314 codons (thioredoxin reductase), 110 codons (thioredoxin), and 158 codons (protein PA). The protein previously called 'atypically small lipoamide dehydrogenase' or 'electron transferring flavoprotein' could now conclusively be identified as a thioredoxin reductase (subunit mass of 34781 Da) by the alignment with the enzyme of Escherichia coli showing the same typical order of the corresponding domains. The thioredoxin (molecular mass of 11742 Da) deviated considerably from the known consensus sequence, even in the most strongly conserved redox-active segment WCGPC that was now GCVPC. The selenocysteine of protein PA (molecular mass of 16609 Da) was encoded by TGA. The protein was highly similar to those of Clostridium purinolyticum and Clostridium sticklandii involved in glycine reductase. Thioredoxin reductase and thioredoxin of E. acidaminophilum could be successfully expressed in E. coli.

Isolation of a cytochrome-deficient mutant strain of Sporomusa sphaeroides not capable of oxidizing methyl groups

The homoacetogenic anaerobic bacterium Sporomusa sphaeroides was mutagenized with UV light. Taking advantage of the ampicillin enrichment technique and a newly developed test for the detection of heme in bacterial colonies, the cytochrome-deficient mutant strain S. sphaeroides BK824 was isolated. In contrast to the wild type, this mutant strain failed to grow on betaine, betaine plus methanol, H2 plus CO2, and methanol plus CO2. Growth on betaine plus formate, betaine plus H2, betaine plus pyruvate, methanol plus H2 and CO2, and acetoin was not impaired. All enzymes of the Wood pathway as well as hydrogenase and carbon monoxide dehydrogenase were detectable at comparable activities in both the wild type and the cytochrome-deficient mutant. Labeling experiments with [14C]methanol demonstrated the inability of S. sphaeroides BK824 to oxidize methyl groups. The role of cytochromes in electron transport steps associated with the Wood pathway enzymes and their possible role in energy conservation during autotrophic growth in acetogens are discussed.

Clostridium sticklandii glycine reductase selenoprotein A gene: cloning, sequencing, and expression in Escherichia coli

Gene grdA, which encodes selenoprotein A of the glycine reductase complex from Clostridium sticklandii, was identified and characterized. This gene encodes a protein of 158 amino acids with a calculated M(r) of 17,142. The known sequence of 15 amino acids around the selenocysteine residue and the known carboxy terminus of the protein are correctly predicted by the nucleotide sequence. An opal termination codon (TGA) corresponding to the location of the single selenocysteine residue in the polypeptide was found in frame at position 130. The C. sticklandii grdA gene was inserted behind the tac promotor of an Escherichia coli expression vector. An E. coli strain transformed with this vector produced an 18-kDa polypeptide that was not detected in extracts of nontransformed cells. Affinity-purified anti-C. sticklandii selenoprotein A immunoglobulin G reacted specifically with this polypeptide, which was indistinguishable from authentic C. sticklandii selenoprotein A by immunological analysis. Addition of the purified expressed protein to glycine reductase protein components B and C reconstituted the active glycine reductase complex. Although synthesis of enzymically active protein A depended on the presence of selenium in the growth medium, formation of immunologically reactive protein did not. Moreover, synthesis of enzymically active protein in a transformed E. coli selD mutant strain indicated that there is a nonspecific mechanism of selenocysteine incorporation. These findings imply that mRNA secondary structures of C. sticklandii grdA are not functional for UGA-directed selenocysteine insertion in the E. coli expression system.

Purification and characterization of protein PC, a component of glycine reductase from Eubacterium acidaminophilum

Protein PC of the glycine reductase from Eubacterium acidaminophilum was purified to homogeneity by chromatography on phenyl-Sepharose and Sepharose S. The apparent molecular mass of the native protein, which showed an associating/dissociating behaviour, was about 420 kDa. Sodium dodecyl sulfate/polyacrylamide gel electrophoresis of protein PC revealed two protein bands corresponding to 48 and 57 kDa, indicating an alpha 4 beta 4 composition. The smaller subunit was identified as an acetyl-group-transferring protein, the 57-kDa protein was hydrophobic. N-terminal amino acid sequences were determined for both subunits. Antibodies raised against the 48-kDa subunit showed cross-reactions with extracts of E. acidaminophilum grown on different substrates and with extracts from other glycine-utilizing anaerobic bacteria such as Clostridium purinolyticum, C. sticklandii, and C. sporogenes. The respective protein from the former two organisms corresponded in molecular mass. When protein PA was chemically carboxymethylated by iodo[2-14C]acetate and incubated with protein PC, acetyl phosphate was a reaction product, thus establishing it as the product of the glycine reductase reaction by using homogeneous preparations of these two proteins from E. acidaminophilum.

Immunological homology among azoreductases from Clostridium and Eubacterium strains isolated from human intestinal microflora

Azoreductases from several anaerobic intestinal bacteria have been shown to reduce azo dyes to carcinogenic aromatic amines. To evaluate the structural similarities of azoreductases from four species of Clostridium and one species of Eubacterium, a polyclonal antibody against purified Clostridium perfringens azoreductase was generated in rabbits. This antibody inhibited the azoreductase activity of all five bacteria tested. ELISA showed different degrees of binding of the antibody to various species of bacteria. In a Western blot, the antibody reacted with the purified azoreductases from all four Clostridium species and the Eubacterium species. These results demonstrate that the azoreductases from the bacteria tested share similar antigenic domains, which are probably located in the active site of the enzyme. Azoreductases from these intestinal bacteria are similar enough to be considered as a single group of enzymes with respect to their functions and antigenicity.