Identification of Yersinia enterocolitica using a random genomic DNA microarray chip.

AIMS: To fabricate a DNA chip containing random fragments of genomic DNA of Yersinia enterocolitica and to verify its diagnostic ability. METHODS AND RESULTS: A DNA microarray chip was fabricated using randomly fragmented DNA of Y. enterocolitica. Chips were hybridized with genomic DNA extracted from other Y. enterocolitica strains, other Yersinia spp. and bacteria in different genera. Genomic DNA extracted from Y. enterocolitica showed a significantly higher hybridization rate compared with DNA of other Yersinia spp. or bacterial genera, thereby distinguishing it from other bacteria. CONCLUSIONS: A DNA chip containing randomly fragmented genomic DNA from Y. enterocolitica can detect Y. enterocolitica and clearly distinguish it from other Yersinia spp. and bacteria in different genera. SIGNIFICANCE AND IMPACT OF THE STUDY: A microarray chip containing randomly fragmented genomic DNA of Y. enterocolitica was fabricated without sequence information, and its diagnostic ability to identify Y. enterocolitica was verified.

Application of a multi-channel system for continuous monitoring and an early warning system.

A multi-channel continuous toxicity monitoring system developed in our laboratory, based on two-stage mini-bioreactors, was successfully implemented in the form of computer-based data acquisition. The multi-channel system consists of a series of a two-stage minibioreactor systems connected by a fiber optic probe to a luminometer, and uses genetically engineered bioluminescent bacteria for the detection of the potential toxicity from the soluble chemicals. This system can be stably and continuously operated due to the separation of the culture reactor from the test reactor and accomplish easy and long-term monitoring without system shut down by abrupt inflows of severe polluting chemicals. Four different recombinant bioluminescent bacteria were used in different channels so that the modes of the samples toxicities can be reasonably identified and evaluated based upon the response signature of each channel. The bioluminescent signatures were delivered from four channels by switching one at once, while the data is automatically logged to an IBM compatible computer. We also achieved the enhancement of the system through the manipulation of the dilution rate and the use of thermo-lux fusion strains. Finally, this system is now being implemented to a drinking water reservoir and river for remote sensing as an early warning system.

Analysis of foreign protein overproduction in recombinant CHO cells. Effect of growth kinetics and cell cycle traverse.

Intracellular foreign protein (beta-galactosidase) expression in recombinant CHO cell lines in continuous culture was analyzed by developing a mathematical model that includes the effects of metabolic burden and cell cycle dependence of intracellular foreign protein expression. This combined growth kinetic and cell cycle model, assuming S- or G1-phase-dependent expression, was stimulated to predict productivity on a single-cell and culture-volume basis in continuous cultures. In the case of S-phase-dependent expression, the intracellular foreign protein level increases monotonically, but in the case of G1-phase-dependent expression it decreases monotonically with increasing dilution rate. Also, the trends of foreign protein concentration in the culture volume differ significantly between S- and G1-dependent expression kinetics. Thus, the cell cycle dependency of foreign protein expression should be included in process optimization concepts and operating strategies of continuous bioreactors.

A multi-channel continuous toxicity monitoring system using recombinant bioluminescent bacteria for classification of toxicity.

A multi-channel system for continuous toxicity monitoring and classification of toxicity was developed based upon a previously developed two-stage minibioreactor system. The multi-channel system consists of a series of a two-stage minibioreactor systems connected by a fiber optic probe to a luminometer. Each channel was used for cultivating different recombinant bacterial strains, such as TV1061 (grpE::luxCDABE), DPD2794 (recA::luxCDABE), and DPD2540 (fabA::luxCDABE), which are induced by protein-, DNA-, and cell membrane damaging-agents, respectively. GC2 (lac::luxCDABE) is a bacterium expressing bioluminescence constitutively, which shows a reduction in its light level as cellular toxicity increases. Artificial wastewater samples were made by combining toxic chemicals, including Mitomycin C (a representative DNA damaging agent), phenol (a representative protein damaging agent), and cerulenin (a representative cell membrane damaging agent), and injecting this sample into each channel in order to simulate the detection of toxicity for mixed chemical samples. Each channel showed a specific bioluminescent response due to the toxic chemicals contained in the sample wastewater, while GC2 showed a general response to cellular toxicity. By using this multi-channel continuous toxicity monitoring system, classification of toxicity in field samples was found to be possible.

Soil biosensor for the detection of PAH toxicity using an immobilized recombinant bacterium and a biosurfactant.

A biosensor for detecting the toxicity of polycylic aromatic hydrocarbons (PAHs) contaminated soil has been successfully constructed using an immobilized recombinant bioluminescent bacterium, GC2 (lac::luxCDABE), which constitutively produces bioluminescence. The biosurfactant, rhamnolipids, was used to extract a model PAH, phenanthrene, and was found to enhance the bioavailability of phenanthrene via an increase in its rate of mass transfer from sorbed soil to the aqueous phase. The monitoring of phenanthrene toxicity was achieved through the measurement of the decrease in bioluminescence when a sample extracted with the biosurfactant was injected into the minibioreactor. The concentrations of phenanthrene in the aqueous phase were found to correlate well with the corresponding toxicity data obtained by using this toxicity biosensor. In addition, it was also found that the addition of glass beads to the agar media enhanced the stability of the immobilized cells. This biosensor system using a biosurfactant may be applied as an in-situ biosensor to detect the toxicity of hydrophobic contaminants in soils and for performance evaluation of PAH degradation in soils.

A two-stage minibioreactor system for continuous toxicity monitoring.

A two-stage minibioreactor system was successfully developed for continuous toxicity monitoring. This system consists of two minibioreactors in series. Recombinant Escherichia coli DPD2794 containing a RecA::luxCDABE fusion as a model strain was utilized to monitor environmental insults to DNA, with mitomycin C as a model toxicant. Pulse type exposures were used to evaluate the system's reproducibility and reliability. Step inputs of mitomycin C have been adopted to show the system's stability. The system's ability to monitor the possible upsets or accidental discharges of toxic chemicals was also evaluated with these step insults. All the data demonstrated that this two-stage minibioreactor system using recombinant bacteria containing stress promoters fused with lux genes is quite appropriate for continuous toxicity monitoring. Long-term operation and minimized media-usage have been investigated. Thus application to many different areas, including an early warning system of wastewater biotreatment plant upsets and the monitoring and tracking of accidental spills, discharges or failures in plant operation are plausible.

A biosensor for the detection of gas toxicity using a recombinant bioluminescent bacterium.

A whole-cell biosensor was developed for the detection of gas toxicity using a recombinant bioluminescent Escherichia coli harboring a lac::luxCDABE fusion. Immobilization of the cells within LB agar has been done to maintain the activity of the microorganisms and to detect the toxicity of chemicals through the direct contact with gas. Benzene, known as a representative volatile organic compound, was chosen as a sample toxic gas to evaluate the performance of this biosensor based on the bioluminescent response. This biosensor showed a dose-dependent response, and was found to be reproducible. The immobilizing matrices of this biosensor were stored at 4 degrees C and were maintained for at least a month without any noticeable change in its activity. The optimal temperature for sensing was 37 degrees C. A small size of this sensor kit has been successfully fabricated, and found to be applicable as a disposable and portable biosensor to monitor the atmospheric environment of a workplace in which high concentrations of toxic gases could be discharged.

Some observations in freeze-drying of recombinant bioluminescent Escherichia coli for toxicity monitoring.

A recombinant bioluminescent bacteria, containing a fabA::luxCDABE fusion gene, has been used to characterize freeze-drying methods, which may be conveniently used as a tool for the development of a portable biosensor. Through residual water, viability, biosensing activity and scanning electron microscopy analyses, the characteristics that four cryoprotectants, trehalose, sucrose, sorbitol, and mannitol, conferred on freeze-dried samples were elucidated, including the morphology, water content and activity of the cells. It was found that trehalose showed the best freeze-drying efficiency among the tested cryoprotectants and it might have a specific capacity limitation in protection of the cells during the freeze step. Humidity might result in damage to the cells, according to the viability, when exposed to air during storage, while the water remaining post freeze-drying showed good correlation with damage to the freeze-dried cells when under air-tight storage conditions. The results with other recombinant bioluminescent bacteria indicated that these findings might be general features of the freeze-drying processes.

Dynamic characterization of recombinant Chinese hamster ovary cells containing an inducible c-fos promoter GFP expression system as a biomarker.

An inducible reporter gene system for Chinese Hamster Ovary (CHO-DHFR(-)) cells has been developed and characterized with respect to its dynamic properties. The reporter gene system consists of the human c-fos promoter and variants of the green fluorescence protein (GFP), either EGFP with enhanced fluorescence or its destabilized form d2EGFP. The expression of wild-type EGFP or its destabilized form was studied in CHO-DHFR(-) cells in response to serum addition or deprivation. It was shown that serum-induced c-fos promoter mediated EGFP expression was considerably higher than expression from the human CMV promoter, a strong, constitutive promoter preferentially used for high-level expression in CHO cells. However, EGFP was less suitable for studying expression dynamics than d2EGFP due to the protein's long half-life in mammalian cells. The use of d2EGFP resulted in a significant improvement in the dynamic characteristics of the biomarker, particularly when the recombinant cells were selected for high-level GFP expression by subcloning or fluorescence activated cell/sorting (FACS). GFP expression in different subclones and cell populations sorted by FACS was characterized with respect to its dynamic responses in the presence or absence of serum in the culture medium. Significant differences in the GFP expression dynamics were observed for the isolated cell populations. The experimental results indicate that cells with high-level GFP expression also have a faster dynamic response and are thus, desirable for practical application of the reporter gene system e.g. in toxicity monitoring.

Growth and induction kinetics of inducible and autoinducible expression of heterologous protein in suspension cultures of recombinant mouse L cell lines.

Mouse Ltk- cells were transfected with four different plasmids for autoinducible and highly-inducible expression of the bacterial lacZ gene and cultivated in suspension. Two selection genes, thymidine kinase (tk) and neomycin resistance (neor), were used to select the clones in both cell lines. The resulting two cell lines, designated M4 and R2, differ in that the inducible MMTV promoter from mouse mammary tumor virus (MMTV) controls glucocorticoid receptor (gr) gene and lacZ gene expression in the M4 cell line ("autoinducible"), while the constitutive rous sarcoma virus (RSV) promoter controls gr gene expression and the MMTV promoter controls lacZ gene expression in the R2 cell line ("highly-inducible"). Both cell lines were stable with respect to reproducibility of growth rate in spinner flasks and inducibility of beta-galactosidase expression. The exponential growth rate of R2 cells was slower than that of M4 cells before induction because the R2 cell line continuously expressed gr genes under the constitutive RSV promoter, and the percent reduction of exponential growth rate mainly caused by gr gene expression was about 20%. The inducibility of the M4 cell line was greater than that of the R2 cell line because in the M4 cell line MMTV promoter controlled gr and lacZ gene expression autoinducibly. Maximum induction of the M4 cell line occurred after induction with the hormone dexamethasone (Dex) at 10(-7) M, and the final beta-galactosidase content increased 400-fold after induction. The optimum conditions for inducer concentration and induction time were determined, and the highest production of beta-galactosidase occurred when Dex was added after the cell concentration had reached its maximum in batch culture. Dex (10(-9) M) is a critical inducer concentration in view of inducibility between M4 and R2 cell lines. The inducibility of R2 cell line is higher than that of the M4 cell line from 0 to 10(-9) M Dex, but the inducibility of M4 was higher than that of the R2 cell line at Dex concentrations of more than 10(-9) M.

A miniature bioreactor for sensing toxicity using recombinant bioluminescent Escherichia coli cells.

A miniature bioreactor was fabricated as a contactor between biosensing cells and toxic materials. This miniature bioreactor (58 mL working volume) showed performance similar to that of a conventional bioreactor, as well as the advantages of easy installation, facile operation, and small medium requirements during long-term continuous operation. A performance evaluation measured the response to ethanol in continuous operation by using a recombinant bioluminescent Escherichia coli strain. Continuous cultures were repeatedly induced by the ethanol challenge. Steady-state cell concentrations (OD) were found to be decreased, the induced specific bioluminescence (SBL) peak value was found to be increased, and the peak response time, which is the time constant of this continuous monitoring system, was found to be decreased with increasing dilution rate. Finally on- and off-line bioluminescence monitoring was shown to be reliable, suggesting that this system is suitable for applications such as monitoring the influent and effluent streams of waste water biotreatment plants.

Characterization of the stress response of a bioluminescent biological sensor in batch and continuous cultures.

The effects of temperature, growth stage, and inducer (ethanol) concentration on the kinetics and magnitude of the stress response were investigated by using an Escherichia coli strain with the grpE heat shock promoter fused to the Vibrio fischeri lux genes. When stressed, the cells responded by changing the level of specific light emission, which was measured both on- and off-line. These measurements were used to characterize and optimize the sensitivity of the construct by determining the conditions at which the culture exhibited maximum specific bioluminescence and minimum response time to ethanol induction in batch cultivation. The results of the batch study were then applied to continuous cultivation, and the effect of dilution rate was determined. These results are of considerable interest in the development of an on-line biological sensor system for the detection and toxicity assessment of chemical pollutants.

Distinct responses of a recA::luxCDABE Escherichia coli strain to direct and indirect DNA damaging agents.

The recombinant Escherichia coli strain DPD2794 containing a recA::luxCDABE fusion is used to detect genotoxicity of various chemicals. Genotoxic agents were previously categorized into two groups, Direct DNA Damaging (DDD) agents and Indirect DNA Damaging (IDD) agents; these two groups have been distinguished with this strain. Minimum detectable concentrations of the DDD agents were about one to five orders of magnitude lower than those of the IDD agents. The response patterns of this strain to DDD agents differed from those to IDD agents in terms of kinetics and the forms of the dose-dependent response.

Bacterial bioluminescent emission from recombinant Escherichia coli harboring a recA::luxCDABE fusion.

This paper describes the quantitative evaluation of a bioluminescence assay for DNA damaging agents with respect to the linearity, sensitivity, specificity and dependence on the cell culture status. A recombinant bacterium, DPD2794, harboring a plasmid with a recA promoter fused to the luxCDABE operon, showed a very sensitive response to DNA-damaging stress. DPD2794 was found to show no noticeable response to non-mutagenic agents, i.e. phenol, except for some false responses appearing soon after injection. DPD2794 also showed a highly sensitive response to Mitomycin C, which was found to be a growth-stage-dependent response, not a growth-rate-dependent response. In addition, the relationship between the bioluminescence emitted in vivo, luciferase activity measured in vitro, and the amount of Lux proteins expressed was determined. The intensity of the bioluminescence emitted was found to be proportional to the luciferase activity in vitro, while the bioluminescence also seems to be correlated with the level of Lux proteins expressed in these Escherichia coli cells, up to 230 min post induction.

Phenolic toxicity--detection and classification through the use of a recombinant bioluminescent Escherichia coli.

A genetically engineered Escherichia coli strain, DPD2540, containing a fabA::luxCDABE fusion that gives a bioluminescent output when membrane fatty acids are limited was used to determine the extent to which phenolics result in the limitation of membrane fatty acids. Tested phenolics were found to be classifiable into two groups according to the bioluminescent response they elicited and their pKa. A dose-dependent bioluminescent response, due to fatty acid limitation, was seen for phenolics with pKa values greater than seven, which exist mainly in the protonated form (HA), while no significant bioluminescent response was seen, compared with the control, for phenolics with pKa values lower than seven, which exist almost entirely as A-. A newly modified distribution model for phenolic compounds in the cellular membrane is proposed and used to predict the bioluminescent response induced by group I phenolics and the cellular toxicity for both groups. The [HA]*, obtained with this model, shows good correlation with the various bioluminescent responses produced by group I phenolics. It was also found that the distribution ratio between the medium and the cell membrane, K1, calculated as well using the proposed model, is a good representative parameter for the cellular toxicity of the phenolic compounds according to their substituted groups when compared with the conventional method of using the octanol-water partition coefficient, log Kow. As a new parameter, the critical concentration was also shown to be a good representative of the cellular toxicity for group I phenolics to the Escherichia coli cells.

Monitoring and classification of toxicity using recombinant bioluminescent bacteria.

Recombinant bioluminescent biosensing cells were used to detect and classify toxicity caused by various chemicals in water environments. Classification of the toxicity was realized based upon the chemicals' actions of toxicity by using DNA-, oxidative- and membrane-damage sensitive strains. Tested samples contained a single chemical or mixture of chemicals in media, wastewater, or river water. Finally, it is suggested that this method for classification of toxic chemicals in wastewater or other aqueous systems may be adopted for primary screening steps of the samples and can give useful information about the samples' characteristics.

Application of recombinant fluorescent mammalian cells as a toxicity biosensor.

With respect to developing a more sensitive biosensor, a recombinant fluorescent Chinese Hamster Ovary cell line was used for the monitoring of various toxicants. Both cell lines, EFC-500 and KFC-A10, were able to detect toxicants sensitively. They were characterized with mitomycin C and gamma-ray as genotoxicants and bisphenol A, nonylphenol, ziram and methyl bromide as possible and known EDCs. When compared to each other, the response of KFC-A10 was generally more informative and sensitive. Compared to typical bacterial biosensor systems, these cell lines offered a sensitivity of 2- to 50-fold greater for the tested chemicals. Based on these results, the use of mammalian cells offers a sensitive biosensor system that is not only fast, cheap and reproducible but also capable of monitoring the endocrine-like characteristics of environmental toxicants.

Enhanced degradation and toxicity reduction of dihexyl phthalate by Fusarium oxysporum f. sp. pisi cutinase.

AIMS: This research aims to investigate the efficiency of two lipolytic enzymes--fungal cutinase and yeast esterase--upon the biodegradation of dihexyl phthalate (DHP). METHOD AND RESULTS: During the enzymatic degradation of DHP dissolved in methanol, several degradation products were detected and their time-course changes were monitored using GC/MS. The DHP-degradation rate of cutinase was surprisingly high; i.e. almost 70% of the initial DHP (500 mg l(-1)) was decomposed within 4.5 h. Although the same amount of esterase was employed, more than 85% of the DHP remained after 3 days. Almost all the DHP was converted by cutinase into 1,3-isobenzofurandione (IBF), whereas hexyl methyl phthalate and IBF were abundantly produced by esterase. In addition, the toxicities of the DHP-degraded products by esterase were evaluated using various recombinant bioluminescent bacteria, which caused oxidative and protein damage, whereas the hydrolysis products from cutinase never caused any cellular damage in the methanol-containing reaction system. CONCLUSIONS: Cutinase starts to act as a DHP-degrader much earlier and faster than esterase, with high stability in ester-hydrolytic activity, therefore a plausible approach to the practical application of cutinase for DHP degradation in the DHP-contaminated environments may be possible. SIGNIFICANCE AND IMPACT OF THE STUDY: This study describes the enhanced degradation and detoxification of DHP using Fusarium oxysporum f. sp. pisi cutinase.

An Escherichia coli biosensor capable of detecting both genotoxic and oxidative damage.

A two-plasmid dual reporter Escherichia coli biosensor was developed using the genes for bacterial bioluminescence and a mutant of the green fluorescent protein, GFPuv4. To achieve this, the two plasmids, which were derivatives of pBR322 and pACYC184, had compatible origins of replication and different antibiotic selection markers: ampicillin and tetracycline. The parent strains DK1 and ACRG43, each carrying a single plasmid with one of the fusion genes (strain DK1 harboring a fusion of the katG promoter to the lux operon while in ACRG43, the recA promoter was fused with the GFP gene), were responsive to oxidative and DNA damage, respectively, resulting in higher bioluminescence or fluorescence under the relevant toxic conditions. The responses of the dual sensor strain, DUAL22, to various toxicants, e.g., mitomycin C, N-methyl-N-nitro--nitrosoguanidine, hydrogen peroxide and cadmium chloride, were characterized and compared with the responses of the parent strains to the same chemicals. Finally, several chemical mixtures that cause various stress responses were tested to demonstrate the ability of this biosensor to detect specific stress responses within a multiple toxicity environment.

Construction of a sodA::luxCDABE fusion Escherichia coli: comparison with a katG fusion strain through their responses to oxidative stresses.

A recombinant bioluminescent Escherichia coli strain, EBHJ, (sodA::luxCDABE), containing the promoter for the manganese superoxide dismutase ( sodA) gene fused to the Vibrio fischeri luxCDABE operon, was successfully constructed and characterized. Redox-cycling agents, such as paraquat and chromium, strongly induced a sodA- regulated response in dose-dependent manners, resulting in an increase of the bioluminescence. In a comparison with an existing oxidative stress responsive strain, DPD2511 (katG::luxCDABE), which is sensitive to H(2)O(2), the mechanism of chemicals that cause oxidative damage was elucidated via the key transcriptional factors involved in induction of the sodA and katG promoters, i.e. SoxRS and OxyR, respectively. It was found that responses from the katG- and sodA-based strains were significantly different dependent upon the chemicals being tested. Therefore, EBHJ, alone or in parallel with DPD2511, can be used to characterize and monitor chemicals that cause oxidative damage.