Team:Bielefeld-Germany/Results
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- | + | For further applications of the Mircobial Fuel Cell outside the lab, we designed three novel Biosafety-Systems called araCtive, TetOR alive and Lac of Growth. This Biosafety-System are successfully characterized and compared togehter, resulting in three functional Biosafety-System, who differ in leakiness of the toxic gene product and can therefore used for any desirabel application [https://2013.igem.org/Team:Bielefeld-Germany/Biosafety/Biosafety_System Read more...]</p> | |
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Revision as of 09:50, 27 October 2013
Results
MFC
After extensive optimization, we were able to build a well functioning Microbial Fuel Cell and establish a protocol for measuring the power output of our electricity generating cultures. We built a stack of five Fuel Cells which was successfully used to power different LEDs and the motor of a small fan. Furthermore, a 3D model was designed, which can be printed out using a 3D printer. This model was made available for download on our wiki, so anyone interested can build a fuel cell of their own.
Glycerol dehydrogenase
We demonstrate that engineering E. coli by introduction of the oxidoreductase glycerol dehydrogenase via gene manipulation can greatly improve the mediator production and power generation. We can show an extreme increase in the intracellular- and extracellular NADH concentration. This leads to 40 % enhanced average electric power in our Microbial Fuel Cell. The overexpression of the glycerol dehydrogenase from Escherichia coli is a great genetic optimization for electron shuttle-mediated extracellular electron transfer from bacteria to electrodes. Read more about GldA in detail.
Riboflavin
Riboflavin possesses the ability to be a potent redoxmediator. By turning the rib-gene cluster from Shewanella oneidensis into a BioBrick and subsequently cloning it into the desired chassis Escherichia coli, the iGEM Team Bielefeld was able to significantly raise the amount of riboflavin produced by E. coli.
This means that the transformation of E. coli with <bbpart>BBa_K1172303</bbpart>, respectively <bbpart>BBa_K1172306</bbpart>, represents a viable option when considering genetic optimization of microorganisms intended for usage in microbial fuel cells (MFC).
Phenazine
There are no practical results in this section. The project was left aside after unsuccessful attempts to amplify the phenazine-coding fragment from Pseudomonas fluorescens sp.
Porins
We heterologously expressed the porin protein OprF from Pseudomonas fluorescens in Escherichia coli. This leads to dramatically increased membrane permeability and a much higher current output in comparison to its parental strain (E. coli KRX) caused by improved electron shuttle-mediated extracellular electron transfer. The heterologous expression of outer membrane porin OprF from Pseudomonas fluorescens in Escherichia coli is a great genetic strategy to improve electricity generation by microorganisms. Read more in detail.
Cytochromes
We isolated the mtrCAB gene cluster from Shewanella oneidensis MR-1 and cloned it into the backbone pSB1C3, generating the BioBrick <bbpart>K1172401</bbpart>. We combined this gene cluster with three promoters and ribosome binding sites of varying strength, thus engineering the devices <bbpart>K1172403</bbpart>, <bbpart>K1172404</bbpart>, <bbpart>K1172405</bbpart>. We transformed these devices into our host organism Escherichia coli, but could not verify correct expression and localization. Read more in detail.
Nanowires
After the successful amplification of the appropriate Geobacter sulfurreducens gene clusters, the transformation of these DNA sequences into the BioBrick form via Gibson Assembly led to substantial problems. Because of this and additional issues, the nanowire project was stopped under further notice to concentrate on the other projects. Read the nanowires page.
Biosafety