Team:UC Chile/Results/LuxBrick

From 2012.igem.org

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[[File:UC_Chile-OD_effect_on_luminescence_.png|462px|right]]
[[File:UC_Chile-OD_effect_on_luminescence_.png|462px|right]]
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If cells diluted in a liquid medium behave as light-emitting entities, light transmittion to the exterior will depend on the cell density.  
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If cells diluted in a liquid media behave as light-emitting entities, light transmittion to the exterior will be a function of cell density of the media.  
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We wanted to know if there is an optimal density, under which the emittion of photons by the total number of bacteria versus the absorbance of the emitted photons by the same bacteria in the media peak. In such a scenario any number of bacteria in excess beyond that point will not contribute to increase light output, and the system will lose efficiency. 
 
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Our measurments showed that such an optimal OD it´s not consistent with the results. The model that best adjusts to the data is an asymptotic effect of OD over luminiscence, reaching a maximum at OD 0.6.
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We wanted to know if there is an optimal density, under which the emittion of photons by the total number of bacteria versus the absorbance of the emitted photons by the same bacteria in the media, peak. In such a scenario any number of bacteria in excess beyond that point will not contribute to increase light output, and the system will lose efficiency. 
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Our measurements showed that such a hypothesis is plausible, where a clear increase of light output is seen towards higher ODs. However, the data shows that the output reaches a maximum at OD 0.6, but by the closeness of the signal of the OD 0.714 and the scarceness of the experimental point measurements, we cannot conclude that at OD 0.6 the maxima is reached. Further OD points ought to be tested to reach such conclusions.  
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<div id="Temperature">
<div id="Temperature">
== Growth temperature ==
== Growth temperature ==
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Lux genes were originally cloned from Vibrio fischeri, a free living bacteria found in tropical sea water that also inhabits the poikilotherm mollusc Euprymna scolopes  body in a symbiotic relationship, therefore we expect the Lux genes performance to be functional in the range of temperatures found in that context.
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Lux genes were originally cloned from <i>Vibrio fischerii</i>, a free living bacteria found in tropical sea water that also inhabits the poikilotherm mollusc Euprymna scolopes  body in a symbiotic relationship, therefore we expect the Lux genes performance to be functional in the range of temperatures found in that context.
It has been shown that the optimal temperature conditions for bioluminescence in V. harveyi range from 20-26°C [[#5|5]] and the LuxBrick page states that luminescence is diminished in temperatures above 30°. We aimed to better characterize the luminiscent response in a set of temperature conditions used in E.coli cultivation.
It has been shown that the optimal temperature conditions for bioluminescence in V. harveyi range from 20-26°C [[#5|5]] and the LuxBrick page states that luminescence is diminished in temperatures above 30°. We aimed to better characterize the luminiscent response in a set of temperature conditions used in E.coli cultivation.
[[File:UC_Chile-Temperature_growth_effect_on_Luminescence_.png|462px| right]]
[[File:UC_Chile-Temperature_growth_effect_on_Luminescence_.png|462px| right]]

Revision as of 23:19, 26 September 2012

Project: Luxilla - Pontificia Universidad Católica de Chile, iGEM 2012