Team:Peking/DataPage
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<h3 id=”tilte4”>Data for pre-existing parts</h3> | <h3 id=”tilte4”>Data for pre-existing parts</h3> | ||
- | <p><b>luxbrick (<a href="http://partsregistry.org/Part:BBa_K325909">Main Page-BBa_K325909</a>)</b> <br/>luxbrick is a bacteria luciferase part constructed by Cambridge 2010 iGEM team. They successfully expressed bacteria luciferase in E.coli, which could produce blue light under L-arabinose induction, and they carefully characterized this part. But because there are data we need while they didn’t give, we made the following supplementary characterization.<br/><br/>The spectrum of the light emitted from E.coli harboring luxbrick was measured and it showed a maximum intensity at 485nm.</p> | + | <p><b>luxbrick (<a href="http://partsregistry.org/Part:BBa_K325909">Main Page-BBa_K325909</a>)</b> <br/>luxbrick is a bacteria luciferase part constructed by Cambridge 2010 iGEM team. They successfully expressed bacteria luciferase in E.coli, which could produce blue light under L-arabinose induction, and they carefully characterized this part. But because there are data we need while they didn’t give, we made the following supplementary characterization.<br /><br />The supplementary characterization and our application of luxbrick part were added to the experience page of this part (see <a href="http://partsregistry.org/Part:BBa_K325909:Experience">Experience-BBa_K325909</a>)<br /><br />The spectrum of the light emitted from E.coli harboring luxbrick was measured and it showed a maximum intensity at 485nm.</p> |
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<img src="/wiki/images/c/c3/Peking2012_light_communication_3.png" alt="Figure 1" /> | <img src="/wiki/images/c/c3/Peking2012_light_communication_3.png" alt="Figure 1" /> |
Revision as of 05:50, 26 September 2012
How Our System Works
Figure 1. Illustration of the function mechanism of our luminesensor. When exposed to blue light, the N-terminal cap of VVD domain will undock and cause VVD domain to dimerize. The dimerization of VVD protein will help the dimerization of N-terminal domains of LexA protien fused to the N-terminal of VVD domain. When helped to dimerize, the NTD of LexA protein will recognize and bind to the SOS box in the promoter of our reporter gene and inhibit transcription initiation.
Data for favorite parts
Optimized Luminesensor(Main Page-BBa_K819005) A fusion protein consisting of an E.coli endogenous SOS system repressor LexA, carrying mutations at positions 40-42, and fungus N. crass photosensor protein VVD, carrying mutations N56K, C71V and I135M. This ultra-sensitive Luminesensor functions as a transcription repressor in response to blue light. And since we have introduced mutations into LexA DNA binding domain, the Luminesensor proved orthogonal to host genetic context. Futher introduced mutations in VVD photosensitive domain significantly improved the dynamic range of our optogenetic module.
Testing device for Luminesensor (Main Page-BBa_K819006) and measurement device for Luminesensor (Main Page-BBa_K819007) a fast degrading GFP ligated to the downstream of SulA408 promoter and RecA408 promoter, respectively. These two parts work independently of the host genetic context.
Data for optimized parts
Fig 2. BL21 cells harboring T7-lux operon(BBa_K819008) are emitting blue luminescence under IPTG induction at 5*10-5M
Lux Operon under T7 promoter (Main Page-BBa_K819008)
We successfully improved the easy-of-use of “lux brick” (BBa_K325909) part constructed by Cambridge 2010 iGEM team by placing the coding sequence of luxbrick (luxCDABEG) and related RBS under T7 promoter (BBa_I712074).
Luxbrick under T7 promoter is more modular because it is transcribed by T7 polymerase, which can be placed under any other promoter, forming an interface between luxbrick and other systems, and thus making it more convenient to use luxbrick in complex systems.
Data for other submitted parts
Luminesensor repressible SulA408 promoter (Main Page-BBa_K819017), Luminesensor repressible RecA408 promoter (Main Page-BBa_K819002)
These are the two promoters used in this year’s project to test the functionality of our optimized Luminesensor and measure the efficiency of the Luminesensor.
Weak CheZ generator (Main Page-BBa_K819009), medium CheZ generator (Main Page-BBa_K819010)
Chemotaxis protein CheZ ligated to three constitutive promoters with varying strengths. These two parts express the CheZ protein in varied quantities, which corresponds to the different levels of induced mobility in the ΔCheZ E.coli strain.
Luminesensor repressible RecA408 promoter (Main Page-BBa_K819015), Luminesensor repressible SulA408 promoter (Main Page-BBa_K819016)
Chemotaxis protein CheZ ligated to Luminesensor repressible SulA408 promoter and RecA408 promoter, respectively. Presumably these two parts can would the chemotaxis pathway of E.coli into a phototaxis system by regulating the expression level of CheZ in ΔCheZ strain in response to blue light.
Luminesensor repressible LacIM generator (Main Page-BBa_K819012)
Coding sequence of LacI mutant protein driven by the Luminesensor repressible SulA408 promoter (BBa_K819017).
Data for pre-existing parts
luxbrick (Main Page-BBa_K325909)
luxbrick is a bacteria luciferase part constructed by Cambridge 2010 iGEM team. They successfully expressed bacteria luciferase in E.coli, which could produce blue light under L-arabinose induction, and they carefully characterized this part. But because there are data we need while they didn’t give, we made the following supplementary characterization.
The supplementary characterization and our application of luxbrick part were added to the experience page of this part (see Experience-BBa_K325909)
The spectrum of the light emitted from E.coli harboring luxbrick was measured and it showed a maximum intensity at 485nm.
Figure 1. TOP10 cells harboring the luxbrick were cultured in LB medium and induced with L-arabinose at 10-3M. 10 hours after induction, the glowing cells were measured for spectrum using SHIMADZU RF5301PC Spectrofluorophotometer.
The time course of luxbrick expression and blue light emission under L-arabinose induction was given in a more visualized way, which is a short movie. As shown in the movie, the cells transformed with luxbrick begin to glow 9 hours after induction, and the entire visible glowing process lasts about 10 hours.
if you can not view this video,please click HERE.
Movie1. the time course of our light emitting cell