Purification and characterization of an arginine regulatory protein, ArgR, from Pseudomonas aeruginosa and its interactions with the control regions for the car, argF, and aru operons.

Pseudomonas aeruginosa ArgR, a regulatory protein that plays a major role in the control of certain biosynthetic and catabolic arginine genes, was purified to homogeneity. ArgR was shown to be a dimer of two equal subunits, each with a molecular mass of 37,000 Da. Determination of the amino-terminal amino acid sequence showed it to be identical to that predicted from the derived sequence for the argR gene. DNase I footprinting showed that ArgR protects a region of 45 to 47 bp that overlaps the promoters for the biosynthetic car and argF operons, indicating that ArgR exerts its negative control on the expression of these operons by steric hindrance. Studies were also carried out with the aru operon, which encodes enzymes of the catabolic arginine succinyl-transferase pathway. Quantitative S1 nuclease experiments showed that expression of the first gene in this operon, aruC, is initiated from an arginine-inducible promoter. Studies with an aruC::lacZ fusion showed that this promoter is under the control of ArgR. DNase I experiments indicated that ArgR protects two 45-bp binding sites upstream of aruC; the 3' terminus for the downstream binding site overlaps the -35 region for the identified promoter. Gel retardation experiments yielded apparent dissociation constants of 2.5 x 10(-11), 4.2 x 10(-12), and 7.2 x 10(-11) M for carA, argF, and aruC operators, respectively. Premethylation interference and depurination experiments with the car and argF operators identified a common sequence, 5'-TGTCGC-3', which may be important for ArgR binding. Alignment of ArgR binding sites reveals that the ArgR binding site consists of two half-sites, in a direct repeat arrangement, with the consensus sequence TGTCGCN8AAN5.     

The arginine regulatory protein mediates repression by arginine of the operons encoding glutamate synthase and anabolic glutamate dehydrogenase in Pseudomonas aeruginosa

The arginine regulatory protein of Pseudomonas aeruginosa, ArgR, is essential for induction of operons that encode enzymes of the arginine succinyltransferase (AST) pathway, which is the primary route for arginine utilization by this organism under aerobic conditions. ArgR also induces the operon that encodes a catabolic NAD(+)-dependent glutamate dehydrogenase (GDH), which converts l-glutamate, the product of the AST pathway, in alpha-ketoglutarate. The studies reported here show that ArgR also participates in the regulation of other enzymes of glutamate metabolism. Exogenous arginine repressed the specific activities of glutamate synthase (GltBD) and anabolic NADP-dependent GDH (GdhA) in cell extracts of strain PAO1, and this repression was abolished in an argR mutant. The promoter regions of the gltBD operon, which encodes GltBD, and the gdhA gene, which encodes GdhA, were identified by primer extension experiments. Measurements of beta-galactosidase expression from gltB::lacZ and gdhA::lacZ translational fusions confirmed the role of ArgR in mediating arginine repression. Gel retardation assays demonstrated the binding of homogeneous ArgR to DNA fragments carrying the regulatory regions for the gltBD and gdhA genes. DNase I footprinting experiments showed that ArgR protects DNA sequences in the control regions for these genes that are homologous to the consensus sequence of the ArgR binding site. In silica analysis of genomic information for P. fluorescens, P. putida, and P. stutzeri suggests that the findings reported here regarding ArgR regulation of operons that encode enzymes of glutamate biosynthesis in P. aeruginosa likely apply to other pseudomonads.     

Cloning and characterization of argR, a gene that participates in regulation of arginine biosynthesis and catabolism in Pseudomonas aeruginosa PAO1.

Gel retardation experiments indicated the presence in Pseudomonas aeruginosa cell extracts of an arginine-inducible DNA-binding protein that interacts with the control regions for the car and argF operons, encoding carbamoylphosphate synthetase and anabolic ornithine carbamoyltransferase, respectively. Both enzymes are required for arginine biosynthesis. The use of a combination of transposon mutagenesis and arginine hydroxamate selection led to the isolation of a regulatory mutant that was impaired in the formation of the DNA-binding protein and in which the expression of an argF::lacZ fusion was not controlled by arginine. Experiments with various subclones led to the conclusion that the insertion affected the expression of an arginine regulatory gene, argR, that encodes a polypeptide with significant homology to the AraC/XylS family of regulatory proteins. Determination of the nucleotide sequence of the flanking regions showed that argR is the sixth and terminal gene of an operon for transport of arginine. The argR gene was inactivated by gene replacement, using a gentamicin cassette. Inactivation of argR abolished arginine control of the biosynthetic enzymes encoded by the car and argF operons. Furthermore, argR inactivation abolished the induction of several enzymes of the arginine succinyltransferase pathway, which is considered the major route for arginine catabolism under aerobic conditions. Consistent with this finding and unlike the parent strain, the argR::Gm derivative was unable to utilize arginine or ornithine as the sole carbon source. The combined data indicate a major role for ArgR in the control of arginine biosynthesis and aerobic catabolism.     

The Multifaceted Proteins MvaT and MvaU,Members of the H-NS Family,Control Arginine Metabolism,Pyocyanin Synthesis,and Prophage Activation in Pseudomonas aeruginosa PAO1

The MvaT and MvaU proteins belonging to the H-NS family were identified as DNA-binding proteins that interact with the regulatory region of the aotJQMOP-argR operon for arginine uptake and regulation. Recombinant MvaT and MvaU proteins were purified, and binding of these purified proteins to the aotJ regulatory region was demonstrated using electromobility shift assays. Polyclonal antibodies against purified MvaT and MvaU were prepared and employed in supershift assays to support these observations. Knockout mutations resulting in a single lesion in mvaT or mvaU, as well as knockout mutations resulting in double lesions, were constructed using biparental conjugation, and the absence of MvaT and MvaU in the resulting mutants was confirmed by immunoblot analysis. Using measurements of the β-galactosidase activities from aotJ::lacZ fusions in the mutants and the parental strain, it was found that MvaT and MvaU serve as repressors in control of aotJ expression. The effects of MvaT and MvaU on pyocyanin synthesis and CupA fimbrial expression in these mutants were also analyzed. Pyocyanin synthesis was induced in the single mutants but was completely abolished in the double mutant, suggesting that there is a complicated regulatory scheme in which MvaT and MvaU are essential elements. In comparison, MvaT had a more profound role than MvaU as a repressor of cupA expression; however, a combination of MvaT depletion and MvaU depletion had a strong synergistic effect on cupA. Moreover, prophage Pf4 integrated into the chromosome of Pseudomonas aeruginosa PAO1 was activated in an mvaT mvaU double mutant but not in a single mutant. These results were supported by purification and nucleotide sequencing of replicative-form DNA and by the release of phage particles in plaque assays. In summary, the mvaT mvaU double mutant was viable, and depletion of MvaT and MvaU had serious effects on a variety of physiological functions in P. aeruginosa.The MvaT and MvaU proteins of Pseudomonas aeruginosa belong to the H-NS family of small DNA-binding proteins. MvaT was initially identified in P. mevalonii as a positive regulator for mevalonate catabolism (25). Subsequently, MvaT homologues have been identified in other pseudomonads based on structural and functional similarities; five homologues have been identified in P. putida, three homologues have been identified in P. fluorescens, four homologues have been identified in P. syringae, and two homologues have been identified in P. aeruginosa. In P. putida, the TurA protein represses the Pu promoter of the TOL plasmid in a temperature-dependent manner (24). In P. fluorescens, the MvaT and MvaV proteins regulate the expression of two biocontrol exoproducts, 2,4-diacetyl phloroglucinol and pyoluteorin (1). In P. aeruginosa, MvaT is involved in quorum-sensing responses and biofilm formation. Inactivation of mvaT resulted in increased production of PA-IL lectin and the toxic exoproduct pyocyanin, reduced biofilm formation, increased drug resistance, and reduced swarming motility (5, 33). In addition, the MvaT protein is involved in the phase-variable expression of the fimbrial cup genes involved in biofilm formation. Moreover, DNA microarray analysis has shown that more than 150 genes are influenced by the MvaT protein (27).The MvaU protein shows high levels of similarity to MvaT and can perform some of the MvaT regulatory functions (28). Like other H-NS-related proteins, MvaT and MvaU possess two distinct domains: the N terminus for oligomerization and the C terminus for DNA-binding activity. The MvaT and MvaU proteins can interact through their N-terminal regions and form hetero- and homodimers (28). In general, mvaT mutation seems to have a much more profound effect than mvaU mutation. In a study using chromatin immunoprecipitation coupled with DNA microarrays, the potential MvaT and MvaU binding sites on the genome of P. aeruginosa were identified (3). In the same report, it was concluded that loss of both MvaT and MvaU from the cell cannot be tolerated.In this study, we identified MvaT and MvaU as components of a nucleoprotein complex that controls the aotJQMOP-argR operon for arginine uptake and regulation (21, 22). Using mvaT and mvaU single- and double-mutant constructs, we also demonstrated the consequences of MvaT and MvaU depletion for prophage activation, pyocyanin synthesis, and fimbrial cupA gene expression.     

Discovery of an operon that participates in agmatine metabolism and regulates biofilm formation in Pseudomonas aeruginosa

Agmatine is the decarboxylation product of arginine and a number of bacteria have devoted enzymatic pathways for its metabolism. Pseudomonas aeruginosa harbours the aguBA operon that metabolizes agmatine to putrescine, which can be subsequently converted into other polyamines or shunted into the TCA cycle for energy production. We discovered an alternate agmatine operon in the P. aeruginosa strain PA14 named agu2ABCA′ that contains two genes for agmatine deiminases (agu2A and agu2A′). This operon was found to be present in 25% of clinical P. aeruginosa isolates. Agu2A′ contains a twin‐arginine translocation signal at its N‐terminus and site‐directed mutagenesis and cell fractionation experiments confirmed this protein is secreted to the periplasm. Analysis of the agu2ABCA′ promoter demonstrates that agmatine induces expression of the operon during the stationary phase of growth and during biofilm growth and agu2ABCA′ provides only weak complementation of aguBA, which is induced during log phase. Biofilm assays of mutants of all three agmatine deiminase genes in PA14 revealed that deletion of agu2ABCA′, specifically its secreted product Agu2A′, reduces biofilm production of PA14 following addition of exogenous agmatine. Together, these findings reveal a novel role for the agu2ABCA′ operon in the biofilm development of P. aeruginosa.     

Regulation of arginine biosynthesis in the psychropiezophilic bacterium Moritella profunda: in vivo repressibility and in vitro repressor-operator contact probing

We report the cloning of the arginine repressor gene from the psychropiezophilic Gram-negative bacterium Moritella profunda, the purification of its product (ArgR(Mp)), the identification of the operator in the bipolar argECBFGH(A) operon, in vivo repressibility studies, and an in vitro analysis of the repressor-operator interaction, including binding to mutant and heterologous arginine operators. The ArgR(Mp) subunit shows about 70% amino acid sequence identity with Escherichia coli ArgR (ArgR(Ec)). Binding of purified hexameric ArgR(Mp) to the control region of the divergent operon proved to be arginine-dependent, sequence-specific, and significantly more sensitive to heat than complex formation with ArgR(Ec). ArgR(Mp) binds E.coli arginine operators very efficiently, but hardly recognizes the operator from Bacillus stearothermophilus or Thermotoga maritima. ArgR(Mp) binds to a single site overlapping the -35 element of argC(P), but not argE(P). Therefore, the arrangement of promoter and operator sites in the bipolar argECBFGH(A) operon of M.profunda is very different from the organization of control elements in the bipolar argECBH operon of E.coli, where both promoters overlap the common operator and are equally repressible. We demonstrate that M.profunda argC(P) is about 44-fold repressible, whereas argE(P) is fully constitutive. A high-resolution contact map of the ArgR(Mp)-operator interaction was established by enzymatic and chemical footprinting, missing contact and base-specific premodification binding interference studies. The results indicate that the argC operator consists of two ARG box-like sequences (18bp imperfect palindromes) separated by 3bp. ArgR(Mp) binds to one face of the DNA helix and establishes contacts with two major groove segments and the intervening minor groove of each ARG box, whereas the minor groove segment facing the repressor at the center of the operator remains largely uncontacted. This pattern is reminiscent of complex formation with the repressors of E.coli and B.stearothermophilus, and suggests that each ARG box is contacted by two ArgR subunits belonging to opposite trimers. Moreover, the premodification interference patterns and mutant studies clearly indicate that the inner, center proximal halves of each ARG box in the M.profunda argC operator are more important for complex formation and repression than the outermost halves. A close inspection of sequence conservation and of single base-pair O(c)-type mutations indicate that the same conclusion can be generalized to E.coli operators.     

N2-Succinylornithine in ornithine catabolism of Pseudomonas aeruginosa

Most Pseudomonas aeruginosa PAO mutants which were unable to utilize l-arginine as the sole carbon and nitrogen source (aru mutants) under aerobic conditions were also affected in l-ornithine utilization. These aru mutants were impaired in one or several enzymes involved in the conversion of N²-succinylornithine to glutamate and succinate, indicating that the latter steps of the arginine succinyltransferase pathway can be used for ornithine catabolism. Addition of aminooxyacetate, an inhibitor of the N²-succinylornithine 5-aminotransferase, to resting cells of P. aeruginosa in ornithine medium led to the accumulation of N²-succinylornithine. In crude extracts of P. aeruginosa an ornithine succinyltransferase (l-ornithine:succinyl-CoA N²-succinyltransferase) activity could be detected. An aru mutant having reduced arginine succinyltransferase activity also had correspondingly low levels of ornithine succinyltransferase. Thus, in P. aeruginosa, these two activities might be due to the same enzyme, which initiates aerobic arginine and ornithine catabolism.Abbreviations OAT ornithine 5-aminotransferase - SOAT N²-succinylornithine 5-aminotransferase - Oru ornithine utilization - Aru arginine utilization     

Crystal structure of the arginine repressor protein in complex with the DNA operator from Mycobacterium tuberculosis

The arginine repressor (ArgR) from Mycobacterium tuberculosis (Mtb) is a gene product encoded by the open reading frame Rv1657. It regulates the l-arginine concentration in cells by interacting with ARG boxes in the promoter regions of the arginine biosynthesis and catabolism operons. Here we present a 2.5-Å structure of MtbArgR in complex with a 16-bp DNA operator in the absence of arginine. A biological trimer of the protein-DNA complex is formed via the crystallographic 3-fold symmetry axis. The N-terminal domain of MtbArgR has a winged helix-turn-helix motif that binds to the major groove of the DNA. This structure shows that, in the absence of arginine, the ArgR trimer can bind three ARG box half-sites. It also reveals the structure of the whole MtbArgR molecule itself containing both N-terminal and C-terminal domains.