5 results on '"luminescent bacteria"'
Search Results
2. Bacterial bioluminescence assay for bioanalysis and bioimaging
- Author
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Xinyu He, Weinan Zhu, Yaohua Li, Haoran Li, and Wei Wang
- Subjects
Bioanalysis ,Bacteria ,Chemistry ,Luminescent bacteria ,Gene Expression Regulation, Bacterial ,Bacterial Physiological Phenomena ,Biochemistry ,Analytical Chemistry ,law.invention ,Anti-Bacterial Agents ,law ,Luminescent Measurements ,Recombinant DNA ,Bioluminescence imaging ,Bioluminescence ,Luciferase ,Viability assay ,Biosensor - Abstract
Bioluminescence occurs through a chemical reaction in organisms that spontaneously produce light. Luminescent bacteria are unique among bioluminescent organisms. Their bioluminescence intensity is an indicator of their metabolic activity, which can directly reflect the influence of environmental factors on cell viability. Moreover, the whole bioluminescence process is totally gene encoded without the addition of extra substrates. As a result, bacterial bioluminescence has been a powerful tool for whole-cell biosensors and bio-reporters in bioanalysis and bioimaging. This review aims to cover the applications of wild-type and recombinant luminescent bacteria to detect the toxicity of environmental pollutants and biological molecules. The bacterial bioluminescence analytical assay has characteristics such as high sensitivity, short-term detection, and easy operation. Meanwhile, due to the development of gene engineering and optical technology, bacterial luciferase as a reporter protein has been successfully expressed in prokaryotic and eukaryotic cells, tissues, and organs of animals. The major applications for bacterial luciferase-based bioluminescence imaging, such as infectious diseases, cancer therapy, and stem cell tracing, are discussed in this review.
- Published
- 2021
3. Different bacterial host-based lux reporter array for fast identification and toxicity indication of multiple metal ions
- Author
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Chunlan Liu, Yuchen Su, Xuemei Jiang, and Weili Wei
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Analyte ,Metal ions in aqueous solution ,02 engineering and technology ,01 natural sciences ,Biochemistry ,Analytical Chemistry ,Plasmid ,Sensor array ,Genes, Reporter ,Limit of Detection ,Bioluminescence ,Promoter Regions, Genetic ,biology ,Bacteria ,Chemistry ,Luminescent bacteria ,010401 analytical chemistry ,Promoter ,021001 nanoscience & nanotechnology ,biology.organism_classification ,0104 chemical sciences ,Spectrometry, Fluorescence ,Genes, Bacterial ,Metals ,0210 nano-technology - Abstract
Although luminescent bacteria-based bioluminescence inhibition assay has been widely used in the toxicity assessment of environmental pollutants, the response of a luminescent bacterium usually lacks specificity to a target analyte. Recently, some specific analyte inductive promoters were fused to the lux genes for the purpose of selective bioluminescent sensing, and suits of specific promoters were fused to lux genes to compose a bioluminescent array sensor for simultaneous identification of multiple analytes. However, specific promoter-based methods still suffer from drawbacks including limited selectivity, slow responding time, expensive to construct different promoters involved plasmids, and laborious to find new promoters. Herein, we proposed a novel strategy to construct a lux reporter array sensor by directly transforming the natural lux genes in different bacterial hosts without the involvement of any specific promoters. Due to the distinct pathways of signal production, the responding time of the current different bacterial host (DBH)-based lux reporter array has nearly an order of magnitude faster than with specific promoter-based methods. The DBH-based lux reporter array was successfully used for simultaneous identification, quantification, and toxicity/bioactivity assessment of multiple metal ions. Obviously, all the chemical synthetic material-based metal ion sensing methods cannot simultaneously achieve analysis and toxicity evaluation. This approach possessed additional advantages of facile construction, easy operation, high selectivity, fast response, and strong adaptability to other analytes. A different bacterial host-based lux reporter array was established for simultaneous analysis and toxicity assessment of multiple metal ions.
- Published
- 2020
4. Luminescent bacteria-based sensing method for methylmercury specific determination
- Author
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Anne Rantala, Marko Virta, Anna-Liisa Välimaa, Mikko Utriainen, Matti Karp, and Nitesh Kaushik
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Luminescence ,Stereochemistry ,chemistry.chemical_element ,Lyases ,Biosensing Techniques ,010501 environmental sciences ,medicine.disease_cause ,01 natural sciences ,Biochemistry ,Analytical Chemistry ,03 medical and health sciences ,chemistry.chemical_compound ,Limit of Detection ,medicine ,Escherichia coli ,Chelation ,Methylmercury ,030304 developmental biology ,0105 earth and related environmental sciences ,Detection limit ,0303 health sciences ,Reporter gene ,Chromatography ,biology ,Bacteria ,Chemistry ,Luminescent bacteria ,Methylmercury Compounds ,biology.organism_classification ,Mercury (element) - Abstract
A bacterial biosensor method for the selective determination of a bioavailable organomercurial compound, methylmercury, is presented. A recombinant luminescent whole-cell bacterial strain responding to total mercury content in samples was used. The bacterial cells were freeze-dried and used as robust, reagent-like compounds, without batch-to-batch variations. In this bacteria-based sensing method, luciferase is used as a reporter, which requires no substrate additions, therefore allowing homogenous, real-time monitoring of the reporter gene expression. A noninducible, constitutively light-producing control bacterial strain was included in parallel for determining the overall cytotoxicity of the samples. The specificity of the total mercury sensor Escherichia coli MC1061 (pmerRBlux) bacterial resistance system toward methylmercury is due to a coexpressed specific enzyme, organomercurial lyase. This enzyme mediates the cleavage of the carbon–mercury bond of methylmercury to yield mercury ions, which induce the reporter genes and produce a self-luminescent cell. The selective analysis of methylmercury with the total mercury strain is achieved by specifically chelating the inorganic mercury species from the sample using an optimized concentration of EDTA as a chelating agent. After the treatment with the chelating agent, a cross-reactivity of 0.2% with ionic mercury was observed at nonphysiological ionic mercury concentrations (100 nM). The assay was optimized to be performed in 3 h but results can already be read after 1 h incubation. Total mercury strain E. coli MC1061 (pmerRBlux) has been shown to be highly sensitive and capable of determining methylmercury at a subnanomolar level in optimized assay conditions with a very high dynamic range of two decades. The limit of detection of 75 ng/l (300 pM) allows measurement of methylmercury even from natural samples.
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- 2011
- Full Text
- View/download PDF
5. Are luminescent bacteria suitable for online detection and monitoring of toxic compounds in drinking water and its sources?
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Shimshon Belkin, Minne B. Heringa, Bram Brouwer, Marjolijn Woutersen, and Annemarie P. van Wezel
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Luminescence ,Water monitoring ,Biosensing Techniques ,Review ,Online Systems ,Biochemistry ,Analytical Chemistry ,Reporter genes ,Water Supply ,Environmental monitoring ,Bioluminescence ,Pollutant ,Bacteria ,Toxicity ,biology ,Chemistry ,Luminescent bacteria ,Contamination ,biology.organism_classification ,Biosensors ,Environmental chemistry ,Bioreporter ,Water quality ,Water Pollutants, Chemical ,Environmental Monitoring - Abstract
Biosensors based on luminescent bacteria may be valuable tools to monitor the chemical quality and safety of surface and drinking water. In this review, an overview is presented of the recombinant strains available that harbour the bacterial luciferase genes luxCDABE, and which may be used in an online biosensor for water quality monitoring. Many bacterial strains have been described for the detection of a broad range of toxicity parameters, including DNA damage, protein damage, membrane damage, oxidative stress, organic pollutants, and heavy metals. Most lux strains have sensitivities with detection limits ranging from milligrams per litre to micrograms per litre, usually with higher sensitivities in compound-specific strains. Although the sensitivity of lux strains can be enhanced by various molecular manipulations, most reported detection thresholds are still too high to detect levels of individual contaminants as they occur nowadays in European drinking waters. However, lux strains sensing specific toxic effects have the advantage of being able to respond to mixtures of contaminants inducing the same effect, and thus could be used as a sensor for the sum effect, including the effect of compounds that are as yet not identified by chemical analysis. An evaluation of the suitability of lux strains for monitoring surface and drinking water is therefore provided.
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- 2010
- Full Text
- View/download PDF
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