Nucleotide sequence of the dmsABC operon encoding the anaerobic dimethylsulphoxide reductase of Escherichia coli

The nucleotide sequence of a 6.5 kilobasepair chromosomal DNA fragment encoding the anaerobic dimethylsulphoxide (DMSO) reductase operon of Escherichia coli has been determined. The DMSO reductase structural operon was shown to consist of three open reading frames, namely dmsABC, encoding polypeptides with predicted molecular weights of 87,350, 23,070, and 30,789 Daltons, respectively. The DMS A polypeptide displayed a high degree of amino acid sequence homology with the single-subunit enzyme, biotin sulphoxide reductase (bisC) and with formate dehydrogenase (fdhF), suggesting that the active site and molybdopterin cofactor binding site that is common to these enzymes is located in the DMS A subunit. A comparison of the predicted N-terminal amino acids of the dmsA gene product to those of the 82,600 subunit of purified DMSO reductase indicated that post-translational processing of a 16 amino acid peptide at the amino terminus of DMS A had occurred. The DMS B polypeptide contains 16 cysteine residues organized in four clusters, two of which are typical of 4Fe-4S binding domains. The DMS C polypeptide is composed of eight segments of hydrophobic amino acids of appropriate length to cross the cytoplasmic membrane, suggesting that this subunit functions to anchor the enzyme to the membrane.     

Binding of the TorR regulator to cis-acting direct repeats activates tor operon expression

The expression of the Escherichia coli torCAD operon, which encodes the anaerobically expressed trimethylamine N-oxide (TMAO) reductase respiratory system, requires the presence of TMAO in the medium. The response regulator, TorR, has recently been identified as the regulatory protein that controls the expression of the torCAD operon in response to TMAO. The torC regulatory region contains four direct repeats of a decameric consensus motif designated the tor boxes. Alteration by base substitutions of any of the four tor boxes in a plasmid containing a torC'-lacZ fusion dramatically reduces TorR-dependent torC expression. In addition, deletion of the distal tor box (box1) abolishes torC induction whereas the presence of a DNA fragment starting three bases upstream from box1 suffices for normal torC expression. Footprinting and gel-retardation experiments unambiguously demonstrated that TorR binds to the torC regulatory region. Three distinct regions are protected by TorR binding. One of approximately 24 nucleotides covers the first two tor boxes (box1 and box2); the second is located upstream from the −35 promoter sequence and includes the third tor box (box3); the last is found downstream from the −35 sequence and corresponds to the fourth tor box (box4). Binding to the upstream tor boxes (box1 and box2) appears to be stronger than binding to the downstream tor boxes (box3 and box4) since only the upstream region is protected at the lower concentration of TorR used in the footprinting experiments.
We propose a model in which multiple binding sites (i.e. the tor boxes) contribute to the formation of a nucleoprotein complex, but only one particular proximal site positions TorR properly so that it interacts with RNA polymerase.     

narI region of the Escherichia coli nitrate reductase (nar) operon contains two genes.

In previous studies it has been established that in Escherichia coli the three known subunits of anaerobic nitrate reductase are encoded by the narGHI operon. From the nucleotide sequence of the narI region of the operon we conclude that, in addition to the narG and narH genes, the nar operon contains two other open reading frames (ORFs), ORF1 and ORF2, that encode proteins of 26.5 and 25.5 kilodaltons, respectively. Protein fusions to each of the genes in the operon showed that expression of all four genes was similarly regulated. The reading frames of ORF1 and ORF2 were verified, and the N-terminal sequence for the ORF1 fusion protein was determined. The nar operon therefore contains four genes designated and ordered as narGHJI.     

The Escherichia coli ynfEFGHI operon encodes polypeptides which are paralogues of dimethyl sulfoxide reductase (DmsABC)

The ynfEFGHI operon is a paralogue of the Escherichia coli dmsABC operon. ynfE and ynfF are paralogues of dmsA. ynfG and ynfH are paralogues of dmsB and dmsC, respectively. YnfI (dmsD) has no dms paralogue. YnfE/F and YnfG could be detected by immunoblotting with anti-DmsAB antibodies when expressed under the control of a tac or dms promoter. Cells harbouring ynfFGH on a multicopy plasmid supported anaerobic growth with dimethyl sulfoxide (DMSO) as respiratory oxidant in a dmsABC deletion, suggesting that YnfFGH forms a heterotimeric enzyme complex similar to DmsABC. Exchange of DmsC by YnfH (DmsAB-YnfH) resulted in membrane localization, anaerobic growth on DMSO, and binding of 2-n-heptyl 4-hydroxyquinoline-N-oxide, indicating that YnfH was a competent anchor. YnfG can also replace DmsB as the electron transfer subunit and assembled [Fe-S] clusters as judged by electron paramagnetic resonance spectroscopy. YnfE and/or YnfF could not form a functional complex with DmsBC and expression of YnfE prevented the accumulation of YnfFGH.     

Dimethyl sulfoxide reductase of Escherichia coli: an investigation of function and assembly by use of in vivo complementation.

Dimethyl sulfoxide (DMSO) reductase of Escherichia coli is a membrane-bound, terminal anaerobic electron transfer enzyme composed of three nonidentical subunits. The DmsAB subunits are hydrophilic and are localized on the cytoplasmic side of the plasma membrane. DmsC is the membrane-intrinsic polypeptide, proposed to anchor the extrinsic subunits. We have constructed a number of strains lacking portions of the chromosomal dmsABC operon. These mutant strains failed to grow anaerobically on glycerol minimal medium with DMSO as the sole terminal oxidant but exhibited normal growth with nitrate, fumarate, and trimethylamine N-oxide, indicating that DMSO reductase is solely responsible for growth on DMSO. In vivo complementation of the mutant with plasmids carrying various dms genes, singly or in combination, revealed that the expression of all three subunits is essential to restore anaerobic growth. Expression of the DmsAB subunits without DmsC results in accumulation of the catalytically active dimer in the cytoplasm. The dimer is thermolabile and catalyzes the reduction of various substrates in the presence of artificial electron donors. Dimethylnaphthoquinol (an analog of the physiological electron donor menaquinone) was oxidized only by the holoenzyme. These results suggest that the membrane-intrinsic subunit is necessary for anchoring, stability, and electron transport. The C-terminal region of DmsB appears to interact with the anchor peptide and facilitates the membrane assembly of the catalytic dimer.