Multiple roles for the twin arginine leader sequence of dimethyl sulfoxide reductase of Escherichia coli

Dimethyl sulfoxide (Me(2)SO) reductase of Escherichia coli is a terminal electron transport chain enzyme that is expressed under anaerobic growth conditions and is required for anaerobic growth with Me(2)SO as the terminal electron acceptor. The trimeric enzyme is composed of a membrane extrinsic catalytic dimer (DmsAB) and a membrane intrinsic anchor (DmsC). The amino terminus of DmsA has a leader sequence with a twin arginine motif that targets DmsAB to the membrane via a novel Sec-independent mechanism termed MTT for membrane targeting and translocation. We demonstrate that the Met-1 present upstream of the twin arginine motif serves as the correct translational start site. The leader is essential for the expression of DmsA, stability of the DmsAB dimer, and membrane targeting of the reductase holoenzyme. Mutation of arginine 17 to aspartate abolished membrane targeting. The reductase was labile in the leader sequence mutants. These mutants failed to support growth on glycerol-Me(2)SO minimal medium. Replacing the DmsA leader with the TorA leader of trimethylamine N-oxide reductase produced a membrane-bound DmsABC with greatly reduced enzyme activity and inefficient anaerobic respiration indicating that the twin arginine leaders may play specific roles in the assembly of redox enzymes.     

Glutamate 87 is important for menaquinol binding in DmsC of the DMSO reductase (DmsABC) from Escherichia coli

Escherichia coli dimethylsulfoxide (DMSO) reductase is a trimeric enzyme with a catalytic dimer (DmsAB) and an integral membrane anchor (DmsC). Using site-directed mutagenesis, we examined six residues in the periplasmic loop between helices two and three, potentially involved in menaquinol binding in DmsC. Mutants were characterised for growth, enzyme expression and activity, and 2-n-heptyl-4-hydroxoquinoline N-oxide (HOQNO) inhibitor binding. Mutations of leucine 66, glycine 67, arginine 71, phenylalanine 73 and serine 75 had no effect on menaquinol binding. Only a glutamate residue (E87) located in helix three was important for menaquinol binding. E87 was replaced with lysine, glutamine and aspartate. All three mutants were assembled into the membrane. Neither the lysine nor the glutamine mutant enzymes were able to support anaerobic growth on glycerol/DMSO minimal media or oxidise lapachol. The glutamine mutant bound the inhibitor with lower affinity compared to wild-type, whereas in the lysine mutant, binding was almost abolished. The aspartate mutant behaved as a wild-type enzyme. The data shows that E87 is important for menaquinol binding and oxidation and is likely to act as a proton acceptor in the menaquinol binding site.     

Investigation of Escherichia coli dimethyl sulfoxide reductase assembly and processing in strains defective for the sec-independent protein translocation system membrane targeting and translocation

Dimethyl sulfoxide reductase is a heterotrimeric enzyme (DmsABC) localized to the cytoplasmic surface of the inner membrane. Targeting of the DmsA and DmsB catalytic subunits to the membrane requires the membrane targeting and translocation (Mtt) system. The DmsAB dimer is a member of a family of extrinsic, cytoplasmic facing membrane subunits that require Mtt in order to assemble on the membrane. We show that the MttA(2), MttB, and presumably MttA(1) but not the MttC proteins are required for targeting DmsAB to the membrane. Unlike other Mtt substrates such as trimethylamine N-oxide reductase, the soluble cytoplasmic DmsAB dimer that accumulates in the mtt deletions is very labile. Deletion of the mttA(2) or mttB genes also prevents anaerobic growth on fumarate even though fumarate reductase does not require Mtt for assembly. This was due to the lethality of membrane insertion of DmsC in the absence of the DmsAB subunits. In the absence of DmsC, DmsAB accumulates in the cytoplasm. A 45-amino acid leader on DmsA is removed during assembly. Processing does not require DmsC but does require Mtt. Translocation of DmsAB to the periplasm is not required for processing. The leader may be cleaved by a novel leader peptidase, or the long DmsA leader may traverse the membrane through the Mtt system resulting in cleavage by the periplasmic leader peptidase I followed by release of DmsA into the cytoplasm.     

Structure of fumarate reductase on the cytoplasmic membrane of Escherichia coli.

The terminal electron transfer enzyme fumarate reductase has been shown to be composed of a membrane-extrinsic catalytic dimer of 69- and 27-kilodalton (kd) subunits and a membrane-intrinsic anchor portion of 15- and 13-kd subunits. We prepared inverted membrane vesicles from a strain carrying the frd operon on a multicopy plasmid. When grown anaerobically on fumarate-containing medium, the membranes of this strain are highly enriched in fumarate reductase. When negatively stained preparations of these vesicles were examined with an electron microscope, they appeared to be covered with knob-like structures about 4 nm in diameter attached to the membrane by short stalks. Treatment of the membranes with chymotrypsin destroyed the 69-kd subunit, leaving the 27-, 15-, and 13-kd subunits bound to the membrane; these membranes appeared to retain remnants of the structure. Treatment of the membranes with 6 M urea removed the 69- and 27-kd subunits, leaving the anchor polypeptides intact. These vesicles appeared smooth and structureless. A functional four-subunit enzyme and the knob-like structure could be reconstituted by the addition of soluble catalytic subunits to the urea-stripped membranes. In addition to the vesicular structures, we observed unusual tubular structures which were covered with a helical array of fumarate reductase knobs.     

Electron donors and the quinone involved in dimethyl sulfoxide reduction inEscherichia coli

Escherichia coli can use dimethyl sulfoxide (DMSO) as an electron acceptor during anaerobic growth on the oxidizable substrate, glycerol. During growth, the DMSO is reduced to dimethyl sulfide (DMS). For the reduction of DMSO, NADH, formate, lactate, reduced benzyl viologen, reduced methyl viologen, and dithionite can serve as electron donors. The terminal reductase and the dehydrogenases linking the various electron donors to the electron transport chain were found to be membrane bound. Chlorate-resistant mutants (chl) were unable to grow and reduce DMSO. However, in the case of thechlD mutant, growth and DMSO reduction can be restored by growth in the presence of high concentrations of molybdate. Mutants ofE. coli blocked in menaquinone (vitamin K₂) biosynthesis—menB, menC, andmenD—were unable to grow with DMSO as an electron acceptor, even though the terminal reductase is present in these mutants. Both growth and DMSO reduction could be restored in these mutants by growth in the presence of the menaquinone intermediates,o-succinylbenzoate and 1,4-dihydroxy-2-naphthoate, depending on the metabolic block of the mutant. Thus menaquinone is involved in electron transport during DMSO reduction.     

Characterization of genes encoding dimethyl sulfoxide reductase of Rhodobacter sphaeroides 2.4.1T: an essential metabolic gene function encoded on chromosome II.

Rhodobacter sphaeroides 2.4.1T is a purple nonsulfur facultative phototrophic bacterium which exhibits remarkable metabolic diversity as well as genomic complexity. Under anoxic conditions, in the absence of light and the presence of dimethyl sulfoxide (DMSO) or trimethylamine N-oxide (TMAO), R. sphaeroides 2.4.1T utilizes DMSO or TMAO as the terminal electron acceptor for anaerobic respiration, which is mediated by the molybdoenzyme DMSO reductase. Sequencing of a 13-kb region of chromosome II revealed the presence of 10 putative open reading frames, of which 5 possess homology to genes encoding the TMAO reductase (the tor system) of Escherichia coli. The dorS and dorR genes encode a sensor-regulator pair of the two-component sensory transduction protein family, homologous to the torS and torR gene products. The dorC gene was shown to encode a 44-kDa DMSO-inducible c-type cytochrome. The dorB gene encodes a membrane protein of unknown function homologous to the torD gene product. The dorA gene encodes DMSO reductase, containing the molybdopterin active site. Mutations were constructed in each of these dor genes, and the resulting mutants were shown to be impaired for DMSO-dependent anaerobic growth in the dark. The mutant strains exhibited negligible levels of DMSO reductase activity compared to the wild-type strain under similar growth conditions. Further, no DorA protein was detected in DorS and DorR mutant strains with anti-DorA antisera, suggesting that the products of these genes are required for the positive regulation of dor expression in response to DMSO. This characterization of the dor gene cluster is the first evidence that genes of chromosome CII encode metabolic functions which are essential under particular growth conditions.     

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.     

Modularity of the Mtr respiratory pathway of Shewanella oneidensis strain MR‐1

Four distinct pathways predicted to facilitate electron flow for respiration of externally located substrates are encoded in the genome of Shewanella oneidensis strain MR‐1. Although the pathways share a suite of similar proteins, the activity of only two of these pathways has been described. Respiration of extracellular substrates requires a mechanism to facilitate electron transfer from the quinone pool in the cytoplasmic membrane to terminal reductase enzymes located on the outer leaflet of the outer membrane. The four pathways share MtrA paralogues, a periplasmic electron carrier cytochrome, and terminal reductases similar to MtrC for reduction of metals, flavins and electrodes or to DmsAB for reduction of dimethyl sulphoxide (DMSO). The promiscuity of respiratory electron transfer reactions catalysed by these pathways has made studying strains lacking single proteins difficult. Here, we present a comprehensive analysis of MtrA and MtrC paralogues in S. oneidensis to define the roles of these proteins in respiration of insoluble iron oxide, soluble iron citrate, flavins and DMSO. We present evidence that some periplasmic electron carrier components and terminal reductases in these pathways can provide partial compensation in the absence of the primary component, a phenomenon described as modularity, and discuss biochemical and evolutionary implications.     

Behaviour of topological marker proteins targeted to the Tat protein transport pathway

The Escherichia coli Tat system mediates Sec-independent export of protein precursors bearing twin arginine signal peptides. Formate dehydrogenase-N is a three-subunit membrane-bound enzyme, in which localization of the FdnG subunit to the membrane is Tat dependent. FdnG was found in the periplasmic fraction of a mutant lacking the membrane anchor subunit FdnI, confirming that FdnG is located at the periplasmic face of the cytoplasmic membrane. However, the phenotypes of gene fusions between fdnG and the subcellular reporter genes phoA (encoding alkaline phosphatase) or lacZ (encoding beta-galactosidase) were the opposite of those expected for analogous fusions targeted to the Sec translocase. PhoA fusion experiments have previously been used to argue that the peripheral membrane DmsAB subunits of the Tat-dependent enzyme dimethyl sulphoxide reductase are located at the cytoplasmic face of the inner membrane. Biochemical data are presented that instead show DmsAB to be at the periplasmic side of the membrane. The behaviour of reporter proteins targeted to the Tat system was analysed in more detail. These data suggest that the Tat and Sec pathways differ in their ability to transport heterologous passenger proteins. They also suggest that caution should be observed when using subcellular reporter fusions to determine the topological organization of Tat-dependent membrane protein complexes.     

Need for cytochrome bc1 complex for dissimilatory nitrite reduction of Pseudomonas aeruginosa

Pseudomonas aeruginosa strains deficient in the genes for cytochrome c1, a subunit of the cytochrome bc1 complex, or the tetraheme membrane protein NapC, which is similar to NirT of Pseudomonas stutzeri, were constructed and their growth was investigated. The cytochrome c1 mutant could not grow under anaerobic conditions with nitrite as an electron acceptor and did not reduce nitrite in spite of its producing active nitrite reductase. NirM (cytochrome c551) and azurin, which are the direct electron donors for nitrite reductase, were reduced by succinate in the presence of the membrane fraction from the wild-type strain as a mediator but not in the presence of that from the cytochrome c1 mutant. These results indicated that cytochrome bc1 complex was necessary for electron transfer from the membrane quinone pool to nitrite reductase. The NapC mutant grew anaerobically at the expense of nitrite, indicating that NapC was not necessary for nitrite reduction.     

Organization of dimethyl sulfoxide reductase in the plasma membrane of Escherichia coli.

Dimethyl sulfoxide reductase is a trimeric, membrane-bound, iron-sulfur molybdoenzyme induced in Escherichia coli under anaerobic growth conditions. The enzyme catalyzes the reduction of dimethyl sulfoxide, trimethylamine N-oxide, and a variety of S- and N-oxide compounds. The topology of dimethyl sulfoxide reductase subunits was probed by a combination of techniques. Immunoblot analysis of the periplasmic proteins from the osmotic shock and chloroform wash fluids indicated that the subunits were not free in the periplasm. The reductase was susceptible to proteases in everted membrane vesicles, but the enzyme in outer membrane-permeabilized cells became protease sensitive only after detergent solubilization of the E. coli plasma membrane. Lactoperoxidase catalyzed the iodination of each of the three subunits in an everted membrane vesicle preparation. Antibodies to dimethyl sulfoxide reductase and fumarate reductase specifically agglutinated the everted membrane vesicles. No TnphoA fusions could be found in the dmsA or -B genes, indicating that these subunits were not translocated to the periplasm. Immunogold electron microscopy of everted membrane vesicles and thin sections by using antibodies to the DmsABC, DmsA, DmsB subunits resulted in specific labeling of the cytoplasmic surface of the inner membrane. These results show that the DmsA (catalytic subunit) and DmsB (electron transfer subunit) are membrane-extrinsic subunits facing the cytoplasmic side of the plasma membrane.     

The correlation between the protein composition of cytoplasmic membranes and the formation of nitrate reductase A,chlorate reductase C and tetrathionate reductase in Proteus mirabilis wild type and some chlorate resistant mutants

Three genotypically different chlorate resistant mutants, chl I, chl II and chl III, appeared to lack completely nitrate reductase A, chlorate reductase C and tetrathionate reductase activity. Fumarate reductase is only partially affected in chl I and chl III and unaffected in chl II. Formate dehydrogenase is only partially diminished in chl II, hydrogenase is diminished in chl I and chl II and completely absent in chl III.Subunits of nitrate reductase A, chlorate reductase C and tetrathionate reductase have been identified in protein profiles of purified cytoplasmic membranes from the wild type and the three mutant strains, grown under various conditions. Only the presence and absence of the largest subunits of these enzymes appeared to be correlated with their repression and derepression in the wild type membranes. On the cytoplasmic membranes of the chl I and chl III mutants these subunits lack for the greater part. In the chl II mutant, however, these subunits are inserted in the membrane all together after anaerobic growth with or without nitrate.A model for the repression/derepression mechanism for the reductases has been proposed. It includes repression by cytochrome b components, whereas the redox-state of the nitrate reductase A molecule itself is also involved in its derepression under anaerobic conditions.     

Analysis of the fnrL gene and its function in Rhodobacter capsulatus.

The fnr gene encodes a regulatory protein involved in the response to oxygen in a variety of bacterial genera. For example, it was previously shown that the anoxygenic, photosynthetic bacterium Rhodobacter sphaeroides requires the fnrL gene for growth under anaerobic, photosynthetic conditions. Additionally, the FnrL protein in R. sphaeroides is required for anaerobic growth in the dark with an alternative electron acceptor, but it is not essential for aerobic growth. In this study, the fnrL locus from Rhodobacter capsulatus was cloned and sequenced. Surprisingly, an R. capsulatus strain with the fnrL gene deleted grows like the wild type under either photosynthetic or aerobic conditions but does not grow anaerobically with alternative electron acceptors such as dimethyl sulfoxide (DMSO) or trimethylamine oxide. It is demonstrated that the c-type cytochrome induced upon anaerobic growth on DMSO is not synthesized in the R. capsulatus fnrL mutant. In contrast to wild-type strains, R. sphaeroides and R. capsulatus fnrL mutants do not synthesize the anaerobically, DMSO-induced reductase. Mechanisms that explain the basis for FnrL function in both organisms are discussed.     

Anaerobic respiration in the Rhodospirillaceae: characterisation of pathways and evaluation of roles in redox balancing during photosynthesis

Abstract Recent discoveries relating to pathways of anaerobic electron transport in the Rhodospirillaceae are reviewed. The main emphasis is on the organism Rhodobacter capsulatus ** but comparisons are made with Rhodobacter sphaeroides ** f. sp. denitrificans and Rhodopseudomonas palustris . The known electron acceptors for anaerobic respiration in Rhodobacter capsulatus are trimethylamine- N -oxide (TMAO), dimethyl sulphoxide (DMSO), nitrate and nitrous oxide. In each case respiration generates a proton electrochemical gradient and in some cases can support growth on non-fermentable carbon sources. However, the principal objective of this review is to discuss the possibility that, apart from a role in energy conservation, anaerobic respiration in the photosynthetic bacteria may have a special function in maintaining redox balance during photosynthetic metabolism. Thus the electron acceptors mentioned above may serve as auxiliary oxidants: (a) to maintain an optimal redox poise of the photosynthetic electron transport chain; (b) to provide a sink for electrons during phototrophic growth on highly reduced carbon substrates.
Molecular properties of the nitrate reductase, nitrous oxide reductase and a single enzyme responsible for reduction of TMAO and DMSO are discussed. These enzymes are all located in the periplasm. Electrons destined for all three enzymes can originate from the rotenone-sensitive NADH dehydrogenase but do not proceed through the antimycin- and myxothiazol-sensitive cytochrome b/c₁ complex. It is likely, therefor, that the pathways of anaerobic respiration overlap with the cyclic photosynthetic electron transport chain only at the level of the ubiquinone pool. Redox components which might be involved in the terminal branches of anaerobic respiration are discussed.     

Differentiation of the multiple S- and N-oxide-reducing activities ofEscherichia coli

InEscherichia coli, several terminal reductases catalyze the reduction of S- and N-oxide compounds. We have used mutants missing either the constitutive dimethylsulfoxide (DMSO) reductase,dmsABC, and/or the inducible trimethylamine N-oxide (TMAO) reductase,torA, to define the roles of each reductase. These studies indicated that the constitutive DMSO reductase can sustain growth on DMSO, TMAO, methionine sulfoxide (MetSO), and other N-oxide compounds. Only one inducible TMAO reductase is expressed inE. coli, and this enzyme sustains growth on TMAO but not DMSO or MetSO. Characterization of atorA ^–, dms^–double mutant revealed that adenosine N-oxide (ANO) reductase is specifically required for anaerobic respiration on ANO in this mutant.     

A model for the structure of fumarate reductase in the cytoplasmic membrane of Escherichia coli

By a recombinant DNA approach we have prepared Escherichia coli cytoplasmic membranes that are highly enriched in the terminal electron transfer enzyme fumarate reductase. This enzyme is composed of four nonidentical subunits in equal molar ratio. A 69,000-dalton covalent flavin-containing subunit and a 27,000-dalton nonheme iron-containing subunit make up a membrane extrinsic catalytic domain. Two very hydrophobic subunits of 15,000 and 13,000 daltons make up the hydrophobic membrane anchor domain. Electron microscopy of negatively stained membranes shows a characteristic knob-and-stalk-type structure composed of the catalytic domain. The anchor polypeptides have been analyzed for hydrophobic segments and alpha-helical content and a model for their organization within the lipid bilayer is presented. The results reviewed in this paper suggest a model for the fumarate reductase complex in the cytoplasmic membrane.     

Electron transfer from menaquinol to fumarate. Fumarate reductase anchor polypeptide mutants of Escherichia coli

Fumarate reductase (FRD) of Escherichia coli is a four-subunit membrane-bound complex that is synthesized during anaerobic growth when fumarate is available as a terminal oxidant. The two subunits that comprise the catalytic domain, FrdA and FrdB, are anchored to the cytoplasmic membrane surface by two small hydrophobic polypeptides, FrdC and FrdD, which are also required for the enzyme to interact with quinone. To better define the individual roles of the FrdC and FrdD polypeptides in FRD complex formation and quinone binding, we selectively mutagenized the frdCD genes. Frd- strains were identified by their inability to grow on restrictive media, and the resulting mutant FRD complexes were isolated and biochemically characterized. The majority of the frdC and frdD mutations were identified as single base deletions that caused premature termination in either FrdC or FrdD and resulted in the loss of one or more of the predicted transmembrane helices. Two additional frdC mutants were characterized that contained single base changes resulting in single amino acid substitutions. All mutant enzyme complexes were incapable of oxidizing the physiological electron donor, menaquinol-6, in the presence of fumarate. Additionally, the ability of the mutant complexes to oxidize reduced benzyl viologen or reduce the ubiquinone analogue 2,3-dimethoxy-5-methyl-6-pentyl-1,4-benzoquinone and phenazine methosulfate with succinate as electron donor were also affected but to varying degrees. The separation of oxidative and reductive activities with quinones suggests there are two quinone binding sites in the fumarate reductase complex and that electron transfer occurs in two le- steps carried out at these separate sites.     

A genetic screen for suppressors of Escherichia coli Tat signal peptide mutations establishes a critical role for the second arginine within the twin-arginine motif

The Escherichia coli Tat protein export pathway transports folded proteins synthesized with N-terminal twin-arginine signal peptides. Twin-arginine signal sequences contain a conserved SRRxFLK "twin-arginine" amino acid sequence motif which is required for protein export by the Tat pathway. The E. coli trimethylamine N-oxide reductase (TorA) is a Tat-dependent periplasmic molybdoenzyme that facilitates anaerobic respiration with trimethylamine N-oxide as terminal electron acceptor. Here, we describe mutant strains constructed with modified TorA twin-arginine signal peptides. Substitution of the second arginine residue of the TorA signal peptide twin-arginine motif with either lysine or aspartate, or the simultaneous substitution of both arginines with lysine residues, completely abolished export. In each case, the now cytoplasmically localised TorA retained full enzymatic activity with the artificial electron donor benzyl viologen. However, the mutant strains were incapable of anaerobic growth with trimethylamine N-oxide and the non-fermentable carbon-source glycerol. The growth phenotype of the mutant strains was exploited in a genetic screen with the aim of identifying second-site suppressor mutations that allowed export of the modified TorA precursors.     

The effect of oxygen on denitrification during steady-state growth of Paracoccus halodenitrificans

Dimethylsulphoxide (DMSO) and trimethylamine oxide (TMAO) sustained anaerobic growth of Proteus vulgaris with the non-fermentable substrate lactate. Cytoplasmic membrane vesicles energized by electron transfer from formate to DMSO displayed anaerobic uptake of serine, which was hindered by metabolic inhibitors known to destroy the proton motive force. This showed that DMSO reduction was coupled with a chemiosmotic mechanism of energy conversion; similar data for TMAO respiration have been presented previously. All biochemical tests applied indicated that the oxides were reduced by the same reductase system. The DMSO and TMAO reductase activities showed the same mobility on ion-exchange chromatography, and polyacrylamide disc gel electrophoresis (pH 8.9), gradient gel electrophoresis, and gel isoelectric focusing; mol. wt. and pI determined were 95,000 and 4.6, respectively. DMSO inhibited reduction of [¹⁴C]TMAO in vesicles. The reductase was inducible to a certain extent; both oxides being equally efficient as inducers. TMAO was reduced at a higher rate than DMSO, explaining faster growth of cells and increased uptake of serine in vesicles with TMAO as electron acceptor. Comparative studies with Escherichia coli also gave evidence for common TMAO and DMSO reductase systems.Abbreviations TMAO trimethylamine oxide - DMSO dimethylsulphoxide