An unsuspected autoregulatory pathway involving apocytochrome TorC and sensor TorS in Escherichia coli

Trimethylamine N-oxide (TMAO) respiration is carried out mainly by the Tor system in Escherichia coli. This system is encoded by the torCAD operon and comprises a periplasmic TMAO reductase (TorA) and a c-type cytochrome (TorC), which shuttles electrons to TorA. Expression of the tor operon is positively controlled by the TorS/TorR phosphorelay system in response to TMAO availability and negatively regulated by apocytochrome TorC. Interaction studies showed that, when immature, TorC can no longer bind TorA efficiently but can bind the periplasmic detector region of sensor TorS. ApoTorC negative autoregulation and TMAO induction are thus mediated by the same sensor protein. As apocytochromes related to TorC could not down-regulate the tor operon, we concluded that this negative control is highly specific. Moreover, the N-terminal half of apoTorC played no role in this control but the immature C-terminal domain of TorC strongly down-regulated the tor operon and interacted with the TorS detector region. This sophisticated autoregulatory pathway thus involves the C-terminal domain of apoTorC and allows optimal TorC biogenesis by preventing from saturation the c-type cytochrome maturation machinery.

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.

Rapid dephosphorylation of the TorR response regulator by the TorS unorthodox sensor in Escherichia coli

Induction of the torCAD operon, encoding the trimethylamine N-oxide (TMAO) respiratory system, is tightly controlled by the TorS-TorR phosphorelay system in response to TMAO availability. TorS is an unorthodox sensor that contains three phosphorylation sites and transphosphorylates TorR via a four-step phosphorelay, His443-->Asp723-->His850-->Asp(TorR). In this study, we provide genetic evidence that TorS can dephosphorylate phospho-TorR when TMAO is removed. Dephosphorylation probably occurs by a reverse phosphorelay, Asp(TorR)-->His850-->Asp723, since His850 and Asp723 are both essential in this process. By using reverse transcriptase PCR, we also show that TMAO removal results in shutoff of tor operon transcription in less than 2 min. Based on our results and on analogy to other phosphorelay signal transduction systems, we propose that reverse phosphotransfer could be a rapid and efficient mechanism to inactivate response regulators.

Two-component systems in Pseudomonas aeruginosa: why so many?

Screening the Pseudomonas aeruginosa genome has led to the identification of the highest number of putative genes encoding two-component regulatory systems of all bacterial genomes sequenced to date (64 and 63 encoding response regulators and histidine kinases, respectively). Sixteen atypical kinases, among them 11 devoid of an Hpt domain, and three independent Hpt modules were retrieved. These data suggest that P. aeruginosa possesses complex control strategies with which to respond to environmental challenges.

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.

Comparison of methods for quantification of cytochrome cd(1)-denitrifying bacteria in environmental marine samples

Two PCR primer sets were developed for the detection and quantification of cytochrome cd(1)-denitrifying bacteria in environmental marine samples. The specificity and sensitivity of these primers were tested. Both primer sets were suitable for detection, but only one set, cd3F-cd4R, was suitable for the quantification and enumeration of the functional community using most-probable-number PCR and competitive PCR techniques. Quantification of cytochrome cd(1) denitrifiers taken from marine sediment and water samples was achieved using two different molecular techniques which target the nirS gene, and the results were compared to those obtained by using the classical cultivation method. Enumerations using both molecular techniques yielded similar results in seawater and sediment samples. However, both molecular techniques showed 1,000 or 10 times more cytochrome cd(1) denitrifiers in the sediment or water samples, respectively, than were found by use of the conventional cultivation method for counting.

The TorR high-affinity binding site plays a key role in both torR autoregulation and torCAD operon expression in Escherichia coli

In the presence of trimethylamine N-oxide (TMAO), the TorS-TorR two-component regulatory system induces the torCAD operon, which encodes the TMAO respiratory system of Escherichia coli. The sensor protein TorS detects TMAO and transphosphorylates the response regulator TorR which, in turn, activates transcription of torCAD. The torR gene and the torCAD operon are divergently transcribed, and the short torR-torC intergenic region contains four direct repeats (the tor boxes) which proved to be TorR binding sites. The tor box 1-box 2 region covers the torR transcription start site and constitutes a TorR high-affinity binding site, whereas box 3 and box 4 correspond to low-affinity binding sites. By using torR-lacZ operon fusions in different genetic backgrounds, we showed that the torR gene is negatively autoregulated. Surprisingly, TorR autoregulation is TMAO independent and still occurs in a torS mutant. In addition, this negative regulation involves only the TorR high-affinity binding site. Together, these data suggest that phosphorylated as well as unphosphorylated TorR binds the box 1-box 2 region in vivo, thus preventing RNA polymerase from binding to the torR promoter whatever the growth conditions. By changing the spacing between box 2 and box 3, we demonstrated that the DNA motifs of the high- and low-affinity binding sites must be close to each other and located on the same side of the DNA helix to allow induction of the torCAD operon. Thus, prior TorR binding to the box 1-box 2 region seems to allow cooperative binding of phosphorylated TorR to box 3 and box 4.

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.

The leader sequence of the Escherichia coli lysC gene is involved in the regulation of LysC synthesis

In Escherichia coli and Bacillus subtilis, long leader sequences are found upstream of the lysC coding sequences which encode lysine-sensitive aspartokinase. Highly conserved regions exist between these sequences. Mutations leading to constitutive expression of the E. coli lysC gene have been localised within these conserved regions, indicating that they participate in the lysine-mediated repression mechanism of lysC expression.

Molecular analysis of the trimethylamine N-oxide (TMAO) reductase respiratory system from a Shewanella species

Trimethylamine N-oxide (TMAO) is an abundant compound of tissues of marine fish and invertebrates. During fish spoilage, certain marine bacteria can reduce TMAO to nauseous trimethylamine (TMA). One such bacterium has been isolated and identified as a new Shewanella species, and called Shewanella massilia. The anaerobic growth of S. massilia is greatly increased when TMAO is added, indicating that TMAO reduction involves a respiratory pathway. The TorA enzyme responsible for TMAO reduction is a molybdenum cofactor-containing protein of 90 kDa located in the periplasm. Whereas TorA is induced by both TMAO and dimethylsulfoxide (DMSO), this enzyme has a high substrate specificity and appears to only efficiently reduce TMAO as a natural compound. The structural torA gene encoding the TMAO reductase (TorA) and its flanking regions were amplified using PCR techniques. The torA gene is the third gene of a TMAO-inducible operon (torECAD) encoding the TMAO respiratory components. The torC gene, located upstream from torA encodes a pentahemic c-type cytochrome, likely to be involved in electron transfer to the TorA terminal reductase. TorC was shown to be anchored to the membrane and, like TorA, is induced by TMAO. Except for the TorE protein, which is encoded by the first gene of the torECAD operon, all the tor gene products are homologous to proteins found in the TMAO/DMSO reductase systems from Escherichia coli and Rhodobacter species. In addition, the genetic organization of these systems is similar. Although these bacteria are found in different ecological niches, their respiratory systems appear to be phylogenetically related, suggesting that they come from a common ancestor.

Crystal structure of oxidized trimethylamine N-oxide reductase from Shewanella massilia at 2.5 A resolution

The periplasmic trimethylamine N-oxide (TMAO) reductase from the marine bacteria Shewanella massilia is involved in a respiratory chain, having trimethylamine N-oxide as terminal electron acceptor. This molybdoenzyme belongs to the dimethyl sulfoxide (DMSO) reductase family, but has a different substrate specificity than its homologous enzyme. While the DMSO reductases reduce a broad spectra of organic S-oxide and N-oxide compounds, TMAO reductase from Shewanella massilia reduces only TMAO as the natural compound. The crystal structure was solved by molecular replacement with the coordinates of the DMSO reductase from Rhodobacter sphaeroides. The overall fold of the protein structure is essentially the same as the DMSO reductase structures, organized into four domains. The molybdenum coordination sphere is closest to that described in the DMSO reductase of Rhodobacter capsulatus. The structural differences found in the protein environment of the active site could be related to the differences in substrate specificity of these enzymes. In close vicinity of the molybdenum ion a tyrosine residue is missing in the TMAO reductase, leaving a greater space accessible to the solvent. This tyrosine residue has contacts to the oxo groups in the DMSO reductase structures. The arrangement and number of charged residues lining the inner surface of the funnel-like entrance to the active site, is different in the TMAO reductase than in the DMSO reductases from Rhodobacter species. Furthermore a surface loop at the top of the active-site funnel, for which no density was present in the DMSO reductase structures, is well defined in the oxidized form of the TMAO reductase structure, and is located on the border of the funnel-like entrance of the active center.

TorD, a cytoplasmic chaperone that interacts with the unfolded trimethylamine N-oxide reductase enzyme (TorA) in Escherichia coli

Reduction of trimethylamine N-oxide (TMAO) in Escherichia coli involves the terminal molybdoreductase TorA, located in the periplasm, and the membrane anchored c type cytochrome TorC. In this study, the role of the TorD protein, encoded by the third gene of torCAD operon, is investigated. Construction of a mutant, in which the torD gene is interrupted, showed that the absence of TorD protein leads to a two times decrease of the final amount of TorA enzyme. However, specific activity and biochemical properties of TorA enzyme were similar to those of the enzyme produced in the wild type. Excess of TorD protein restores the normal level of TorA enzyme, and also, leads to the appearance of a new cytoplasmic form of TorA on SDS-polyacrylamide gel electrophoresis using gentle conditions. This probably indicates a new folding state of the cytoplasmic TorA protein when TorD is overexpressed. BIAcore techniques demonstrated direct specific interaction between the TorA and TorD proteins. This interaction was enhanced when TorA was previously unfolded by heating. Finally, as TorA is a molybdoenzyme, we demonstrated that TorD can interact with TorA before the molybdenum cofactor has been inserted. As TorD homologue encoding genes are found in various TMAO reductase loci, we propose that TorD is a chaperone protein specific for the TorA enzyme. It belongs to a family of TorD-like chaperones present in several bacteria, and, probably, involved in TMAO reductase folding.

Transphosphorylation of the TorR response regulator requires the three phosphorylation sites of the TorS unorthodox sensor in Escherichia coli

Two-component regulatory systems allow cells to adapt to environmental changes. In Escherichia coli, the TorS/TorR two-component system induces the expression of the tor structural operon encoding the trimethylamine N-oxide reductase respiratory system in response to substrate availability. TorS belongs to a sensor subfamily that includes a classical transmitter domain, a receiver, and a C-terminal alternative transmitter domain. The histidine phosphorylation sites of each TorS transmitter domain and the aspartate phosphorylation site of the TorS receiver were individually changed by site-directed mutagenesis. All three phosphorylation sites proved essential for in vivo induction of the tor structural operon and for in vitro transphosphorylation of the cognate TorR response regulator. The His to Gln change in the classical transmitter domain abolished TorS autophosphorylation, whereas TorS underwent significant autophosphorylation when the phosphorylation site of its receiver or alternative transmitter was changed. Complementation between pairs of defective TorS proteins was achieved in vitro, allowing TorR transphosphorylation. This strongly suggests that TorS is a multimer in which intermolecular phosphorylation occurs. The wild-type alternative transmitter domain alone was shown to complement a TorS protein mutated in its C-terminal alternative transmitter. Interestingly, overproduction of the alternative transmitter domain led to in vivo TorR-dependent constitutive expression of the tor operon in a torS+ or torS context. Hence, the TorS alternative transmitter contains the phosphodonor site for TorR. Taken together, our results support a TorS phosphorylation cascade from the classical transmitter to the sensor receiver and the alternative transmitter phosphorylation sites.

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 for 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 TorS 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 for 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.

High substrate specificity and induction characteristics of trimethylamine-N-oxide reductase of Escherichia coli

Using a wide variety of N- and S-oxide compounds we have shown by kinetic analysis that only two N-oxides, trimethylamine-N-oxide and 4-methylmorpholine-N-oxide, can be considered good substrates for trimethylamine-N-oxide (TMAO) reductase on the basis of their kcat/Km ratio. This result demonstrates that TMAO reductase possesses a high substrate specificity. Induction of the torCAD operon using the same S- and N-oxide compounds was also analyzed. We demonstrate that there is no correlation between the ability for a compound to be reduced by TMAO reductase and to induce TMAO reductase synthesis.

The periplasmic TorT protein is required for trimethylamine N-oxide reductase gene induction in Escherichia coli

Expression of the Escherichia coli torCAD operon, which encodes the trimethylamine N-oxide reductase system, is regulated by the presence of trimethylamine N-oxide through the action of the TorR response regulator. We have identified an additional gene, torT, located just downstream from the torR gene, which is necessary for torCAD structural operon expression. Insertion within the torT gene dramatically reduced the expression of a torA'-'lacZ fusion, while presence of the gene in trans restored the wild-type phenotype. Overproduction of TorR in a torT strain resulted in partial constitutive expression of the torA'-'lacZ fusion, suggesting that TorR acts downstream from TorT. The torT gene codes for a 35.7-kDa periplasmic protein which presents some homology with the periplasmic ribose-binding protein of E. coli. We discuss the possible role of TorT as an inducer-binding protein involved in signal transduction of the tor regulatory pathway.

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.

Conservation of cis-acting elements within the tor regulatory region among different Enterobacteriaceae

The Escherichia coli (Ec) torCAD operon encoding the trimethyl amine N-oxide (TMAO) reductase system is induced by both TMAO and anaerobiosis. The tor regulatory regions from bacteria related to Ec have been amplified by the polymerase chain reaction (PCR) using degenerate oligodeoxyribonucleotide primers based on conserved sequences of the tor products. The amplified regions from Salmonella enteritidis and Sa. typhimurium (St) were the same size as that from Ec and showed 82% identity with it. Interestingly, four boxes of a 10-nucleotide motif (5'-CTGTTCATAT) were found in direct repeat at the same location in the tor regulatory region of the three species. Although the amplified fragment from Shigella sonneï (Ss) was highly homologous to the Ec corresponding segment, the first tor box was missing. In Ec, the St and Ss tor promoters were still regulated by both TMAO and anaerobiosis, but their transcriptional activities were significantly lower than that of the Ec tor promoter. Deletion of the two first boxes of the Ec tor regulatory region inactivated the tor promoter while deletion of the region just upstream from the tor boxes led to a significant decrease in tor expression. Our results strongly suggest that the tor boxes, as well as specific sequences outside the tor boxes, play an important role in the expression of the tor operon.

The torR gene of Escherichia coli encodes a response regulator protein involved in the expression of the trimethylamine N-oxide reductase genes

Expression of the Escherichia coli torCAD operon encoding the trimethylamine N-oxide (TMAO) reductase system is induced by both TMAO and anaerobiosis. A torR insertion mutant unable to express the torA gene had previously been isolated. The torR gene was cloned and sequenced. It encodes a 25,000-Da protein which shares homology with response regulators of two-component systems and belongs to the OmpR-PhoB subclass. Overproduction of TorR mimics the presence of the inducer TMAO while the anaerobic control is unchanged, suggesting that TorR mediates only the TMAO induction. The overproduced TorR protein was purified to more than 90%. The torR gene is located just upstream of the torCAD operon, with an opposite transcription direction. The torR-torCAD intergenic region is unusual in that it contains four direct repeats of a 10-nucleotide motif. Part or all of these motifs could be involved in the binding of TorR. The gene encoding the sensor partner does not seem to be adjacent to torR, since the divergent open reading frame found immediately downstream of torR exhibits none of the features of a protein histidine kinase.

Purification of the MutX protein of Streptococcus pneumoniae, a homologue of Escherichia coli MutT. Identification of a novel catalytic domain for nucleoside triphosphate pyrophosphohydrolase activity

The mutX gene of Streptococcus pneumoniae, a homologue of the Escherichia coli mutT mutator gene (Méjean, V., Salles, C., Bullions, L. C., Bessman, M. J., and Claverys, J.-P. (1993) Mol. Microbiol. 11, 323-330) has been cloned into an expression vector, and its gene product, the MutX protein, has been purified to apparent homogeneity. Like MutT, the pure MutX protein hydrolyzes all of the canonical nucleoside triphosphates at different rates with a preference for dGTP, yielding nucleoside monophosphates and inorganic pyrophosphate. Despite this similarity in enzymatic activity, the two proteins have notably dissimilar primary and quaternary structures. They share only a small region of amino acid homology, and under the same conditions in which MutT exists as a monomer in solution, MutX behaves as a trimer. The small region of conserved amino acid sequence most likely identifies a protein domain responsible for the novel nucleoside triphosphate pyrophosphohydrolase activity shared by the two enzymes, and by another protein of unknown function, the product of the E. coli orf17 gene (Takahagi, M., Iwasaki, H., Nakata, A., and Shinegawa, H. (1991) J. Bacteriol. 173, 5747-5753).

TMAO anaerobic respiration in Escherichia coli: involvement of the tor operon

The trimethylamine N-oxide (TMAO) respiratory system is subject to a strict positive control by the substrate. This property was exploited in the performance of miniMu replicon-mediated in vivo cloning of the promoter region of gene(s) positively regulated by TMAO. This region, located at 22 min on the chromosome, was shown to control the expression of a transcription unit composed of three open reading frames, designated torC, torA and torD, respectively. The presence of five putative c-type haem-binding sites within the TorC sequence, as well as the specific biochemical characterization, indicated that torC encodes a 43,300 Da c-type cytochrome. The second open reading frame, torA, was identified as the structural gene for TMAO reductase. A comparison of the predicted amino-terminal sequence of the torA gene product to that of the purified TMAO reductase indicated cleavage of a 39 amino acid signal peptide, which is in agreement with the periplasmic location of the enzyme. The predicted TorA protein contains the five molybdenum cofactor-binding motifs found in other molybdoproteins and displays extensive sequence homology with BisC and DmsA proteins. As expected, insertions in torA led to the loss of TMAO reductase. The 22,500 Da polypeptides encoded by the third open reading frame does not share any similarity with proteins listed in data banks.

Characterization of the mutX gene of Streptococcus pneumoniae as a homologue of Escherichia coli mutT, and tentative definition of a catalytic domain of the dGTP pyrophosphohydrolases

We show that deletion of a gene of Streptococcus pneumoniae, which we call mutX, confers a mutator phenotype to resistance to streptomycin. Analysis of the DNA sequence changes that occurred in several streptomycin-resistant mutants showed that mutations are unidirectional AT to CG transversions. The mutX gene is located immediately downstream of the previously identified ung gene and genetic evidence suggests that the two genes are co-ordinately regulated. Nucleotide sequence determination reveals that the mutX gene encodes a 17,870 Da protein (154 residues) which exhibits significant homology with the MutT protein of Escherichia coli, a nucleoside triphosphatase (dGTP pyrophosphohydrolase). The mutX gene complements the E. coli mutT mutator phenotype when introduced on a plasmid. Site-directed mutagenesis and analysis of nitrosoguanidine-induced mutT mutants suggest that a small region of high homology between the two proteins (61% identity over 23 residues) is part of the catalytic site of the nucleoside triphosphatase. Computer searching for sequence homology to MutX uncovered a second E. coli protein, the product of orf17, a gene of unknown function located near the ruvC gene. The region of high homology between MutX and MutT is also conserved in this protein, which raises the interesting possibility that the orf17 gene plays some role in determining mutation rates in E. coli. Finally, a small set of proteins, including a family of virus-encoded proteins and two evolutionarily conserved proteins encoded by an antisense transcript from the Xenopus laevis and human bFGF genes, were also found to harbour significant homology to this highly conserved region.

DNA processing during entry in transformation of Streptococcus pneumoniae

The current model for processing DNA during entry in the transformation of Streptococcus pneumoniae is that following double-strand cleavage of DNA bound at the cell surface, uptake of one strand proceeds linearly from a newly formed 3'-end with simultaneous degradation of the opposite strand. Two important predictions of this model have been tested in the work reported here: first that the polarity of DNA degradation is the opposite of that for entry, and second that the rate of DNA degradation is (at least) equal to the rate of entry. The processing of DNA during entry was investigated using donor molecules constructed in vitro and labeled in one strand only. With uniformly labeled donor molecules, an amount of label equivalent to that taken up by the cells was recovered in acid-soluble form in the transformation medium. Experiments with 3'- or 5'-end-labeled molecules revealed that whereas essentially all of the 3'-end label was susceptible to degradation, most 5'-end label was resistant. Kinetic analysis of both entry and degradation revealed very similar rates for these processes, about 100 nucleotides s-1 at 31 degrees C, suggesting that they occur concomitantly. Entry and degradation appear to proceed with opposite polarity, 3'-->5' for entry and 5'-->3' for degradation. A prediction of the entry model, that a single-strand interruption would inhibit the uptake of DNA sequences located 5' to the nick, was confirmed experimentally. Therefore, we suggest that an intact sugar phosphate backbone is required by the entry machinery for continuous uptake.

Mismatch repair genes of Streptococcus pneumoniae: HexA confers a mutator phenotype in Escherichia coli by negative complementation

DNA repair systems able to correct base pair mismatches within newly replicated DNA or within heteroduplex molecules produced during recombination are widespread among living organisms. Evidence that such generalized mismatch repair systems evolved from a common ancestor is particularly strong for two of them, the Hex system of the gram-positive Streptococcus pneumoniae and the Mut system of the gram-negative Escherichia coli and Salmonella typhimurium. The homology existing between HexA and MutS and between HexB and MutL prompted us to investigate the effect of expressing hex genes in E. coli. Complementation of mutS or mutL mutations, which confer a mutator phenotype, was assayed by introducing on a multicopy plasmid the hexA and hexB genes, under the control of an inducible promoter, either individually or together in E. coli strains. No decrease in mutation rate was conferred by either hexA or hexB gene expression. However, a negative complementation effect was observed in wild-type E. coli cells: expression of hexA resulted in a typical Mut- mutator phenotype. hexB gene expression did not increase the mutation rate either individually or in conjunction with hexA. Since expression of hexA did not affect the mutation rate in mutS mutant cells and the hexA-induced mutator effect was recA independent, it is concluded that this effect results from inhibition of the Mut system. We suggest that HexA, like its homolog MutS, binds to mismatches resulting from replication errors, but in doing so it protects them from repair by the Mut system. In agreement with this hypothesis, an increase in mutS gene copy number abolished the hexA-induced mutator phenotype. HexA protein could prevent repair either by being unable to interact with Mut proteins or by producing nonfunctional repair complexes.

Uracil-DNA glycosylase affects mismatch repair efficiency in transformation and bisulfite-induced mutagenesis in Streptococcus pneumoniae

The generalized mismatch repair system of Streptococcus pneumoniae (the Hex system) can eliminate base pair mismatches arising in heteroduplex DNA during transformation or by DNA polymerase errors during replication. Mismatch repair is most likely initiated at nicks or gaps. The present work was started to examine the hypothesis that strand discontinuities arising after removal of uracil by uracil DNA-glycosylase (Ung) can be utilised as strand discrimination signals. We show that mismatch repair efficiency is enhanced 3- to 6-fold when using uracil-containing DNA as donor in transformation. In order to assess the contribution of Ung to nascent strand discrimination for postreplication mismatch repair, we developed a positive selection procedure to isolate S. pneumoniae Ung- mutants. We succeeded in isolating Ung- mutants using this procedure based on chromosomal integration of uracil-containing hybrid DNA molecules. Cloning and characterization of the ung gene was achieved. Comparison of spontaneous mutation rates in strains either proficient or deficient in mismatch and/or uracil repair gave no support to the hypothesis that Ung plays a major role in targeting the Hex system to neosynthesized DNA strands. However Ung activity is responsible for the increased efficiency of mismatch repair observed in transformation with uracil-containing DNA. In addition Ung is involved in repair of bisulfite-treated transforming DNA.

Direction of DNA entry in competent cells of Bacillus subtilis

Direction of DNA entry in Bacillus subtilis competent cells was studied using molecules in which only one of the two strands was radioactively labelled. The label was either distributed homogeneously or was localized in a small region of the strand, in the centre or at one of the ends. Regardless of the distribution and the position of the label, similar amounts of radioactivity were taken up by the cells exposed to the labelled molecules. This suggests that DNA enters B. subtilis either by two different uptake systems having opposite polarities, or by a single non-polar system.

An improved method for the purification of high molecular weight bacterial chromosomal DNA

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Strand targeting signal(s) for in vivo mutation avoidance by post-replication mismatch repair in Escherichia coli

The involvement of GATC sites in directing mismatch correction for the elimination of replication errors in Escherichia coli was investigated in vivo by analyzing mutation rates for a gene carried on a series of related plasmids that contain 2, 1 and 0 such sites. This gene encoding chloramphenicol acetyl transferase (Cat protein) was inactivated by a point mutation. In vivo mutations restoring resistance to chloramphenicol were scored in mismatch repair proficient (mut+) and deficient (mutHLS-) strains. In mut+ cells, reduction of GATC sites from 2 to 0 increased mutation rates approximately 10-fold. Removal of the GATC site distal to the cat- mutation increased the rate of mutation less than 2-fold, indicating that mismatch repair can proceed normally with a single site. The mutation rate increased 3-fold after removal of the GATC site proximal to the mutation. In the absence of a GATC site, mutL- and mutS- strains exhibited a 2- to 3-fold increased mutation rate as compared to isogenic mutH- and mut+ strains. This indicates that 50%-70% of replication errors can be corrected in a mutLS-dependent way in the absence of any GATC site to target mismatch correction to newly synthesized DNA strands. Other strand targeting signals, possibly single strand discontinuities, might be used in mutLS-dependent repair.

Polarity of DNA entry in transformation of Streptococcus pneumoniae

DNA transport in Streptococcus pneumoniae was studied using donor molecules labelled either at the 3' or at the 5' end, on one strand only. In contrast to 5' end label, 3' end label was not taken up by the cells indicating that entry is a polarized process. Our results together with those of previous studies are consistent with a model for entry in which double-stranded donor DNA is nicked on binding at the cell surface. Entry of a single strand then proceeds linearly from a newly formed 3' end to the extremity of the donor fragment.

Constitutive expression of erythromycin resistance mediated by the ermAM determinant of plasmid pAM beta 1 results from deletion of 5' leader peptide sequences

We have sequenced the erythromycin resistance determinant (erm) of the Streptococcus faecalis plasmid pAM beta 1 to investigate its relationship to other known resistance determinants. We show that this determinant is strongly (99%) homologous at the DNA level to that of plasmid pAM77 (Streptococcus sanguis) and of transposon Tn917 (S. faecalis). Moreover, nucleotide sequence comparison with the determinants of pAM77 and Tn917 shows that most of the probable regulatory region is absent, providing an explanation for the constitutive expression of the pAM beta 1 erm determinant.

Long- and short-patch gene conversions in Streptococcus pneumoniae transformation

In pneumococcal transformation some point mutations are integrated by an excision-repair pathway which switches the heteroduplex DNA into homoduplex. This transfer of information is a gene conversion. We have reviewed some of the properties of this system especially those relating to heteroduplex specificity and given evidence that this extends over several kilobases of DNA. We then describe a new process of conversion in pneumococcal transformation which occurs over a very short distance (5 to 27 base-pairs) and is triggered by a single site mutation resulting from the transversion 5'-ATTCAT...to 5'...ATTAAT... Only one of the two heteroduplexes 5'...A...3'/3'...G...5', is converted.

Effect of mismatched base pairs on the fate of donor DNA in transformation of Streptococcus pneumoniae

Investigation of the mechanism that discriminates against mismatched base pairs in transformation of Streptococcus pneumoniae of genotype hex+ was based on the use of a radioactively labeled cloned fragment of pneumococcal DNA as donor in transformation. The fate of the donor label was followed by lysis of the transformed cells and separation by agarose gel electrophoresis of DNA fragments generated by restriction endonucleases. As a result of Hex action, most of the donor DNA fragment, which was a few kilobases in length, was lost when a mismatched base pair occurred between donor and recipient DNA. This was not observed in hex- recipient cells. Kinetic studies of mismatch-induced donor DNA loss showed that the process is faster in strain 800, an R6 derivative, than in DP1601, a strain of different origin. In the latter strain, the amount of donor label that becomes double stranded rises substantially, indicating extensive formation of donor-recipient heteroduplex structures, before falling to the expected level. At 30 degrees C the process is essentially completed 15 min after entry.

Use of a cloned DNA fragment to analyze the fate of donor DNA in transformation of Streptococcus pneumoniae

The integration of donor label into the recipient fragment is followed during transformation of Streptococcus pneumoniae. The method used involves gel analysis of restriction endonuclease-treated recipient DNA after recombination with a radioactively labeled homologous cloned fragment.

Mismatch repair in Streptococcus pneumoniae: relationship between base mismatches and transformation efficiencies

Genetic transformation in Streptococcus pneumoniae involves the insertion of single-stranded pieces of donor DNA into a recipient genome. Efficiencies of transformation strongly depend on the mutations (markers) carried by donor DNA. Markers are classified according to their transforming efficiencies into very high, high, intermediate, and low efficiency. The last is approximately 1/20th as efficient as the first. This marker effect is under the control of the Hex system, which is thought to correct mismatches at the donor-recipient heteroduplex stage in transformation. To investigate this effect, wild type, mutant, and revertant DNA sequences at five genetic sites within the amiA locus were determined. The results show that low-efficiency markers arise from transitional changes A . T to G . C. The transversion A . T to T . A corresponds to an intermediate-efficiency marker. Transversions G . C to T . A and G . C to C . G lead to high-efficiency markers. Among the eight possible mismatches that could exist transiently at the heteroduplex stage in transformation, only two--namely, A/G and C/C--are not corrected by the Hex system. It is noteworthy that the four possible base pairs (A . T, T . A, G . C, and C . G) have been encountered at the very same site (amiA6 site), which constitutes a good illustration of the marker effect. DNA sequence analysis also reveals that short deletions (33 or 34 bases long) are integrated with very high efficiencies. These results confirm that the Hex system corrects point mismatches harbored in donor-recipient heteroduplexes thousands of bases long. The correction pattern of the Hex system toward multiple-base mismatches has also been investigated. Its behavior toward double-base mismatches is complex, suggesting that neighboring sequences may affect the detection of mispaired bases.

Rapid cloning of specific DNA fragments of Streptococcus pneumoniae by vector integration into the chromosome followed by endonucleolytic excision

A method for the rapid cloning of specific Streptococcus pneumoniae DNA fragments depends on the integration by homologous recombination into the bacterial chromosome of a plasmid which carries an insert of S. pneumoniae DNA, but which cannot be autonomously maintained in S. pneumoniae. Selection for plasmid integration employs aminopterin or erythromycin resistance. Host sequences adjacent to the site of insertion are easily cloned by enzymatic excision and recircularization of the plasmid, followed by propagation in Escherichia coli. This is particularly useful for repeated cloning of a given fragment that carries various mutations.

Base specificity of mismatch repair in Streptococcus pneumoniae

DNA sequence analysis was undertaken to investigate the structural basis of mutations showing different integration efficiencies in Streptococcus pneumoniae. Wild type, mutant and revertant sequences at two sites in the amiA locus were determined. It appears that markers which transform efficiently or inefficiently can result from single base pair changes. A low efficiency (LE) marker corresponds to a C:G to T:A change and a high efficiency (HE) marker to a G:C to T:A change. In the latter case, two mismatches, G/A and T/C, can exist at the heteroduplex stage in transformation; only T/C appears to be recognized by the hex system which controls transforming efficiencies in pneumococcus. Each of the recognized mismatches, T/G and C/A, which result from transitional change, and T/C appears to involve at least one pyrimidine. It is proposed that the mismatch repair system of S. pneumoniae is directed against mismatched pyrimidines. DNA sequence analysis also reveals that short deletions (33 or 34 bases long) behave as very high efficiency markers, confirming that deletions are not recognized by the hex system.