Team:Imperial College London/Results

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The CatO2ase protein, except as an ideal output signal for our engineered bacterial detector it can also serve as a great reporter gene. Its characteristics can be exploited in a wide range of fields across biological sciences field, so it was one of the team's first candidates for further characterization. Qualitative and quantitative data were gathered and presented. All further tests involving XylE transformed cells were quantified by measuring absorbonce at 380nm wavelenth.
The CatO2ase protein, except as an ideal output signal for our engineered bacterial detector it can also serve as a great reporter gene. Its characteristics can be exploited in a wide range of fields across biological sciences field, so it was one of the team's first candidates for further characterization. Qualitative and quantitative data were gathered and presented. All further tests involving XylE transformed cells were quantified by measuring absorbonce at 380nm wavelenth.
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[[Image:CS1.JPG|thumb|right|200px]]
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[[Image:CS1.JPG|right|200px]]
Catechol ,the initial substrate of CatO2las enzyme, is colourless. However within seconds of its addition the colonies/liquid cultures of XylE expressing cells become yellow, indicating production of product which absorbs light in the region visible spectrum. An spectrophotometric assay was prepared, where the spectra of two cultures of E.coli (one XylE gene transformed and the other not)were compared on addition of 0.1mM Catechol substrate. The spectra (figure 1) showed that in XylE transformed cells, a broad peak appears at about '''380nm'''. The absorbance of the particular wavelengths of light by the product of the enzymatic reaction 2-hydroxymuconic semialdehyde, is what causes the yellow output.
Catechol ,the initial substrate of CatO2las enzyme, is colourless. However within seconds of its addition the colonies/liquid cultures of XylE expressing cells become yellow, indicating production of product which absorbs light in the region visible spectrum. An spectrophotometric assay was prepared, where the spectra of two cultures of E.coli (one XylE gene transformed and the other not)were compared on addition of 0.1mM Catechol substrate. The spectra (figure 1) showed that in XylE transformed cells, a broad peak appears at about '''380nm'''. The absorbance of the particular wavelengths of light by the product of the enzymatic reaction 2-hydroxymuconic semialdehyde, is what causes the yellow output.
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[[Image:Spectra of Xyle cells.jpg|thumb|center|500px|Figure 1: Spectra of cultures of cells -ve and +ve on XylE gene. Note the broad peak in the spectra of Xyle transformed cells, which is centered around 380nm.]]
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[[Image:Spectra of Xyle cells.jpg|center|500px| Spectra of cultures of cells -ve and +ve on XylE gene. Note the broad peak in the spectra of Xyle transformed cells, which is centered around 380nm.]]
==References==
==References==
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==Experiment 2 | The threshold value of catechol assay==
==Experiment 2 | The threshold value of catechol assay==
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[[Image:PA190014.JPG|thumb|right|200px|Threshold value experiment was conducted on a 96 well plates. Yellow wells are the positive tests, LB color and M9 color mediums wells are the negative tests. ]]
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[[Image:PA190014.JPG|right|200px|Threshold value experiment was conducted on a 96 well plates. Yellow wells are the positive tests, LB color and M9 color mediums wells are the negative tests. ]]
Addition of catechol to a a culture of cells constitutively expressing C(2,3)0 enzyme results  into production of yellow colonies on plate or yellow liquid cultures if E.coli is grown in liquid medium. In a lab where a spectrophotometer is readily available anyone can accurately quantify production of even the smallest quantity of the yellow 2-hydroxymuconic semialdehyde product. However, as our biological detector is intended for field use where sophisticated spectroscopic equipment is not available, it was obvious that we needed to establish the threshold value at which a positive result (yellow color) would be detectable by the naked eye.
Addition of catechol to a a culture of cells constitutively expressing C(2,3)0 enzyme results  into production of yellow colonies on plate or yellow liquid cultures if E.coli is grown in liquid medium. In a lab where a spectrophotometer is readily available anyone can accurately quantify production of even the smallest quantity of the yellow 2-hydroxymuconic semialdehyde product. However, as our biological detector is intended for field use where sophisticated spectroscopic equipment is not available, it was obvious that we needed to establish the threshold value at which a positive result (yellow color) would be detectable by the naked eye.
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==Experiment 3 | Characterizing kinetic parameters of C23O in whole cells==
==Experiment 3 | Characterizing kinetic parameters of C23O in whole cells==
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[[Image:Xyle reaction pic.jpg|thumb|left|300px|Catechol converted to 2-hydroxymuconic semialdehyde by C(2,3)lase]]
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[[Image:Xyle reaction pic.jpg|left|300px|Catechol converted to 2-hydroxymuconic semialdehyde by C(2,3)lase]]
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[[Image:Catechol assay graph (0.2-1).jpg|thumb|right|300px|The first catechol assay data analysis. The assay involved addition of catechol concentrations of 0.2, 0.4, 0,6 0.8 and 1mM to 0.5 O.D. of XylE transformed E.coli cell cultures. The XylE gene was under the influence of J23101 promoter.]]
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[[Image:Catechol assay graph (0.2-1).jpg|right|300px|The first catechol assay data analysis. The assay involved addition of catechol concentrations of 0.2, 0.4, 0,6 0.8 and 1mM to 0.5 O.D. of XylE transformed E.coli cell cultures. The XylE gene was under the influence of J23101 promoter.]]
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[[Image:IC_Assay_3_sept.jpg|thumb|left|300px|Catechol assay on XylE-trasformed cells in a 96-well plate (A to H decreasing cell concentration, 1-10 decreasing catechol concentration, column 11 and 12 negative and control)]]
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[[Image:IC_Assay_3_sept.jpg|left|300px|Catechol assay on XylE-trasformed cells in a 96-well plate (A to H decreasing cell concentration, 1-10 decreasing catechol concentration, column 11 and 12 negative and control)]]
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Despite these limitations some useful data were extracted out of these assays. More specifically we acquired data that delineate the course of the reaction in terms of yellow product production over time at various catechol concentrations. The results of one of these assays is presented in the figure below. In order to extract data that will allow characterization of the kinetic parameters of catechol dioxygenase enzyme our lab team proposes purification of the protein from cell lysate, '''several fold dilution''', and in vitro characterization.
Despite these limitations some useful data were extracted out of these assays. More specifically we acquired data that delineate the course of the reaction in terms of yellow product production over time at various catechol concentrations. The results of one of these assays is presented in the figure below. In order to extract data that will allow characterization of the kinetic parameters of catechol dioxygenase enzyme our lab team proposes purification of the protein from cell lysate, '''several fold dilution''', and in vitro characterization.
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[[Image:HMS prod. over time curve for xylE.jpg|thumb|400px|center|Graph shows production of HMS (yellow product) over time after catechol addition at time 0 minutes. Different curves represent different catechol concentration added to the cell cultures.]]
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[[Image:HMS prod. over time curve for xylE.jpg|400px|center|Graph shows production of HMS (yellow product) over time after catechol addition at time 0 minutes. Different curves represent different catechol concentration added to the cell cultures.]]
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==Experiment 4==
==Experiment 4==
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[[Image:IC Module3.JPG|thumb|center|300px|The GFP-XylE gene construct]]
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[[Image:IC Module3.JPG|center|300px|The GFP-XylE gene construct]]
In paper blabla.... In our construct, GFP was added to the N-terminal of C(2,3) monomer. C(2,3) enzyme is a homotetramer were all 4 subunits are required for its activity. We hoped that by adding GFP at the N-terminus of the catechol dioxygenase enzyme, we would block tetramerization of the enzyme, thus render it inactive. This modification is important as it makes our system inducible. The cleavage of the GFP by TEV protease, on arrival of input signal, means that Catechol dioxygenase becomes active only when the parasite is detected.  
In paper blabla.... In our construct, GFP was added to the N-terminal of C(2,3) monomer. C(2,3) enzyme is a homotetramer were all 4 subunits are required for its activity. We hoped that by adding GFP at the N-terminus of the catechol dioxygenase enzyme, we would block tetramerization of the enzyme, thus render it inactive. This modification is important as it makes our system inducible. The cleavage of the GFP by TEV protease, on arrival of input signal, means that Catechol dioxygenase becomes active only when the parasite is detected.  
To investigate this, an experiment was designed where catechol was added to XylE transformed E.coli. The velocity of the reaction was monitored at various initial catechol concentrations. The experimental set up is essentially the same as described above for determining the kinetics of C(2,3)O enzyme. The only difference is that E.coli cells used are the ones transformed with GFP-XylE gene construct instead of XylE gene.
To investigate this, an experiment was designed where catechol was added to XylE transformed E.coli. The velocity of the reaction was monitored at various initial catechol concentrations. The experimental set up is essentially the same as described above for determining the kinetics of C(2,3)O enzyme. The only difference is that E.coli cells used are the ones transformed with GFP-XylE gene construct instead of XylE gene.
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Revision as of 14:31, 24 October 2010

Results
C230

The XylE gene, originating from the TOL plasmid of Pseudomonas putida, was the choice for the output signal mediator of our system. The system is based on catechol 2,3-dioxygenase enzyme. Colonies of cells that express xylE gene product become yellow within seconds after selection plates are sprayed with catechol, a colorless substrate, that is converted by CatO2ase to the yellow product, 2-hydroxymuconic semialdehyde. This reporter system is ideal for our project as it has very fast kinetics, gives a visual output by naked eye and the substrate used is very cheap.

Characterization of C230

Experiment 1 | Determining optimum absorption wavelength for catechol assays

The CatO2ase protein, except as an ideal output signal for our engineered bacterial detector it can also serve as a great reporter gene. Its characteristics can be exploited in a wide range of fields across biological sciences field, so it was one of the team's first candidates for further characterization. Qualitative and quantitative data were gathered and presented. All further tests involving XylE transformed cells were quantified by measuring absorbonce at 380nm wavelenth.

CS1.JPG

Catechol ,the initial substrate of CatO2las enzyme, is colourless. However within seconds of its addition the colonies/liquid cultures of XylE expressing cells become yellow, indicating production of product which absorbs light in the region visible spectrum. An spectrophotometric assay was prepared, where the spectra of two cultures of E.coli (one XylE gene transformed and the other not)were compared on addition of 0.1mM Catechol substrate. The spectra (figure 1) showed that in XylE transformed cells, a broad peak appears at about 380nm. The absorbance of the particular wavelengths of light by the product of the enzymatic reaction 2-hydroxymuconic semialdehyde, is what causes the yellow output.



Spectra of cultures of cells -ve and +ve on XylE gene. Note the broad peak in the spectra of Xyle transformed cells, which is centered around 380nm.

References

  • Chromogenic identification of genetic regulatory signals in Bacillus subtilis based on expression of a cloned Pseudomonas gene. Zukowski, M.M., Gaffney, D.F., Speck, D., Kauffmann, M., Findeli, A., Wisecup, A., Lecocq, J.P. Proc. Natl. Acad. Sci. U.S.A. (1983)

Experiment 2 | The threshold value of catechol assay

Threshold value experiment was conducted on a 96 well plates. Yellow wells are the positive tests, LB color and M9 color mediums wells are the negative tests.

Addition of catechol to a a culture of cells constitutively expressing C(2,3)0 enzyme results into production of yellow colonies on plate or yellow liquid cultures if E.coli is grown in liquid medium. In a lab where a spectrophotometer is readily available anyone can accurately quantify production of even the smallest quantity of the yellow 2-hydroxymuconic semialdehyde product. However, as our biological detector is intended for field use where sophisticated spectroscopic equipment is not available, it was obvious that we needed to establish the threshold value at which a positive result (yellow color) would be detectable by the naked eye.

The set up of this experiment involved preparation of XylE expressing E.coli cultures at an O.D. of 0.5 in LB and M9 medium. Then a gradient of catechol concentrations was prepared and added to the cell cultures. A group of 5 individuals, but not the lab member preparing the test samples, were given the test cultures and asked where on the gradient they were not able anymore to see the yellow color. The 2 concentrations where the transition from yellow to colorless occurred were identified and a second gradient of catechol concentrations was prepared. In this second gradient the gap between the 2 concentration was analysed. The highest catechol concentration was the least yellow from the first part of the experiment, while the lowest catechol concentration was the first "colourless" concentration from the first part of the experiment. Again the group of 5 testers identified the transition concentrations from yellow to colorless.

The threshold concentration of catechol needed for a person to identify a yellow positive test was found to be 30-40μM.

Experiment 3 | Characterizing kinetic parameters of C23O in whole cells

Catechol converted to 2-hydroxymuconic semialdehyde by C(2,3)lase


In our Parasight project the XylE gene product, C(2,3)lase enzyme, is the means by which an output signal is generated. If the parasite is present is the water supply, the bacterial system is activated by an input signal which produces the yellow color, the positive output signal. Test assays in the lab on colonies of cells expressing XylE gene, become yellow only seconds after addition of catechol (100mM). From this it was realized our group that the kinetics of the C(2,3)lase enzyme are such that make it an attractive candidate as a reporter enzyme. So, we decided that further characterization of the kinetics of the C(2,3)lase might help identify a really efficient reporter for research centers.



The first catechol assay data analysis. The assay involved addition of catechol concentrations of 0.2, 0.4, 0,6 0.8 and 1mM to 0.5 O.D. of XylE transformed E.coli cell cultures. The XylE gene was under the influence of J23101 promoter.


In this experiment we investigated how the velocity of the reaction (catechol converted to 2-hydroxymuconic semialdehyde by C(2,3)lase) varies with increasing initial concentrations of catechol, the substrate. Overnight cultures of XylE transformed E.coli were plated on a 96 wells plate at an optical density (O.D.) of 0.5 units of absorbance. (The optimum initial O.D. of cells was determined in a previous experiment. This O.D. may vary across different labs as the sensitivity of the spectrophotometer/plate reader is a factor). Catechol concentrations ranging from 0.1-1mM were made from 100mM stock solution and added to the cells of the 96-well plate. The velocity of the reaction was monitored using the plate reader spectrophotometer as the reaction is directly proportional to the production of yellow color. The yellow output was measured at 380nm wavelength, while cell density at 600nm. The XylE gene expression was under the influence of J23101 promoter.



Catechol assay on XylE-trasformed cells in a 96-well plate (A to H decreasing cell concentration, 1-10 decreasing catechol concentration, column 11 and 12 negative and control)




The results of the experiment confirmed previous hints of the huge catalytic turnover rate of the C(2,3)0 enzyme. The graph of the right illustrates production of yellow product per min. The slope at the initial stages of the reaction (first minutes) would represent the rate of the reaction, that is the initial Velocity. By calculating initial velocities of the reaction at different substrate concentrations, one can plot a Michaelis-Menten curve to extract kinetic parameters such as Vmax, Km and catalytic turnover number.







Several attempts were made to determine these parameters on whole cells. Unfortunately due to the actual nature of the enzyme, velocity of reaction and technical limitations of lab equipement this has been proven impossible. To start with one of the limitation was that the color output and the extinction coefficient of the yellow product is so large, that the system saturates within the first minutes after catechol addition to cell cultures. The spectrophotometer and plate reader reaches its detection maximum reading value from the start of the reaction. Also due to the high velocity of the reaction, in the time frame of about 10 seconds that are needed to load the plate into the plate reader after catechol addition, the reaction has already proceeded too far. So initial velocity measurements of the reactions needed for construction of Michaelis-Menten curve are inaccurate. These problem could be overcome by decreasing total enzyme concentration. In whole cell cultures this would be possible by decreasing cell density in each well as each cell contain an average C(2,3)O enzyme concentration. However, previous experiments showed that cell cultures with optical densities lower than 0.5 O.D. introduce serious perturbations in the readings of the spectrophotometer and plate reader detectors.

Despite these limitations some useful data were extracted out of these assays. More specifically we acquired data that delineate the course of the reaction in terms of yellow product production over time at various catechol concentrations. The results of one of these assays is presented in the figure below. In order to extract data that will allow characterization of the kinetic parameters of catechol dioxygenase enzyme our lab team proposes purification of the protein from cell lysate, several fold dilution, and in vitro characterization.

Graph shows production of HMS (yellow product) over time after catechol addition at time 0 minutes. Different curves represent different catechol concentration added to the cell cultures.

Experiment 4

The GFP-XylE gene construct

In paper blabla.... In our construct, GFP was added to the N-terminal of C(2,3) monomer. C(2,3) enzyme is a homotetramer were all 4 subunits are required for its activity. We hoped that by adding GFP at the N-terminus of the catechol dioxygenase enzyme, we would block tetramerization of the enzyme, thus render it inactive. This modification is important as it makes our system inducible. The cleavage of the GFP by TEV protease, on arrival of input signal, means that Catechol dioxygenase becomes active only when the parasite is detected.

To investigate this, an experiment was designed where catechol was added to XylE transformed E.coli. The velocity of the reaction was monitored at various initial catechol concentrations. The experimental set up is essentially the same as described above for determining the kinetics of C(2,3)O enzyme. The only difference is that E.coli cells used are the ones transformed with GFP-XylE gene construct instead of XylE gene.