Role of the DmpR-Mediated Regulatory Circuit in Bacterial Biodegradation Properties in Methylphenol-Amended Soils

Sarand, Inga; Skärfstad, Eleonore; Forsman, Mats; Romantschuk, Martin; Shingler, Victoria

doi:10.1128/aem.67.1.162-171.2001

Cited by 43 publications

(41 citation statements)

References 54 publications

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“…Alternatively micro-scale niches in the soil environment may be present where the halogenated phenols were reduced sufficiently to enable localized onset of phenol degradation. The soil conditions could possibly also promote rapid adaptation of A. chlorophenolicus to the substrates present as reported previously for another phenol-degrading strain (Sarand et al 2001).…”

Section: Discussionmentioning

confidence: 84%

Degradation of mixtures of phenolic compounds by Arthrobacter chlorophenolicus A6

et al. 2007

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In this study the chlorophenol-degrading actinobacterium, Arthrobacter chlorophenolicus A6, was tested for its ability to grow on mixtures of phenolic compounds. During the experiments depletion of the compounds was monitored, as were cell growth and activity. Activity assays were based on bioluminescence output from a luciferase-tagged strain. When the cells were grown on a mixture of 4-chlorophenol, 4-nitrophenol and phenol, 4-chlorophenol degradation apparently was delayed until 4-nitrophenol was almost completely depleted. Phenol was degraded more slowly than the other compounds and not until 4-nitrophenol and 4-chlorophenol were depleted, despite this being the least toxic compound of the three. A similar order of degradation was observed in non-sterile soil slurries inoculated with A. chlorophenolicus. The kinetics of degradation of the substituted phenols suggest that the preferential order of their depletion could be due to their respective pKa values and that the dissociated phenolate ions are the substrates. A mutant strain (T99), with a disrupted hydroxyquinol dioxygenase gene in the previously described 4-chlorophenol degradation gene cluster, was also studied for its ability to grow on the different phenols. The mutant strain was able to grow on phenol, but not on either of the substituted phenols, suggesting a different catabolic pathway for the degradation of phenol by this microorganism.

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Section: Discussionmentioning

confidence: 84%

Degradation of mixtures of phenolic compounds by Arthrobacter chlorophenolicus A6

et al. 2007

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“…Also, the regulators of TOL meta-cleavage pathway genes, XylS and XylS1, differ in only five amino acids but have different effector profiles and display different sigma factor dependence (37). Finally, the ability of bacterial strains to grow with multiple hydroxylated aromatic substrates has been linked to enhanced effector responses, such as those caused by single-amino-acid changes in DmpR, a regulator of phenol degradation genes (40). Therefore, it seems reasonable that the few differences between NtdR and NagR could drastically alter the effector profile as well as the observed basal level of expression.…”

Section: Discussionmentioning

confidence: 99%

Expression of the Nitroarene Dioxygenase Genes inComamonassp. Strain JS765 andAcidovoraxsp. Strain JS42 Is Induced by Multiple Aromatic Compounds

et al. 2003

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This work reports a genetic analysis of the expression of nitrobenzene dioxygenase (NBDO) in Comamonas sp. strain JS765 and 2-nitrotoluene dioxygenase (2NTDO) in Acidovorax sp. strain JS42. Strains JS765 and JS42 possess identical LysR-type regulatory proteins, NbzR and NtdR, respectively. NbzR/NtdR is homologous to NahR, the positive salicylate-responsive transcriptional activator of the naphthalene degradation genes in Pseudomonas putida G7. The genes encoding NBDO and 2NTDO in each strain are cotranscribed, and transcription starts at the same site within identical promoter regions for each operon. Results from a lacZ reporter gene fusion demonstrated that expression of NBDO and 2NTDO is induced by multiple aromatic compounds, including an array of nitroaromatic compounds (nitrobenzene, 2-, 3-, and 4-nitrotoluene, 2,4-and 2,6-dinitrotoluene, and aminodinitrotoluenes), as well as salicylate and anthranilate. The nitroaromatic compounds appear to be the actual effector molecules. Analysis of ␤-galactosidase and 2NTDO activities with strain JS42 demonstrated that NtdR was required for induction by all of the inducing compounds, high basal-level expression of 2NTDO, and complementation of a JS42 ntdR null mutant. Complementation with the closely related regulators NagR (from Ralstonia sp. strain U2) and NahR restored only induction by the archetype inducers, salicylate or salicylate and anthranilate, respectively, and did not restore the high basal level of expression of 2NTDO. The mechanism of 2NTDO gene regulation in JS42, and presumably that of NBDO gene regulation in JS765, appear similar to that of NahR-regulated genes in Pseudomonas putida G7. However, NbzR and NtdR appear to have evolved a broader specificity in JS42 and JS765, allowing for recognition of nitroaromatic compounds while retaining the ability to respond to salicylate and anthranilate. NtdR is also the first example of a nitroarene-responsive LysR-type transcriptional activator.

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“…A plasmid carrying DmpR was introduced into the selection Po-km strain (Po is the promoter activated by DmpR). Further analysis demonstrated that these strains had point mutations within the A domain of DmpR, which produced an enhanced response to 4-methylphenol (Sarand et al, 2001). This produced one mutant bearing a point mutation in the A domain of the protein, which displayed not only a novel response to 4-ethylphenol but also showed an increased reaction to 4-methyphenol and 3,4-dimethyphenol.…”

Section: Sensing Signals With Transcriptional Regulators Of Environmementioning

confidence: 99%

Engineering input/output nodes in prokaryotic regulatory circuits

2010

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A large number of prokaryotic regulatory elements have been interfaced artificially with biological circuits that execute specific expression programs. Engineering such circuits involves the association of input/output components that perform discrete signal-transfer steps in an autonomous fashion while connected to the rest of the network with a defined topology. Each of these nodes includes a signal-recognition component for the detection of the relevant physicochemical or biological stimulus, a molecular device able to translate the signal-sensing event into a defined output and a genetic module capable of understanding such an output as an input for the next component of the circuit. The final outcome of the process can be recorded by means of a reporter product. This review addresses three such aspects of forward engineering of signal-responding genetic parts. We first recap natural and non-natural regulatory assets for designing gene expression in response to predetermined signals - chemical or otherwise. These include transcriptional regulators developed by in vitro evolution (or designed from scratch), and synthetic riboswitches derived from in vitro selection of aptamers. Then we examine recent progress on reporter genes, whose expression allows the quantification and parametrization of signal-responding circuits in their entirety. Finally, we critically examine recent work on other reporters that confer bacteria with gross organoleptic properties (e.g. distinct odour) and the interfacing of signal-sensing devices with determinants of community behaviour.

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Role of the DmpR-Mediated Regulatory Circuit in Bacterial Biodegradation Properties in Methylphenol-Amended Soils

Cited by 43 publications

References 54 publications

Degradation of mixtures of phenolic compounds by Arthrobacter chlorophenolicus A6

Degradation of mixtures of phenolic compounds by Arthrobacter chlorophenolicus A6

Expression of the Nitroarene Dioxygenase Genes inComamonassp. Strain JS765 andAcidovoraxsp. Strain JS42 Is Induced by Multiple Aromatic Compounds

Engineering input/output nodes in prokaryotic regulatory circuits

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