The arcB gene of Escherichia coli encodes a sensor-regulator protein for anaerobic repression of the arc modulon

The arcA (dye) and arcB genes of Escherichia coli are responsible for anaerobic repression of target operons and regulons of aerobic function (the arc modulon). The amino acid sequence of ArcA (Dye) indicated that it is the regulator protein of a two-component control system. Here we show that ArcB is a membrane sensor protein on the basis of its deduced amino acid sequence (778 residues), hydropathicity profile, and cellular distribution. On the carboxyl end of the ArcB sequence there is an additional domain showing homology with conserved regions of regulator proteins. Deletion into this domain destroyed ArcB function. ArcB conserved a histidine residue for autophosphorylation of the sensor proteins, and aspartic residues important for the regulator proteins.     

Anaerobic regulation by an atypical Arc system in Shewanella oneidensis

Shewanella oneidensis strain MR-1 is well known for its respiratory versatility, yet little is understood about how it regulates genes involved in anaerobic respiration. The Arc two-component system plays an important role in this process in Escherichia coli; therefore, we determined its function in S. oneidensis. arcA from S. oneidensis complements an E. coli arcA mutant, but the Arc regulon in S. oneidensis constitutes a different suite of genes. For example, one of the strongest ArcA-regulated gene clusters in E. coli, sdh, is not regulated by the Arc system in S. oneidensis, and the cyd locus, which is induced by ArcA in E. coli under microaerobic conditions, is repressed by ArcA in S. oneidensis under anaerobic conditions. One locus that we identified as being potentially regulated by ArcA in S. oneidensis contains genes predicted to encode subunits of a dimethyl sulphoxide (DMSO) reductase. We demonstrate that these genes encode a functional DMSO reductase, and that an arcA mutant cannot fully induce their expression and is defective in growing on DMSO under anaerobic conditions. While S. oneidensis lacks a highly conserved full-length ArcB homologue, ArcA is partially activated by a small protein homologous to the histidine phosphotransfer domain of ArcB from E. coli, HptA. This protein alone is unable to compensate for the lack of arcB in E. coli, indicating that another protein is required in addition to HptA to activate ArcA in S. oneidensis.     

Mutational analysis of signal transduction by ArcB, a membrane sensor protein responsible for anaerobic repression of operons involved in the central aerobic pathways in Escherichia coli.

In Escherichia coli, the expression of a group of operons involved in aerobic metabolism is regulated by a two-component signal transduction system in which the arcB gene specifies the membrane sensor protein and the arcA gene specifies the cytoplasmic regulator protein. ArcB is a large protein belonging to a subclass of sensors that have both a transmitter domain (on the N-terminal side) and a receiver domain (on the C-terminal side). In this study, we explored the essential structural features of ArcB by using mutant analysis. The conserved His-292 in the transmitter domain is indispensable, indicating that this residue is the autophosphorylation site, as shown for other homologous sensor proteins. Compression of the range of respiratory control resulting from deletion of the receiver domain and the importance of the conserved Asp-533 and Asp-576 therein suggest that the domain has a kinetic regulatory role in ArcB. There is no evidence that the receiver domain enhances the specificity of signal transduction by ArcB. The defective phenotype of all arcB mutants was corrected by the presence of the wild-type gene. We also showed that the expression of the gene itself is not under respiratory regulation.     

Phosphorelay as the sole physiological route of signal transmission by the arc two-component system of Escherichia coli

The Arc two-component system, comprising a tripartite sensor kinase (ArcB) and a response regulator (ArcA), modulates the expression of numerous genes involved in respiratory functions. In this study, the steps of phosphoryl group transfer from phosphorylated ArcB to ArcA were examined in vivo by using single copies of wild-type and mutant arcB alleles. The results indicate that the signal transmission occurs solely by His-Asp-His-Asp phosphorelay.     

Differentiation of arcA, arcB, and cpxA mutant phenotypes of Escherichia coli by sex pilus formation and enzyme regulation.

In Escherichia coli, mutations in arcA (dye) or arcB anaerobically derepress the synthesis of a multitude of enzymes of aerobic function, and mutations in arcA or cpxA impair F-pilus formation. It is thought that arcA encodes a promoter-recognizing protein, whereas arcB and cpxA encode sensor proteins which interact with the arcA product. In this study we found that anaerobic growth of a wild-type F' strain decreased the synthesis of both the enzymes and the pilus. Although the two arcA mutants examined were both anaerobically derepressed in the enzymes and impaired in aerobic pilus formation as expected, one mutant hyperproduced the pilus anaerobically. The two arcB mutants examined showed normal pilus formation when grown aerobically. When grown anaerobically they developed more pili than the wild-type strain did when grown aerobically. When a cpxA mutant was examined for synthesis of two aerobic enzymes, normal regulation was found. The available data suggest the following. The arcA product anaerobically represses certain genes of aerobic function and activates certain genes related to F function. It appears that the arcB product senses the redox or energy state; absence of the gene function shifts the arcA product to the nonrepressive form for enzyme synthesis for aerobic pathways. The cpxA product, on the other hand, senses the sexual state; absence of the gene function shifts the arcA product to the inactive form for F-pilus synthesis.     

Effect of ArcA and FNR on the expression of genes related to the oxygen regulation and the glycolysis pathway in Escherichia coli under microaerobic growth conditions

Escherichia coli has several elaborate sensing mechanisms for response to the availability of oxygen and the presence of other electron acceptors. The adaptive responses are coordinated by a group of global regulators, which include the one-component Fnr protein, and the two-component Arc system. To quantitate the contribution of Arc and FNR dependent regulation under microaerobic conditions, the gene expression pattern of the fnr the arcA and arcB regulator genes, and the glycolysis related genes in a wild-type E. coli, an arcA mutant, an fnr mutant, and a double arcA, fnr mutant, in glucose limited cultures and different oxygen concentrations was studied in chemostat cultures at steady state using QRT-PCR. It was found that ArcA has a negative effect on fnr expression under microaerobic conditions. Moreover, the expression levels of the FNR regulated genes, yfiD and frdA, were higher in cultures of the arcA mutant strain compared to the wild-type. These imply that a higher level of the FNR regulator is in the activated form in cultures of the arcA mutant strain compared to the wild-type during the transition from aerobic to microanaerobic growth. The results also show that the highest expression level of aceE, pflB, and adhE were obtained in cultures of the arcA mutant strain under microaerobic growth while higher levels of ldhA expression were obtained in cultures of the arcA mutant strain and the arcA, fnr double mutant strain compared to the wild-type and the fnr mutant strain. While the highest expression of adhE and pflB in cultures of the arcA mutant strain can explain the previous report of high ethanol flux and flux through pyruvate formate lyase (PFL) in cultures of this strain, the higher level of ldhA expression was not sufficient to explain the trend in lactate fluxes. The results indicate that lower conversion of pyruvate to acetyl-CoA is the main reason for high fluxes through lactate dehydrogenase (LDH) in cultures of the arcA, fnr double mutant strain.     

Requirement for terminal cytochromes in generation of the aerobic signal for the arc regulatory system in Escherichia coli: study utilizing deletions and lac fusions of cyo and cyd.

Escherichia coli has two terminal oxidases for its respiratory chain: cytochrome o (low O2 affinity) and cytochrome d (high O2 affinity). Expression of the cyo operon, encoding cytochrome o, is decreased by anaerobic growth, whereas expression of the cyd operon, encoding cytochrome d, is increased by anaerobic growth. We show by the use of lac gene fusion that the expressions of cyo and cyd are under the control of the two-component arc system. In a cyo+ cyd+ background, expression of phi(cyo-lac) is higher when the organism is grown aerobically than when it is grown anaerobically. A mutation in either the sensor gene arcB or the pleiotropic regulator gene arcA almost abolishes the anaerobic repression. In the same background, expression of phi(cyd-lac) is higher under anaerobic growth conditions than under aerobic growth conditions. A mutation in arcA or arcB lowers both the aerobic and anaerobic expressions, suggesting that ArcA plays an activating role instead of the typical repressing role. Under aerobic growth conditions, double deletions of cyo and cyd lower phi(cyo-lac) expression but enhance phi(cyd-lac) expression. The double deletions also prevent elevated aerobic induction of the lct operon (encoding L-lactate dehydrogenase), another target operon of the arc system. In contrast, these deletions do not circumvent aerobic repression of the nar operon (encoding the anaerobic respiratory enzyme nitrate reductase) under the control of the pleiotropic fnr gene product. It thus appears that ArcB senses the presence of O2 by level of an electron transport component in reduced form or that of an nonautoxidizable compound linked to the process by a redox reaction, whereas Fnr senses O2 by a different mechanism.     

arc-dependent thermal regulation and extragenic suppression of the Escherichia coli cytochrome d operon.

In a screen for Escherichia coli genes whose products are required for high-temperature growth, we identified and characterized a mini-Tn10 insertion that allows the formation of wild-type-size colonies at 30 degrees C but results in microcolony formation at 36 degrees C and above (Ts- phenotype). Mapping, molecular cloning, and DNA sequencing analyses showed that the mini-Tn10 insertion resides in the cydB gene, the distal gene of the cydAB operon (cytochrome d). The Ts- growth phenotype was also shown to be associated with previously described cyd alleles. In addition, all cyd mutants were found to be extremely sensitive to hydrogen peroxide. Northern (RNA) blot analysis showed that cyd-specific mRNA levels accumulate following a shift to high temperature. Interestingly, this heat shock induction of the cyd operon was not affected in an rpoH delta background but was totally absent in an arcA or arcB mutant background. Extragenic suppressors of the Cyd Ts- phenotype are found at approximately 10(-3). Two extragenic suppressors were shown to be null alleles in either arcA or arcB. One interpretation of our results is that in the absence of ArcA or ArcB, which are required for the repression of the cyo operon (cytochrome o), elevated levels of Cyo are produced, thus compensating for the missing cytochrome d function. Consistent with this interpretation, the presence of the cyo gene on a multicopy plasmid suppressed the Ts- and hydrogen peroxide-sensitive phenotypes of cyd mutants.     

A second global regulator gene (arcB) mediating repression of enzymes in aerobic pathways of Escherichia coli.

In Escherichia coli anaerobic growth lowers the basal or induced levels of numerous enzymes associated with aerobic metabolism. Mutations in arcA (dye) at min 0 relieve this pleiotropic anaerobic repression and render the cell sensitive to the redox dye toluidine blue. In this study we identified a second pleiotropic control gene, arcB, at min 69.5. Mutations, including a deletion, in this gene also relieved the anaerobic repression and caused sensitivity to toluidine blue. Mutations in arcA or arcB did not significantly change the catabolite repression of the target phi(sdh-lacZ) operon, in which lacZ is fused to a structural gene for succinate dehydrogenase, nor did the mutations strikingly influence the pattern of excretion products during glucose fermentation. The presence of arcA+ in a multicopy plasmid restored anaerobic repression in arcB mutants, as indicated by the expression of phi(sdh-lacZ). The arcB product might be a sensor protein for the redox or energy state of the arc regulatory system.     

Effect of oxygen, and ArcA and FNR regulators on the expression of genes related to the electron transfer chain and the TCA cycle in Escherichia coli

Microbial cells possess numerous sensing/regulator systems in order to respond rapidly to environmental changes. Escherichia coli has several elaborate sensing mechanisms for response to the availability of oxygen and the presence of other electron acceptors. A group of global regulators, which include the one component Fnr protein and the two-component Arc system, coordinate the adaptive responses. To quantitate the contribution of Arc and FNR-dependent regulation under microaerobic conditions, the gene expression pattern of the electron transfer chain genes and the TCA cycle genes in wild-type E. coli, an arcA mutant, an fnr mutant, and a double arcA, fnr mutant, in glucose limited cultures and different oxygen concentrations was studied in chemostat cultures at steady state using QRT-PCR. It was found that the TCA cycle genes, icd, gltA, sucC, and sdhC are repressed by ArcA while Fnr has a minor or no effect on the expression of these genes under microaerobic conditions. The expression levels of the electron transfer chain genes, nuoA, ndh, and ubiE, were not significantly affected by either ArcA or Fnr regulation proteins, while a lower expression of cydA (up to 9-fold lower) and a higher expression of cyoA (up to 31-fold higher) were observed in cultures of the arcA mutant strain compared to those of the wild type. Since significantly higher NADH/NAD+ ratios were previously observed in cultures of the arcA mutant strain compared to the wild type it seems that the cytochrome o oxidase (the product of cyoABCDE) cannot efficiently support aerobic respiration when the cells are grown under microaerobic conditions.     

Mapping of the arginine deiminase gene in Pseudomonas aeruginosa

A mutant of Pseudomonas aeruginosa PAO lacking arginine deiminase activity (arcA) was isolated by screening for a derivative of an arcB mutant (deficient in catabolic ornithine carbamoyltransferase) that did not excrete citrulline under conditions of limited aeration. The arcA mutation was highly cotransducible with arcB.