Gene Structure, Organization, Expression, and Potential Regulatory Mechanisms of Arginine Catabolism in<i>Enterococcus faecalis</i>

Barcelona, Belén; Marina, Alberto; Rubio, Vicente

doi:10.1128/jb.184.22.6289-6300.2002

Cited by 97 publications

(106 citation statements)

References 71 publications

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“…The presence of two arginine regulator homologues in Enterococcus faecalis has recently been described (2). Only a single Asp residue, as is the case for ArgR Ll , is present in the putative arginine-binding region of both E. faecalis homologues, leading to the suggestion that these regulators may bind metabolites other than arginine.…”

Section: Vol 186 2004 Regulation Of Arginine Metabolism In L Lactimentioning

confidence: 99%

ArgR and AhrC Are Both Required for Regulation of Arginine Metabolism in Lactococcus lactis

et al. 2004

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The DNA binding proteins ArgR and AhrC are essential for regulation of arginine metabolism in Escherichia coli and Bacillus subtilis, respectively. A unique property of these regulators is that they form hexameric protein complexes, mediating repression of arginine biosynthetic pathways as well as activation of arginine catabolic pathways. The gltS-argE operon of Lactococcus lactis encodes a putative glutamate or arginine transport protein and acetylornithine deacetylase, which catalyzes an important step in the arginine biosynthesis pathway. By random integration knockout screening we found that derepression mutants had ISS1 integrations in, among others, argR and ahrC. Single as well as double regulator deletion mutants were constructed from Lactococcus lactis subsp. cremoris MG1363. The three arginine biosynthetic operons argCJDBF, argGH, and gltS-argE were shown to be repressed by the products of argR and ahrC. Furthermore, the arginine catabolic arcABD1C1C2TD2 operon was activated by the product of ahrC but not by that of argR. Expression from the promoter of the argCJDBF operon reached similar levels in the single mutants and in the double mutant, suggesting that the regulators are interdependent and not able to complement each other. At the same time they also appear to have different functions, as only AhrC is involved in activation of arginine catabolism. This is the first study where two homologous arginine regulators are shown to be involved in arginine regulation in a prokaryote, representing an unusual mechanism of regulation.Arginine, a nonessential amino acid in the lactic acid bacterium Lactococcus lactis, is synthesized de novo from glutamate in eight enzymatic steps (Fig. 1). The recent publication of the L. lactis genome sequence (5) has revealed that the putative arginine biosynthesis genes are encoded by the three operons argCJDBF, gltS-argE, and argGH. The products of these genes all show homology to known arginine biosynthetic enzymes, except for that of gltS, which has been annotated as a putative glutamate or arginine ABC transporter (5). While the biosynthetic genes have been shown to be regulated by the presence of arginine in other organisms, this has not been investigated in lactic acid bacteria (LAB). The activities of the biosynthetic enzymes have been shown to be repressed by arginine in Lactobacillus plantarum (6), but regulatory studies on the transcriptional level have not been performed on LAB.Mechanisms for arginine catabolism vary among organisms (1). In L. lactis, complete degradation of arginine into ornithine, ammonium, and carbon dioxide takes place via the arginine deiminase pathway (ADI pathway) in three enzymatic steps catalyzed by arginine deiminase (ArcA), ornithine carbamoyltransferase (ArcB), and carbamate kinase (ArcC) (Fig. 1). The genes arcA, arcB, arcC1, and arcC2 encoding these enzymes are located in the arcABD1C1C2TD2 gene cluster. L. lactis harbors an extra arcC homologue, called arcC3, which is located distant from the remainder of the arginine-related ge...

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Section: Vol 186 2004 Regulation Of Arginine Metabolism In L Lactimentioning

confidence: 99%

ArgR and AhrC Are Both Required for Regulation of Arginine Metabolism in Lactococcus lactis

et al. 2004

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“…In S. mutans and E. faecalis, the AgDS closely resembles the arginine deiminase system (ADS), a pathway that generates ammonia, CO 2 , and ATP from arginine (4,6,13,23,33,37,39). The ADS is considered a primary mechanism of acid tolerance used by some oral bacteria to survive the frequent cycles of acidification encountered in den-tal plaque, but it is not present in the genome of S. mutans (9).…”

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Regulation and Physiologic Significance of the Agmatine Deiminase System of Streptococcus mutans UA159

2006

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We previously demonstrated that Streptococcus mutans expresses a functional agmatine deiminase system (AgDS) encoded by the agmatine-inducible aguBDAC operon (A. R. Griswold, Y. Y. Chen, and R. A. Burne, J. Bacteriol. 186:1902Bacteriol. 186: -1904Bacteriol. 186: , 2004). The AgDS yields ammonia, CO 2 , and ATP while converting agmatine to putrescine and is proposed to augment the acid resistance properties and pathogenic potential of S. mutans. To initiate a study of agu gene regulation, the aguB transcription initiation site was identified by primer extension and a putative 70 -like promoter was mapped 5 to aguB. Analysis of the genome database revealed an open reading frame (SMU.261c) encoding a putative transcriptional regulator located 239 bases upstream of aguB. Inactivation of SMU.261c decreased AgD activity by sevenfold and eliminated agmatine induction. AgD was also found to be induced by certain environmental stresses, including low pH and heat, implying that the AgDS may also be a part of a general stress response pathway of this organism. Interestingly, an AgDS-deficient strain was unable to grow in the presence of 20 mM agmatine, suggesting that the AgDS converts a growth-inhibitory substance into products that can enhance acid tolerance and contribute to the competitive fitness of the organism at low pH. The capacity to detoxify and catabolize agmatine is likely to have major ramifications on oral biofilm ecology.

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“…Despite differences in the organization of genes involved in arginine metabolism, experimental evidence indicates that the mechanism of arginine-dependent regulation of these genes is highly conserved among a range of different organisms, including Gram-negative, Gram-positive and extremophilic bacteria (1)(2)(3)(4)(5)(6)(7)(8)(9)(10)(11)(12). Regulation is exerted by binding of single transcriptional regulators of the ArgR family to so-called ARG operator sites preceding the relevant target genes, generally leading to repression of arginine biosynthetic genes and activation of catabolic genes, in the presence of arginine.…”

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“…A few recent investigations have proven that these ArgR homologues are not merely orthologous but fulfill distinct functions in these organisms. A study in Enterococcus faecalis revealed the presence, upstream of the arginine catabolic arcABCRD operon, of two genes named argR1 and argR2 (10). Although the function of the E. faecalis ArgR-type regulators was not investigated, it was proven that the divergently transcribed argR1 and argR2 genes were differentially expressed in response to arginine and glucose, possibly via putative ARG boxes preceding the genes (10).…”

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confidence: 99%

“…A study in Enterococcus faecalis revealed the presence, upstream of the arginine catabolic arcABCRD operon, of two genes named argR1 and argR2 (10). Although the function of the E. faecalis ArgR-type regulators was not investigated, it was proven that the divergently transcribed argR1 and argR2 genes were differentially expressed in response to arginine and glucose, possibly via putative ARG boxes preceding the genes (10). In our laboratory, a random knock-out screening led to the identification of the argR and ahrC genes in L. lactis, the gene products of which were responsible for repression of the arginine biosynthetic gltSargE operon (12).…”

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Interaction between ArgR and AhrC Controls Regulation of Arginine Metabolism in Lactococcus lactis

Larsen

Kok

Kuipers

2005

Journal of Biological Chemistry

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The expression of arginine metabolism in Lactococcus lactis is controlled by the two homologous transcriptional regulators ArgR and AhrC. Genome sequence analyses have shown that the occurrence of multiple homologues of the ArgR family of transcriptional regulators is a common feature of many low-G ؉ C Gram-positive bacteria. Detailed studies of ArgR type regulators have previously only been carried out in bacteria containing single regulators. Here, we present a first characterization of the two L. lactis arginine regulators by means of gel retardation and DNase I footprinting. ArgR of L. lactis was shown to bind to the promoter regions of both the arginine biosynthetic argCJDBF operon and the arginine catabolic arcABD1C1C2TD2yvaD operon, but in an arginine-independent manner. Surprisingly, AhrC alone was unable to bind to DNA. Arginine-dependent DNA binding was obtained by mixing the two regulators in gel retardation assays. With both regulators present, the addition of arginine led to increased binding of ArgR-AhrC to the biosynthetic argC promoter but also to diminished binding to the catabolic arcA promoter. Footprinting showed ArgR-AhrC protection of regions containing ARG box operator sequences preceding argC. In the absence of AhrC, ArgR protected sites in the arcA promoter region with similarity to ARG box half-sites, here called ARC boxes. We propose a model for repression of arginine biosynthesis and activation of catabolism by anti-repression, involving arginine-dependent interaction between the two L. lactis regulator proteins, ArgR and AhrC.Despite differences in the organization of genes involved in arginine metabolism, experimental evidence indicates that the mechanism of arginine-dependent regulation of these genes is highly conserved among a range of different organisms, including Gram-negative, Gram-positive and extremophilic bacteria (1-12). Regulation is exerted by binding of single transcriptional regulators of the ArgR family to so-called ARG operator sites preceding the relevant target genes, generally leading to repression of arginine biosynthetic genes and activation of catabolic genes, in the presence of arginine.Crystal structures of the ArgR type transcriptional regulators of Escherichia coli (ArgREc (13, 14)), Bacillus stearothermophilus (ArgRBst (15)), and Bacillus subtilis (AhrCBsu (16)) have revealed these to be structurally similar proteins, making up a complex of six identical subunits. The subunits are arranged in hexameric structures, which are organized as dimers of trimers. In E. coli and B. subtilis, the hexameric structure is maintained both in the absence and presence of arginine (4, 17), whereas the regulator of B. stearothermophilus mainly exists as a trimer that assembles into hexamers dependent of the concentrations of arginine, protein, and DNA (5, 15). Six arginine molecules are bound at the trimer-trimer interface, strengthening the interaction between the trimers and at the same time introducing a conformational change in the regulator, thus increasing its affini...

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Gene Structure, Organization, Expression, and Potential Regulatory Mechanisms of Arginine Catabolism inEnterococcus faecalis

Cited by 97 publications

References 71 publications

ArgR and AhrC Are Both Required for Regulation of Arginine Metabolism in Lactococcus lactis

ArgR and AhrC Are Both Required for Regulation of Arginine Metabolism in Lactococcus lactis

Regulation and Physiologic Significance of the Agmatine Deiminase System of Streptococcus mutans UA159

Interaction between ArgR and AhrC Controls Regulation of Arginine Metabolism in Lactococcus lactis

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