Generation of Novel Bacterial Regulatory Proteins That Detect Priority Pollutant Phenols

Wise, Arlene A.; Kuske, Cheryl R.

doi:10.1128/aem.66.1.163-169.2000

Cited by 83 publications

(74 citation statements)

References 29 publications

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“…A number of different molecular genetic strategies have previously been used to isolate mutations within the A domain of DmpR that positively or negatively modulate the response to aromatic effectors. These include positive genetic selection systems and random PCR mutagenesis to generate mutants with enhanced sensitivity and/or novel sensory capacity (31,42,52), genetic selection of second-site suppressors of constitutively active mutations of DmpR (26), and DNA shuffling between the A domain of DmpR and that of the toluene-xylene response regulator XylR (44). The locations of the mutations identified in this study relative to previously identified mutations are shown in Fig.…”

Section: Discussionmentioning

confidence: 99%

“…Not all effectors are equally efficient in activating DmpR, and modulation of the A-C domain inhibitory interaction through mutations in either the A or C domain can alter the magnitude of the response to a given effector (26,31). In addition, mutations within the signal reception A domain can expand the range of compounds that can activate DmpR to promote transcription (31,42,52). As illustrated in Fig.…”

Section: Discussionmentioning

confidence: 99%

“…The mutations DmpR-R109C, DmpR-D116N, and DmpR-E135K show the broadest spectrum of response to para-substituted compounds, which includes the ability to respond to the priority-list pollutants 2,4-dimethylphenol, 2,4-dichlorophenol, and 4-nitrophenol. Thus, this class of mutants have potential utility in whole-cell biosensor applications for pollution monitoring (44,52).…”

Section: Resultsmentioning

confidence: 99%

“…Locations of the A-domain dmpR mutations identified in the present study (upper arrowheads) in relation to previously identified A-domain mutations (lower arrowheads). Open arrowheads indicate mutations that positively affect the response to aromatic compounds as identified by enhanced responses to an effector(s) of wild-type DmpR and/or expanded specificity range (31,42,52). Grey and black arrowheads indicate mutations that negatively affect the aromatic response of DmpR.…”

Section: Discussionmentioning

confidence: 99%

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

Sarand

Skärfstad

Forsman

et al. 2001

Appl Environ Microbiol

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Pathway substrates and some structural analogues directly activate the regulatory protein DmpR to promote transcription of the dmp operon genes encoding the (methyl)phenol degradative pathway of Pseudomonas sp. strain CF600. While a wide range of phenols can activate DmpR, the location and nature of substituents on the basic phenolic ring can limit the level of activation and thus utilization of some compounds as assessed by growth on plates. Here we address the role of the aromatic effector response of DmpR in determining degradative properties in two soil matrices that provide different nutritional conditions. Using the wild-type system and an isogenic counterpart containing a DmpR mutant with enhanced ability to respond to para-substituted phenols, we demonstrate (i) that the enhanced in vitro biodegradative capacity of the regulator mutant strain is manifested in the two different soil types and (ii) that exposure of the wild-type strain to 4-methylphenol-contaminated soil led to rapid selection of a subpopulation exhibiting enhanced capacities to degrade the compound. Genetic and functional analyses of 10 of these derivatives demonstrated that all harbored a single mutation in the sensory domain of DmpR that mediated the phenotype in each case. These findings establish a dominating role for the aromatic effector response of DmpR in determining degradation properties. Moreover, the results indicate that the ability to rapidly adapt regulator properties to different profiles of polluting compounds may underlie the evolutionary success of DmpR-like regulators in controlling aromatic catabolic pathways.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

See 2 more Smart Citations

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

Sarand

Skärfstad

Forsman

et al. 2001

Appl Environ Microbiol

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“…They are also included in the composition of plant root exudates, and are components of fl ower and fruit dyes (Krupa and Latocha 2007). The main sources of these compounds are industry and agricultural activity (Wise and Kuske 2000, Thakur et al 2013, Wang et al 2015.…”

Section: Introductionmentioning

confidence: 99%

Content of phenolic compounds in soils originating from two long-term fertilization experiments

Sadej

Żołnowski

Marczuk

2016

Archives of Environmental Protection

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Abstract:The objective of the study was to compare the impact of three systems of multiannual fertilization applied in two long-term fi eld experiments on the content of phenolic compounds in the soil. In the study, both natural (manure, slurry) and mineral (NPK) fertilizers were used, along with combined, organic-and-mineral fertilization. Experiment I was established in 1972 on grey brown podzolic soil; experiment II, in 1973 on brown soil. In both experiments crops were cultivated in a 7-year rotation, with a 75% share of cereals. The experimental samples were taken from the top layer of soil after 36 (experiment I) and 35 (experiment II) years following the establishment of the experiments. It was demonstrated that the presence of phenolic compounds in the soils was signifi cantly dependent on the contents of organic C and total N, type of soil and the type and dose of used fertilizers. In grey brown podzolic soil, the content of total phenolic compounds was at a lower level than the content found in brown soil. Multiannual fertilization contributed to an increase in the content of total phenolic compounds in relation to the values obtained in control objects, which was particularly refl ected in the soil originating from objects fertilized with slurry applied at a dose being equivalent to manure in terms of the amount of introduced organic carbon. The percentage of water-soluble phenols in the total content of these compounds in grey brown podzolic soil was at the level of 18.4%, while in brown soil it amounted to 29.1%.

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Recombinant Whole‐Cell Bioreporter Systems Based on Beetle Luciferases

Ivask

Kahru

Virta

2007

Handbook of Biosensors and Biochips

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Bioluminescence is one of the most widely used reporter systems in living cells. Luciferase encoded by luc gene from the firefly Photinus pyralis is a commonly used reporter gene that can be detected by bioluminescence and utilized in the construction of bioreporters. In a classical bioreporter, the expression of a reporter gene is controlled by a natural regulatory circuit, which in many cases consists of a regulatory protein and its corresponding promoter. In the absence of analyte, the regulatory protein is either repressing the transcription initiation from the corresponding promoter or simply does not activate the transcription. However, when the analyte is present in the bioreporter cells, it binds with the regulatory protein, which initiates the transcription and thus, the expression of the reporter gene, the specificity of a bioreporter, is mostly defined by the regulatory unit. An overview is given on the possibilities and limitations of beetle luciferases in whole‐cell bioreporter systems and biosensors. Examples of the use of beetle luciferase‐based bacterial and yeast‐based bioreporter systems for the quantification of bioavailable heavy metals and organic compounds in environmental samples as well as for identifying endocrine disruptive compounds are given.

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Generation of Novel Bacterial Regulatory Proteins That Detect Priority Pollutant Phenols

Cited by 83 publications

References 29 publications

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

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

Content of phenolic compounds in soils originating from two long-term fertilization experiments

Recombinant Whole‐Cell Bioreporter Systems Based on Beetle Luciferases

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