Team:UC Chile2/Cyanolux/Project

From 2012.igem.org

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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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<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[[#7 7]], [[#8 8]] . (Images at right from cited papers.)
To try our approach, we selected various promoter which could serve the purpose.  Our rational for selecting candidate promoters involved amplitude of oscillation, peak activity, hour, absence of restriction sites, predicted strength of promoter according to the role of the gene and reproducibility between experiments (based on the literature available).  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 prioritized promoters from genes that would be involved in central energetic metabolism as we thought that their expression would be most robust and reliable. We choose the transaldolase promoter <b>(specific name here and code in Synechocystis Genome)</b> to direct the expression of the LuxAB genes and we found a couple of other promoters which filled the other requirements from above. Pcaa3 (NAME HERE AND DESCRIPTION OF ENDOGENOUS ACTIVITY) and PsigE (NAME HERE AND DESCRIPTION OF ENDOGENOUS ACTIVITY), the former being already in Biobrick format (courtesy from the Utah team iGEM 2010).
To try our approach, we selected various promoter which could serve the purpose.  Our rational for selecting candidate promoters involved amplitude of oscillation, peak activity, hour, absence of restriction sites, predicted strength of promoter according to the role of the gene and reproducibility between experiments (based on the literature available).  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 prioritized promoters from genes that would be involved in central energetic metabolism as we thought that their expression would be most robust and reliable. We choose the transaldolase promoter <b>(specific name here and code in Synechocystis Genome)</b> to direct the expression of the LuxAB genes and we found a couple of other promoters which filled the other requirements from above. Pcaa3 (NAME HERE AND DESCRIPTION OF ENDOGENOUS ACTIVITY) and PsigE (NAME HERE AND DESCRIPTION OF ENDOGENOUS ACTIVITY), the former being already in Biobrick format (courtesy from the Utah team iGEM 2010).
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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>
<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
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(2) Nitrogen fixation by marine cyanobacteria. Jonathan P. Zehr. Trends in microbiology, Volume 19, Issue 4,
(2) Nitrogen fixation by marine cyanobacteria. Jonathan P. Zehr. Trends in microbiology, Volume 19, Issue 4,
April 2011, Pages 162–17
April 2011, Pages 162–17
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(3) Carl Hirschie Johnson and Susan S. Golden. CIRCADIAN PROGRAMS IN CYANOBACTERIA: Adaptiveness
(3) Carl Hirschie Johnson and Susan S. Golden. CIRCADIAN PROGRAMS IN CYANOBACTERIA: Adaptiveness
and Mechanism. Annual Review of Microbiology, Vol. 53: 389-409
and Mechanism. Annual Review of Microbiology, Vol. 53: 389-409
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(4) Ducat, D. C., Way, J. C., & Silver, P. a. (2011). Engineering cyanobacteria to generate high-value products.
(4) Ducat, D. C., Way, J. C., & Silver, P. a. (2011). Engineering cyanobacteria to generate high-value products.
Trends in biotechnology, 29(2), 95-103.
Trends in biotechnology, 29(2), 95-103.
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(5) Huang, H.-H., Camsund, D., Lindblad, P., & Heidorn, T. (2010). Design and characterization of molecular
(5) Huang, H.-H., Camsund, D., Lindblad, P., & Heidorn, T. (2010). Design and characterization of molecular
tools for a Synthetic Biology approach towards developing cyanobacterial biotechnology. Nucleic acids
tools for a Synthetic Biology approach towards developing cyanobacterial biotechnology. Nucleic acids
research, 38(8), 2577-93
research, 38(8), 2577-93
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(6) Peca, L., Kós, P. B., Máté, Z., Farsang, A., & Vass, I. (2008). Construction of bioluminescent cyanobacterial
(6) Peca, L., Kós, P. B., Máté, Z., Farsang, A., & Vass, I. (2008). Construction of bioluminescent cyanobacterial
reporter strains for detection of nickel, cobalt and zinc. FEMS microbiology letters, 289(2), 258-64.
reporter strains for detection of nickel, cobalt and zinc. FEMS microbiology letters, 289(2), 258-64.
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<div id="7">
(7) Kucho, K.-ichi, Okamoto, K., Tsuchiya, Y., Nomura, S., Nango, M., Kanehisa, M., Ishiura, M., et al. (2005).
(7) Kucho, K.-ichi, Okamoto, K., Tsuchiya, Y., Nomura, S., Nango, M., Kanehisa, M., Ishiura, M., et al. (2005).
Global Analysis of Circadian Expression in the Cyanobacterium Synechocystis sp . Global Analysis of Circadian
Global Analysis of Circadian Expression in the Cyanobacterium Synechocystis sp . Global Analysis of Circadian
Expression in the Cyanobacterium. Society.
Expression in the Cyanobacterium. Society.
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<div id="8">
(8) Layana, C., & Diambra, L. (2011). Time-course analysis of cyanobacterium transcriptome: detecting
(8) Layana, C., & Diambra, L. (2011). Time-course analysis of cyanobacterium transcriptome: detecting
oscillatory genes. PloS one, 6(10), e26291.
oscillatory genes. PloS one, 6(10), e26291.
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<div id="9">
(9) Kunert, a, Hagemann, M., & Erdmann, N. (2000). Construction of promoter probe vectors for
(9) Kunert, a, Hagemann, M., & Erdmann, N. (2000). Construction of promoter probe vectors for
Synechocystis sp. PCC 6803 using the light-emitting reporter systems Gfp and LuxAB. Journal of
Synechocystis sp. PCC 6803 using the light-emitting reporter systems Gfp and LuxAB. Journal of
microbiological methods, 41(3), 185-94.
microbiological methods, 41(3), 185-94.
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Revision as of 18:44, 22 September 2012

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