Arsenic Biosensor
From 2006.igem.org
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The arsR gene codes for a repressor which binds to the arsenic promoter in the absence of arsenate or arsenite. These two genes can be linked to the lacZ gene, in order to place lactose metabolism under the control of an arsenic activated promoter. | The arsR gene codes for a repressor which binds to the arsenic promoter in the absence of arsenate or arsenite. These two genes can be linked to the lacZ gene, in order to place lactose metabolism under the control of an arsenic activated promoter. | ||
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The ability to metabolise lactose should result in the acidification of the medium, and an output of H+ ions, giving a pH response to the input of arsenate/arsenite molecules. | The ability to metabolise lactose should result in the acidification of the medium, and an output of H+ ions, giving a pH response to the input of arsenate/arsenite molecules. | ||
Revision as of 16:37, 29 June 2006
This is our first formalised project idea. The details are as follows:
Contents |
Aim
Develop a bacterial biosensor that responds to a range of arsenic concentrations and produces a change in pH that can be calibrated in relation with the arsenic concentration.
Background
This project is motivated by the needs of parts of the developing world. For details, see [Background]
Possible mechanisms
INPUT [Arsenate/Arsenite] -> Detector -> Reporter -> OUTPUT [H+]
The arsR gene codes for a repressor which binds to the arsenic promoter in the absence of arsenate or arsenite. These two genes can be linked to the lacZ gene, in order to place lactose metabolism under the control of an arsenic activated promoter.
The ability to metabolise lactose should result in the acidification of the medium, and an output of H+ ions, giving a pH response to the input of arsenate/arsenite molecules.
It should be possible to obtain a curve for pH vs. arsenic concentration, where a range of pH values representing an unsafe level, a safe level, or an intermediate level of arsenic is present can be elucidated after calibrating the biosensor with known concentrations of arsenic.
Problems
The arsenic promoter shows some background activity even when arsenic is not present. It may be possible to reduce this noise by adding an extra control method to repress the lacZ gene parallel to the action of the arsR product, with for example an antiswitch.
It will not be possible to get a linear relationship between pH and the arsenic concentration because the relationship between gene expression and the cofactor concentration is not linear.
The arsenic concentration has to be the limiting factor in the reaction to result in the steady state obtained being the correct pH in relation to arsenic concentration. If the cell number is the limiting factor the pH may not drop low enough to indicate the arsenic level present in the time taken before measuring.
Experiments required
A lot of this project will be calibrating the sensor, finding the time to reach a steady state, finding out which amount of cells is ideal for reaching the steady state which gives distinct results for each pH range, and finding out which pH range represents which concentration of arsenic. It would be ideal to have the threshold for the legal limit of arsenic at the point of the curve which gives the most accurate result.
Parts required
Arsenic binding repressor protein Arsenic repressor protein responsive promoter lacZ protein coding gene
