Team:Bielefeld-CeBiTec/Project/rMFC/GeneticalApproach
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rMFC
Genetical approach
Altering the metabolic pathway of fumarate by knocking out the fumarate antiporter DcuB in E. coli and manipulating different fumarate reductases.
Figure 1: The electron flow mediated by redox active molecules.
Figure 1: The electron flow in the respiratory chain.
Fumarate Reductase
Overview:
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. 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. 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. 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). Mediators diffuse into inner membrane and transfer electrons to fumarate reductase. After that the reduced fumarate reductase transfer electrons to fumarate producing succinate. 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. Electrons are transferred to FAD+, which generate proton translocation from cytosol into the periplasmatic space. The proton motoric force achieve ATP production. So mediator-dependent activity of fumarate reductase serve as energy source for bacterial cells.