Team:WashU StLouis/Project/light
From 2014.igem.org
(Difference between revisions)
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style="width: 100%;" alt="Disfunctioning plasmid" | style="width: 100%;" alt="Disfunctioning plasmid" | ||
src="https://static.igem.org/mediawiki/2014/1/16/WashU_Original_Light.png"><br> | src="https://static.igem.org/mediawiki/2014/1/16/WashU_Original_Light.png"><br> | ||
- | <div style="text-align: center;" | + | <div style="text-align: center;"> |
Figure above: Original Light induction experiment once all the cloning | Figure above: Original Light induction experiment once all the cloning | ||
- | was over. No fluorescence seen. | + | was over. No fluorescence seen. |
</div><br> | </div><br> | ||
<div style="text-align: justify;">After all our cloning mishaps | <div style="text-align: justify;">After all our cloning mishaps | ||
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style="width: 100%;" alt="Troubleshooting pTet" | style="width: 100%;" alt="Troubleshooting pTet" | ||
src="https://static.igem.org/mediawiki/2014/9/92/WashU_Troubleshooting_pTet.png">Figure | src="https://static.igem.org/mediawiki/2014/9/92/WashU_Troubleshooting_pTet.png">Figure | ||
- | above: We ran another crude experiment to check what could be the issue. | + | above: We ran another crude experiment to check what could be the issue.<br> |
<div style="text-align: justify;">Our original positive control | <div style="text-align: justify;">Our original positive control | ||
was under control of constitutive promoter, J23100, and was the only | was under control of constitutive promoter, J23100, and was the only | ||
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<div style="text-align: center;">Figure above: Fluorescence in | <div style="text-align: center;">Figure above: Fluorescence in | ||
the dark (when promoter not active) same regardless of chromophore | the dark (when promoter not active) same regardless of chromophore | ||
- | presence. | + | presence. |
</div> <br> | </div> <br> | ||
</td> | </td> | ||
<td style="vertical-align: top; text-align: center;"><img | <td style="vertical-align: top; text-align: center;"><img | ||
style="width: 100%;" alt="Chromophore light" | style="width: 100%;" alt="Chromophore light" | ||
- | src="https://static.igem.org/mediawiki/2014/f/f2/WashU_Fluorescence_in_Light.png"><br | + | src="https://static.igem.org/mediawiki/2014/f/f2/WashU_Fluorescence_in_Light.png"><br |
Figure above: Fluorescence in the light (when repressor active) shows | Figure above: Fluorescence in the light (when repressor active) shows | ||
some difference with aTc present. Hybrid leaky.<br> | some difference with aTc present. Hybrid leaky.<br> | ||
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src="https://static.igem.org/mediawiki/2014/9/92/WashU_dark_vs_light.png"><br> | src="https://static.igem.org/mediawiki/2014/9/92/WashU_dark_vs_light.png"><br> | ||
<div style="text-align: center;">Figure above: Final Light | <div style="text-align: center;">Figure above: Final Light | ||
- | experimental data | + | experimental data |
</div> | </div> | ||
</td> | </td> |
Revision as of 03:21, 17 October 2014
Using an inducible hybrid light-sensitive promoter for heterologous regulation of the nif clusterBenjamin Huang, Jeffrey Lee
Synthetic biology is an exciting area of research that aims to
genetically improve organisms to make them more efficient and hopefully
more useful to us as well. The human population in 1950 was 2.5
billion, yet it is predicted to surpass 9 billion by 2050 [1]. Even
with population growth slowing, increasing life spans and standards of
living will soon tax our natural resources. One of the most concerning
is our food supply. The agriculture industry needs a revolution in
order to keep up with our expected growth rates. Currently about 80% of
chemically fixated nitrogen is used as agricultural fertilizers, the
majority in developed lands [1]. Intracellular nitrogen fixation in
crops could help to sustain the burgeoning world population, especially
in areas with less fertile soil without taxing the planet’s waterways.
The exponential increase in nitrogen fertilizer has led to more runoff
into rivers and oceans. Fertilizers then provide nutrition for algal
blooms that result in hypoxia and form oceanic dead zones. These dead
zones lead to the death of marine species and have potentially large
economic consequences. The ramifications of nitrogen fertilizer runoff can be averted by genetically engineering plant crops to fix their own nitrogen. Some cyanobacteria fix nitrogen for nutritional needs, while most organisms can only acquire it from the food it consumes. Synthetic biology allows us to transfer this ability to fix nitrogen to a heterologous host that has many genetic tools, Escherichia coli, so that we can learn how to give single cell organisms, and eventually chloroplasts the ability to create their own nitrogen fertilizer. Diazotrophic (organisms that fix nitrogen) cyanobacteria such Nostoc Punctiforme or Anabaena use heterocysts (specialized nitrogen fixing cells) to create a mini-anaerobic environment to aid nitrogen fixation. However, Cyanothece 51142, a non-heterocyst, fixes nitrogen in the same cell as photosynthesis by relying on a circadian metabolic process, when there is less oxygen byproduct from photosynthesis. Our goal this summer is to engineer the regulation of the proteins necessary for nitrogen fixation so that they are highly repressed when activated by broad spectrum light (such as the sun), and are highly active when there is no light around, mimicking the cycle where photosynthesis occurs during the day and nitrogen fixation occurs at night. Traditionally, gene expression has been induced through chemical means. However, this method requires expensive chemicals, and can have deleterious side effects on cell health. In Tabor et. al (2010), it was shown that it is possible to induce expression of a reporter gene with light in E. coli using light sensitive proteins (CcaR/CcaS) from the model cyanobacterium Synechocystis S. 6803. Light induction has several advantages over chemical induction, including: long term cost of chemical inducers, ability to tune expression levels with different light intensities, and most importantly, can be turned on and off easily. The ability to control genes of interest has important applications in engineering nitrogen fixation. The end goal of our project is for plants to fix nitrogen on their own within their chloroplasts--the true powerhouse of plant cells, where the most ATP is present to overcome the high costs associated with breaking nitrogen’s triple bond. ObjectivesSynechtocystis PCC6803 (hereafter S. 6803) is a strain of cyanobacteria that is of particular interest to us. S. 6803 is important because it is the first cyanobacteria to have its complete genome sequenced; and it is easily manipulated via homologous recombination. Another aspect of S. 6803 that renders it a relevant is based on the ultimate goal of allowing plants to fix their own nitrogen. Nitrogen fixation in these genetically engineered plants would have their own cellular machinery (analogous to chloroplasts and mitochondria) that direct the evolution of nitrogen. Based on the Endosymbiotic theory, chloroplasts and mitochondria are thought to have been cyanobacteria that were engulfed by cells. Thus, S. 6803 is an important platform from which further manipulation of the nitrogen fixation can occur.Recently it has been shown that one can induce via green light, the expression of a phycobilisome-related gene [2]. Instead of regulating gene expression via proteins, having to worry about different concentration levels, potential cross effects, etc., regulation via light can be easily tested for and manipulated as well. Therefore, we propose to design a hybrid inducible light-sensitive promoter for heterologous regulation of the nif cluster in E. Coli. ApproachWe created a 4 piece assembly plasmid integrating light regulation components from pJT122, but swapping out cph8 (for EYFP from pSL2264) and lacZ (for TetR from pTet-PP*) and combined them into a plasmid PBJ003 which should repress expression of EYFP when induced by light. PBJ003 is controlled by the basic cpcG2 promoter driving TetR production. We also created a hybrid promoter to swap out for the basic cpcG2 promoter. Both these parts are on the registry under BBa_K1385000 and BBa_K1385001.
Summer PROPOSED Work FlowWeek 1: Familiarize self with standard laboratory methods and procedures. Design primers for transcriptional units and plasmid backbone.Week 2-3: Test light regulation in pBJ003 (driven by basic PcpcG2). Use positive and negative controls as well to ensure system is working as intended with EYFP fluorescence as our gene expression. Week 4-5: Swap out basic PcpcG2 in pBJ003 with our hybrid promoter and test for increased Fluorescence of EYFP. Week 6-8: Swap out tetR/ptet with CRISPRi mechanism with dCas9 and sgRNA plasmids. If things go as planned, swap out EYFP with nif cluster in hybrid promoter driven plasmid. Week 9-10: Analyze data, comparing fluorescence in different intensities of light, wavelengths, time intervals, etc. Our general workflow for each plasmid cloning is as follows: a. Primer design for backbone and pieces b. PCR pieces for amplification c. Run a gel extraction d. Gel DNA Recovery Treat with DpnI and purify if necessary e. Digestion/Ligation (Golden Gate or Blunt End) f. Transformation (Electroporation) g. Plate and grow overnight h. Pick colonies and start liquid culture overnight i. Freeze and Miniprep cultures j. Run sequencing PCR to check junctions k. Run visualization gel for sequencing PCR l. Send for sequencing m. Verify sequence products are as intended With every step there is a chance that things could go wrong, and we would troubleshoot in order to determine the best course of action going forward. Data
Results
2. Hirose, Shimada, et al. PNAS July 15, 2008 vol. 105 no.28 3. Lutz and Bujard Nucleic Acids Research, 1997, Vol. 25, No. 6 4. Hirose, Narikawa, et al. PNAS May 11, 2010 vol. 107 no. 19 5. Huang et al. Nucleic Acids Research, 2010 Vol. 38 No. 8 6. Tabor, Levskaya, et al. J. Mol. Biol. (2011) 405, 315-324 7. Kim, White, et al. Molecular Systems Biology 2006 doi:10.1038/msb4100099 8. Brantl, Wagner. J. Bacteriol. 2002, doi:10.1128/JB.184.10.2740-2747.2002. 9. Larson , Gilbert, et al. Nature, Oct. 2013 vol. 8 no. 11 10. Abe, Koichi, et al. Microbial biotechnology (2014). |