Team:UC Chile2/Cyanolux/Project

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<p>The lux operon is a group of genes that are responsible for density-dependent bioluminescent behavior
<p>The lux operon is a group of genes that are responsible for density-dependent bioluminescent behavior
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in various prokariotic organisms such as <i>Vibrio fischeri</i> and <i>Photorabdus luminescens</i>. In <i>V. fischeri</i>, the operon is composed of 8 genes: LuxA and LuxB encode for the monomers of a heterodimeric luciferase; LuxC, LuxD and LuxE code for fatty acid reductases enzymes and LuxR and LuxI are responsible for the regulation of the whole operon.</p>
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in various prokariotic organisms such as <i>Vibrio fischeri</i> and <i>Photorabdus luminescens</i> [[#12|12]]. In <i>V. fischeri</i>, the operon is composed of 8 genes: LuxA and LuxB encode for the monomers of a heterodimeric luciferase; LuxC, LuxD and LuxE code for fatty acid reductases enzymes and LuxR and LuxI are responsible for the regulation of the whole operon [[#13|13]].</p>
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<p>Lastly LuxG is believed to act as a FMNH2 dependent FADH reductase, although luminescence is barely affected
<p>Lastly LuxG is believed to act as a FMNH2 dependent FADH reductase, although luminescence is barely affected
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in its absence. The n-decanal ( n= 9 to 14) substrate oxidization to n-decanoic acid by the LuxAB heterodimer is coupled with the reduction of FMNH to FMNH2 and the releasing of oxygen and x photons of light at x wavelength.</p>
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in its absence [[#14|14]]. The n-decanal ( n= 9 to 14) substrate oxidization to n-decanoic acid by the LuxAB heterodimer is coupled with the reduction of FMNH to FMNH2 and the releasing of oxygen and light.</p>
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<p>The carboxylic group of the product is then reduced to aldehyde by CDE proteins allowing the reaction to
<p>The carboxylic group of the product is then reduced to aldehyde by CDE proteins allowing the reaction to
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start over.</p>
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start over [[#15|15]].</p>
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<img src="https://static.igem.org/mediawiki/2012/5/56/Alagain_uc_chile.jpg" width="300" align="left" style ="margin-right:15px"></html>
<img src="https://static.igem.org/mediawiki/2012/5/56/Alagain_uc_chile.jpg" width="300" align="left" style ="margin-right:15px"></html>
<p>LuxAB genes have been widely used as reporters dependent on the addition of n-decanal to the culture
<p>LuxAB genes have been widely used as reporters dependent on the addition of n-decanal to the culture
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media and in 2010, the Cambridge iGEM team engineered LuxABCDEG to an <i>E. coli</i>-optimized biobrick
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media [[#16|16]] and in 2010, the [https://2010.igem.org/Team:Cambridge Cambridge iGEM team] engineered LuxABCDEG to an <i>E. coli</i>-optimized biobrick
format, uncoupling it from the LuxR and LuxI regulation.</p>
format, uncoupling it from the LuxR and LuxI regulation.</p>
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<p>Due to issues mentioned in the results page (PUT LINK HERE) we designed a new plasmid backbone.
<p>Due to issues mentioned in the results page (PUT LINK HERE) we designed a new plasmid backbone.
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This is an integration plasmid which makes Synechocystis susceptible to copper concentrations higher than X uM [[#10|10]] by disrupting the CopS gene. We believe that this strategy serves as a biosafety measure to avoid the possibility of having a leakage of recombinant DNA to the environment. The plasmid uses Spectynomycin as a selectable marker. [PUT LINK TO CONSTRUCT HERE]
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This is an integration plasmid which makes Synechocystis susceptible to copper concentrations higher than 0.75 uM [[#10|10]] by disrupting the CopS gene. We believe that this strategy serves as a biosafety measure to avoid the possibility of having a leakage of recombinant DNA to the environment. The plasmid uses Spectynomycin as a selectable marker. [PUT LINK TO CONSTRUCT HERE]
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We plan on expressing LuxCDEG under the control of the promoters Pcaa3 and PsigE (mentioned above). These promoters have peak activities 1 hour before dusk. We believe that we might enhance bioluminescence yield initially by setting the substrate production/regeneration part of the operon prior to the expression of the luciferase.(LINK TO MODELLING?)
We plan on expressing LuxCDEG under the control of the promoters Pcaa3 and PsigE (mentioned above). These promoters have peak activities 1 hour before dusk. We believe that we might enhance bioluminescence yield initially by setting the substrate production/regeneration part of the operon prior to the expression of the luciferase.(LINK TO MODELLING?)
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(11)Kucho, K., Aoki, K., Itoh, S., & Ishiura, M., (2005). Improvement of the bioluminescence reporter system for real-time monitoring of circadian rhythms in the cyanobacterium Synechocystis sp. strain PCC 6803. Genes Genet. Syst.  80, p. 19–23
(11)Kucho, K., Aoki, K., Itoh, S., & Ishiura, M., (2005). Improvement of the bioluminescence reporter system for real-time monitoring of circadian rhythms in the cyanobacterium Synechocystis sp. strain PCC 6803. Genes Genet. Syst.  80, p. 19–23
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<div id="12">
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(12)Meighen, E. a. (1991). Molecular biology of bacterial bioluminescence. Microbiological reviews, 55(1), 123-42.
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(13)Dunlap, P. V. (1999). Quorum regulation of luminescence in Vibrio fischeri. Journal of molecular microbiology and biotechnology, 1(1), 5-12.
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(14)Luciferase, R. (2001). Differential Transfers of Reduced Flavin Cofactor and Product by Bacterial Flavin. Society, 1749-1754.
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(15) Kelly, C. J., Hsiung, C.-J., & Lajoie, C. a. (2003). Kinetic analysis of bacterial bioluminescence. Biotechnology and bioengineering, 81(3), 370-8. doi:10.1002/bit.10475
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(16)Tehrani, G. A., Mirzaahmadi, S., Bandehpour, M., & Laloei, F. (2011). Molecular cloning and expression of the luciferase coding genes of Vibrio fischeri. Journal of Biotechnology, 10(20), 4018-4023. doi:10.5897/AJB10.2363
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Latest revision as of 22:52, 25 September 2012

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