Difference between revisions of "Team:Bielefeld-CeBiTec/Results/HeavyMetals"

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     <p>Compared to the <i>in vivo</i> results, the response to arsenic was relatively small and we measured a high background signal. We assume that this is due to the different construct we used <i>in vitro</i>. This construct had been optimized for our CFPS by exchanging the natural promoter for the T7 promoter and exchanging mRFP1 for our optimized sfGFP. However, we assume that the repression in the presence of ArsR was not effective enough to observe a clear induction. The reason is most likely that the distance between the T7 promoter and the arsenic operator was too large. The distance was a result of our cloning strategy and would likely be suitable for <i>E. coli</i> promoters. However, the T7 promoter requires the operator to be very close for an efficient repression (<a href="https://2015.igem.org/Team:Bielefeld-CeBiTec/Results/HeavyMetals#Karig2012">Karig et al. 2012</a>). </p>
 
     <p>Compared to the <i>in vivo</i> results, the response to arsenic was relatively small and we measured a high background signal. We assume that this is due to the different construct we used <i>in vitro</i>. This construct had been optimized for our CFPS by exchanging the natural promoter for the T7 promoter and exchanging mRFP1 for our optimized sfGFP. However, we assume that the repression in the presence of ArsR was not effective enough to observe a clear induction. The reason is most likely that the distance between the T7 promoter and the arsenic operator was too large. The distance was a result of our cloning strategy and would likely be suitable for <i>E. coli</i> promoters. However, the T7 promoter requires the operator to be very close for an efficient repression (<a href="https://2015.igem.org/Team:Bielefeld-CeBiTec/Results/HeavyMetals#Karig2012">Karig et al. 2012</a>). </p>
 
     <p>In addition, we performed an experiment in which the arsenic repressor was not present in the reaction from the beginning, but was encoded on a second plasmid. The plasmid concentrations we used had been predicted by our model. In accordance with the aforementioned results, we observed no clear repression and addition of arsenic showed no effect. This experiment is discussed on the <a href="https://2015.igem.org/Team:Bielefeld-CeBiTec/Modeling/Application">Modeling pages</a>.</p>
 
     <p>In addition, we performed an experiment in which the arsenic repressor was not present in the reaction from the beginning, but was encoded on a second plasmid. The plasmid concentrations we used had been predicted by our model. In accordance with the aforementioned results, we observed no clear repression and addition of arsenic showed no effect. This experiment is discussed on the <a href="https://2015.igem.org/Team:Bielefeld-CeBiTec/Modeling/Application">Modeling pages</a>.</p>
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<h2>To sum it up</h2>
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<p>The arsenic sensor is the most prominent example of heavy metal biosensors. Our results confirm that it is possible to detect the safety limit of 10 µg/L arsenic with a cell-based arsenic senosor. The results of the tests in our CFPS indicate that this approach is suitable for the detection of arsenic as well. However, we believe that the genetic construct requires further optimization.</p>
  
 
<h3>References</h3>
 
<h3>References</h3>

Revision as of 11:34, 18 September 2015

iGEM Bielefeld 2015


Heavy Metals

To make a long story short.

Adjusting the detection limit
Influence of heavy metals on the growth of E.coli KRX. The tested concentrations were 20 µg/L lead, 60 µg/L mercury, 60 µg/L chromium, 80 µg/L nickel, 40 mg/L copper, which represent ten times the WHO guideline. The influence of arsenic was not tested as E. coli is known to be resistant to arsenic.

We tested our heavy metal biosensors in Escherichia coli as well as in our cell-free protein synthesis.

Prior to the in vivo characterization, we tested whether the heavy metals have a negative effect on the growth of E. coli.

As can be seen from the figure, we observed no significant difference between the growth in the presence of heavy metals and the controls. This first experiment showed us that in vivo characterization of these sensors is possible. Most cultivations for in vivo characterization were performed in the BioLector. Due to the accuracy of this device, we could measure our samples in duplicates. Subsequently, all functional biosensors were tested in vitro.

Click on the test strip for the results of our biosensor tests in E. coli and in our CFPS:

teststrip

To sum it all up

We have characterized heavy metal sensors for arsenic, chromium, copper, lead, mercury and nickel. The results for our nickel characterization indicated that the constructed nickel sensor is not suitable for our test strip. The sensors for lead and chromium showed great potential, as they showed responses to chromium or lead, but require further optimization. Copper, our new heavy metal sensor, worked as expected and was able to detect different copper concentrations. The already well-characterized sensors for arsenic and mercury were tested as well. While the arsenic sensor worked well in vivo, it requires some omptimization for the use in vitro. Mercury showed that a fully optimized sensor works very well in our in vitro system and has the potential to detect even lower concentrations than in vivo.