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| | <h1> rMFC </h1> | | <h1> rMFC </h1> |
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| | <div class="element"> | | <div class="element"> |
| | <div id="text"> | | <div id="text"> |
| | <h6>Short summary</h6> | | <h6>Short summary</h6> |
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| | <p>In the first module we aim to identify possible mediators that are capable for electron transport. We want to | | <p>In the first module we aim to identify possible mediators that are capable for electron transport. We want to |
| | use electricity to chemically reduce these mediators and transport them into the cells. The process takes | | use electricity to chemically reduce these mediators and transport them into the cells. The process takes |
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| | mediator is that its reduction potential is high enough to restore reduction equivalents, like NAD(P)H | | mediator is that its reduction potential is high enough to restore reduction equivalents, like NAD(P)H |
| | (nicotinamide adenine dinucleotide (phosphate)). These reduction equivalents enter the respiratory chain where | | (nicotinamide adenine dinucleotide (phosphate)). These reduction equivalents enter the respiratory chain where |
| - | ATP (adenosine triphosphate) is produced which will be used in the <a href="https://2014.igem.org/Team:Bielefeld- | + | ATP (adenosine triphosphate) is produced which will be used in the <a href="https://2014.igem.org/Team:Bielefeld-CeBiTec/Project/CO2-fixation">next module.</a> |
| - | CeBiTec/Project/CO2-fixation">next module.</a>
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| - | </p> | + | <a href="https://2014.igem.org/Team:Bielefeld-CeBiTec/Results/rMFC">Here </a> you will find the results of |
| - | < p><a href="https://2014.igem.org/Team:Bielefeld-CeBiTec/Results/rMFC">Here </a> you will find the results of | + | |
| | the rMFC. | | the rMFC. |
| | </p> | | </p> |
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| | </div> | | </div> |
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| | <div class="element" style="width:150px"> | | <div class="element" style="width:150px"> |
| | <img src="https://static.igem.org/mediawiki/2014/3/35/Bielefeld_CeBiTec_2014-08-14_ecoliM1.jpg" width="150px" align="center"> | | <img src="https://static.igem.org/mediawiki/2014/3/35/Bielefeld_CeBiTec_2014-08-14_ecoliM1.jpg" width="150px" align="center"> |
| | </div> | | </div> |
| - | </center> | + | </center--> |
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| - | <div class="element" style="margin: 10px 10px 10px 10px; padding: 10px 10px 10px 10px">
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| - | <h6>Theory</h6>
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| - | <br><br>
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| - | <center><h2>Electrotrophes</h2></center>
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| - | <p>
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| - | There are several approaches to feed microorganisms with electrons in order to support microbial
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| - | respiration. One promising feasibility is the direct transfer of electrons to microorganisms. Bacteria that
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| - | can directly accept electrons from electrodes for the reduction of terminal electron acceptors are called
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| - | electrotrophes or electrode oxidizing bacteria.
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| - | The possibility of electron transfer to microorganisms was investigated for the first time by studies with
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| - | <i>Geobacter</i> species. (<a href="#lovley2011">Lovley, Derek R., 2011</a>) <br>
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| - | Normally the production of multi-carbon organic products relies on organic feedstocks (biomass) as electron
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| - | donor. The use of biomass has the disadvantages that biomass production competes with food production and
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| - | that the costs for the required carbon source are a major factor if a production process is profitable or not.
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| - | That is why the possibility of powering microbial processes with electricity is very attractive.
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| - | (<a href="#lovley2013">Lovley, Derek R. & Nevin, Kelly P. 2013</a>) <br>
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| - | Microorganisms can be provided with electrons via two major principles: Direct- and indirect electron
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| - | transfer.
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| - | <br><br>
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| - | <center><h2>Indirect electron transfer</h2></center>
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| - | </p>
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| - | <br><br>
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| - | <center><h2>Direct electron transfer</h2></center>
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| - | <p>
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| - | </p>
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| - | <h6>Design of a electrobiochemical reactor system</h6>
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| - | <p>To perform our cultivation experiments under well defined conditions it was necessary to design a new
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| - | bioreactor system. Besides the typically controlled parameters in bioreactors like the oxygen partial pressure, pH-signal, temperature and other parameters, it was indispensable to have the possibility to energize the reactor with a defined current. That is why we decided to build an H-cell reactor. This kind of reactor consits of two compartments which are connected by a glass flange. It is possible to fix a membrane in the middle of the flange connection so that the two compartments are seperated. We used a cation selective Nafion® membrane which allowed the divison of the two compartments into an anode and cathode space. <br>
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| - | Figure 1 shows schematically the layout of our design.
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| - | <img src="https://static.igem.org/mediawiki/2014/4/41/Bielefeld_CeBiTec_2014-10-05_Reaktor_Aufbau_klein.png" width="300px" align="center">
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| - | The H-cell reactor could be used for batch fermentations and is constructed for the electron transfer via a mediator.<br>
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| - | That is why we considered an alternative reactor design. The other reactor concept is named "scalable flow cell reactor" (SFC) and allows an continous mode of operation. In this reactor type the electron transfer must be realized by direct electron transfer. That is possible if the cells stay in direct contact to the electrode material. The electron transfer is carried out by cytochromes in the outer membrane. That is why we focused on different types of mediators and the expression of key type cytochromes. The Layout of the SFC is shown in Figure 2.
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| - | <img src="https://static.igem.org/mediawiki/2014/f/f0/Bielefeld-CeBiTec_2014-08-31_Fig._10_-_kontinuierlicher_Fermenter.png" width="300px" align="center">
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| - | </div>
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| - | </center>
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| - | <h6>Measurement system</h6>
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| - | <p>
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| - | For the investigation of electroactive microorganisms highly sensitive analytics are required. That is why we use a Potentiostat which allows it to set and hold a defined electrode potential. Furthermore we tried out different media and buffer compositions and observed the effect of different electrode materials on the mediator oxidation and reduction peaks. <br>
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| - | <h6>Mediators</h6>
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| - | <br><br>
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| - | <center><h2>Neutral red</h2></center>
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| - | <p> Neutral red is a phenazine-based dye which has an suitable redox-potential to function as an electron-shuttle from the electrode to the cells.
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| - | <br><br>
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| - | <center><h2>Bromphenol blue</h2></center>
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| - | Bromphenolblue is a triarylmethane dye that is similar to neutral red and also capable to function as mediator.
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| - | <br><br><br>
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| - | <center><h2>Cytochromes</h2></center>
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| - | Cytochromes are proteins containing a heme group. They are primarly responsible for the electron transport in the respiratory chain.
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| - | <h6>Cultivation conditions</h6>
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| - | <p> For each compartment of the H-cell reactor (cathode and anode space) were used different media and buffers.
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| - | <h6>Genetical approach</h6>
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| - | <p> Altering the metabolic pathway of fumarate by knocking out the fumarate antiporter DcuB in <i>E. coli</i> and manipulating different fumarate reductases.
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| - | <center>
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| - | <div class="element" style="width:300px">
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| - | <img src="https://static.igem.org/mediawiki/2014/d/d0/Bielefeld-CeBiTec_2014-10-12_Mediator_Cytochrome.png" width="600px" align="center">
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| - | </div>
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| - | <img src="https://static.igem.org/mediawiki/2014/8/84/Bielefeld-CeBiTec_2014-10-12_respiratory_chain.png" width="600px" align="center">
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| - | </div>
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| - | </center>
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| - | <br><br>
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| - | <center><h2>Fumarate Reductase</h2></center>
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| - | We expressed the fumarate reductase (frd) from Escherichia coli under controll of the T7 promotor in different E. coli strains.
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| - | This enzyme is located in the inner membrane and leads to an increased succinat production in the cell.
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| - | The fumarate reductase can serve as e key enzyme in electron transfer into the cell and use the reduced mediator as electron donor.
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| - | <br>
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| - | Overview:
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| - | <br>
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| - | Fumarate reductase is part of the anaerobic fumarate respiration in E. coli. The related enzyme in aerobic respiration is succinate dehydrogenase, which catalyse the reaction from succinat to fumarate.
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| - | The electrons were transferred from succinate to FADH2 producing fumarate. Succinat dehydrogenase is also a membrane enzyme and it is part of the citric cycle.
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| - | Fumarate reductase catalyses the reverse reaction of succinate dehydrogenase. Electrons were transferred under anaerobic conditions from FADH2 to fumarate. Succinate is secreted into the media to take electrons out of the cell.
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| - | In our project we use fumarate reductase in combination with an extracellular mediator as electron donor to transfer electrons into bacterial cells. The reduced mediator cross the outer membrane of E. coli through outer membrane porine OprF (BBa_K1172507).
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| - | Mediators diffuse into inner membrane and transfer electrons to fumarate reductase. After that the reduced fumarate reductase transfer electrons to fumarate producing succinate.
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| - | Succinate can serve as substrate for succinate dehydrogenase, which catalyzes oxidation of succinate into fumarate again. So we create a loop in the citric cycle between fumarate and succinate generating FADH2 as reductive power in the cell.
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| - | Electrons are transferred to FAD+, which generate proton translocation from cytosol into the periplasmatic space. The proton motoric force achieve ATP production.
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| - | So mediator-dependent activity of fumarate reductase serve as energy source for bacterial cells.
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| - | <h6>Outlook</h6>
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| - | <p> Up-scaling/ alternative electrode material etc.
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| | Qiao, Yan; Bao, Shu-Juan; Li, Chang Ming (2010): Electrocatalysis in microbial fuel cells—from electrode material to direct electrochemistry. In: <a href="http://pubs.rsc.org/en/Content/ArticleLanding/2010/EE/b923503e#!divAbstract" | | Qiao, Yan; Bao, Shu-Juan; Li, Chang Ming (2010): Electrocatalysis in microbial fuel cells—from electrode material to direct electrochemistry. In: <a href="http://pubs.rsc.org/en/Content/ArticleLanding/2010/EE/b923503e#!divAbstract" |
| | target="_blank">Energy Environ. Sci.</a>, 3 (5), pp. 544. | | target="_blank">Energy Environ. Sci.</a>, 3 (5), pp. 544. |
| | + | </div> |
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| | + | <li id="harnisch2012"> |
| | + | <div class="element" style="margin_10px 10px 10px 10px; padding:10px 10px 10px 10px"> |
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| | + | Harnisch, F. & Freguia, S., 2012. A Basic Tutorial on Cyclic Voltammetry for the investigation of Electroactive Microbial Biofilms. |
| | + | In: <a href="http://www.ncbi.nlm.nih.gov/pubmed/22279004" |
| | + | target="_blank">Chemistry – An Asian Journal</a>, 7 (3), pp. 466–475. |
| | </div> | | </div> |
| | </div> | | </div> |
| | </li> | | </li> |
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| | </ul> | | </ul> |
| | </div> | | </div> |
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