The tungsten-containing formate dehydrogenase from Methylobacterium extorquens AM1: purification and properties.

NAD-dependent formate dehydrogenase (FDH1) was isolated from the alpha-proteobacterium Methylobacterium extorquens AM1 under oxic conditions. The enzyme was found to be a heterodimer of two subunits (alpha1beta1) of 107 and 61 kDa, respectively. The purified enzyme contained per mol enzyme approximately 5 mol nonheme iron and acid-labile sulfur, 0.6 mol noncovalently bound FMN, and approximately 1.8 mol tungsten. The genes encoding the two subunits of FDH1 were identified on the M. extorquens AM1 chromosome next to each other in the order fdh1B, fdh1A. Sequence comparisons revealed that the alpha-subunit harbours putative binding motifs for the molybdopterin cofactor and at least one iron-sulfur cluster. Sequence identity was highest to the catalytic subunits of the tungsten- and selenocysteine-containing formate dehydrogenases characterized from Eubacterium acidaminophilum and Moorella thermoacetica (Clostridium thermoaceticum). The beta-subunit of FDH1 contains putative motifs for binding FMN and NAD, as well as an iron-sulfur cluster binding motif. The beta-subunit appears to be a fusion protein with its N-terminal domain related to NuoE-like subunits and its C-terminal domain related to NuoF-like subunits of known NADH-ubiquinone oxidoreductases.     

Nitrate-inducible formate dehydrogenase in Escherichia coli K-12. I. Nucleotide sequence of the fdnGHI operon and evidence that opal (UGA) encodes selenocysteine.

The fdnGHI operon of Escherichia coli encodes nitrate-inducible formate dehydrogenase. We report here the entire nucleotide sequence of fdnGHI. The sequence contains three open reading frames of sizes appropriate to encode the three subunits of formate dehydrogenase-N. fdnG contains an in-frame UGA codon that specifies selenocysteine incorporation, and the predicted amino acid sequence of FdnG shows similarity to two other bacterial formate dehydrogenase enzymes. FdnH contains 4 cysteine clusters typical of those found in iron-sulfur proteins. FdnG also contains a cysteine cluster. Evidence from sequence and spectral analyses suggest that FdnI encodes cytochrome bFdn556. Implications for the membrane topology of formate dehydrogenase-N and its mechanism of proton translocation are discussed.     

Purification and properties of the formate dehydrogenase and characterization of the<Emphasis Type="Italic"> fdhA</Emphasis> gene of<Emphasis Type="Italic"> Sulfurospirillum multivorans</Emphasis>

The soluble periplasmic subunit of the formate dehydrogenase FdhA of the tetrachloroethene-reducing anaerobe Sulfurospirillum multivorans was purified to apparent homogeneity and the gene (fdhA) was identified and sequenced. The purified enzyme catalyzed the oxidation of formate with oxidized methyl viologen as electron acceptor at a specific activity of 1683 nkat/mg protein. The apparent molecular mass of the native enzyme was determined by gel filtration to be about 100 kDa, which was confirmed by the fdhA nucleotide sequence. fdhA encodes for a pre-protein that differs from the truncated mature protein by an N-terminal 35-amino-acid signal peptide containing a twin arginine motif. The amino acid sequence of FdhA revealed high sequence similarities to the larger subunits of the formate dehydrogenases of Campylobacter jejuni, Wolinella succinogenes, Escherichia coli (FdhN, FdhH, FdhO), and Methanobacterium formicicum. According to the nucleotide sequence, FdhA harbors one Fe₄/S₄ cluster and a selenocysteine residue as well as conserved amino acids thought to be involved in the binding of a molybdopterin guanidine dinucleotide cofactor.Abbreviations Fdh Formate dehydrogenase - PCE Tetrachloroethene     

Selective selC-Independent Selenocysteine Incorporation into Formate Dehydrogenases

The formate dehydrogenases (Fdh) Fdh-O, Fdh-N, and Fdh-H, are the only proteins in Escherichia coli that incorporate selenocysteine at a specific position by decoding a UGA codon. However, an excess of selenium can lead to toxicity through misincorporation of selenocysteine into proteins. To determine whether selenocysteine substitutes for cysteine, we grew Escherichia coli in the presence of excess sodium selenite. The respiratory Fdh-N and Fdh-O enzymes, along with nitrate reductase (Nar) were co-purified from wild type strain MC4100 after anaerobic growth with nitrate and either 2 µM or 100 µM selenite. Mass spectrometric analysis of the catalytic subunits of both Fdhs identified the UGA-specified selenocysteine residue and revealed incorporation of additional, ‘non-specific’ selenocysteinyl residues, which always replaced particular cysteinyl residues. Although variable, their incorporation was not random and was independent of the selenite concentration used. Notably, these cysteines are likely to be non-essential for catalysis and they do not coordinate the iron-sulfur cluster. The remaining cysteinyl residues that could be identified were never substituted by selenocysteine. Selenomethionine was never observed in our analyses. Non-random substitution of particular cysteinyl residues was also noted in the electron-transferring subunit of both Fdhs as well as in the subunits of the Nar enzyme. Nar isolated from an E. coli selC mutant also showed a similar selenocysteine incorporation pattern to the wild-type indicating that non-specific selenocysteine incorporation was independent of the specific selenocysteine pathway. Thus, selenide replaces sulfide in the biosynthesis of cysteine and misacylated selenocysteyl-tRNA^Cys decodes either UGU or UGC codons, which usually specify cysteine. Nevertheless, not every UGU or UGC codon was decoded as selenocysteine. Together, our results suggest that a degree of misincorporation of selenocysteine into enzymes through replacement of particular, non-essential cysteines, is tolerated and this might act as a buffering system to cope with excessive intracellular selenium.     

Purification of NADPH-dependent electron-transferring flavoproteins and N-terminal protein sequence data of dihydrolipoamide dehydrogenases from anaerobic, glycine-utilizing bacteria.

Three electron-transferring flavoproteins were purified to homogeneity from anaerobic, amino acid-utilizing bacteria (bacterium W6, Clostridium sporogenes, and Clostridium sticklandii), characterized, and compared with the dihydrolipoamide dehydrogenase of Eubacterium acidaminophilum. All the proteins were found to be dimers consisting of two identical subunits with a subunit Mr of about 35,000 and to contain about 1 mol of flavin adenine dinucleotide per subunit. Spectra of the oxidized proteins exhibited characteristic absorption of flavoproteins, and the reduced proteins showed an A580 indicating a neutral semiquinone. Many artificial electron acceptors, including methyl viologen, could be used with NADPH as the electron donor but not with NADH. Unlike the enzyme of E. acidaminophilum, which exhibited by itself a dihydrolipoamide dehydrogenase activity (W. Freudenberg, D. Dietrichs, H. Lebertz, and J. R. Andreesen, J. Bacteriol. 171:1346-1354, 1989), the electron-transferring flavoprotein purified from bacterium W6 reacted with lipoamide only under certain assay conditions, whereas the proteins of C. sporogenes and C. sticklandii exhibited no dihydrolipoamide dehydrogenase activity. The three homogeneous electron-transferring flavoproteins were very similar in their structural and biochemical properties to the dihydrolipoamide dehydrogenase of E. acidaminophilum and exhibited cross-reaction with antibodies raised against the latter enzyme. N-terminal sequence analysis demonstrated a high degree of homology between the dihydrolipoamide dehydrogenase of E. acidaminophilum and the electron-transferring flavoprotein of C. sporogenes to the thioredoxin reductase of Escherichia coli. Unlike these proteins, the dihydrolipoamide dehydrogenases purified from the anaerobic, glycine-utilizing bacteria Peptostreptococcus glycinophilus, Clostridium cylindrosporum, and C. sporogenes exhibited a high homology to dihydrolipoamide dehydrogenases known from other organisms.     

A selDABC cluster for selenocysteine incorporation in Eubacterium acidaminophilum

The four genes required for selenocysteine incorporation were isolated from the gram-positive, amino acid-fermenting anaerobe Eubacterium acidaminophilum, which expresses various selenoproteins of different functions. The sel genes were located in an unique organization on a continuous fragment of genomic DNA in the order selD1 (selenophosphate synthetase 1), selA (selenocysteine synthase), selB (selenocysteine-specific elongation factor), and selC (selenocysteine-specific tRNA). A second gene copy, encoding selenophosphate synthetase 2 (selD2), was present on a separate fragment of genomic DNA. SelD1 and SelD2 were only 62.9% identical, but the two encoding genes, selD1 and selD2, contained an in-frame UGA codon encoding selenocysteine, which corresponds to Cys-17 of Escherichia coli SelD. The function of selA, selB, and selC from E. acidaminophilum was investigated by complementation of the respective E. coli deletion mutant strains and determined as the benzyl viologen-dependent formate dehydrogenase activity in these strains after anaerobic growth in the presence of formate. selA and selC from E. acidaminophilum were functional and complemented the respective mutant strains to 83% (selA) and 57% (selC) compared to a wild-type strain harboring the same plasmid. Complementation of the E. coli selB mutant was only observed when both selB and selC from E. acidaminophilum were present. Under these conditions, the specific activity of formate dehydrogenase was 55% of that of the wild type. Transformation of this selB mutant with selB alone was not sufficient to restore formate dehydrogenase activity.     

Analysis and comparison of nucleotide sequences encoding the genes for [NiFe] and [NiFeSe] hydrogenases from Desulfovibrio gigas and Desulfovibrio baculatus.

The nucleotide sequences encoding the [NiFe] hydrogenase from Desulfovibrio gigas and the [NiFeSe] hydrogenase from Desulfovibrio baculatus (N.K. Menon, H.D. Peck, Jr., J. LeGall, and A.E. Przybyla, J. Bacteriol. 169:5401-5407, 1987; C. Li, H.D. Peck, Jr., J. LeGall, and A.E. Przybyla, DNA 6:539-551, 1987) were analyzed by the codon usage method of Staden and McLachlan. The reported reading frames were found to contain regions of low codon probability which are matched by more probable sequences in other frames. Renewed nucleotide sequencing showed the probable frames to be correct. The corrected sequences of the two small and large subunits share a significant degree of sequence homology. The small subunit, which contains 10 conserved cysteine residues, is likely to coordinate at least 2 iron-sulfur clusters, while the finding of a selenocysteine codon (TGA) near the 3' end of the [NiFeSe] large-subunit gene matched by a regular cysteine codon (TGC) in the [NiFe] large-subunit gene indicates the presence of some of the ligands to the active-site nickel in the large subunit.     

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.     

Structural features of the 66-kDa subunit of the energy-transducing NADH-ubiquinone oxidoreductase (NDH-1) of Paracoccus denitrificans.

The structural gene of the Paracoccus denitrificans NADH-ubiquinone oxidoreductase encoding a homologue of the 75-kDa subunit of bovine complex I (NQO3) has been located and sequenced. It is located approximately 1 kbp downstream of the gene coding for the NADH-binding subunit (NQO1) [Xu, X., Matsuno-Yagi, A., and Yagi, T. (1991) Biochemistry 30, 6422-6428] and is composed of 2019 base pairs and codes for 673 amino acid residues with a calculated molecular weight of 73,159. The M(r) 66,000 polypeptide of the isolated Paracoccus NADH dehydrogenase complex is assigned the NQO3 designation on the basis of N-terminal protein sequence analysis, amino acid analysis, and immuno-cross-reactivity. The encoded protein contains a putative tetranuclear iron-sulfur cluster (probably cluster N4) and possibly a binuclear iron-sulfur cluster. An unidentified reading frame (URF3) which is composed of 396 base pairs and possibly codes for 132 amino acid residues was found between the NQO1 and NQO3 genes. When partial DNA sequencing of the regions downstream of the NQO3 gene was performed, sequences homologous to the mitochondrial ND-1, ND-5, and ND-2 gene products of bovine complex I were found, suggesting that the gene cluster carrying the Paracoccus NADH dehydrogenase complex contains not only structural genes encoding water-soluble subunits but also structural genes encoding hydrophobic subunits.     

Biochemical and EPR characterization of a high potential iron-sulfur protein in Thiobacillus ferrooxidans

Abstract A soluble acid-stable high potential iron-sulfur protein (HiPIP) was purified from Thiobacillus ferrooxidans using the periplasmic extraction method. It was isolated in the form of a tetramer consisting of four subunits with a molecular mass of 5582 Da, and its biochemical and biophysical properties were characterized. The N-terminal amino acid sequence (15 residues) was compared with the nucleotide sequence of the iro gene isolated from another strain and the two sequences were found to be identical. The iron content measurement together with optical and EPR spectroscopic studies of the purified protein were consistent with the presence of one [4Fe-4S] cluster per subunit. The EPR spectrum recorded in the oxidized state was attributed to a [4Fe-4S]³⁺ cluster and the redox potential has been determined to be +380 mV.     

Characterization by electron paramagnetic resonance and studies on subunit location and assembly of the iron-sulfur clusters of Bacillus subtilis succinate dehydrogenase

Succinate dehydrogenase is a conserved membrane-bound enzyme consisting of two nonidentical subunits: a flavo iron-sulfur protein (Fp) subunit, containing a covalently bound flavin, and an iron-sulfur protein (Ip) subunit. Bacillus subtilis succinate dehydrogenase in wild type bacteria and 12 well characterized succinate dehydrogenase-defective mutants were examined by low temperature EPR spectroscopy to characterize the enzyme and study subunit location and biosynthesis of its iron-sulfur clusters. The wild type B. subtilis enzyme contains iron-sulfur clusters which are analogous to clusters S-1 and S-3 of bovine heart succinate dehydrogenase but with slightly different EPR characteristics. Spins from cluster S-2 were not detectable as in the case of the intact form of bovine heart succinate dehydrogenase. However, dithionite reduction of the B. subtilis enzyme greatly enhanced spin relaxation of the ferredoxin-type cluster S-1, indicating the presence of the cluster S-2. Iron-sulfur cluster S-1 was found to be assembled in soluble succinate dehydrogenase subunits in the cytoplasm, but only if full-length Fp polypeptides and relatively large fragments of Ip polypeptides were present. Cluster S-1 was not detected in mutants with soluble mutated Fp polypeptides or in a mutant totally lacking Ip subunit polypeptide. Iron-sulfur clusters S-1, S-2, and S-3 were assembled also when the covalently bound flavin in the Fp subunit was absent. Clusters S-1 and S-3 in the membrane-bound flavin-deficient succinate dehydrogenase were not reduced by succinate but could be reduced by electron transfer from NADH dehydrogenase via the menaquinone pool.     

Overproduction of a selenocysteine-containing polypeptide in Escherichia coli: the fdhF gene product

The fdhF gene of Escherichia coli codes for the selenocysteine-including protein subunit of formate dehydrogenase H. The protein subunit consists of 715 amino acid residues containing a single selenocysteine residue at position 140 which is encoded by a UGA codon. The decoding of this opal termination codon occurs under anaerobic growth conditions by means of a specific tRNA, i.e. the selC gene product. The ability of E. coli cells to overproduce a selenopolypeptide was examined using the fdhF gene as a model system. Surprisingly, E. coli was able to synthesize the fdhF gene product at the level of approximately 12% of the total cellular protein. This was achieved by cloning fdhF in a multicopy plasmid together with a synthetic selC gene under the Ipp promoter. FdhF production was absolutely dependent upon the addition of selenium to the culture medium and was almost completely blocked in the presence of oxygen. The product was specifically labelled with 75Se, proving that it consisted of a selenoprotein. The product was purified to homogeneity and shown to exhibit the catalytic properties characteristic of formate dehydrogenase H.     

Delivery of iron-sulfur clusters to the hydrogen-oxidizing [NiFe]-hydrogenases in Escherichia coli requires the A-type carrier proteins ErpA and IscA

During anaerobic growth Escherichia coli synthesizes two membrane-associated hydrogen-oxidizing [NiFe]-hydrogenases, termed hydrogenase 1 and hydrogenase 2. Each enzyme comprises a catalytic subunit containing the [NiFe] cofactor, an electron-transferring small subunit with a particular complement of [Fe-S] (iron-sulfur) clusters and a membrane-anchor subunit. How the [Fe-S] clusters are delivered to the small subunit of these enzymes is unclear. A-type carrier (ATC) proteins of the Isc (iron-sulfur-cluster) and Suf (sulfur mobilization) [Fe-S] cluster biogenesis pathways are proposed to traffic pre-formed [Fe-S] clusters to apoprotein targets. Mutants that could not synthesize SufA had active hydrogenase 1 and hydrogenase 2 enzymes, thus demonstrating that the Suf machinery is not required for hydrogenase maturation. In contrast, mutants devoid of the IscA, ErpA or IscU proteins of the Isc machinery had no detectable hydrogenase 1 or 2 activities. Lack of activity of both enzymes correlated with the absence of the respective [Fe-S]-cluster-containing small subunit, which was apparently rapidly degraded. During biosynthesis the hydrogenase large subunits receive their [NiFe] cofactor from the Hyp maturation machinery. Subsequent to cofactor insertion a specific C-terminal processing step occurs before association of the large subunit with the small subunit. This processing step is independent of small subunit maturation. Using western blotting experiments it could be shown that although the amount of each hydrogenase large subunit was strongly reduced in the iscA and erpA mutants, some maturation of the large subunit still occurred. Moreover, in contrast to the situation in Isc-proficient strains, these processed large subunits were not membrane-associated. Taken together, our findings demonstrate that both IscA and ErpA are required for [Fe-S] cluster delivery to the small subunits of the hydrogen-oxidizing hydrogenases; however, delivery of the Fe atom to the active site might have different requirements.     

Targeted insertion of selenocysteine into the alpha subunit of formate dehydrogenase from Methanobacterium formicicum.

Selenocysteine incorporation into proteins is directed by an opal (UGA) codon and requires the existence of a stem-loop structure in the mRNA flanking the UGA at its 3' side. To analyze the sequence and secondary-structure requirements for UGA decoding, we have introduced mutations into the fdhA gene from Methanobacterium formicicum, which codes for the alpha subunit of the F420-reducing formate dehydrogenase. The M. formicicum enzyme contains a cysteine residue at the position where the Escherichia coli formate dehydrogenase H carries a selenocysteine moiety. The codon (UGC) for this cysteine residue was changed into a UGA codon, and mutations were successively introduced at the 5' and 3' sides to generate a stable secondary structure of the mRNA and to approximate the sequence of the predicted E. coli fdhF mRNA hairpin structure. It was found that introduction of the UGA and generation of a stable putative stem-loop structure were not sufficient for decoding with selenocysteine. Efficient selenocysteine incorporation, however, was obtained when the loop and the immediately adjacent portion of the putative stem had a sequence identical to that present in the E. coli fdhF mRNA structure.     

Purification and characterization of Desulfovibrio vulgaris (Hildenborough) hydrogenase expressed in Escherichia coli

Hydrogenase from Desulfovibrio vulgaris (Hildenborough) is a heterologous dimer of molecular mass 46 + 13.5 kDa. Its two structural genes have been cloned on a 4664-base-pair fragment of known sequence in the vector pUC9. Expression of hydrogenase polypeptides in Escherichia coli transformed with this plasmid is poor (approximately 0.1% w/w of total protein). Deletion of up to 1.9 kb of insert DNA brings the gene encoding for the large subunit in close proximity to the lac promotor of pUC9 and results in a 50-fold increased expression of hydrogenase polypeptides in E. coli. The protein formed is inactive and was purified in order to delineate its defect. Complete purification was achieved with a procedure similar to that used for the isolation of active hydrogenase from D. vulgaris H. The derived protein is also an alpha beta dimer and electron-paramagnetic resonance studies indicate the presence of the electron-transferring ferredoxin-type iron-sulfur clusters. In contrast to the native protein from D. vulgaris H, these can only be reduced with dithionite, not with hydrogen, indicating that the hydrogen-binding active centre which also contains an iron-sulfur cluster is missing.     

Purification and characterization of an alpha-haloketone-resistant formate dehydrogenase from Thiobacillus sp. strain KNK65MA, and cloning of the gene

Thiobacillus sp. strain KNK65MA, which produced an NAD-dependent formate dehydrogenase (FDH) highly resistant to alpha-haloketones, was newly isolated, i.e., the enzyme showed no loss of activity after a 5-h incubation with alpha-haloketones, such as ethyl 4-chloro-3-oxobutanoate. The enzyme was also resistant to SH reagents. The enzyme, purified to homogeneity, was a dimer composed of identical subunits. The specific activity was 7.6 u/mg, and the apparent Km values for formate and NAD+ were 1.6 and 0.048 mM, respectively. The cloned gene of FDH contained one open reading frame (ORF) of 1206 base pairs, predicted to encode a polypeptide of 401 amino acids, with a calculated molecular weight of 44,021; this gene was highly expressed in E. coli cells. The deduced amino acid sequence of this FDH had high identity to other bacterial FDHs.     

Cloning, expression, and nucleotide sequence of the formate dehydrogenase genes from Methanobacterium formicicum

The genes for the two subunits of the formate dehydrogenase from Methanobacterium formicicum were cloned and their sequences determined. When expressed in Escherichia coli, two proteins were produced which had the appropriate mobility on an SDS gel for the two subunits of formate dehydrogenase and cross-reacted with antibodies raised to purified formate dehydrogenase. The genes for the two formate dehydrogenase subunits overlap by 1 base pair and are preceded by DNA sequences similar to both eubacterial and archaebacterial promoters and ribosome-binding sites. The amino acid sequences deduced from the DNA sequence were analyzed, and the arrangement of putative iron-sulfur centers is discussed.