Team:WashU StLouis/Project/light
From 2014.igem.org
(Difference between revisions)
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interest to us. S. 6803 is important because it is the first | interest to us. S. 6803 is important because it is the first | ||
cyanobacteria to have its complete genome sequenced; and it is easily | cyanobacteria to have its complete genome sequenced; and it is easily | ||
- | manipulated via homologous recombination. | + | manipulated via homologous recombination. S. 6803 has highly |
- | that | + | characterized photosynthetic genes that are light regulated, which |
- | plants to fix | + | would be useful if we want plants to eventually fix nitrogen. Based on |
- | + | the Endosymbiotic theory, chloroplasts and | |
- | + | ||
- | + | ||
mitochondria are thought to have been cyanobacteria that were engulfed | mitochondria are thought to have been cyanobacteria that were engulfed | ||
by cells. Thus, S. 6803 is an important platform from which further | by cells. Thus, S. 6803 is an important platform from which further | ||
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light can be easily tested for and manipulated as well. Therefore, we | light can be easily tested for and manipulated as well. Therefore, we | ||
propose to design a hybrid inducible light-sensitive promoter for | propose to design a hybrid inducible light-sensitive promoter for | ||
- | heterologous regulation of the nif cluster in E. | + | heterologous regulation of the <span style="font-style: italic;">nif</span> |
+ | cluster in <span style="font-style: italic;">E. coli</span>. <br> | ||
<h3 style="text-align: center;"><a name="3"></a><span | <h3 style="text-align: center;"><a name="3"></a><span | ||
style="text-decoration: underline;">Approach</span></h3> | style="text-decoration: underline;">Approach</span></h3> | ||
We created a 4 piece assembly plasmid integrating light regulation | We created a 4 piece assembly plasmid integrating light regulation | ||
- | components from pJT122, but swapping out cph8 (for EYFP from pSL2264) | + | components from pJT122, but swapping out <span |
- | and lacZ (for TetR from pTet-PP*) and combined them into a plasmid | + | style="font-style: italic;">cph8</span> (for EYFP from pSL2264) |
+ | and <span style="font-style: italic;">lacZ</span> (for TetR from | ||
+ | pTet-PP*) and combined them into a plasmid | ||
PBJ003 which should repress expression of EYFP when induced by light. | PBJ003 which should repress expression of EYFP when induced by light. | ||
- | PBJ003 | + | We used these plasmids because they were easily available in the Moon |
- | production. We also created a hybrid promoter to swap out for the basic | + | Lab at Washington University in St. Louis, and we didn't need to get |
+ | them from other labs or the registry. PBJ003 contains the basic cpcG2 | ||
+ | promoter driving <span style="font-style: italic;">tetR</span> | ||
+ | production. When induced by light, the TetR generated will bind to the | ||
+ | tet promoter which should repress <span style="font-style: italic;">eyfp | ||
+ | </span>production. We also created a hybrid promoter to swap out | ||
+ | for the basic | ||
cpcG2 promoter. Both these parts are on the registry under <a | cpcG2 promoter. Both these parts are on the registry under <a | ||
href="http://parts.igem.org/Part:BBa_K1385000">BBa_K1385000</a> and <a | href="http://parts.igem.org/Part:BBa_K1385000">BBa_K1385000</a> and <a | ||
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[3]. Operator sites for the green-light sensitive PcpcG2 promoter are | [3]. Operator sites for the green-light sensitive PcpcG2 promoter are | ||
well known [4], additionally, the hybrid trc1O promoter has been shown | well known [4], additionally, the hybrid trc1O promoter has been shown | ||
- | to be highly expressed in E. coli | + | to be highly expressed in <span style="font-style: italic;">E. coli </span>even |
+ | without IPTG | ||
[5]. The trc1O promoter has one lac operator site and is thus easier to | [5]. The trc1O promoter has one lac operator site and is thus easier to | ||
induce than the more tightly repressed trc2O that contains two | induce than the more tightly repressed trc2O that contains two | ||
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be obtained by creating our own plasmids with these genes (already | be obtained by creating our own plasmids with these genes (already | ||
done). Our hybrid promoter could be cloned into a vector that contains | done). Our hybrid promoter could be cloned into a vector that contains | ||
- | a fluorescent reporter protein EYFP driven by | + | a fluorescent reporter protein EYFP driven by pTet. Our eventual goals |
- | + | would be to regulate the <span style="font-style: italic;">nif </span>cluster | |
- | + | once we properly characterize the system.</td> | |
- | + | ||
</tr> | </tr> | ||
</tbody> | </tbody> | ||
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transcription start site in N. Punctiforme and S. 6803, is a region | transcription start site in N. Punctiforme and S. 6803, is a region | ||
where CcaR binds to PcpcG2 as an activator [4]. We choose to use Ptrc1O | where CcaR binds to PcpcG2 as an activator [4]. We choose to use Ptrc1O | ||
- | and keep the whole sequence intact because it is shown to be | + | and keep the whole sequence intact because it is shown to be a |
- | + | constitutive promoter in <span style="font-style: italic;">E. coli</span>, | |
- | constitutive promoter in E. coli, | + | and has been reported to |
be leaky in S. 6803 [5]. By combining the upstream components (CcaR | be leaky in S. 6803 [5]. By combining the upstream components (CcaR | ||
binding site) of PcpcG2 with Ptrc1O, while keeping the Ptrc1O ribosomal | binding site) of PcpcG2 with Ptrc1O, while keeping the Ptrc1O ribosomal | ||
- | binding sequence intact, our hybrid PcpcG2/trc1O promoter in E. | + | binding sequence intact, our hybrid PcpcG2/trc1O promoter in <span |
- | + | style="font-style: italic;">E. coli</span> | |
should be highly expressed in (green) light with basal levels of | should be highly expressed in (green) light with basal levels of | ||
- | transcription | + | transcription during the dark.<br> |
+ | </td> | ||
</tr> | </tr> | ||
</tbody> | </tbody> | ||
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gate, where in high light conditions, our product (currently EYFP), | gate, where in high light conditions, our product (currently EYFP), | ||
will be highly repressed. <br> | will be highly repressed. <br> | ||
+ | <br> | ||
Different switches based on RNA have been well documented in E. coli; | Different switches based on RNA have been well documented in E. coli; | ||
we have several options. First we are testing the repression mechanism | we have several options. First we are testing the repression mechanism | ||
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light, and strong expression in dark. <br> | light, and strong expression in dark. <br> | ||
<br> | <br> | ||
- | + | We planned our next step to swap out the pTet/TetR repression with | |
a system of CRISPR interference to block transcription initiation or | a system of CRISPR interference to block transcription initiation or | ||
elongation based on binding to the template or non-template strand of a | elongation based on binding to the template or non-template strand of a | ||
chosen sequence [9]. In our case, we would tune the sgRNA to bind to | chosen sequence [9]. In our case, we would tune the sgRNA to bind to | ||
the -35 box of our hybrid promoter in order to block transcription. The | the -35 box of our hybrid promoter in order to block transcription. The | ||
- | reason we | + | reason we wanted to use CRISPRi is because it has been shown to be |
functional in both prokaryotes and eukaryotes, although slightly more | functional in both prokaryotes and eukaryotes, although slightly more | ||
complex, this becomes a much more powerful tool once people transition | complex, this becomes a much more powerful tool once people transition | ||
- | to eukaryotic environments. | + | to eukaryotic environments. We were unable to get far enough this |
- | + | summer to transition to a CRISPR system.<br> | |
- | <br> | + | |
<br> | <br> | ||
Meanwhile, once the other half of our iGem team gets nif cluster | Meanwhile, once the other half of our iGem team gets nif cluster | ||
- | working in E. coli, we should be able to swap out the fluorescent | + | working in <span style="font-style: italic;">E. coli,</span> we should |
+ | be able to swap out the fluorescent | ||
protein for the nif cluster in our plasmid to regulate the nif cluster | protein for the nif cluster in our plasmid to regulate the nif cluster | ||
- | in E. | + | in <span style="font-style: italic;">E. coli</span> with light. In |
+ | dark conditions, the switch will be “off”, | ||
namely there should be fluorescence; and in the light, the system | namely there should be fluorescence; and in the light, the system | ||
should be repressed. We expect to see higher levels of repression with | should be repressed. We expect to see higher levels of repression with | ||
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byproduct) nitrogenase would not be produced, and therefore not wasted; | byproduct) nitrogenase would not be produced, and therefore not wasted; | ||
while during the night, nitrogen fixation can occur. This creates a | while during the night, nitrogen fixation can occur. This creates a | ||
- | temporal regulatory system | + | temporal regulatory system complementary to Cyanothece 51142’s native |
circadian regulation of controlling nitrogen fixation (through | circadian regulation of controlling nitrogen fixation (through | ||
metabolic pathways), increasing the overall chance of success.</td> | metabolic pathways), increasing the overall chance of success.</td> | ||
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src="https://static.igem.org/mediawiki/2014/7/79/WashU_Cyanothece_Light_Regulation.png"></td> | src="https://static.igem.org/mediawiki/2014/7/79/WashU_Cyanothece_Light_Regulation.png"></td> | ||
<td style="vertical-align: middle; text-align: justify;">By | <td style="vertical-align: middle; text-align: justify;">By | ||
- | integrating the light regulation from S. 6803 into E. coli, we are | + | integrating the light regulation from S. 6803 into E<span |
+ | style="font-style: italic;">. coli</span>, we are | ||
transitioning to the next step in our big picture, which would be to | transitioning to the next step in our big picture, which would be to | ||
get the system working in the cyanobacteria S. 6803. Eventually we want | get the system working in the cyanobacteria S. 6803. Eventually we want | ||
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procedures. Design primers for transcriptional units and plasmid | procedures. Design primers for transcriptional units and plasmid | ||
backbone.<br> | backbone.<br> | ||
- | Week 2-3: Test light regulation in | + | 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 | positive and negative controls as well to ensure system is working as | ||
intended with EYFP fluorescence as our gene expression.<br> | intended with EYFP fluorescence as our gene expression.<br> | ||
- | Week 4-5: Swap out basic PcpcG2 in | + | Week 4-5: Swap out basic PcpcG2 in PBJ003 with our hybrid promoter and |
test for increased Fluorescence of EYFP.<br> | test for increased Fluorescence of EYFP.<br> | ||
Week 6-8: Swap out tetR/ptet with CRISPRi mechanism with dCas9 and | Week 6-8: Swap out tetR/ptet with CRISPRi mechanism with dCas9 and | ||
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src="https://static.igem.org/mediawiki/2014/6/6d/WashU_chromophore_dark.png"> | src="https://static.igem.org/mediawiki/2014/6/6d/WashU_chromophore_dark.png"> | ||
<div style="text-align: center;">Figure above: In | <div style="text-align: center;">Figure above: In | ||
- | the dark, when promoter not active<br> | + | the dark, when promoter not active.<br> |
- | No statistical difference | + | No statistical difference w/ and w/o chromophore. Both Hybrid and |
+ | Regular systems leaky.<br> | ||
</div> | </div> | ||
</td> | </td> | ||
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style="width: 90%;" alt="Chromophore light" | style="width: 90%;" 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: In the light, when repressor | + | Figure above: In the light, when repressor isactive.<br> |
- | Some difference with aTc present. Hybrid leaky.<br> | + | Some difference with aTc present. Hybrid very leaky.<br> |
</td> | </td> | ||
</tr> | </tr> | ||
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When we compare the hybrid promoter to the normal cpcG2 promoter, it | When we compare the hybrid promoter to the normal cpcG2 promoter, it | ||
seems like there is a bigger change between dark and light in the | seems like there is a bigger change between dark and light in the | ||
- | system. In constant light, aTc is known to degrade, which | + | system. In constant light, aTc is known to degrade, which would bind up |
- | of | + | less of tetR and cause greater repression. Hence, in the light we do |
+ | not | ||
know how much of the repression is due to the strength of the promoter, | know how much of the repression is due to the strength of the promoter, | ||
or the reduction of aTc. It is apparent that the hybrid promoter is | or the reduction of aTc. It is apparent that the hybrid promoter is | ||
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very little fluorescence in the light. A comparable amount of aTc would | very little fluorescence in the light. A comparable amount of aTc would | ||
have degraded in the light of both the hybrid and normal promoter, but | have degraded in the light of both the hybrid and normal promoter, but | ||
- | it is hard to say if the difference | + | it is hard to say if the stark difference of both the Hybrid and normal |
- | have been as apparent | + | system with aTc would |
+ | have been as apparent when taking into account the degradation of aTc..<br> | ||
</td> | </td> | ||
</tr> | </tr> |
Revision as of 03:03, 18 October 2014
Using an inducible hybrid light-sensitive promoter for heterologous regulation of the nif clusterBenjamin Huang, Jeffrey Lee
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. S. 6803 has highly characterized photosynthetic genes that are light regulated, which would be useful if we want plants to eventually fix 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. We used these plasmids because they were easily available in the Moon Lab at Washington University in St. Louis, and we didn't need to get them from other labs or the registry. PBJ003 contains the basic cpcG2 promoter driving tetR production. When induced by light, the TetR generated will bind to the tet promoter which should repress eyfp 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
1. Rogers, Oldroyd. Journal of Experimental Botany March 2014 doi:10.1093/jxb/eru098 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). |