Cys359 of GrdD is the active-site thiol that catalyses the final step of acetyl phosphate formation by glycine reductase from Eubacterium acidaminophilum.

In the amino-acid-fermenting anaerobe Eubacterium acidaminophilum, acetyl phosphate is synthesized by protein C of glycine reductase from a selenoprotein A-bound carboxymethyl-selenoether. We investigated specific thiols present in protein C for responsibility for acetyl phosphate liberation. After cloning of the genes encoding the large and the small subunit (grdC1, grdD1), they were expressed separately in Escherichia coli and purified as Strep-tag proteins. GrdD was the only subunit that catalysed arsenate-dependent hydrolysis of acetyl phosphate (up to 274 U.mg-1), whereas GrdC was completely inactive. GrdD contained two cysteine residues that were exchanged by site-directed mutagenesis. The GrdD(C98S) mutant enzyme still catalysed the hydrolysis of acetyl phosphate, but the GrdD(C359A) mutant enzyme was completely inactive. Next, these thiols were analysed further by chemical modification. After iodoacetate treatment of GrdD, the enzyme activity was lost, but in the presence of acetyl phosphate enzyme activity was protected. Subsequently, the inactivated carboxymethylated enzyme and the protected enzyme were both denatured, and the remaining thiols were pyridylethylated. Peptides generated by proteolytic cleavage were separated and subjected to mass spectrometry. Cys98 was not accessible to carboxymethylation by iodoacetate in the native enzyme in the presence or absence of the substrate, but could be alkylated after denaturation. Cys359, in contrast, was protected from carboxymethylation in the presence of acetyl phosphate, but became accessible to pyridylethylation upon prior denaturation of the protein. This clearly confirmed the catalytic role of Cys359 as the active site thiol of GrdD responsible for liberation of acetyl phosphate.

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.

In vitro processing of the proproteins GrdE of protein B of glycine reductase and PrdA of D-proline reductase from Clostridium sticklandii: formation of a pyruvoyl group from a cysteine residue.

GrdE and PrdA of Clostridium sticklandii are subunits of glycine reductase and D-proline reductase, respectively, that are processed post-translationally to form a catalytic active pyruvoyl group. The cleavage occurred on the N-terminal side of a cysteine residue, which is thus the precursor of a pyruvoyl moiety. Both proproteins could be over-expressed in Escherichia coli and conditions were developed for in vitro processing. GrdE could be expressed as full-size protein, whereas PrdA had to be truncated N-terminally to achieve successful over-expression. Both proproteins were cleaved at the in vivo observed cleavage site after addition of 200 mM NaBH4 in Tris buffer (pH 7.6) at room temperature as analysed by SDS/PAGE and MS. Cleavage of GrdE was observed with a half-time of approximately 30 min. Cys242, as the precursor of the pyruvoyl group in GrdE, was changed to alanine, serine, or threonine by site-directed mutagenesis. The Cys242-->Ser and Cys242-->Thr mutant proteins were also cleaved under similar conditions with extended half-times. However, the Cys242-->Ala mutant protein was not cleaved indicating a pivotal role of the thiol group of cysteine or hydroxyl group of serine and threonine during the processing of pyruvoyl group-dependent reductases.

Selenium, the element of the moon, in life on earth.

The present status of selenium biochemistry is reviewed with particular emphasis on biomedical problems related to the selenium status of humans and experimental animals. Historical milestones of selenium biochemistry starting from the identification of the first selenoenzymes up to the elucidation of prokaryotic and eukaryotic selenoprotein biosynthesis are compiled. Topical hypotheses on the biological role of selenium in general and of individual selenoproteins in respect to antioxidant defense, redox regulation of metabolic processes, thyroid function, spermatogenesis, oncogenesis, and atherogenesis are critically evaluated.

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.

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.

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.

Partial purification of an iron-dependent L-serine dehydratase from Clostridium sticklandii.

An oxygen-sensitive and highly unstable L-serine dehydratase was partially purified from the Gram-positive anaerobe Clostridium sticklandii. The final active preparation contained five proteins of 27, 30, 44.5, 46, and 58 kDa as judged by SDS-PAGE. The N-terminal sequence of the 30 kDa subunit showed some similarity to the alpha-subunits of the iron-containing L-serine dehydratases from Clostridium propionicum and Peptostreptococcus asaccharolyticus. Oxygen-inactivated L-serine dehydratase from C. sticklandii was reactivated by incubation with Fe2+ under reducing conditions. Furthermore, the enzyme was inactivated by iron-chelating substances like phenanthroline and EDTA. Pyridoxal-5-phosphate (PLP) did not stimulate the activity, and known inhibitors of PLP-containing enzymes such as NaBH4 had no effect on the activity of L-serine dehydratase from C. sticklandii.

Studies on the inactivation of the flavoprotein D-amino acid oxidase from Trigonopsis variabilis.

Inactivation of D-amino acid oxidase occurred by different mechanisms. The enzyme showed a rapid loss of activity in the presence of micromolar amounts of Cu2+ and Hg2+. It was also sensitive to oxidative inactivation by Fe2+ and H2O2 when both reagents were added in millimolar amounts. When oxidatively inactivated D-amino acid oxidase and a corresponding non-treated control were modified with the sulfhydryl-modifying, fluorescent reagent monobromobimane and subsequently digested with endoproteinase Glu-C, Cys-298 was identified to be a target for oxidative modification according to differences in the known peptide profile of fluorescence intensity. Another reason for the observed loss of enzyme activity in crude extracts was the specific proteolytic digestion of D-amino acid oxidase, which was dependent on the growth phase of the cells used. This cleavage was catalyzed by a serine-type proteinase and was the introductory step for the further complete degradation of the enzyme. In addition, a coenriched 50-kDa protein, identified as NADPH-specific glutamate dehydrogenase, significantly decreased the stability of the D-amino acid oxidase activity. Treatment of apo-D-amino acid oxidase from T. variabilis with monobromobimane resulted in a significantly increased fluorescence of two peptides, neither of which contained any cysteine residue. Thus, an involvement of cysteine residues in binding the FAD coenzyme should be excluded.

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.

Purification and characterization of a pyrrole-2-carboxylate oxygenase from Arthrobacter strain Py1.

Pyrrole-2-carboxylate oxygenase was purified 8.2-fold to homogeneity from Arthrobacter strain Py1 grown on pyrrole-2-carboxylate as sole carbon, nitrogen, and energy source. FAD and dithioerythritol had to be present during the purification procedure to stabilize the enzyme activity. The molecular mass of the pyrrole-2-carboxylate oxygenase was about 160 kDa by gel filtration chromatography and native gradient PAGE, only one polypeptide of about 60 kDa was present after SDS-PAGE. The FAD content was 2.7 to 3.6 mol FAD per enzyme (160 kDa). The non-covalently bound FAD of the pyrrole-2-carboxylate oxygenase was reduced by NADH and reoxidized by oxygen and pyrrole-2-carboxylate. The enzyme exhibited a narrow substrate specificity. Besides pyrrole-2-carboxylate, only pyrrole, pyrrole-2-aldehyde, and indole-2-carboxylate stimulated the oxygen consumption at a very low rate. The enzyme activity was strongly reduced by different sulfhydryl group inhibitors, but it could be restored by 2-mercaptoethanol or dithiothreitol. The content of pyrrole-2-carboxylate oxygenase was about 6% of the soluble protein as determined by antibodies raised against the enzyme. No cross reacting material was present in other bacteria also able to degrade pyrrole-2-carboxylate. A low amount of the enzyme was present in uninduced cells of Arthrobacter strain Py1, although the enzymatic activity was below the detection limit. The N-terminal amino acid sequence of the enzyme did not contain the consensus sequence GXGXXG found to be present close to the N-terminus of many flavin-dependent monoxygenases sequenced so far.

Evidence for the functional importance of Cys298 in D-amino acid oxidase from Trigonopsis variabilis.

D-Amino acid oxidase from Trigonopsis variabilis was purified to homogeneity by a combination of freeze/thawing, isoelectric precipitation and chromatography on Mono Q. This purification procedure required very little working effort. The homogeneous enzyme exhibited a ratio A280/A450 of about 6.5 and was obtained in high yield (63%) and a good stability. Using D-methionine as a substrate, a specific activity of 120 U/mg was determined colorimetrically at 26 degrees C, corresponding to 185 U/mg polarographically at 37 degrees C. Polyclonal antibodies were raised against the homogeneous protein and Western immunoblot analysis showed that the 39-kDa subunit can undergo defined cleavages at the carboxy terminus of amino acid positions 104, 106 and 108, leading to 27-kDa and 12-kDa fragments as revealed by SDS/PAGE, which are still enzymically active in their native form. The enzyme was inactivated by all sulfhydryl-modifying reagents tested. Inactivation by 5,5'-dithiobis(-2-nitrobenzoate) was correlated with a modification of up to 2 mol/mol protein of the six cysteine residues present in the monomer. Identification of the most reactive cysteine was achieved by inactivation of the enzyme with the fluorescent, sulfhydryl-modifying reagent monobromobimane. In the presence of a substrate amino acid, under anaerobic conditions, the protein could be protected from modification and, thus, inactivation by this reagent. Peptide mapping by reverse-phase chromatography of endoproteinase Glu-C-digested monobromobimane-labeled enzyme revealed one major fluorescence peak which was not obtained when the protein was modified in the presence of a substrate amino acid under anaerobic conditions. Isolation and sequencing of the labeled peptide led to the identification of Cys298 as the reactive cysteine residue.

Fermentation of glucose, fructose, and xylose by Clostridium thermoaceticum: effect of metals on growth yield, enzymes, and the synthesis of acetate from CO 2 .

Clostridium thermoaceticum ferments xylose, fructose, and glucose with acetate as the only product. In fermentations with mixtures of the sugars, xylose is first fermented, then fructose, and last, glucose. Fructose inhibits the fermentation of glucose, and this inhibition appears to be due to a repression of the synthesis of an enzyme needed for glucose utilization. Addition of metals to the culture medium increases the cell yield drastically from about 7 to 18 g per liter, and Y(glucose) values between 40 and 50 are obtained. According to the postulated pathways of the fermentation of glucose and synthesis of acetate from CO(2) by C. thermoaceticum, 3 mol of ATP are available as energy for growth. Thus a Y(adenosine 5'-triphosphate) of 13 to 16 is obtained. Because the normal Y(ATP) value is 10.5, this could mean that an additional source of ATP is available by an unknown mechanism. The addition of metals also increases the nicotinamide adenine dinucleotide phosphate-dependent formate dehydrogenase activity, the overall reaction ((14)CO(2) --> acetate), and the incorporation of the methyl group of 5-methyltetrahydrofolate into acetate. These reactions are catalyzed very efficiently by cells harvested in early growth, whereas cells obtained at the end of a fermentation have very low formate dehydrogenase activity and capacity to incorporate CO(2) into acetate. The following enzymes involved in the synthesis of acetate from CO(2) and in the metabolism of pyruvate are present in extracts of C. thermoaceticum: 10-formyltetrahydrofolate synthetase, 5,10-methenyltetrahydrofolate cyclohydrolase, 5,10-methylenetetrahydrofolate dehydrogenase, 5,10-methylenetetrahydrofolate reductase, phosphate acetyltransferase, and acetate kinase. These enzymes are not or are very little affected by the addition of metals to the growth medium. The amount of corrinoids in cells from early growth is low, whereas it is high in cells harvested late in growth. The opposite is found for the activity of delta-aminolevulinate dehydratase, which is high at the beginning of growth and low at the end.