Team:Panama INDICASAT

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Revision as of 23:02, 15 July 2012

Genetically Modified E. coli as an Alternative Biosensor of Cyanide and Cyanide Compounds

Proyect Description

Cyanide is consedered an extremely harmful toxic for the enviroment and living organism since it inhibits the cellular respiration at the level of electron transport chain. In the industrial sector, cyanide is used to produce paper, paints, textiles and plastics. It is also very common in the mining industry as a way to recover metals.

Due to its application and toxicity, it is necessary to monitor and keep the cyanide at subtoxic level. The most recent methods for the detection of cyanide compounds include simple vision detection, spectrometry/colorimetry, capillary electrophoresis with optical absorbance detection, fluorometry, chemoluminiscense, near-infrared spectroscopy, atomic absorption spectrometry, electrochemical methods, mass spectrometry, gas chromatography and quartz crystal monitoring.

In this project, we are generating a new alternative by using genetic engineering to modify E. coli genetically. We will incorporate genes that will allow the bacteria to become a biosensor with the capacity to detect the presence of cyanide and cyanide compounds by adding the expression of a reporter gene (RFP) under the control of a promoter inducible bby these compunds.

This gene comes from the bacteria Pseudomonas pseudoalcaligenes. This new technique, wich will be used to detect water and soil contamination, will also become a platform so that in the future we cound incorporate a gene that allows the bacteria, not only detect, but also degrade these compunds using a method that is accessible and environmentally friendly through bioremediation.

In order for the bacteria to degrade cyanide, it needs not only the metabolic route, but a sort of resistance to these compounds.

For this reason, we will also add cyanide resistant genes (cioAB) to elevate the detection potential of our biosensor. This will provide the bacteria an alternate route for the electron transportation insensitive to cyanide. consectetuer adipiscing elit. Mauris fermentum dictum magna. Sed laoreet aliquam leo.

Sed laoreet aliquam leo. Ut tellus dolor, dapibget, elementum vel, cursus eleifend, elit. Aenean auctor

wisi et ur liquam erat volutpat.

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 <div><font class="ws8" color="#808080" face="Tahoma">Cyanide is consedered an extremely harmful toxic for the enviroment and living organism since it inhibits the cellular respiration at the level of electron transport chain. In the industrial sector, cyanide is used to produce paper, paints, textiles and plastics. It is also very common in the mining industry as a way to recover metals.</font></div>
 <div><font class="ws8" color="#808080" face="Tahoma">Due to its application and toxicity, it is necessary to monitor and keep the cyanide at subtoxic level. The most recent methods for the detection of cyanide compounds include simple vision detection, spectrometry/colorimetry, capillary electrophoresis with optical absorbance detection, fluorometry, chemoluminiscense, near-infrared spectroscopy, atomic absorption spectrometry, electrochemical methods, mass spectrometry, gas chromatography and quartz crystal monitoring.</font></div>
 <div><font class="ws8" color="#FF9900" face="Tahoma"><BR></font></div>
-<div><font class="ws8" color="#6FA6D2" face="Tahoma"><U>Sed Due to its application and toxicity, it is necessaryaliquam leo. Ut tellus dolor, dapibget, elementum vel, cursus eleifend, elit. Aenean auctor</U></font></div>
+<div><font class="ws8" color="#6FA6D2" face="Tahoma"><U>In this project, we are generating a new alternative by using genetic engineering to modify E. coli genetically. We will incorporate genes that will allow the bacteria to become a biosensor with the capacity to detect the presence of cyanide and cyanide compounds by adding the expression of a reporter gene (RFP) under the control of a promoter inducible bby these compunds.</U></font></div>
-<div><font class="ws8" color="#6FA6D2" face="Tahoma"><U>wisi et ur liquam erat volutpat. </U></font><font class="ws8" color="#6FA6D2" face="Tahoma"><B><U> </U></B></font></div>
+<div><font class="ws8" color="#FF9900" face="Tahoma"><B><BR> This gene comes from the bacteria Pseudomonas pseudoalcaligenes. This new technique, wich will be used to detect water and soil contamination, will also become a platform so that in the future we cound incorporate a gene that allows the bacteria, not only detect, but also degrade these compunds using a method that is accessible and environmentally friendly through bioremediation.</B></font></div>
-<div><font class="ws8" color="#FF9900" face="Tahoma"><B><BR></B></font></div>
+<div><font class="ws8" color="#FF9900" face="Tahoma"><BR>In order for the bacteria to degrade cyanide, it needs not only the metabolic route, but a sort of resistance to these compounds.</font></div>
-<div><font class="ws8" color="#FF9900" face="Tahoma"><BR></font></div>
-<div><font class="ws8" color="#969696" face="Tahoma">Duis ultricies pharetra magna. Donec accumsan malesuada orci. Donec sit amet eros. Losum dolor sit amet, consectetuer adipiscing elit. Mauris fermentum dictum magna. </font><font class="ws8" color="#808080" face="Tahoma">consectetuer adipiscing elit. Mauris fermentum dictum magna. Sed laoreet aliquam leo.</font></div>
+<div><font class="ws8" color="#969696" face="Tahoma">For this reason, we will also add cyanide resistant genes (cioAB) to elevate the detection potential of our biosensor. This will provide the bacteria an alternate route for the electron transportation insensitive to cyanide.
+</font><font class="ws8" color="#808080" face="Tahoma">consectetuer adipiscing elit. Mauris fermentum dictum magna. Sed laoreet aliquam leo.</font></div>
 <div><font class="ws8" color="#FF9900" face="Tahoma"><BR></font></div>