Team:UC Chile2/Cyanolux/Project

From 2012.igem.org

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<h1>Motivational drive</h1>
<h1>Motivational drive</h1>
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<p>Natural cycles have always fascinated mankind, probably due to the mysterious mechanisms involved in them and the power they exert in our everyday life. Since the dawn of synthetic biology, engineering oscillatory systems has been a recurrent topic, being Ellowitz's represillator a classical example. Nevertheless, to date no iGEM team has accomplished the implementation of a robust oscillatory system. That will be our challenge for this year's iGEM project.</p>
<p>Natural cycles have always fascinated mankind, probably due to the mysterious mechanisms involved in them and the power they exert in our everyday life. Since the dawn of synthetic biology, engineering oscillatory systems has been a recurrent topic, being Ellowitz's represillator a classical example. Nevertheless, to date no iGEM team has accomplished the implementation of a robust oscillatory system. That will be our challenge for this year's iGEM project.</p>
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knowledge, no iGEM team has ever accomplished a successful direct <i>Synechocystis</i> transformation with naked DNA.</p>
knowledge, no iGEM team has ever accomplished a successful direct <i>Synechocystis</i> transformation with naked DNA.</p>
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<h2>Lux Operon (faltan referencias!!)</h2>
<h2>Lux Operon (faltan referencias!!)</h2>
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produced by this pathway is much more visually appealing than other systems from the registry (i.e XFPs),
produced by this pathway is much more visually appealing than other systems from the registry (i.e XFPs),
moreover, the light production doesn´t depend on a single peptide but on a whole pathway involving several genes, which makes it much more tunable, for instance, decoupling in time the substrate recovery from the luciferase reaction itself.</p>
moreover, the light production doesn´t depend on a single peptide but on a whole pathway involving several genes, which makes it much more tunable, for instance, decoupling in time the substrate recovery from the luciferase reaction itself.</p>
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<h1>Experimental Strategy</h1>
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<p>We have devised different strategies to achieve bioluminescence controlled under circadian rhythms. Here we describe the strategies used for building the constructs to reach our goals.</p>
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<h2>Splitting the Lux operon and choosing promoters</h2>
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[[File:circadiancyano.jpg|400px|right]]
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<p>We decided that we would separate LuxAB (the luciferase part of the operon) and LuxCDEG (the substrate producing enzymes LuxCDE with LuxG the FMNH2/FMN reducing enzyme) to allow phase-dependent expression of the parts. Using specific promoters of Synechocystis PCC. 6803 we can have fine-tunning of the production of bioluminescence. Recent work on global gene expression in Synechocystis aided on finding adecuate promoters (Kucho K. , et al., (2005) Global Analysis of Circadian Expression in the Cyanobacterium Synechocystis sp. Strain PCC 6803., J. Bacteriol. , 187(6):2190. DOI: 10.1128/JB.187.6.2190-2199; and Layana C, Diambra L (2011) Time-Course Analysis of Cyanobacterium Transcriptome: Detecting Oscillatory Genes. PLoS ONE 6(10): e26291. DOI:10.1371/journal.pone.0026291. Images at right from cited papers.)
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We choose various promoters to try our approach. We looked for promoters which would have peak expression nearby dusk hours and that were slightly out of phase to optimize production of bioluminescence according to our mathematical models. <b>(LINK OVER HERE!)</b>. We choose the transaldolase promoter <b>(specific name here)</b> to direct the expression of the LuxAB genes and we found a couple of other promoters which filled the requirement from above. Pcaa3 (NAME HERE AND DESCRIPTION) and PsigE (NAME HERE AND DESCRIPTION), one of which already was in the registry (PsigE from Hawaii iGEM 2007 DOUBLECHECKTHIS).
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</p>
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<h2>Building constructs for Synechocystis PCC 6803</h2>
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<p>As transformation in Synechocystis is undergone through double recombination of DNA strands, we designed two constructs that have different recombination locations in the Synechocystis chromosome. </p>
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<h3>pSB1C3_IntK</h3>
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<p>The first of our constructs is an integrative plasmid which targets neutral recombination sites (slr0370 and slr03770 DOUBLECHECK this). We selected this locus because it has been extensively used in the literature (CAPAZ EXAGERE?) and it shown to have no deleterious effects on Synechocystis viability. We selected Kanamycin resistance as our transformation marker. [PUT LINK TO CONSTRUCT HERE].</p>
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<h3>pSB1C3_IntS</h3>
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<p>We designed another construct that besides serving as a double recombination plasmid it makes Synechocystis susceptible to copper concentrations higher than X uM (Giner-Lamia, J., Lopez-Maury, L., Reyes, J. C., & Florencio, F. J. (2012). The CopRS two-component system is responsible for resistance to copper in the cyanobacterium Synechocystis sp. PCC 6803. Plant physiology, 159(August), 1806-1818.). We have designed this construct to interrupt the CopS gene as a biosafety measure to avoid the possibility of having a leakage of recombinant DNA to the environment.  This plasmid has Spectynomycin resistance as the transformation marker. [PUT LINK TO CONSTRUCT HERE]
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</p>
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<h3>pSB1A2_IntC (Utah 2010 iGEM Team integration plasmid)</h3>
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<p>Alternatively, we designed our LuxCDEG contructs for the Utah 2010 iGEM Team plasmid backbone pSB1A2_IntC. [PUT LINK TO CONSTRUCT HERE].</p>
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<p>(1) Evolution of photosynthesis. Hohmann-Marriott MF, Blankenship. Annual Review of Plant Biology Vol. 62: 515-548
<p>(1) Evolution of photosynthesis. Hohmann-Marriott MF, Blankenship. Annual Review of Plant Biology Vol. 62: 515-548

Revision as of 17:10, 22 September 2012

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