Characterization of the Streptomyces clavuligerus argC gene encoding N-acetylglutamyl-phosphate reductase: expression in Streptomyces lividans and effect on clavulanic acid production

Microarray Analysis of the Genomic Effect of Eugenol on Methicillin-Resistant Staphylococcus aureus

Staphylococcus aureus is a highly adaptive human pathogen responsible for serious hospital- and community-acquired infectious diseases, ranging from skin and soft tissue infections, to complicated and life-threatening conditions such as endocarditis and toxic shock syndrome (TSS). The rapid development of resistance of this organism to available antibiotics over the last few decades has necessitated a constant search for more efficacious antibacterial agents. Eugenol (4-allyl-2-methoxyphenol) belongs to the class of chemical compounds called phenylpropanoids. It is a pure-to-pale yellow, oily liquid substance, mostly extracted as an essential oil from natural products such as clove, cinnamon, nutmeg, basil, and bay leaf. Eugenol has previously been shown to have antimicrobial activity against methicillin-resistant Staphylococcus aureus (MRSA). However, the mechanism of action of eugenol against MRSA has not, as yet, been elucidated; hence, the necessity of this study. Global gene expression patterns in response to challenge from subinhibitory concentrations of eugenol were analysed using the Agilent DNA microarray system to identify genes that can be used as drug targets—most importantly, essential genes involved in unique metabolic pathways elicited for bacterial survival. Transcriptomic analysis of fluctuating genes revealed those involved in amino acid metabolism, fatty acid metabolism, translational, and ribosomal pathways. In amino acid metabolism, for instance, the argC gene encodes for N-acetyl-gamma-glutamyl-phosphate reductase. The argC gene plays an important role in the biosynthesis of arginine from glutamate in the amino acid metabolic pathway. It is the enzyme that catalyses the third step in the latter reaction, and without this process the production of N-acetylglutamate 5-semialdehyde cannot be completed from the NADP-dependent reduction of N-acetyl-5-glutamyl phosphate, which is essential for the survival of some microorganisms and plants. This study enables us to examine complete global transcriptomic responses in MRSA when challenged with eugenol. It reveals novel information with the potential to further benefit the exploratory quest for novel targets against this pathogen, with a view to the development of efficacious antimicrobial agents for the treatment of associated infections.

A single P115Q mutation modulates specificity in the Corynebacterium pseudotuberculosis arginine repressor

The arginine repressor (ArgR) regulates the expression of genes involved in arginine biosynthesis. Upon attaining a threshold concentration of arginine in the cytoplasm, the trimeric C-terminal domain of ArgR binds three arginines in a shallow surface cleft and subsequently hexamerizes forming a dimer of trimers containing six Arg co-repressor molecules which are buried at the subunit interfaces. The N-terminal domains of this complex bind to the DNA promoter thereby interrupting the transcription of the genes related to Arg biosynthesis. The crystal structures of the wild type and mutant Pro115Gln ArgR from Corynebacterium pseudotuberculosis determined at 1.7 Å demonstrate that a single amino acid substitution switches co-repressor specificity from Tyr to Arg. Molecular dynamics simulations indicate that the first step, i.e., the binding of the co-repressor, occurs in the trimeric state and that Pro115Gln ArgR preferentially binds Arg. It was also shown that, in Pro115 ArgR hexamers, the concomitant binding of sodium ions shifts selectivity to Tyr. Structural data combined with phylogenetic analyses of ArgR from C. pseudotuberculosis suggest that substitutions in the binding pocket at position 115 may alter its specificity for amino acids and that the length of the protein interdomain linker can provide further functional flexibility. These results support the existence of alternative ArgR regulatory mechanisms in this pathogenic bacterium.

Mutations that improve efficiency of a weak-link enzyme are rare compared to adaptive mutations elsewhere in the genome

New enzymes often evolve by gene amplification and divergence. Previous experimental studies have followed the evolutionary trajectory of an amplified gene, but have not considered mutations elsewhere in the genome when fitness is limited by an evolving gene. We have evolved a strain of Escherichia coli in which a secondary promiscuous activity has been recruited to serve an essential function. The gene encoding the ‘weak-link’ enzyme amplified in all eight populations, but mutations improving the newly needed activity occurred in only one. Most adaptive mutations occurred elsewhere in the genome. Some mutations increase expression of the enzyme upstream of the weak-link enzyme, pushing material through the dysfunctional metabolic pathway. Others enhance production of a co-substrate for a downstream enzyme, thereby pulling material through the pathway. Most of these latter mutations are detrimental in wild-type E. coli, and thus would require reversion or compensation once a sufficient new activity has evolved.

Tyrosine binding and promiscuity in the arginine repressor from the pathogenic bacterium Corynebacterium pseudotuberculosis

The arginine repressor (ArgR) regulates arginine biosynthesis in a number of microorganisms and consists of two domains interlinked by a short peptide; the N-terminal domain is involved in DNA binding and the C-terminal domain binds arginine and forms a hexamer made-up of a dimer of trimers. The crystal structure of the C-terminal domain of ArgR from the pathogenic Corynebacterium pseudotuberculosis determined at 1.9 Å resolution contains a tightly bound tyrosine at the arginine-binding site indicating hitherto unobserved promiscuity. Structural analysis of the binding pocket displays clear molecular adaptations to accommodate tyrosine binding suggesting the possible existence of an alternative regulatory process in this pathogenic bacterium.

Analyzing the Transcriptomes of Two Quorum-Sensing Controlled Transcription Factors, RcsA and LrhA, Important for Pantoea stewartii Virulence

The Gram-negative proteobacterium Pantoea stewartii subsp. stewartii causes wilt disease in corn plants. Wilting is primarily due to bacterial exopolysaccharide (EPS) production that blocks water transport in the xylem during the late stages of infection. EsaR, the master quorum-sensing (QS) regulator in P. stewartii, modulates EPS levels. At low cell densities EsaR represses or activates expression of a number of genes in the absence of its acyl homoserine lactone (AHL) ligand. At high cell densities, binding of AHL inactivates EsaR leading to derepression or deactivation of its direct targets. Two of these direct targets are the key transcription regulators RcsA and LrhA, which in turn control EPS production and surface motility/adhesion, respectively. In this study, RNA-Seq was used to further examine the physiological impact of deleting the genes encoding these two second-tier regulators. Quantitative reverse transcription PCR (qRT-PCR) was used to validate the regulation observed in the RNA-Seq data. A GFP transcriptional fusion reporter confirmed the existence of a regulatory feedback loop in the system between LrhA and RcsA. Plant virulence assays carried out with rcsA and lrhA deletion and complementation strains demonstrated that both transcription factors play roles during establishment of wilt disease in corn. These efforts further define the hierarchy of the QS-regulated network controlling plant virulence in P. stewartii.

ArgR of Streptomyces coelicolor is a versatile regulator

ArgR is the regulator of arginine biosynthesis genes in Streptomyces species. Transcriptomic comparison by microarrays has been made between Streptomyces coelicolor M145 and its mutant S. coelicolor ΔargR under control, unsupplemented conditions, and in the presence of arginine. Expression of 459 genes was different in transcriptomic assays, but only 27 genes were affected by arginine supplementation. Arginine and pyrimidine biosynthesis genes were derepressed by the lack of ArgR, while no strong effect on expression resulted on arginine supplementation. Several nitrogen metabolism genes expression as glnK, glnA and glnII, were downregulated in S. coelicolor ΔargR. In addition, downregulation of genes for the yellow type I polyketide CPK antibiotic and for the antibiotic regulatory genes afsS and scbR was observed. The transcriptomic data were validated by either reverse transcription-PCR, expression of the gene-promoter coupled to the luciferase gene, proteomic or by electrophoresis mobility shift assay (EMSA) using pure Strep-tagged ArgR. Two ARG-boxes in the arginine operon genes suggest that these genes are more tightly controlled. Other genes, including genes encoding regulatory proteins, possess a DNA sequence formed by a single ARG-box which responds to ArgR, as validated by EMSA.

Crystallization and preliminary X-ray diffraction analysis of the arginine repressor of the hyperthermophile Thermotoga neapolitana

The arginine repressor of Thermotoga neapolitana (ArgRTnp) is a member of the family of multifunctional bacterial arginine repressors involved in the regulation of arginine metabolism. This hyperthermophilic repressor shows unique DNA-binding features that distinguish it from its homologues. ArgRTnp exists as a homotrimeric protein that assembles into hexamers at higher protein concentrations and/or in the presence of arginine. ArgRTnp was crystallized with and without its corepressor arginine using the hanging-drop vapour-diffusion method. Crystals of the aporepressor diffracted to a resolution of 2.1 A and belong to the orthorhombic P2(1)2(1)2(1) space group, with unit-cell parameters a = 117.73, b = 134.15, c = 139.31 A. Crystals of the repressor in the presence of its corepressor arginine diffracted to a resolution of 2.4 A and belong to the same space group, with similar unit-cell parameters.

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.

ORF6 from the clavulanic acid gene cluster of Streptomyces clavuligerus has ornithine acetyltransferase activity

The clinically used beta-lactamase inhibitor clavulanic acid is produced by fermentation of Streptomyces clavuligerus. The orf6 gene of the clavulanic acid biosynthetic gene cluster in S. clavuligerus encodes a protein that shows sequence homology to ornithine acetyltransferase (OAT), the fifth enzyme of the arginine biosynthetic pathway. Orf6 was overexpressed in Escherichia coli (at approximately 15% of total soluble protein by SDS/PAGE analysis) indicating it was not toxic to the host cells. The recombinant protein was purified (to > 95% purity) by a one-step technique. Like other OATs it was synthesized as a precursor protein which underwent autocatalytic internal cleavage in E. coli to generate alpha and beta subunits. Cleavage was shown to occur between the alanine and threonine residues in a KGXGMXXPX--(M/L)AT (M/L)L motif conserved within all identified OAT sequences. Gel filtration and native electrophoresis analyses implied that the ORF6 protein was an alpha2beta2 heterotetramer and direct evidence for this came from mass spectrometric analyses. Although anomalous migration of the beta subunit was observed by standard SDS/PAGE analysis, which indicated the presence of two bands (as previously observed for other OATs), mass spectrometric analyses did not reveal any evidence for post-translational modification of the beta subunit. Extended denaturation with SDS before PAGE resulted in observation of a single major beta subunit band. Purified ORF6 was able to catalyse the reversible transfer of an acetyl group from N-acetylornithine to glutamate, but not the formation of N-acetylglutamate from glutamate and acetyl-coenzyme A, nor (detectably) the hydrolysis of N-acetylornithine. Mass spectrometry also revealed the reaction proceeds via acetylation of the beta subunit.

Transcription regulation in thermophilic bacteria: high resolution contact probing of Bacillus stearothermophilus and Thermotoga neapolitana arginine repressor-operator interactions

Arginine-mediated regulation is remarkably well conserved in very divergent bacteria, and shows a number of unusual features that distinguish arginine regulation from other transcriptional control mechanisms. The arginine repressor subunit consists of a basic N-terminal DNA-binding domain, which belongs to the winged helix-turn-helix family, connected through a flexible linker to an acidic C-terminal domain responsible for binding of arginine and assembly of the high-affinity holohexamer, which binds an approximately 40 bp target. To gain further insight into the molecular details of arginine repressor-operator interactions we have established a high resolution contact map of the argC operator from Bacillus stearothermophilus, a moderate thermophilic Gram-positive bacterium, and the argR operator from Thermotoga neapolitana, a Gram-negative hyperthermophile, with the corresponding ArgR proteins. Enzymatic and chemical footprinting have been combined with missing contact, pre-modification, base substitution, and small ligand binding interference techniques to gather information on backbone and base-specific contacts with major and minor groove determinants of the operators. Wild-type and mutant argC operators have been compared for their interaction with the repressor, using both in vivo and in vitro approaches. Our results indicate that the operators of B. stearothermophilus and T. neapolitana consist of two ARG box-like sequences, 18 bp imperfect palindromes, separated by two and three base-pairs, respectively, and that the repressors from thermophilic origin establish base-specific contacts with two major groove segments and the intervening minor groove of each ARG box, all aligned on one face of the helix. In contrast, no specific contacts are established in the minor groove facing the repressor in the centre of the operator, nevertheless this region plays a crucial structural role in complex formation, as indicated by mutant studies. This picture is reminiscent of arginine repressor binding in Escherichia coli, and therefore reinforces the uniform view of arginine regulation, but also reveals a number of striking differences at particular positions of the boxes and in the length and base-pair composition of the spacer connecting two ARG boxes in the operator. These might be responsible, in part, for subtle but important functional and mechanistic differences in the way species-specific repressors interact with their cognate target sites. These variations are underlined by the different behaviour of the repressors from E. coli, B. stearothermophilus and T. neapolitana in their potential to bind heterologous operators, their requirement for arginine, and the resistance of complex formation to non-specific competitor DNA. Our findings are discussed in view of the crystal structure of the arginine repressor from B. stearothermophilus.

Primary metabolism and its control in streptomycetes: a most unusual group of bacteria

Streptomycetes are Gram-positive bacteria with a unique capacity for the production of a multitude of varied and complex secondary metabolites. They also have a complex life cycle including differentiation into at least three distinct cell types. Whilst much attention has been paid to the pathways and regulation of secondary metabolism, less has been paid to the pathways and the regulation of primary metabolism, which supplies the precursors. With the imminent completion of the total genome sequence of Streptomyces coelicolor A3(2), we need to understand the pathways of primary metabolism if we are to understand the role of newly discovered genes. This review is written as a contribution to supplying these wants. Streptomycetes inhabit soil, which, because of the high numbers of microbial competitors, is an oligotrophic environment. Soil nutrient levels reflect the fact that plant-derived material is the main nutrient input; i.e. it is carbon-rich and nitrogen- and phosphate-poor. Control of streptomycete primary metabolism reflects the nutrient availability. The variety and multiplicity of carbohydrate catabolic pathways reflects the variety and multiplicity of carbohydrates in the soil. This multiplicity of pathways has led to investment by streptomycetes in pathway-specific and global regulatory networks such as glucose repression. The mechanism of glucose repression is clearly different from that in other bacteria. Streptomycetes feed by secreting complexes of extracellular enzymes that break down plant cell walls to release nutrients. The induction of these enzyme complexes is often coordinated by inducers that bear no structural relation to the substrate or product of any particular enzyme in the complex; e.g. a product of xylan breakdown may induce cellulase production. Control of amino acid catabolism reflects the relative absence of nitrogen catabolites in soil. The cognate amino acid induces about half of the catabolic pathways and half are constitutive. There are reduced instances of global carbon and nitrogen catabolite control of amino acid catabolism, which again presumably reflects the relative rarity of the catabolites. There are few examples of feedback repression of amino acid biosynthesis. Again this is taken as a reflection of the oligotrophic nature of the streptomycete ecological niche. As amino acids are not present in the environment, streptomycetes have rarely invested in feedback repression. Exceptions to this generalization are the arginine and branched-chain amino acid pathways and some parts of the aromatic amino acid pathways which have regulatory systems similar to Escherichia coli and Bacillus subtilis and other copiotrophic bacteria.

Genes and enzymes of the acetyl cycle of arginine biosynthesis in the extreme thermophilic bacterium Thermus thermophilus HB27

An arginine biosynthetic gene cluster, argC-argJ, of the extreme thermophilic bacterium Thermus thermophilus HB27 was isolated by heterologous complementation of an Escherichia coli acetylornithinase mutant. The recombinant plasmid (pTHM1) conferred ornithine acetyltransferase activity to the E. coli host, implying that T. thermophilus uses the energetically more economic pathway for the deacetylation of acetylornithine. pTHM1 was, however, unable to complement an E. coli argA mutant and no acetylglutamate synthase activity could be detected in E. coli argA cells containing pTHM1. The T. thermophilus argJ-encoded enzyme is thus monofunctional and is unable to use acetyl-CoA to acetylate glutamate (contrary to the Bacillus stearothermophilus homologue). Alignment of several ornithine acetyltransferase amino acid sequences showed no obvious pattern that could account for this difference; however, the monofunctional enzymes proved to have shorter N-termini. Sequence analysis of the pTHM1 3.2 kb insert revealed the presence of the argC gene (encoding N-acetylglutamate-5-semialdehyde dehydrogenase) upstream of the argJ gene. Alignment of several N-acetylglutamate-5-semialdehyde dehydrogenase amino acid sequences allowed identification of two strongly conserved putative motifs for cofactor binding: a putative FAD-binding site and a motif reminiscent of the NADPH-binding fingerprint. The relationship between the amino acid content of both enzymes and thermostability is discussed and an effect of the GC content bias is indicated. Transcription of both the argC and argJ genes appeared to be vector-dependent. The argJ-encoded enzyme activity was twofold repressed by arginine in the native host and was inhibited by ornithine. Both upstream of the argC gene and downstream of the argJ gene an ORF with unknown function was found, indicating that the organization of the arginine biosynthetic genes in T. thermophilus is new.

Arginine biosynthesis and regulation in Lactobacillus plantarum: the carA gene and the argCJBDF cluster are divergently transcribed

A cluster of citrulline biosynthetic genes has been cloned and sequenced from a fragment of Lactobacillus plantarum CCM 1904 (ATCC 8014) DNA isolated as complementing a Bacillus subtilis argF mutation. The gene order was carA-argCJBDF, with carA transcribed divergently from the arg cluster. Although other gram-positive bacteria show similar arg clusters, this arrangement for carA is thus far unprecedented. Downstream from the arg cluster, two open reading frames (ORF7 and ORF8) having unknown functions were found. Sequence analysis of the end of a 10.5-kb cloned DNA fragment showed that argF was 3.5 kb from the ldhL gene coding for L-(+)-lactate dehydrogenase. A tree representation of amino acid sequence clustering relationships of 31 ornithine carbamoyltransferases (OTCases) from various organisms revealed two prokaryotic groups: one with ArgF of L. plantarum and one with ArgF of B. subtilis, which are paralogous. This divergence was not observed in vivo because an L. plantarum argF mutant (AM 1215) harboring no OTCase activity was complemented by the argF genes of L. plantarum and B. subtilis. No OTCase activity was detectable when L. plantarum was grown in the presence of saturating amounts of arginine or citrulline. Arginine may repress the citrulline biosynthetic genes in L. plantarum by using 11 identified DNA motifs which resemble the Escherichia coli ARG box consensus and which are in most cases separated by multiples of 11 bp, corresponding to a DNA helical turn. The carA and argCJBDF genes are divergently transcribed. Their putative promoters are 6 bp apart and are partially overlapped by putative ARG boxes, suggesting concerted transcription regulation.

Implication of a repression system, homologous to those of other bacteria, in the control of arginine biosynthesis genes in Streptomyces coelicolor

As with most amino acid biosynthetic pathways in streptomycetes, enzymes of arginine biosynthesis in Streptomyces coelicolor show only slight derepression in minimal medium without, as opposed to with, exogenous arginine. However, when an arginine auxotroph was cultured in limiting arginine, ornithine carbamoyltransferase (OCT) activities rose by as much as 100-fold. The response was not due to a general starvation effect. To elucidate the repression-derepression mechanism, a DNA fragment containing the upstream region of the previously isolated S. coelicolor argCJB cluster was cloned into a multicopy vector and transformed into wild-type S. coelicolor; a slight transient derepression of OCT was observed in minimal medium without, though not with, added arginine, consistent with titration by the insert of a negatively acting macromolecule such as a repressor. A subfragment carrying the 5' end of argC and the region immediately upstream showed specific binding, in mobility shift assays, to purified AhrC, the repressor/activator of genes of arginine metabolism in Bacillus subtilis. It is therefore likely that in S. coelicolor, expression of arginine biosynthesis genes is controlled by a protein homologous to the well-characterised B. subtilis and Escherichia coli repressors.

The argG gene of Streptomyces clavuligerus has low homology to unstable argG from other actinomycetes: effect of amplification on clavulanic acid biosynthesis

The argG gene of Streptomyces clavuligerus (Scl) has been cloned by complementation of argG mutants of Escherichia coli and S. lividans (Sl). The argG nucleotide (nt) sequence showed that it corresponds to a new type of argG different from the corresponding genes of S. coelicolor (Sco) and Sl. It encodes a 43,250-Da protein that showed higher similarity to argininosuccinate synthetases (ASS) from Methanococcus vannielii and Methanosarcina barkeri than to ASS deduced from other Streptomyces argG. No hybridization of the Scl argG was found with the homologous genes of Sl or Sco. The argH gene was located downstream from argG in Scl. The genomic region around argG and argH in Scl was different from the homologous regions in other Streptomyces and is not genetically unstable, unlike in Sco and Sl. Amplification of argG in transformant Scl[pULAR113] results in a 2.3-fold increase in the production of clavulanic acid (CA) in relation to the control strain Scl[pIJ699].

Multicopy suppression by asd gene and osmotic stress-dependent complementation by heterologous proA in proA mutants

Auxotrophic proA mutants of Escherichia coli were complemented by two different classes of Corynebacterium glutamicum genes. One of these was the asd gene. The E. coli asd gene also complements the same proA alleles. Complementation of proA by the asd+ gene requires a high asd dosage and the proB and the proC gene products. The reciprocal complementation pattern (asd by the proA+ gene) was not observed. This complementation appears to be due to multicopy suppression by a proline biosynthetic gene whose product was expected to play a negligible role in this pathway. The other class of complementing clones carries the C. glutamicum proA gene. Complementation of E. coli proA mutants by the C. glutamicum proA+ gene was optimal at high osmolarity.

Clavulanic acid biosynthesis in Streptomyces clavuligerus: gene cloning and characterization

Seven classes of Streptomyces clavuligerus mutants defective in clavulanic acid (CLA) biosynthesis have been identified and used to clone the chromosomal DNA encoding eight CLA biosynthetic genes. The complete sequences of three and the partial sequences of two of these biosynthetic genes are reported, together with their known or predicted functions.

A cluster of three genes (dapA, orf2, and dapB) of Brevibacterium lactofermentum encodes dihydrodipicolinate synthase, dihydrodipicolinate reductase, and a third polypeptide of unknown function

The dapA and dapB genes, encoding, respectively, dihydrodipicolinate synthase and dihydrodipicolinate reductase, the two first enzymes of the lysine branch of the aspartic amino acid family, were cloned from the DNA of the amino acid-producing bacterium Brevibacterium lactofermentum. The two genes were clustered in a 3.5-kb Sau3AI-BamHI fragment but were separated by an open reading frame of 750 nucleotides. The protein encoded by this open reading frame had little similarity to any protein in the data banks, and its function remains unknown. The three genes were translated in Escherichia coli, giving the corresponding polypeptides.