TorT, a member of a new periplasmic binding protein family, triggers induction of the Tor respiratory system upon trimethylamine N-oxide electron-acceptor binding in Escherichia coli

In anaerobiosis, Escherichia coli can use trimethylamine N-oxide (TMAO) as a terminal electron acceptor. Reduction of TMAO in trimethylamine (TMA) is mainly performed by the respiratory TMAO reductase. This system is encoded by the torCAD operon, which is induced in the presence of TMAO. This regulation involves a two-component system comprising TorS, an unorthodox histidine kinase, and TorR, a response regulator. A third protein, TorT, sharing homologies with periplasmic binding proteins, plays a key role in this regulation because disruption of the torT gene abolishes tor expression. In this study we showed that TMAO protects TorT against degradation by the GluC endoproteinase and modifies its temperature-induced CD spectrum. We also isolated a TorT negative mutant that is no longer protected by TMAO from degradation by GluC. Isothermal titration calorimetry confirmed that TorT binds TMAO with a binding constant of 150 mum. Therefore, we conclude that TorT binds TMAO and that this binding promotes a conformational change of TorT. We also showed that TorT interacts with the periplasmic domain of TorS in both the presence and absence of TMAO but the TorT-TMAO complex induces a higher GluC protection of TorS than TorT alone. These results support the idea that TMAO binding to TorT induces a cascade of conformational changes from TorT to TorS, leading to TorS activation. We identified several homologues of the TorT protein that define a new family of periplasmic binding proteins. We thus propose that the members of this family bind TMAO or related compounds and that they are involved in signal transduction or even substrate transport.     

TorC apocytochrome negatively autoregulates the trimethylamine N-oxide (TMAO) reductase operon in Escherichia coli

The trimethylamine N-oxide (TMAO) anaerobic respiratory system of Escherichia coli comprises a periplasmic terminal TMAO reductase (TorA) and a pentahaem c-type cytochrome (TorC), which is involved in electron transfer to TorA. The structural proteins are encoded by the torCAD operon whose expression is induced in the presence of TMAO through the TorS/TorR two-component system. By using a genomic library cloned into a multicopy plasmid, we identified TorC as a possible negative regulator of the tor operon. Interestingly, in trans overexpression of torC not only decreased the activity of a torA'-'lacZ fusion, but also dramatically reduced the amount of mature TorC cytochrome. This led us to propose that, after translocation, TorC apocytochrome downregulates the tor operon unless it is properly matured. In agreement with this hypothesis, we have shown that mini-Tn10 insertions within genes involved in the c-type cytochrome maturation pathway or haem biosynthesis decreased tor operon expression. Dithiothreitol (DTT), which reduces disulphide bonds and thus prevents the first step in c-type cytochrome formation, also strongly decreases the tor promoter activity. The DTT effect is TorC dependent, as it is abolished when torC is disrupted. In contrast, overexpression of the c-type cytochrome maturation (ccm ) genes relieved the tor operon of the negative control and allowed the bacteria to produce a higher amount of TorC holocytochrome. Therefore, the TorC negative autoregulation probably means that maturation of the c-type cytochrome is a limiting step for Tor system biogenesis. Genetic experiments have provided evidence that TorC control is mediated by the TorS/TorR two-component system and different from the tor anaerobic control. In our working model, TMAO and apoTorC bind to the periplasmic side of TorS, but TMAO activates TorS autophosphorylation, whereas apoTorC inhibits the TorS kinase activity.     

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.     

An unorthodox sensor protein (TorS) mediates the induction of the tor structural genes in response to trimethylamine N-oxide in Escherichia coli

We isolated and characterized three spontaneous mutations leading to trimethylamine N-oxide (TMAO)-independent expression of the tor operon encoding the TMAO-reductase anaerobic respiratory system in Escherichia coli. The mutations lie in a new tor regulatory gene, the torS gene, which probably encodes a sensor protein of a two-component regulatory system. One mutation, which leads to full TMAO-constitutive expression, is a 3-amino-acid deletion within the potential N-terminal periplasmic region, suggesting that this region contains the TMAO-detector site. For the other two mutations, a further induction of the tor operon is observed when TMAO is added. Both are single substitutions and affect the linker region located between the detector and the conserved transmitter domains. Thus, as proposed for other sensors, the TorS linker region might play an essential role in propagating conformational changes between the detector and the cytoplasmic signalling regions. The TorR histidine kinase is an unorthodox sensor that contains a receiver and a C-terminal alternative transmitter domain in addition to the domains found in most sensors. Previously, we showed that TMAO induction of the tor operon requires the TorR response regulator and the TorT periplasmic protein. Additional genetic data confirm that torS encodes the sensor partner of TorR and TorT. First, insertion within torS abolishes tor operon expression whatever the growth conditions. Second, overexpressed TorR bypasses the requirement for torS, whereas the torT gene product is dispensable for tor operon expression in a torS constitutive mutant. This supports a signal-transduction cascade from TorT to TorR via TorS.     

The torYZ (yecK bisZ) operon encodes a third respiratory trimethylamine N-oxide reductase in Escherichia coli

The bisZ gene of Escherichia coli was previously described as encoding a minor biotin sulfoxide (BSO) reductase in addition to the main cytoplasmic BSO reductase, BisC. In this study, bisZ has been renamed torZ based on the findings that (i) the torZ gene product, TorZ, is able to reduce trimethylamine N-oxide (TMAO) more efficiently than BSO; (ii) although TorZ is more homologous to BisC than to the TMAO reductase TorA (63 and 42% identity, respectively), it is located mainly in the periplasm as is TorA; (iii) torZ belongs to the torYZ operon, and the first gene, torY (formerly yecK), encodes a pentahemic c-type cytochrome homologous to the TorC cytochrome of the TorCAD respiratory system. Furthermore, the torYZ operon encodes a third TMAO respiratory system, with catalytic properties that are clearly different from those of the TorCAD and the DmsABC systems. The torYZ and the torCAD operons may have diverged from a common ancestor, but, surprisingly, no torD homologue is found in the sequences around torYZ. Moreover, the torYZ operon is expressed at very low levels under the conditions tested, and, in contrast to torCAD, it is not induced by TMAO or dimethyl sulfoxide.     

An asymmetry-to-symmetry switch in signal transmission by the histidine kinase receptor for TMAO

The osmoregulator trimethylamine-N-oxide (TMAO), commonplace in aquatic organisms, is used as the terminal electron acceptor for respiration in many bacterial species. The TMAO reductase (Tor) pathway for respiratory catalysis is controlled by a receptor system that comprises the TMAO-binding protein TorT, the sensor histidine kinase TorS, and the response regulator TorR. Here we study the TorS/TorT sensor system to gain mechanistic insight into signaling by histidine kinase receptors. We determined crystal structures for complexes of TorS sensor domains with apo TorT and with TorT (TMAO); we characterized TorS sensor associations with TorT in solution; we analyzed the thermodynamics of TMAO binding to TorT-TorS complexes; and we analyzed in vivo responses to TMAO through the TorT/TorS/TorR system to test structure-inspired hypotheses. TorS-TorT(apo) is an asymmetric 2:2 complex that binds TMAO with negative cooperativity to form a symmetric active kinase.     

Electron transfer and binding of the c-type cytochrome TorC to the trimethylamine N-oxide reductase in Escherichia coli

Reduction of trimethylamine N-oxide (E'(0(TMAO/TMA)) = +130 mV) in Escherichia coli is carried out by the Tor system, an electron transfer chain encoded by the torCAD operon and made up of the periplasmic terminal reductase TorA and the membrane-anchored pentahemic c-type cytochrome TorC. Although the role of TorA in the reduction of trimethylamine N-oxide (TMAO) has been clearly established, no direct evidence for TorC involvement has been presented. TorC belongs to the NirT/NapC c-type cytochrome family based on homologies of its N-terminal tetrahemic domain (TorC(N)) to the cytochromes of this family, but TorC contains a C-terminal extension (TorC(C)) with an additional heme-binding site. In this study, we show that both domains are required for the anaerobic bacterial growth with TMAO. The intact TorC protein and its two domains, TorC(N) and TorC(C), were produced independently and purified for a biochemical characterization. The reduced form of TorC exhibited visible absorption maxima at 552, 523, and 417 nm. Mediated redox potentiometry of the heme centers of the purified components identified two negative midpoint potentials (-177 and -98 mV) localized in the tetrahemic TorC(N) and one positive midpoint potential (+120 mV) in the monohemic TorC(C). In agreement with these values, the in vitro reconstitution of electron transfer between TorC, TorC(N), or TorC(C) and TorA showed that only TorC and TorC(C) were capable of electron transfer to TorA. Surprisingly, interaction studies revealed that only TorC and TorC(N) strongly bind TorA. Therefore, TorC(C) directly transfers electrons to TorA, whereas TorC(N), which probably receives electrons from the menaquinone pool, is involved in both the electron transfer to TorC(C) and the binding to TorA.     

Effects of ISSo2 insertions in structural and regulatory genes of the trimethylamine oxide reductase of Shewanella oneidensis

We have isolated three Shewanella oneidensis mutants specifically impaired in trimethylamine oxide (TMAO) respiration. The mutations arose from insertions of an ISSo2 element into torA, torR, and torS, encoding, respectively, the TMAO reductase TorA, the response regulator TorR, and the sensor TorS. Although TorA is not the sole enzyme reducing TMAO in S. oneidensis, growth analysis showed that it is the main respiratory TMAO reductase. Use of a plasmid-borne torE'-lacZ fusion confirmed that the TorS-TorR phosphorelay mediates TMAO induction of the torECAD operon.     

Anaerobic induction of trimethylamine N-oxide reductase and cytochromes by dimethyl sulfoxide inEscherichia coli

Reduction of trimethylamine N-oxide is catalyzed by at least two enzymes inEscherichia coli: trimethylamine N-oxide reductase, which is anaerobically induced by trimethylamine N-oxide, and the constitutive enzyme dimethyl sulfoxide reductase. In this study, an increase in the specific activity of trimethylamine N-oxide reduction was observed in the anaerobic culture with dimethyl sulfoxide, but the specific activity of dimethyl sulfoxide reduction was not changed. The inducible enzyme trimethylamine N-oxide reductase was found in this culture. A marked expression of the structural genetorA for trimethylamine N-oxide reductase was also observed in atorA-lacZ gene fusion strain under anaerobic conditions with either trimethylamine N-oxide or dimethyl sulfoxide.l-Methionine sulfoxide and the N-oxides of adenosine, picolines, and nicotinamide slightly repressed expression of the gene. Membrane-boundb- andc-type cytochromes involved in the trimethylamine N-oxide reduction were also produced in a wild-type strain grown anaerobically with dimethyl sulfoxide. But thec-type cytochrome was not produced in thetorA-lacZ strain grown anaerobically with trimethylamine N-oxide or dimethyl sulfoxide; this suggests that there is a correlation between the expression oftorA and the synthesis of the cytochrome.     

Proton translocation coupled to trimethylamine N-oxide reduction in anaerobically grown Escherichia coli.

Proton translocation coupled to trimethylamine N-oxide reduction was studied in Escherichia coli grown anaerobically in the presence of trimethylamine N-oxide. Rapid acidification of the medium was observed when trimethylamine N-oxide was added to anaerobic cell suspensions of E. coli K-10. Acidification was sensitive to the proton conductor 3,5-di-tert-butyl-4-hydroxybenzylidenemalononitrile (SF6847). No pH change was shown in a strain deficient in trimethylamine N-oxide reductase activity. The apparent H+/trimethylamine N-oxide ratio in cells oxidizing endogenous substrates was 3 to 4 g-ions of H+ translocated per mol of trimethylamine N-oxide added. The addition of trimethylamine N-oxide and formate to ethylenediaminetetraacetic acid-treated cell suspension caused fluorescence quenching of 3,3'-dipropylthiacarbocyanine [diS-C3-(5)], indicating the generation of membrane potential. These results indicate that the reduction of trimethylamine N-oxide in E. coli is catalyzed by an anaerobic electron transfer system, resulting in formation of a proton motive force. Trimethylamine N-oxide reductase activity and proton extrusion were also examined in chlorate-resistant mutants. Reduction of trimethylamine N-oxide occurred in chlC, chlG, and chlE mutants, whereas chlA, chlB, and chlD mutants, which are deficient in the molybdenum cofactor, could not reduce it. Protons were extruded in chlC and chlG mutants, but not in chlA, chlB, and chlD mutants. Trimethylamine N-oxide reductase activity in a chlD mutant was restored to the wild-type level by the addition of 100 microM molybdate to the growth medium, indicating that the same molybdenum cofactor as used by nitrate reductase is required for the trimethylamine N-oxide reductase system.